MECHANISM OF A1NTIMALARIAL ACTION OF DESFERRIOXAMINE B A Thesis Presented to the Board of Graduate Studies of the University of Ghana, Legon, in Partial Fulfillment of the Requirement for the Degree of Master Of Philosophy (M.Pbil.) in Biochemistry ROBERT Nil AYITEY ARYEE DEPARTMENT OF BIOCHEMISTRY UNIVERSITY OF GHANA LEGON JANUARY 2000 University of Ghana http://ugspace.ug.edu.gh { X 3 8 3 3 S 0 R M £ > 6 6 ' - t ) Z 7 A T t u t i Q s> e> \ University of Ghana http://ugspace.ug.edu.gh DECLARATION I declare that except for references to other people’s work, which have been duly acknowledged, this study is a result of my own research. I certify in addition that this thesis, either in whole or in part has not been previously presented for any degree and is not being concurrently submitted in candidature for any other degree. ROBERT Nil AYITEY ARYEE (Researcher) Dr. JONATHAN P. a'd JIMANI (Supervisor) (Supervisor) University of Ghana http://ugspace.ug.edu.gh I wish to express my sincere thanks to my supervisors Dr. J. P. Adjimani of the Department of Biochemistry, University of Ghana and Dr. G. E. Armah, Head of the Electron Microscopy and Histopathology Unit of the Noguchi Memorial Institute for Medical Research (NMIMR) of the University of Ghana, Legon for their patience and direction My gratitude also goes to Messrs. Ben Gyang, Michael Ofori and Prince Hodo all of the Immunology Unit of the NMIMR for their help and support. I also wish to express my appreciation to Mr. B. K. Asiedu of the Haematology Unit of the NMIMR I express my appreciation to the staff of the Electron Microscopy and Histopathology Unit of the NMIMR Messrs. Alexander Ayim, S. Y. Amelor, Alfred K. Dodoo, Isaac Odoi and Harry Asmah and also to Mrs. Suzie Damanka. My thanks also go to Messrs. Dramani and Bosompem, Miss Doris Amanor, Miss Christiana Nettey and Miss Harriet Antwi-Boasiako all of the Department of Biochemistry, University o f Ghana, Legon I also acknowledge all those whose names are too numerous to mention here but whose contribution have been immense. May God bountifully bless you all. Finally, I wish to acknowledge THE SHELL FOUNDATION whose fellowship made it possible for me to complete the course successfully. Thank you Jesus. ACKNOWLEDGMENTS University of Ghana http://ugspace.ug.edu.gh Dedicated to my family, Auntie, Doris, Jeff, Suzie, Sue and Aunt £melia. University of Ghana http://ugspace.ug.edu.gh TABLE OF CONTENTS TITLE i* AGE ............ ............................................................................ 1 DECLARATION......................................................................................................................................... ill ACKNOWLEDGEMENTS — --------- iv DEDICATION............................................................................................................................................. v TABLE OF CONTENTS™ ..... - ---------- vi LIST OF TABLES...................................................................................................................................... ix LIST OF FIGURES-------------------------------------------------------------------------------------------- x LIST OF ABBREVIATIONS................................................................................................................... xii ABSTRACT._________________________ xiii CHAPTER 1 INTRODUCTION AND LITERATURE REVIEW......................................................... 1 INTRODUCTION.___________________________ 1 JUSTIFICATION....................................................................................................................................... 4 MAIN OBJECTIVES OF STUDY. .......................... 5 LITERATURE REVIEW............................................................................................................... 6 MALARIA: THE CAUSATIVE ORGANISM............................................................................................. 6 MODE OF TRANSMISSION.......................................................................................................................7 THE ARTHROPOD HOST........................................................................................................................... 7 LIFE-CYCLE OF THE MALARIA PARASITE...........................................................................................8 Asexual cycle.................................................................................................................................................8 Sexual cycle...................................................................................................................................................9 BIOCHEMISTRY OF THE PARASITE......................................................................................................10 Nucleic acid synthesis..................................................................................................................................10 Folate synthesis..................................................................................... j j University of Ghana http://ugspace.ug.edu.gh Breakdown of hemoglobin and metabolism of amino acids........................................................................12 DIAGNOSIS............................................................................................................................................... 16 TREATMENT.............................................................................................................................................16 BIOCLASSIFICATION OF ANTIMALARIAL AGENTS........................................................................ 16 CLASSIFICATION OF ANTIMALARIALS BASED ON THEIR CHEMICAL STRUCTURE...............18 MODE OF ACTION OF COMMON ANTIMALARIALS.......................................................................25 Dihydrofolate reductase inhibitors.............................................................................................................25 Dihydropteroate synthase inhibitors........................... :.............................................................................. 26 Heme polymerase inhibitors.................... ................................................................................................... 27 MALARIA CONTROL..............................................................................................................................27 Blocking mail-vector contact..................................................................................................................... 28 Insecticide spraying. ......... ......................................................................................................................28 Removal of breeding sites.......................................................................................................................... 29 Larviciding............................................... ,.............................................. 29 Biological control..................................................... .................................................................................. 29 DRUG RESISTANCE IN MALARIA PARASITES................................................................................. 30 Mechanisms of resistance...........................................................................................................................30 Control of resistance...................................................................................................................................31 SIDEROFHORES.......................................................................................................................................33 Strnctoral featnres...................................................................................................................................... 33 DESFERRIOXAMINE B............................................................................................................................35 CHAPTER 2: MATERIALS AND METHODS.................................................................................... 39 MATERIALS._____________________________________ _______ _______________________39 METHOD..................................................................................................................................................40 IN VIVO EXPERIMENTS.........................................................................................................................40 IN VITRO EXPERIMENTS....................................................................................................................... 43 INHIBITION OF HEME POLYMERISATION.........................................................................................43 University of Ghana http://ugspace.ug.edu.gh SPECTROSCOPIC DETERMINATION OF BINDING............................................................................ 45 STATISTICAL ANALYSIS........................................................................................................................45 CHAPTER 3: RESULTS----------------------------------------------------------------------------------------- 46 HEMATOLOGICAL EXPERIMENTS___________________________________________________ 46 INHIBITION OF HEME POLYMERIZATION.___________________________________________ 59 SPECTROSCOPY............................................................................................................................................64 CHAPTER 4: DISCUSSION AND CONCLUSIONS_________________________________________69 DISCUSSION................................- .......................................... 69 CONCLUSIONS__________________________________________________ 79 RECOMMENDATIONS FOR FURTHER W ORK............................................................... 79 REFERENCES.---------------------------------------------------------------------------------------------------- 80 APPENDICES .................................................................................................................. 87 APPENDIX A..............................................................................................................................................87 APPENDIX B.............................................................................................................................................. 88 APPENDIX C. 92 University of Ghana http://ugspace.ug.edu.gh LIST OF TABLES T a b l e 3 -1 : G r o w t h O f Pl a s m o d iu m b e r g h e ia n k a i n C h l o r o q u i n e T r e a t e d M ic e C o m p a re d t o D e s f e r r io x a m in e B T r e a t e d M ic e ................................................................................................................................... 50 T a b le 3 -2 : E x t e n t o f I n h ib i t i o n o f H em e P o l y m e r i s a t i o n b y t h e V a r io u s C o m p o u n d s T e s t e d .........60 Ta b l e 3 -3 . S t a t is t ic a l C o m p a r is o n in P e r c e n t a g e In h ib it io n o f H e m e P o l y m e r is a t io n P r o d u c e d Ch l o r o q u in e , C it r a t e a n d D e s f e r r io x a m in e B ...................................................................................................... 61 T a b l e 3 -4 : In h ib it io n o f H e m e P o l y m e r is a t io n P r o d u c e d b y M o n o d e n t a t e Ir o n C h e l a t o r s ............62 T a b l e 3 -5 : W a v e l e n g t h s o f M a x im u m A b s o r p t io n E x h ib it e d b y H e m a t in . D e s f e r r io x a m in e B , C h l o r o q u in e a n d t h e ir C o m b in a t io n s f r o m t h e U V -V is ib l e s p e c t r a ......................................................63 T a b l e 3 -6 : P ea k s A s s ig n m e n t s in t h e In f r a r e d Sp e c t r u m o f H e m a t in ............................................................... 6 6 T a b le B - l : G r o w t h P a t t e r n o f Pl a sm o d iu m B e r g h e iA n k a i n C B A M ic e T r e a t e d w i t h D e s f e r r io x a m in e B C o m p a r e d t o C o n t r o l M ic e G iv e n P h o s p h a t e B u f f e r e d S a l in e .....................88 T a b le B -2 : G r o w t h P a t t e r n o f Pl a s m o d iu m B e r g h e iA n k a in C h l o r o q u i n e - T r e a t e d CBA M ic e C o m p a re d t o C o n t r o l M ic e G iv e n P h o s p h a t e B u f f e r e d S a l i n e .................................................................. 89 T a b le B -3 : G r o w t h O f Pl a s m o d iu m B e r g h e iA m a in C h l o r o q u i n e T r e a t e d M ic e C o m p a re d D ir e c t l y t o D e s f e r r io x a m in e B T r e a t e d M ic e .......................................................................................................90 T a b le B-4: G r o w t h Of Pl a s m o d iu m be r g h e ia n k a i n C h l o r o q u i n e T r e a t e d M ic e C o m p a re d t o D e sf e r r io x a m in e B T r e a t e d M ic e ....................................................................................................................................91 TABLE C-l: HEMATIN CALIBRATION CURVE.........................................................................................................................................................92 TABLE C-2: ABSORBANCES AND THE CORRESPONDING HEMATIN CONCENTRATIONS IN THE HEME POLYMERISATUN INHIBITION ASSAY.................................................................................................................................................92 ix University of Ghana http://ugspace.ug.edu.gh LIST OF FIGURES F ig u r e 1-1: L if e c y c l e o f t h e m a l a r ia p a r a s it e ................................................................................................................ 10 F ig u r e 1-2: St r u c t u r e o f D e h y d r o f o l ic A c id ......................................................................................................................12 F ig u r e 1-3 : St r u c t u r e o f H e m o z o in ...........................................................................................................................................15 F ig u r e 1-4: St r u c t u r e s o f So m e 4 -a m in o q u in o l in e s ....................................................................................................... 18 F ig u r e 1-5: A n 8 -A m in o q u in o l in e ............................................................................................................................................... 19 F ig u r e 1-6: A n e x a m p l e o f 9 -a m in o q u in o l in e ......................................................................................................................20 F ig u r e 1-7: A C in c h o n a a l k a l o id ............................................................................................................................................... 20 F ig u r e 1-8: St r u c t u r e s o f s o m e s e s q u it e r p e n e s ................................................................................................................21 F ig u r e 1-9: A Su l p h o n e ..................................................................................................................................................................... 22 F ig u r e 1-10: St r u c t u r e o f s o m e Su l e h o n a m id e s ...............................................................................................................23 F ig u r e 1-11: St r u c t u r e o f s o m e D l m n o p y r im id i n e s ...................................................................................................2 4 F ig u r e 1-12: P r o g u a n il a n d C y c l o g u a n il ............................................................................................................................ 24 F ig u r e 1-13: St r u c t u r e o f A P h e n a n t h r e n e M e t h a n o l ............................................................................................. 25 F ig u r e 1-14: F o r m a t io n o f D ih y d r o f t e r o ic A c id ........................................................................................................... 2 6 F ig u r e 1-15: T h e t w o m a in c h e l a t in g g r o u p s u s e d b y s id e r o p h o r e s ................................................................... 33 F ig u r e 1-16: A n e x a m p l e o f a c a t e c h o l a t e s id e r o p h o r e .............................................................................................34 F ig u r e 1-17: So m e h y d r o x a m a t e s id e r o ih o r e s ................................................................................................................. 35 F ig u r e 1-18: St r u c t u r e o f d e s f e r r io x a m in e B ...................................................................................................................35 F ig u r e 1-19: St r u c t u r e o f F h {r io x a m in e B .......................................................................................................................... 37 F ig u r e 2 -1 : F l o w d ia g r a m s h o w in g t h e s e q u e n c e o f e v e n t s in t h e h e m a t in p o l y m e r is a t io n e x p e r im e n t s ....................................................................................................................................................................................44 F ig u r e 3 -1 : G r o w t h p a t t e r n o f P . b . a n k a in C B A m ic e .................................................................................................47 F ig u r e 3 -2 : E F F E C T O F d e s f e r r io x a m in e B a n d c h l o r o q u in e o n Pl a s m o d iu m b e r g h e i a n k a g r o w t h in c b a m ic e . Pe r ip h e r a l p a r a s it e C O U N T S in m ic e t r e a t e d w it h O F d e s f e r r io x a m in e B a n d c h l o r o q u in e c o m p a r e d t o u n t r e a t e d c o n t r o l s g iv e n o n l y p h o s p h a t e b u f f e r e d s a l in e ............48 X University of Ghana http://ugspace.ug.edu.gh F ig u r e 3-3: P e r i p h e r a l p a r a s i t e c o u n t in m ic e t r e a t e d w i t h a c o m b in a t io n o f c h l o r o q u i n e a n d d e s f e r r io x a m in e c o m p a r e d t o d e s f e r r i o x a m i n e - t r e a t e d a n d p h o s p h a te b u f f e r e d s a l i n e - t r e a t e d c o n t r o l s .......................................................................................................................................................................51 F ig u r e 3 -4 : C o m p a r is o n o f t h e e f f e c t o f d e s f e r r i o x a m i n e a n d c h l o r o q u i n e t o e x t r a c t s o f t h e c o m m o n ly u s e d h e r b s M o r in d a l u c id a a n d Ca s s ia s ia m e a (CRQ) o n t h e g r o w t h o f m a l a r i a p a r a s i t e s in C B A m ic e .............................................................................................................................................................. 52 F ig u r e 3 -5 : N o n - in f e c t e d r e d b l o o d c e l l s c o m p a r e d t o in f e c t e d r e d c e l l s ......................................... 53 F ig u r e 3 -6 : U l t r a s t r u c t u r a l c h a n g e s o b s e r v e d a f t e r d r u g t r e a t m e n t ........................................................ 57 F ig u r e 3-7: H e m a t in s t a n d a r d c u r v e ................................................................................................................... 59 F ig u r e 3 -8 : E l e c t r o n i c a b s o r p t i o n s p e c t r a o f h e m a t in , d e s f e r r i o x a m i n e B a n d a c o m b in a t io n o f t h e t w o ............................................................................................................................................................................................. 64 F ig u r e 3-9: E l e c t r o n ic a b s o r p t io n s p e c t r a o f h e m a t in a n d a c o m b in a t io n o f h e m a t in a n d c h l o r o q u in e .................................................................................................................................................................................. 65 F ig u r e 3 -10 : In f r a r h ) s p e c t r a o f h e m a t in a l o n e , d e s f e r r io x a m in e a l o n e a n d a c o m b in a t io n o f d e sf e r r io x a m in e a n d c h l o r o q u in e ................................................................................................................................. 68 F ig u r e 4 -1 : H e m a t in in b a s ic m e d iu m ........................................................................................................................................ 7 6 University of Ghana http://ugspace.ug.edu.gh LEST OF ABBREVIATIONS. Abs absolute value CHQ chloroquine CRQ Cassia siamea DF desferrioxamine B Grp group IR infra red [x] absolute value of x. Val value PBS phosphate-buffered saline BHA benzohydroxamic acid. RA rhodotorulic acid AHA acetohydroxamic acid T time Hrs hours xii University of Ghana http://ugspace.ug.edu.gh ABSTRACT. Desferrioxamine B was shown to exhibit potent antimalaria activity. A single bolus injection of lOOmg o f desferrioxamine B per kilogram body weight of mice reduced Plasmodium berghei anka parasitemia in CBA mice for 24 hours. Peripheral blood samples of desferrioxamine B-treated mice taken at 0, 3, 6, 12, 24 and 48 hours after drug administration show gross adverse ultrastructural changes in all developmental stages of the malaria parasite (trophozoites, schizonts and gametocytes) and a reduction in parasite numbers. The iron chelator was also found to function as an inhibitor of heme polymerisation by binding to and immobilising the central ferric ion of parasite-associated heme and hence disrupting heme detoxification into hemozoin It was concluded that desferrioxamine B is active against Plasmodium berghei anka and that iron chelation provides a new possible alternate strategy for the treatment o f malaria. xiii University of Ghana http://ugspace.ug.edu.gh CHAPTER 1 INTRODUCTION AND LITERATURE REVIEW. INTRODUCTION. Malaria is unquestionably an important protozoan disease with a world wide high level of mortality and morbidity. It has been estimated that about two billion people live in areas exposed to malaria and 300 million individuals are infected every year (WHO, 1997). The transmission of malaria has increased in recent years in most countries and has re- emerged in countries where it was once eradicated or controlled (McNeely et al, 1998; Bruce-Chwatt, 1980). In Africa, south of the Sahara alone, over one million children die annually as a result of the disease (Kondrachine, 1997). Children, pregnant women and I the immunologically naive are the most vulnerable making the disease a major public health problem, which must be addressed. Malaria chemotherapy has come a long way since 1820 when quinine was first isolated from bark of the cinchona tree. la the eighteenth and nineteenth centuries, high and uncontrolled exploitation led to reduced natural and commercial plantation sources of the bark. There was also a threat to supplies of this useful drag during the First World War. These factors together with the high toxicity of quinine, led to intensive efforts to find synthetic replacements. This was accomplished in 1824 with the discovery of Pamaquine and later Mepacrine. Unfortunately, these drugs have also been found to be toxic and furthermore large doses are required to be effective. Therefore, they did not meet the requirements of being less toxic, fast-acting, and effective at lower concentrations. University of Ghana http://ugspace.ug.edu.gh The new class of antimalarials following these satisfied these, conditions. These include the dihydrofolate reductase inhibitors, proguanil and pyrimethamine, and new quinoline containing drugs such as primaquine and chloroquine. Following its release, chloroquine became the drug of choice for the treatment of malaria and together with proguanil and pyrimethamine became the major drugs for prophylaxis. Primaquine was used solely for radical cure of infections with relapsing malarias caused by P. malariae, P. ovale and P. vivax (Wemsdorfer, 1981). This happy state of affairs was not to last long with the emergence and rapid spread of I parasite strains resistant to proguanil and pyrimethamine (Peterson et al, 1990; Wemsdorfer, 1981). This was followed shortly by the ■ appearance of chloroquine resistant parasite species in East Africa (Brace-Chwatt, 1980), South East Asia and Latin America (WHO, 1984; Nguyen-Dinh, 1978), gradually spreading globally. Strains resistant to combinations of these drugs have also been identified in East Asia and Africa (Desjardines et al, 1979; Peterson et al, 1990). The appearance and rapid spread of these resistant species has resulted in a global increase in the incidence and transmission of malaria. This worldwide resurgence of malaria underscore the urgent need for new and more effective therapeutic agents. It is therefore gratifying to note that siderophores such as Desferrioxamine B, have been found to have anti-malaria activity (Gordeuk et al, 1993; Hershko et al, 1992; Scott el al, 1990) and rfiay be of clinical significance in the treatment of malaria (Scheibel and Adler, 1980). 2 University of Ghana http://ugspace.ug.edu.gh Siderophores are low molecular weight iron chelating substances, that are excreted by aerobic fungi and bacteria in iron limiting environments (Hershko et al, 1992; Raymond et al, 1984; Cotton et al, 1980). Iron is required in virtually all living organisms, for a wide variety of metabolic processes such as DNA replication and cell division (Weinberg, 1974). However, ferric iron at physiological pH is insoluble due to the formation of ferric hydroxide. Microorganisms, in a bid to acquire this critically important element, have evolved Siderophores. They are produced by these organisms and excreted into the external environment to solubilise and assimilate iron. Iron chelators have a high and low affinity for ferric and ferrous iron respectively. They also have a low affinity for other metal ions. This selective affinity for ferric iron may have an important role in the use of iron chelators as antimalarials. Several different iron chelators have been identified (Raymond et al, 1984; Neilands and Ratledge, 1980). However, the iron-chelating drug Desferrioxamine B is the only iron chelator presently available for clinical use. It has been used for over three decades as an essential drug for the management of transfusional iron overload (Hershko, 1992) and also for the removal of iron from the body upon acute iron poisoning (Raymond et c, 1984; Anderson, 1981). However, its potential as an antimalaria agent has just begun to emerge. Murray et al, (1980) noted that in areas of hyperendemic P. falciparum infections, patients with clinical iron deficiency exhibited an attenuated incidence and severity of the disease. When such patients were fed an iron-replete diet, many exhibited sudden recrudescence of previously smouldering malaria infections. Laboratory observations also showed that several iron-binding substances including desferrioxamine 3 University of Ghana http://ugspace.ug.edu.gh B, desferrithiocin, lactoferrin and desferricrocin block the replication of P. falciparum and other malaria parasite strains in vitro (Hepner et al, 1988). As a potential drug in the treatment of malaria, the mechanism of action of siderophores, including desferrioxamine B, at the cellular level is unclear (Scott et al, 1990). They have been reported to function by chelating iron from a “pool” in the parasites’ compartment, rather than the chelation of intra- or extra-erythrocytic iron (Scott et al, 1990). However, the nature of the chelatable iron is not clear (Scott et al, 1990; Hepner et al, 1988). It has been suggested however that, the iron in this pool could be from hemoglobin (Scott et al, 1990). This suggests that iron chelators may work by binding to the iron atom in hemoglobin or by binding to the iron atom in hemozoin. The net result in either case is the prevention of the extension and formation of hemozoin thereby interfering with heme polymerisation, leading to the accumulation o f heme which is toxic to the parasite. JUSTIFICATION. This study involves the use of murine models to determine the mode of action of desferrioxamine B in treatment and prophylaxis of malaria. A detailed understanding of the mechanism of action of siderophore mediated antimalaria activity would facilitate the design of new drugs for better management of malaria. I 4 University of Ghana http://ugspace.ug.edu.gh MAIN OBJECTIVES OF STUDY. a) To investigate the effect of desferrioxamine B on Plasmodium berghei anka growth in CBA mice, b) To determine whether the anti-malarial properties of desferrioxamine B is due to its inhibition of heme polymerisation. c) To determine whether this inhibition is as a result of binding of desferrioxamine B to the heme iron present in hematin and P-hematin. d) To determine any structural changes in the parasite as observed under light microscopy. 5 University of Ghana http://ugspace.ug.edu.gh LITERATURE REVIEW MALARIA: THE CAUSATIVE ORGANISM. Malaria is caused by the intracellular microorganism belonging to the phylum Protozoa, subphylum Sporozoa, class Telesporida and of subclass Cocidiomorpha. These parasites are of the family Plasmodidae and genus Plasmodium (Wernsdorfer, 1980) There are over one hundred species of malaria parasites infecting a wide spectrum of vertebrate host species among which birds and mammals are The most widely infected. Malaria parasites vary greatly in host specificity, pattern of growth and pathogenicity. For example, P. rodhaini is specific for apes and gorillas, P berghei, P. yoelii and P. vinckei are found to infect rodents. The owl monkey can be infected by human malaria parasites. Human malaria. Four species of malaria parasites are recognised as responsible for causing the disease in I man. These are P. malariae which causes mild quartan malaria with a schizogonic periodicity of 72 hours, P vivax causes benign tertian malaria of 48 hour periodicity, P. ovale; causes tertian malaria also of 48 hour periodicity and P. falciparum causing malignant tertian malaria also with a periodicity of 48 hours. P falciparum causes the most fatal of all human malaria which is a supreme killer in endemic regions. 6 University of Ghana http://ugspace.ug.edu.gh Distribution. P. vivax is the most widely distributed species. It is naturally prevalent in many temperate as well as tropical and sub-tropical zones. P falciparum is the commonest in the tropics and sub-tropics although it may occur in some areas with temperate climate. P. malariae is patchily present over the same range as P. falciparum but much less common. P. ovale is found chiefly in tropical Africa, but also occasionally in the West Pacific (Bruce-Chwatt, 1980). MODE OF TRANSMISSION. Natural transmission of human malaria occurs through exposure to the bites of infective female Anopheles mosquitoes. The source of infection is nearly always a human subject whether a sick person or a symptomless carrier, although transmission of P. malariae from infected chimpanzees to humans are known to occur. Accidental transmission, although infrequent, may occur as a result of blood transfusion when a donor harbours the parasite. Drug addicts may also transmit malaria by sharing used needles. Finally, congenital infection of the newborn from an infected mother is also known to occur, but this mode of transmission is rare. THE ARTHROPOD HOST. Only the female anopheles mosquito can transmit human malaria. This is because males of the species feed exclusively on nectar and fruit juices while the female feeds primarily on blood (Stone et al, 1985) Of the 400 species of anopheles identified, only about 60 are important as vectors of malaria under natural conditions. Factors that determine 7 University of Ghana http://ugspace.ug.edu.gh whether a particular species of Anopheles is an important vector of malaria in a given locality include its preference of feeding on man to feeding on other vertebrates, the mean longevity of the local population of that species and its density in the area. Consequently, these vectors of malaria have definite distribution over large areas and an important vector in one region may be less important in another region (Wemsdorfer, 1980). For example in Africa, the main vectors are A. gambiae, A. fiuneslus and A. rufipes whilst in southern Mexico, the Caribbean islands and fringes of the South American coast, the most important vectors include A. darlingi, A. aquasalis, and A. Cruzi (Ahmed, 1989). LIFE CYCLE OF THE MALARIA PARASITE. Malaria parasites employ a complex life cycle, alternating between an arthropod secondary host-and a vertebrate primary host (Figure 1-1). This cycle, consists of an endogenous asexual cycle that occurs in man and an exogenous sexual cycle that takes place in female anopheles mosquitoes. Asexual cycle. With the bite of an infected female mosquito, sporozoites are injected and reach the blood stream. Within an hour they disappear from the blood, most of them having been destroyed by the immune system. The remaining sporozoites enter the parenchyma cells of the liver, where, during the next 10-14 days they undergo a pre-erytlirocytic stage of development and multiplication (schizogony) to form merozoites. At the end of this stage, the liver cells rupture and the merozoites are released into the blood. These infe t the red blood cells and form motile intracellular parasites named trophozoites. University of Ghana http://ugspace.ug.edu.gh Development and multiplication of the plasmodia within these cells constitute the erythrocytic stage. 1 Following mitotic replication of its nucleus, the trophozoites in an erythrocyte develop through schizogony to form schizonts, which grow and mature into merozoites. The merozoites grow and multiply until the red cell rupture, releasing the contents of the cell including the merozoites into the blood. The rupture of the red cell and the release of red cell contents into the blood is associated with chills, vomiting and hot and cold spells which are the symptoms of malaria. Sexual cycle. Some merozoites on entering the red cell differentiate into male and female forms called gametocytes, which can only complete the life cycle when taken up by a female mosquito. The cycle in the mosquito involves fertilisation of the female gametocyte by the male gametocyte with the formation of a zygote, which develops into an oocyst (sporocysts). A further stage of division and multiplication occurs leading to rupture o f the sporocysts with release of sporozoites, which then migrate to the mosquito salivary glands and enter another human host with the mosquito’s bite. In certain forms of malaria (P vivax and P. ovale) infections, some sporozoites on entering the liver cells develop into hypnozoites, which are resting forms of tire parasite. These can be reactivated to continue an exo-erythrocytic cycle of multiplication leading to another bout of infection even in the absence of introduction of fresh parasites. Relapses of malaria are likely to occur for these forms that have the lormant hypnozoites since they can emerge after an interval of several weeks or months to restart the infection. 9 University of Ghana http://ugspace.ug.edu.gh Figure 1-1: Life cycle of the malaria parasite. BIOCHEMISTRY OF THE PARASITE. Nucleic acid synthesis. Synthesis of purines. Intra-erythrocytic malaria parasites are unable to synthesise purines de novo but posses a salvage pathway and are therefore able to use some amount of pre-formed guanine and adenine bases arid nucleosides exogenously derived from the host in synthesis of DNA and RNA (Homewood and Neame, 1980; Elford et al, 1995). 10 University of Ghana http://ugspace.ug.edu.gh Synthesis of pyrimidines. Exogenous pyrimidines, in contrast, cannot be taken up by most species (Conklin et al, 1973). Even if taken up, the parasite cannot use most of the cytosine, uracil and thymidine bases present in the host system due to a lack of the presence of the appropriate kinases. For example, P. chabaudi lacks thymidine kinase and hence cannot phosphorylate and use pre-existing thymidine (Walter et al, 1974). The parasite therefore relies on an obligatory de novo synthesis of pyrimidines (Elford et al, 1995). Mammals in contrast, are prototrophic and able to synthesise both purine and pyrimidine nucleotides de novo as well as incorporate pre-formed bases when available. Their survival therefore, is not dependent upon the absorption of theso compounds. Folate synthesis. During the de novo synthesis of thymidine in the parasite, N5, N 10 methylene- tetrahydrofolate is required to transfer one carbon (methyl) groups to deoxyuridylate to form thymidylate, a necessary precursor to thymidine formation. However, the malaria parasite can only use a negligible amount of pre-formed folate and hence it relies on obligatory de novo synthesis of dihydrofolate from pteridine, para-aminobenzoate : 1 (PABA) and glutamate. This process requires the presence of the enzyme dihydropteroate synthase which catalyses the formation of dihydropteroic acid from PABA and pteridine. In contrast to the parasite, humans cannot synthesise folate by this process and must obtain it as a vitamin in the diet (Martins et al, 1987). This important difference in folate syntheses between host and parasite, present a point for antimalarials to exert their effect. 11 University of Ghana http://ugspace.ug.edu.gh COOH I ' u (CH2)2 ~ 1 c — N CH O COOH Dihydrofolic Acid Figure 1-2: Structure of Dihydrofolic Acid. In order for folate to serve as a carrier, dihydrofolate (a reduced form of dihydrofolic acid, Figure 1-2) must be reduced to tetrahydrofolate by the enzyme dihydrofolate reductase (DHFR) which uses NADPH as a hydride donor. This enzyme is a small monomeric protein containing no disulphide bonds and present in both host and parasite cells in i different isozymes. The presence of these different isozymes present an opportunity for the use of antimalarials that would selectively inhibit parasite DHFR enzymes. This is because the different isozymes of this enzyme have varying degrees of susceptibility to various (antimalarial) drugs. The parasite enzymes are more susceptible than human enzymes (Zubay, 1983). Breakdown of hemoglobin and metabolism of amino acids. The malaria parasite, like all other living cells, require proteins for growth, development and repair. This is particularly true for the intra-erythrocytic stages where the highest amount of growth and development occurs. However, Ihe parasite has a limited capacity to synthesise all the amino acids it requires de novo (Goldberg et al, 1990). 12 University of Ghana http://ugspace.ug.edu.gh It is worthy of note that the parasite matures within the red blood cell in which hemoglobin is the single most important cytosolic protein. It cm therefore, obtain those amino acids it cannot synthesise either by digestion of red cell hemoglobin or from free amino acids occurring in host plasma (Homewood and Nearre, 1980; Goldberg et al, 1990; Chou and Fitch, 1992). Part of the parasite’s requirement of amino acids, especially methionine, isoleucine (which is absent in hemoglobin), and glutamine is satisfied exogenously from host plasma (Goldberg et al, 1990; Elford et al, 1995) and to facilitate this, parasitised red cells are made more permeable to these and other amino acids so Ihat much higher amounts would enter by diffusion or by active transport using membrane bound carriers (Sherman and Tanigoshi, 1971). In the actively growing trophozoite, the parasite greedily ingests and degrades most of the host erythrocytic hemoglobin. This catabolic process is achieved through an efficient, ordered degradative pathway that takes place in the food vacuoles. Ingestion of host hemoglobin is done by means of the cytostome, which is a specialised structure, developed across the double membrane between the outer membrane of the parasite and the inner membrane of the host’s red cell. Here, hemoglobin-containing vesicles are pinched off the cytostome and travel to the digestive vacuoles where proteolytic enzymes break it down to the constituent amino acids, peptides, heme containing compounds and free heme (Goldberg et al, 1990; Goldberg, 1992; Slater et al, 1991). 13 University of Ghana http://ugspace.ug.edu.gh The free heme produced is potentially toxic to biological membranes (Goldberg et al, 1990; Matiney et al, 1996; Basilico et al, 1998). It has the ability to catalyse formation of oxygen-derived free radical species that can interact with cellulai membranes and cytoplasmic constituents. It also accumulates in normal and thalassemic erythrocytes as membrane-bound hemichromes. This behaviour of free heme may lead to a modification of the functional integrity of the cells and their membranes and also damage various other cellular constituents such as enzymes especially, those involved in DNA synthesis and repair (Rice-Evans and Baysal, 1987). Therefore in all living cells, free heme must be removed or detoxified immediately it is formed. In the mammalian host, toxic heme produced during the normal hemoglobin break down is detoxified by heme oxygyenase, an enzyme which catalyses the breakdown of free heme to biliverdin leading ultimately to the re-use of heme iron for synthesis of new hemoglobin or for storage in ferritin (Zubay, 1983). In contrast to the host, a parasite specific heme polymerisation activity occurring in the food vacuole detoxifies the free heme by cross-linking the heme monomers to form hemozoin or malaria pigment. This process is catalysed by a novel heme polymerase enzyme found to occur exclusively in the parasite (Slater and Cerami, 1992; Chou and Fitch, 1992). Hemozoin is an insoluble crystalline material consisting mainly of 65% protein and peptides, 16% ferriprotoporphyrin-IX also called hematin, 6% carbohydrate and trace 14 University of Ghana http://ugspace.ug.edu.gh amounts of lipid and nucleic acids. The overwhelming majority of the protein component is a mixture of native and denatured host globin, non-covalently associated with the matalloporphyrin. The carbohydrate groups also seem to come from non-enzymatic glycosylation of hemoglobin (Goldie et al, 1990). The most important component seems to be polymerised hematin. The structure of hemozoin (figure 1-3) comprises a polymer of ferriprotoporphyrin-IX (heme) molecules linked between the central ferric ion of one heme and a carboxylate side-group oxygen of another (Slater and Cerami, 1992). „ch2 COOH Figure 1-3: Structure of Hemozoin. 15 University of Ghana http://ugspace.ug.edu.gh This unique heme polymerising activity and differences in nucleic acid synthesis between the parasite and the human host, present researchers with useful points at which to attack and kill the malaria parasite. DIAGNOSIS The presence of malaria infection is empirically established on finding parasites in blood films. However, semi-immune individuals living in endemic regions may have pre-patent concentrations of parasites without showing the disease. The presence of malaria is confirmed when a Giemsa stained thin blood smear obtained from a finger prick or the ear lobe of a subject and observed under oil immersion in a light microscope shows the presence of parasitised erythrocytes ihat present themselves as blue dots. Thick Giemsa stained films and serological tests may also be used in diagnosis. TREATMENT. Presently, malaria is treated mostly by chemotherapy. Chemical agents', are used to eliminate both blood and tissue forms of malaria causing plasmodia once their presence have been established. The most widely used drugs include chloroquine,. amodiaquine and quinine. Most of these chemo therapeutic agents are aimed at eliminating erythrocytic forms of the disease since these forms present the easiest targets. BIOCLASSIFICATION OF ANTIMALARIAL AGENTS. The different stages in the life cycle of malaria parasites show different susceptibilities to the different antimalarial agents presently available. On this basis, antimalaria 16 University of Ghana http://ugspace.ug.edu.gh compounds can be classified generally as schizontocidal, gamotocidal and sporontocidal depending upon the stage of the parasite most affected by the drug. Schizontocidal drugs attack malaria parasites in the red blood cell, preventing or terminating the clinical attack. Examples include chloroquine, amodiaquine and quinine. The majority of antimalaria drugs are schizontocidal and are used in clinical treatment of the disease. Tissue schizontocidal drugs act on all the exo-erythrocytic forms, especially the pre- erythrocytic forms in the liver, thereby, preventing invasion of the red cell. Drugs in this category include proguanil and pyrimethamine. They are used mainly in prophylaxis but can also be used to effect radical cure of relapsing malaria. Gametocidal drugs destroy all sexual forms of the parasite. Some of these drugs have a pronounced anti relapse effect and are extensively used for radical cure of malaria. Primaquine is one such drug. Sporontocidal drugs prevent or inhibit formation of oocysts and sporozoites in the stomach wall of a gamete-carrying mosquito. Sporontocidally active drugs include proguanil and primaquine. 17 University of Ghana http://ugspace.ug.edu.gh CLASSIFICATION OF ANTIMALARIALS BASED ON THEIR CHEMICAL STRUCTURE. Generally, antimalarials can be divided into groups based on their chemical structure and reactive groups in relation to their mode of action and biological activity (Bruce-Chwat, 1980). This system, classifies antimalarials as 4-aminoquinolines, 8-aminoquinolines, aminoacridines, cinchona alkaloids, biguanides, diaminopyrimidines, sulphonamides, sesquiterpene lactones, phenanthrene methanols and other compounds such as iron chelators (mainly desferrioxamine B) and herbal drugs, 4-Aminoquinolines such as chloroquine, amodiaquine and mefloquine (figure 1-4) have a quinoline ring with an active side chain, which is a substituted anilino group. This side chain is linked to the carbon atom at the 4th position of the quinoline ring. NHM A . Wtefloqiine Chloroquine Arcdaqiire Figure 1-4: Structures of Some 4-aminoquinolines. These drugs, are potent and rapid blood schizontocides, effective, against all species of malaria parasites. 18 University of Ghana http://ugspace.ug.edu.gh .8-Aminoquinolines: The most important member of this group is primaquine (figure 5). Others include pamaquine and quinocide. The other drugs in this category are too toxic to the host for routine amimalarial use although they are active as blood schizontocides (Bruce-Chwat, 1980). They have an alkylammo chain attached to the carbon at position 8 in the quinoline ring. Compounds of this group have an additional ability to inhibit parasite’s mitochondrial respiration and this is thought to form one facet of their antimalaria action (Bitonti et al, 1988) Primaquine and the other closely related compounds prevent relapses and hence could be used to effect radical cure since they destroy hypnozoites that persist in the liver. They are also effective against gametocytes but not against forms of the parasite in circulating blood. Because they are poor blood schizontocides, 8-aminoquinolines are used mainly in prophylaxis and in combination with other antimalaria drugs for treatment. Pam aquine Figure 1-5: An 8-Aminoquinoline 19 University of Ghana http://ugspace.ug.edu.gh _9-Aminoacridines: e.g. mepacrine (figure 1-6). These have the aoridine ring. Mepacrine is not for routine use and considered an obsolete drug because of its high toxicity (Bruce-Chwatt, 1986). C2H5 c 2h 5 3 M epacrine Figure 1-6: An example of 9-aminoacridines _The cinchona alkaloids: The four most important alkaloids from the cinchona bark are quinine (figure 1-7), quinidine cinchonine and cinchonidine. Quinine and quinidine are the most important as far as antimalaria activity is concerned. It has a complex structure involving the basic quinoline ring. CH=CH2 Quinine Figure 1-7: A Cinchona alkaloid. 20 University of Ghana http://ugspace.ug.edu.gh It is highly active against blood scliizonts and hence effective for clinical use as an emergency antimalarial. It is also effective against chloroquine resistant parasites. Sesquiterpene lactones (figure 1-8): Artemisinine is the parent of this new group. Tlx important derivatives include artemether, arteether and artesunate. Thes j antimalarial drugs were isolated from the herb Artemesia annua (The Quingaosu Antimalarial Coordinating Research Group, 1979/ They have a complex structure with an endoperoxide group which is essential for their antimalarial activity, destruction of which leads to a loss of activity (Meshnick, 1994). They have a broad window antimalaria effect, being potent against all forms of the parasite from rings to mature trophozoites. They are also known to be potent blood schizontocides, effective even against multiple drug resistant species of P. falciparum (Cook, 1996). O \ ^ K C H 2)2COOH oArtem is in in e Artesunate Figure 1-8: Structures of some sesquiterpenes. 21 University of Ghana http://ugspace.ug.edu.gh The presence of the trioxane structure suggests that it is a potent oxidising agent (Hamburger and Hostettman, 1991). It had been observed that oxidising agents with this structure adversely affect parasite membranes by the generation of free radicals. Tb artemisinine-derived free radicals then form covalent bonds with parasite membrane structures leading to alkylation and destruction of these membranes (Cook, 1996). Sulphones and sulphonamides: Antimicrobial compounds such as sulphcnes (figure 1- 9) and sulphonamides (figure 1-10) interfere with coenzyme (folate) metabolism This I occurs at the dihydropteroate synthase reaction. These compounds could also be classified as antimalarials since they inhibit the growth and reproduction of malaria parasites. Sulphones are represented by the diamino-diphenyl sulphone (dapsone). Diphenyl -sulphone (Dapsone) Figure 1-9: A Sulphone. The base of all the suphonamides is sulphanilamide. There are a large number of sulphur drug to be used in malaria treatment The most active sulphonamides are those in which the SO2NH2 group has been replaced with a bulky heterocyclic ring such as in suphadoxine. derivatives of suphonamides of which sulphadiazane is the first and most successful 22 University of Ghana http://ugspace.ug.edu.gh Sulpha doxine Figure 1-10: Structure of some Suiphon amides. The sulphones and sulphonamides are usually used in combination with the antifolate antimalarials such as proguanil, and pyrimethamine in treatment. They are active against sporozoites and primary exo-erythrocytic forms of the parasites. They also act on blood forms of the parasites and this action is similar to that of the antifolates. However, they are slow acting and a combination with pyrimethamine increases their therapeutic action greatly (Bruce-Chwatt, 1986). Such combination formulation include Fansidar® (pyrimethamine and sulphonamide) and Fansimef® (mefloquine, pyrimethamine and sulphonamide). > ! Diaminopyriotidines: -These are characterised by the presence of a triazine or pyrimidine ring with two diamino groups attached to it. Examples include pyrimethamine and trimethoprim (figure 1-11). These attack the parasite in the blood and in the liver (Bruce- Chwatt, 1986). 23 University of Ghana http://ugspace.ug.edu.gh NH, .OCHs > — N L T i rh X o o b C2H5 Pyrimethamine H2N N' Trimethoprim Figure 1-11: Structure of some Diaminopyrimidines. Biguanides: Represented by proguanil, this class of antimalarials is characterised by the presence of a bignanide chain attached at one end to a chlorophenyl (diaminobenzyl) ring. Proguanil is a pro drug that undergoes oxidative ring closure in the liver through metabolism by the cytochrome P450 family (Cyp 2C19) to cycloguanil (figure 1-12), which is the active antimal trial (Bruce-Chwatt, 1986). NH N -t HN H f ^ ^ N H cyp 450 C H Cycloguanil Proguanil Figure 1-12: Proguanil and Cycloguanil. 24 University of Ghana http://ugspace.ug.edu.gh Phenanthrene methanols: The most promising drug of phenanthrene methanol origin is halofanthrine (figure 1-13), It is active against the erythrocytic stages of all species of malaria parasites but not against exo-erythrocytic form (Bruce-Chwait, 1986). Halofanthrine Figure 1-13: Structure of a Phenanthrene Methanol. Other compounds that have been found to act against human malaria parasites include iron chelators such as desferrioxamine B and many substances of plant origin whose active principles and modes of action are yet to be elucidated. MODE OF ACTION OF COMMON ANTIMALARIALS. 7 I Dihydrofolate reductase inhibitors. These destroy the malaria parasite by interfering with the metabolism of folate. Folate is involved in reactions that require one carbon transfers. Such reactions are important in the synthesis of nucleic acids and also in cell division in living systems. These drugs selectively bind to the enzyme dihydrofolate reduc tase of the parasite and prevent the conversion of dihydrofolate to- tetrahydrofolate. Because they are competitive 25 University of Ghana http://ugspace.ug.edu.gh inhibitors, they are structural analogs of folate. They include pyrimnthamine, trimethoprim, and cycloguanil. These drugs therefore, prevent one-carbon transfers by inhibiting formation of tetrahydrofolate and S-adenosine methionine (SAM) and eventually prevent DNA synthesis in the parasite (Bruce-Chwatt, 1986). Dihydropteroate synthase inhibitors. These drugs also act by blocking the synthesis of the coenzyme tetrahydrofolate, which is needed either directly or indirectly for many methylation reactions, and other one carbon transfers at different biochemical sites. They compete with para-amino benzoate thereby inhibiting the enzyme dihydropteroate synthase that catalyses the formation of dihydropteroate by the conjugation of PABA and pteridine pyrophosphate (figure 1-14). Pteridine Pyrophosphate Dihydropteroic /.cid Figure 1-14: Formation of Dihydroptcroic Acid. They also combine with pteridine to form spurious dihydropteroate compounds that cannot be combined with glutamate to form dihydrofolate. They are structural analogues of PABA. All the sulphur drugs such as sulphadoxine, dapsone and sulphadiaxine can be COOH' Para Aminoiienzoic Acid University of Ghana http://ugspace.ug.edu.gh placed in this category. Administration of a combination of dihydrofolate reductase and dihydroptheroate inhibitors in the treatment of malaria leads to reciprocal potentiation of each other’s antimalaria activity. This is achieved by a sequential blockade of those two enzymes involved in the same pathway of folate synthesis at different points. Heme polymerase inhibitors. The quinoline-containing antimalarials block heme polymerisation by inhibiting the heme-polymerising enzyme, heme polymerase. This leads to accumulation of toxic ferriprotoporphyrin IX that kills off the parasite (Slater and Cerami, 1992). Evidence provided by Slater and Cerami (1992) seems to suggests that alternate explanations of drug action such as for example, the assertion that quinoline containing antimalaria drugs directly affect lysosome function or that they intercalate into DNA and interrupt gene expression, are unlikely. MALARIA CONTROL. Malaria control and eradication involves interruption of the transmission' chain, reduction of the incidence and transmission of the disease and elimination of the reservoir of infected cased. Since the anopheline mosquito is the principal vector, it plays an important role in transmission of malaria and its removal could spell a break in the life cycle. Therefore, malaria control includes measures that are aimed at killing both adult and larval forms of the vector. These include: 27 University of Ghana http://ugspace.ug.edu.gh Blocking man-vector contact. The screening of doors, windows and other openings of human habitations during the main biting periods of the vector prevent mosquitoes from feeding on man, which is from sunset to sunrise. The use of bednets impregnated with insecticides are especially effective in repelling and preventing mosquito bites (Binka, 1997). In addition, the use of protective apparel that leaves little skin uncovered, in combination with the use of insect repellents are effective in warding off mosquitoes. Insecticide spraying. Application of insecticides such as the organophosphates (Fenthion and Malathion (0- isopropoxyphenyl)) chlorinated hydrocarbons, such as dichloro-diphenyl-trichloroethaL or DDT, hexachlorocyclohexane (HCH), dieldrin and aldrin and the carbamates such as propoxur (O-isopropozyphenyl methylcarbamate) and carbaryl (naphthyl methylcarbamate) produced a major breakthrough in the fight against the malaria vector. When the WHO begun its malaria eradication programmes in 1957, the use of these residual insecticides to control the vector featured prominently. However, resistance in mosquitoes against the organophosphates and organochlonnts and the persistence of these insecticides in the environment caused health problems, which led the WHO to discontinue their use. Some malaria vectors such as Anopheles araliensis, A. gambiae and A. fiunestus have also developed widespread resistance to dieldrin and DDT. This has necessitated the use of new pyrethrum based insecticides, such as permethrin and pyrethroid for malaria control. Resistance to these insecticides have not yet been reported (Manson-Bahr, et al, 1987). 28 University of Ghana http://ugspace.ug.edu.gh Removal of breeding sites. Engineering or mechanical methods aimed at the removal of mosquito breeding places such as swamps, marshes burrow pits, rain and seepage pools by methods which include draining, flushing and trimming of canals and open drains all lead to malaria control. Also, removal of floatage and vegetation from canals and rivers also prevent mosquitoes from multiplying in these bodies (Bruce-Chwatt, 1986), hence a good meafure for the control of the vector. Larviciding. This involves the spread of substance of hydrocarbon origin, usually petroleum oils, over pools of water to form continuous thin films on the surface thereby preventing the development of mosquito larvae in these pools. Among the most commonly used larvicides are Paris green (copper aceto-arsenate) and Temphos ( 0 ,0 ,0 ’-phenylk e phosphate). Larviciding as a control measure is only effective when the surfaces of the breeding ponds are not very extensive (WHO, 1992). Biological control. Biological means involving the use of larvae eating fish such as Gambusia sp., Tilapia sp. and Northobranchus sp. have also been used successfully to control mosquito populations in places where the ponds are stable enough to support growth of the fish. By the use of a combination of any of these methods, the mosquito population can be controlled and consequently, the incidence of the disease (Wemsdorfer, 1980). 29 University of Ghana http://ugspace.ug.edu.gh DRUG RESISTANCE IN MALARIA PARASITES. Resistance to antimalarial drugs probably causes the most important interference with the control of the disease. Drug resistance is the ability of a parasite strain to survive and/or multiply in the presence of drugs to which they were hitherto susceptible (WHO, 1973). It must be noted however, that antimalarial drugs directed against pathogenic plasmodia show marked stage-specific and often also, species-specific action. Implicit in this observation is the feet that natural population of parasites consist of individuals showing different susceptibilities to a given antimalarial-drug (Wernsdorfer, 1981V Mechanisms of resistance. I Resistant mutants survive either by a modification of the mechanisms that transport the drug into the parasite or elimination of the drug from the parasite. Either way, there is a reduction in the amount of the drug that gets into the immediate environs of the parasite. P. falciparum strains resistant to chloroquine, for example, have been reported to posses membrane transporters that increase the excretion of the drug (Wernsdorfer, 1981). Resistance to the anti-folate antimalarials arise from a modification of the dihydrofolate reductase gene leading to the production of mutant enzymes with reduced affinity for these drugs. Other parasite strains are known to use alternative pathways therefore reducing the importance of the pathways inhibited by the drug. Here, the salvage pathway for folate synthesis that allows the parasite to use pre-formed folate assumes prominence when the dihydrofolate reductase (DHFR) enzyme is inhibited (Cook, 1996). Resistance appears to stem from spontaneous mutations in the chromosomes which are genetically expressed at multiple loci on the genes (Wernsdorfer, 1981). Differential 30 University of Ghana http://ugspace.ug.edu.gh resistance of P. falciparum to the DHFR-inhibitors pyrimethamine and cycloquanil for example, result from specific mutations in the sequence of bases that code for the DHF enzyme. A single point mutation at position 108 changes Ser-108 (coded for by the bases AGC) to Asn-108 (AAC) in the DHFR active site cavity. This change confers a high level of resistance to pyrimethamine with only a small decrease in cycloquanil susceptibility. By contrast, the paired mutations of Ser-108 (AGC) to Thr -108 (ACC) and Ala-16 (GCA) to Val-16 (GTA) cause cycloguanil resistance with only a small change in pyrimethamine response (Gyang et al, 1992). Selection of resistant species is effected under drug pressure, which prevails under conditions such as prophylaxis and the administration of inadequate doses. These conditions are responsible for the occurrence and spread of resistant species (Wemsdorfer, 1981). Control of resistance. Possible measures to combat drug resistance include limiting the use of antimalaria drugs to reduce drug pressure, radical cure of microscopically diagnosed cases.and the use of drug combinations (Wemsdorfer, 1981). Various combinations of antimalaria drugs have been employed to combat resistant stains. The use of complementary drug combinations enables the drugs involved to attack the parasite at different stages in the life cycle. The use of a combination of chloroquine and pyrimethamine in the treatment and prevention of (vivax) malaria takes advantage of both the gametocidal action of primaquine and the schizontocidal action of chloroquine. Additive drug combinations involving the use of two or more antimalarials that act at the same stage in the life cycle is also effective. The most frequently use additive combination is the use of quinine and tetracycline in the therapy of multiple-drug resistant P falciparum infections. Potentiating antimalarial 31 University of Ghana http://ugspace.ug.edu.gh drugs reinforce the action of each other and the combination is active against parasites at all stages of the cycle. An example is the use of sulpliones or sulphonamides with pyrimethamine (Fansidar). The ability of some calcium-channel antagonists such as Verapamil to inhibit the enhanced efflux of chloroquine in resistant phenotypes thereby re-establishing sensitivity also offers an excellent opportunity to overcoming chloroquine resistance. Finally, the development and use of new drugs such as iron chelators also offer new opportunities to overcome resistance and fight the disease. 32 University of Ghana http://ugspace.ug.edu.gh SIDEROPHORES. Structural features. Siderophores are flexible organic molecules with two or more ciectronegative groups thal form stable co-ordinate-covalent bonds with cationic ferric atoms. There is considerable diversity in siderophore structure and chemistry. The common feature of siderophores, is the use of electronegative oxygen-donor-type ligands as functional groups in che formation of complexes with ferric ion (Cotton and Wilkinson, 1980). The greater the number of these ligands present in a given siderophore, the more stable the metal-chelator complex and the more effective the siderophore in chelating iron (Raymond et al, 1984). Iron chelators are classified as hydroxamate, catecholate or mixed function siderophores on the basis of the type of functional groups used in the chelation process. In hydroxamate siderophores, the ligating groups contain the oxygen atoms of hydroxamic acid. Catecholate siderophores make use of catechol, and the mixed function types employ a mixture of the two (figure 1-15). \ c = oI N O’ O ' H y d r o x a m a t e f u n c t i o n a l group C a t e c h o l a t e f u n c t i o n a l g ro u p Figure 1-15: The two main chelating groups used by siderophores. 33 University of Ghana http://ugspace.ug.edu.gh Catecholate siderophores These contain dihydroxybenzoyl groups, which are used in forming very stable complexes with Fe3+. These stable complexes have formation constants of about 1052. Bacteria, fungi and micro-algae are the main catecholate siderophores producers. Examples include such cyclic siderophores as enterobactin and linear iron chelators sue i as agrobactin and parabactin (figure 1-16). Figure 1-16: An example of a catecholate siderophore. Hydroxamate siderophores. A large number of the siderophores that have been characterised are hydroxamate. These are produced by fungi and include the ferrichromes. Ferrichromes contain cyclic hexapeptides in which three successive amino acid residues (mainly ornithine) have side chains that end in hydroxamate groups. Each hydroxamate group donates two oxygen atoms, which form co-ordinate bonds with Fe3+. Six oxygen atoms are thus made available in the ferrichrome molecule to satisfy the six-coordination valence of ferric iron which then forms a trischelate octahedral complex. Other hydroxamate siderophore include the rhodoturulic acids (figure 1-17), the mycobactins, the fusarinines and the 34 University of Ghana http://ugspace.ug.edu.gh ferrioxamines to which desferrioxamine B belongs (Neiiands, 1981; Adjimani et al, 1987). H I n OHO 0 OH 11C — NH H Rhodoturulic Acid Benzohydroxamic.Acid Figure 1-17: Some hydroxamate siderophores. DESFERRIOXAMINE B. Desferrioxamine B (figure 1-18) is a colourless crystalline substance produced / Streptomyces pilosus and used in the management of transfusional iron overload (Hershko, 1992; Raymond et al, 1984; Zevin et al, 1992). It consists of a chain of three hydroxamic acid groups terminating in the free amino acid L-ornithine (Neilands, 1980). This free amino acid enables the molecule form salts with inorganic compounds such as sodium sulphate yielding water soluble desferrioxamine mesylate (Desferal®). h2n co nh co nh 1 II / / \ (C H ? )2 , (C H g Js r H N— C 'O O II 1 II“O o 0 o D e s f e r r i o x a m ine B Figure 1-18: Structure of desferrioxamine B. 35 University of Ghana http://ugspace.ug.edu.gh The siderophore binds ferric iron avidly but binds ferrous iron and other, essential trace metals poorly. Desferrioxamine B easily penetrates and interacts with a number of cell types including red blood cells (Pippard et al, 1982), liver, spleen, kidney and brain cells (Octave et al, 1983). It is also able to rcact with iron located in these cells (Hershko, 1992). The ! compound is readily catabolised in vivo and has a very short metabolic half life which is i ' H ■ I ! estimated to be about one hour however, it is estimated to be distributed over 65% of the body (Hershko, 1992). This rapid body-wide distribution is very useful in the treatment of malaria. The desferrioxamine B molecule has a high affinity for ferric (Fe3+) iron and it combines with the ion at a molar ratio of 1:1 to form ferrioxamine B (figure 1-19) with stability constants of 1031. The molecule is wrapped around the Fe3+ nucleus encasing it in an envelope of organic material. As a result of this change in configuration following interaction with iron, the siderophore becomes an extremely stable compound, resistant to en2ymatic degradation and incapable of penetrating cells. It therefore, accumulates in the intracellular space (Hershko, 1992). 36 University of Ghana http://ugspace.ug.edu.gh l-feN\ CONH CONH / \ / \ Ferrioxamine B Figure 1-19: Structure of Ferrioxamine B. Mode and site of action. I In normal subjects, most of the body’s iron is unavailable for chelation and urinary excretion. This is because desferrioxamine B fails to compete for biologically chelated iron, such as the iron found in microsomal and mitochondrial cytochromes and rr st hemoproteins (Hershko, 1992). Although it can chelate iron from transferrin (Hepner, et al, 1988), transferrin-bound iron is a poor source for the drug (Hershko, 1992; Peto et al, 1986). Therefore, the most likely source of iron for chela.ion is iron stored in either hemosiderin or ferritin, or a labile iron pool present in erythrocytes and which is in dynamic equilibrium with the two iron binding proteins (Hershko, 1992). It has been proposed that, this intermediate iron pool serve as the main source of iron for serum iron- binding proteins and the iron stores of the body and also for the intraerythrocytic parasite. This is because (a) ferritin easily donates iron to desferrioxamine B upon in vitro incubation, (b) Fe-labelled ferritin associated with hepatic parenchymal cells is the single most effective source of iron for in vivo chelation in animal studies, and (c.) because the 37 University of Ghana http://ugspace.ug.edu.gh larger the size of iron stored in hemosiderin and ferritin, the higher the amount of iron excreted in the urine following desferrioxamine B treatment. The nature of this proposed iron pool, however, is not known (Hershko and Peto, 1988, Hershko, 1992). It has been observed that, the antimalarial activity of the drug is directly proportional to its ability to enter parasitised red cells (Cotton and Wilkinson, 1980). Parasite uptake of , desferrioxamine B is also a prerequisite for its antimalarial activity (Scott et al, 1990). Hence, it could be concluded that, chelation of serum iron is unimportant and that, the antimalarial effect is exerted mainly in the erythrocytes. It follows therefore that, either i I I ' i ' i l i 'desferrioxamine B may be chelating iron that is essential to the malaria parasite and1 making it unavailable for growth and reproduction or it may work by interfering with the process of heme polymerisation thereby releasing free heme that may be toxic to the parasite. Toxicity and side effects. Effective as desferrioxamine B is in the treatment of iron overload and malaria, the drug is poorly absorbed when administered orally (Bertram, 1992: Hershko, 1992; Hepner, et al, 1988; Raymond, et al, 1984) necessitating its intravenous or intramuscular administration. Although it is relatively non-toxic when administered in low doses (Hershko, 1992), high dose and long term desferrioxamine B therapy is associated with such conditions as vision and hearing loss, impairment of growth in children and breathing difficulties (Bertram, 1992), Therefore, new orally effective, relatively non-toxic inexpensive iron chelators are required if their use as antimalarials is to be accepted. 38 University of Ghana http://ugspace.ug.edu.gh CHAPTER 2 MATERIALS AND METHODS. MATERIALS. CHEMICALS. Desferal® (Desferrioxamine mesylate) was obtained from CIBA-GEIGY Limited, Switzerland. Chloroquine injection from TROGE MEDICA GmbH, Germany. Giemsa: Gurr improved stain, sodium chloride, sodium hydroxide, ethanol and diethyl ether from 1 " !! - BDH, England. Trisodium citrate from HOPKIN & WILLLIAMS, England and hematin I form SIGMA, USA. EQUIPMENT. Denley Wellscan, DENLEY INSTRUMENTS LTD, England. Kobuta microfuge, KOBUTA, Japan. Shimadzu double-beam spectrophotometer UV-190 and Shimad i infrared spectrophotometer IR-450 from SHIMADZU CORPORATION, Japan. PLASMODIUM BERGHEI. Plasmodium berghei anka was obtained from NMIMR, Ghana. ANIMALS. CBA mice from BOM, Denmark. 39 University of Ghana http://ugspace.ug.edu.gh METHOD. IN VIVO EXPERIMENTS. Culture of Plasmodium berghei anka in CBA mice. Thin blood smears were made from the tails of three 12-day-old BALB .C mice infected with P. berghei (Anka strain) and allowed to dry. The dried blood smears were fixed with methanol, air dried and stained with a 1:10 dilution of Giemsa stain in phosphate buffer for 15 minutes. The stained films were then washed with a gentle flow of water I ! !. . I and parasitemia determined. The mouse with the highest parasitenjiia (> 86%) was ■anaesthetised with diethyl ether and a total of 0.7ml of blood drawn by cardiac puncture. This blood obtained from the BALB C mouse was used to culture the malaria parasites in the CBA mice used in the study. 1.4ml of sterile phosphate buffered saline (PBS) was added to the blood and centrifuged at 5000g for 20mins and the supernatant discarded. Washing was repeated four more times and the pellet (containing both parasitised and non-parasitised erythrocytc ;) resuspended in 0.7ml of sterile PBS. 20pl this of washed suspension was added to 4.0ml of sterile PBS to attain a dilution of 1:200 pi. A Neubaur cell counting chamber (hemocytometer) was completely filled with the diluted erythrocyte suspension and the cell concentration determined. 40 University of Ghana http://ugspace.ug.edu.gh Number o f RBCs per 5 central squares = 19 7 Number of RBCs per central 25 squares =197 x 5 ! Number of RBCs /field of 5 central squares = No. of RBCs in a field x Dilution factor _ 0.1 nl Where 0.1 |j.l is the total volume of fluid occupied by a field of 5 central squares Number o f RBCs /ml o f blood = 197x5 x 2 0 0 x lOOOnl/ml 5x0.1(j.l =3.94 x 108 RBCs/ml Therefore number, of RBCs /lOOpl of blood = 0.394 x 108,1 But percentage parasitemia of Balb C mouse was 86.74% parasitised RBCs per 100^1 of blood = 86.74 x 0.394 x 108 100 = ; 1 0.342 x l0 8 parasites. ! ' | This means that 34.2 x 106 parasites are contained in 1 00jj.1 of blood. .'. 1 x 106 parasites are contained in 2.9pl of blood. 17.4 microlitres of this parasitised blood was made up to 1200|j.l with phosphate buffered saline. 200jil of this dilution containing 106 parasitised RBCs was injected intraperitoneally into each of five CBA mice. Parasitemia levels were determined on the third day after passage and subsequently, every other day for 14 days after which time the average parasitemia was in excess of 30%. The passage was continued for six consecutive times to establish the P. b Anka in the CBA mice. One hundred 6-8 week old CBA mice each weighing between 21-23g (average weight of 22g) were housed in groups of between 5 and 15 in stainless-steel cages with stainless steel grid lids and fed ad lib with RNM3 food, and tap wa'sr from plastic bottles. Animals were sacrificed by diethyl ether anaesthesia and blood samples taken via cardiac puncture and/or from the tail. 41 University of Ghana http://ugspace.ug.edu.gh Fixation, staining and determination of parasitemia. Blood samples taken from the tail were made into thin uniform smears on microscope slides of dimension 76 x 26mm, allowed to dry and then fixed with methanol and air dried. The fixed films were then stained with 10% Giemsa for 15 minutes, washed under running tap water, dried and examined microscopically under oil immersion. Parasitemia was determined as a percentage of the ratio of the number of parasitised erythrocytes to a total number of 1000 erythrocytes. Inoculation of CBA mice and administration of antimalarial compounds. ' <' | i 1 I , ' Eighty 6-8 week old female CBA mice (of average weight of 22g) were inoculated intraperitoneally with 106 P. berghei infected RBCs and parasitemia levels monitored daily. The mice were put into 3 groups of 15 mice each and the rate of growth of parasites monitored daily. On the 13th day, average parasitemia was in excess of 28%. The first group was given an intraperitoneal injection of lOOul of PBS only (placebo or control group), the second 100p.l of chloroquine (5mg/kg body weight).and the third 100 (0.1 desferrioxamine B (lOOmg/kg body weight). Blood samples were collected from three mice from each group via cardiac puncture at times 0, 3, 6, 12, 24, 36 and 48 hours post injection. Thin smears were made on microscope slides for parasiten a determination. Samples were also taken for histological analysis. 42 University of Ghana http://ugspace.ug.edu.gh IN VITRO EXPERIMENTS. INHIBITION OF HEME POLYMERISATION. One hundred microlitres of a solution containing 4mM solution of hematin dissolved inI O.IMNaOH, was distributed m a 96-well round-bottomed microplate to achieve a concentration of 0.4|dmol/well. 50|j.L of 200mM solution of desferrioxamine B was added to each of triplicate wells to give a desferrioxamine to heme ration of 2.5:1. 50|j.L of chloroquine concentrations of 4p.mol/well and 1 Ojj.mol/well were also added in triplicate to other test wells. 50|a.L of ddH20 was added to control wells and hematin i j i ! polymerisation initiated by the addition of 50pL of 16M acetic acid (containing 0.8mmol) at a final pH of 3 and the suspension incubated at 37°C for 24hours to allow complete polymerisation. Plates were then spun at 3300g for 15 min, and the supernatant of unpolymerised hematin collected (fraction I). The remaining pellet was resuspended in 99.9% DMSO to remove unreacted hematin. The plates were again centrifuged at 3300g for 15min and the DMSO soluble fraction (fraction II) was collected. The pellet in each well consisting of pure (3-hematin was dissolved in 200pL of O.IMNaOH (fraction III). 150|aL aliquot of each fraction was transferred to new plates and a two-fold serial dilution performed. The amount of hematin present in each fraction was determined spectrophotometically at 405nm using a microtitre plate reader (Denley Wellscan). A standard curve of unpolymerised hematin dissolved in O.IMNaOH was used to calculate the amount of hematin present in each fraction. 43 University of Ghana http://ugspace.ug.edu.gh This procedure of measuring the extent of heme polymerisation was repeated using other iron chelators including benzohydroxamic acid, rhodoturulic acid and acetohydroxamic acid in place of desferrioxamine B. Figure 2-1: 100|j.l of 4mM hematin in 0.1M NaOH Add 50(j.l of a solution of the antimalarial or ddH20 Add 50jj.l of 8mmol acetic acid to initiate polymerisation reaction Incubate at 37°C for 24 hours Supernatant (Fraction I) Centrifuge at 3300g for 15min. r Supernatant (Fraction II) Pellet (Polymerised hematin) Resuspend in DMSO and centrifuge at 3300g for 15min (washing). Pellet ( polymerised (3-hematin) Dissolve in O.IMNaOH (Fraction III) for spectroscopy Flow diagram showing the sequence of events in the hematin polymerisation experiments. 44 University of Ghana http://ugspace.ug.edu.gh Spectroscopic determination of binding. Solutions of hematin (4mM) , desferrioxamine B (4rnM) and chloroquine dissolved in NaOH were analysed spectrophotometrically in the UV-visible range (800-1 lOnm). Spectra for hematin-desferrioxamine B and hematin-chloroquine combinations at drug:hematin ratios of 1:1 were also analysed spectrophotometrically in the UV-visible region. Infrared scan of desferrioxamine B and hematin were run separately. Combinations of the two compounds were also run. The hematin-desferrioxamine B reaction was carried out in 0.1M NaOH on microplates and the plates left uncovered Overnight to allow the I aqueous NaOH to evaporate. These were then dissolved in 10(al of DMSO for the (infrared) IR analysis. The IR spectra were obtained using KBr discs. STATISTICAL ANALYSIS. Mean percentage parasitemia were expressed as the average of percentage parasitemia ± standard deviation of three separate determinations and the student’s t-test was used to analyse the significance of all data to within 95% confidence levels. 45 University of Ghana http://ugspace.ug.edu.gh CHAPTER 3 RESULTS. HEMATOLOGICAL EXPERIMENTS. Plasmodium Berghei. Anka Cultures. The growth of Plasmodium berghei anka strain in CBA mice was not found to be sigmoidal (figure 3-1) as seen in the growth pattern of most microbial systems under optimum conditions (Goodsel, 1996). There Was an initial establishment period during which growth was slow (day 0 to 10). This was followed by a rapid acceleration phase after day 10 . The period (between day 10 and day 21) within which plasmodia growth was exponential was chosen for the efficacy test as parasites in this phase are the most amenable to physical and chemical changes in their environment (Prcscot et al, 1993). In addition, this period in the growth of parasites provides a good approximation of non-severe malaria in living systems. 46 University of Ghana http://ugspace.ug.edu.gh Figure 3-1: Growth pattern of P. b. anka in CBA mice. All but a few of the parasite-treated experimental mice survived after day 21. The percentage of the infected mice that survived reduced rapidly from a value of 96% at 18 days after infection to fewer than 3% after 21 days of infection with the malaria parasites. This trend seems to be the result of increased burden of parasites. The mice at this time had a mean parasitemia of about 60% of the total red cell count. At this level of parasitemia, mice were sluggish, had dull eyes and rough coats. Most of them died shortly after exhibiting these symptoms. 47 University of Ghana http://ugspace.ug.edu.gh Figure 3-2 shows the effect o f injection o f lOOmg o f desferrioxamine per kg body weight or 5mg o f chloroquine per kg body weight on peripheral parasite growth in P. berghei. anka infected CBA mice. Mice in the control group were given phosphate buffered saline alone. All the drugs were constituted in PBS. Figure 3-2: Effect of Desferrioxamine B and Chloroquine on Plasmodium berghei anka growth in CBA Mice. Peripheral parasite count in mice treated with desferrioxamine B and chloroquine compared to untreated controls given only phosphate buffered saline. In the desferrioxamine-treated group, parasitemia increased from an initial value o f 30% to a maximum of 38%, three hours after treatment. The parasite count then reduced from this peak level to 32.53% six hours after treatment. Parasitemia levels remained almost 48 University of Ghana http://ugspace.ug.edu.gh unchanged at 32% until the 24th hour after which the levels increased again to 42.76% by the 48th hour. Peak parasitemia of 34% was observed in mice treated with 5mg of chloroquine per kg body weight by the third hour from an initial 32% level. Parasitemia levels then fell to a negligible value of 0.5% by 48 hours into the experiment. \Vithin this same period, percentage parasitemia in mice in the untreated group increased steadily to a peak of 57% in 48hours. Until hour 6, there was no statistically significant difference between percentage parasitemia in both treated and untreated control mice (p < 14). However, at-12 hours and after, differences in parasite counts in chloroquine treated mice became significant (p = 14.76). Significant differences in parasitemia levels between desferrioxamine B treated mice and the control was observed after 24 hours of treatment (p < 16.32). These significant differences were maintained from this point onwards (Table 3-1). Two of the mice receiving desferrioxamine B died 6 and 12 hours after treatment was started. These deaths were presumed to be the result of drug toxicity since the mice looked extremely sluggish and had stunted growth (lower weights). This was in contrast to the fact that none of the mice in the other groups (chloroquine and phosphate buffered . saline treated) suffered any such adverse outward symptoms and fate. No significant differences were observed between desferrioxamine B treated and control mice (phosphate buffered saline treated) until 24 hours after drug administration. University of Ghana http://ugspace.ug.edu.gh Table 3-1: Growth of Plasmodium bergliei anka in Chloroquine Treated Mice Compared to Desferrioxamine B Treated Mice. Time after Mean percentage parasitemia. Statistical injection (hours) difference __________________ CHQ treated group df treated group____________________ 0 32.00 ±5.38 30.36+ 11.93 NS 3 33.94 ±9.22 38.49 ±2.89 NS 6 27.86 ±4.09 32.84 ± 9.22 NS 12 21.72 ±8.73 33.23 ± 13.70 ' . NS 1 24 9.89 ±3.57 32.53 ±7.76 S 36 3.35 ± 1.20 39.54 ±9.61 s 48 0.51 ±0.07 42.76 ±8.11 s * Two-tailed test at 95% confidence interval. S Significant NS Not significant 50 University of Ghana http://ugspace.ug.edu.gh A combination o f desferrioxamine B and chloroquine has been reportedly used in the treatment o f malaria (Thuma et al, 1998; Hersko et al, 1992; Raventous-Suarez et al, 1982). To study the effects o f this combination therefore, 50mg o f desferrioxamine B and 2.5mg o f chloroquine per kg body weight o f mice dissolved in phosphate buffered saline was administered. This drug combination injected intraperitoneally into P. b. anka- infected CBA mice produced the effects presented in figure 3-3 below. Figure 3-3: Peripheral parasite count in mice treated with a combination of chloroquine and desferrioxamine compared to desferrioxamine-treated and phosphate buffered saline-treated controls. Here, percentage parasitemia increased from an initial level o f 31 %, to a peak value of 34% after three hours of treatment. It them reduced to a minimum value o f 0.5% at hours 36 and 48. 51 University of Ghana http://ugspace.ug.edu.gh T im e ( H o u r s ) P o s t In o c u la tio n Figure 3-4: Comparison of the effect of desferrioxamine and chloroquine to extracts of the commonly used herbs Morinda lucida and Cassia siamea (CRQ) on the growth of malaria parasites in CBA mice. The effect of extracts of Morinda lucida was particularly striking. The growth inhibition pattern was similar to that of chloroquine. Cassia siamea however, was not found to be particularly effective. In the presence of chloroquine and Morinda lucida, parasite clearance was almost complete 38 hours after injection of drug whilst with desferrioxamine B only about half of the parasites present initially had been cleared. 52 University of Ghana http://ugspace.ug.edu.gh ULTRASTRUCTURAL CHANGES INDUCED IN PLASMODIUM BERGHEI ANKA AS A RESULT OF DRUG TREATMENT. Study of the structure o f the parasites and infected red cells would help identify the possible site of action of the antimalarial drugs and the mechanism of action of desferrioxamine B. Under the light microscope, infected red blood cells were found to have enlarged to a size of about two times that o f the uninfected cells. These cells were also puffy and exhibited gross morphological changes. Infected cells also had knobs spaced at regular intervals on their surfaces (figure 3-5). Figure 3-5: Non-infected red blood cells compared to infected red cells. 53 University of Ghana http://ugspace.ug.edu.gh The predominant forms of parasites observed at the time treatment commenced were trophozoites (65% of infected cells) which were the matured ring-forms and schizoni. (28% of infected cells), having up to 32 merozoites through the mitotic division of the trophozoites. Very few gametocytes were seen. Parasites were found to occupy up to 16% of the internal space of infected red cells. The presence of two or more parasites per red cell was not uncommon. At this stage, most parasites had thin staining cytoplasm containing granules with small and compact purple-staining nuclei. Three hours after drug injection. I Very little changes, other that those observed at the time of drug injection, were observed in infected red blood cells of both desferrioxamine and chloroquine-treated mice. However, a small proportion of parasites in the chloroquine-treated group had enlarged nuclei with faint-staining cytoplasms. The proportion of young trophozoites in this group had also decreased significantly by 75%, results of this observation not shown. Six hours after drug injection. In the chloroquine-treated group, changes were seen in about 50% of the infected red cells. Parasite nuclei had increased in size with most becoming ovai-shaped,. Most cytoplasms had also become enlarged, discontinuous and pale, but these observations were not clearly shown by the photographs presented. In the desferrioxamine B treated group, the proportion of trophozoites had decreased. Both trophozoites and schizonts observed to have lost some of their cytoplasms whilst the rest had become enlarged and thin staining was difficult to see. 54 University of Ghana http://ugspace.ug.edu.gh Meanwhile in the control (PBS-treated group), the proportion of both young and old trophozoites had increased. The cytoplasms of the parasites had become darker with more prominent granules and rods. The changes had also become more widespread engulfing more previously uninfected red blood cells. Twelve hours after drug injection. Widespread1 morphological changes were observed after 12hoors. These include the observation of irregularly shaped gametocytes in the chloroquine-treated group. About 90% of the other forms had lost their cytoplasms and that of the rest could only be detected with difficulty. In the desferrioxamine B-treated group, there was little change in the morphology of the parasites except for the observation that, those changes observed after six hours had spread to cover more parasitised cells. Twenty-four hours after drug injection. I Most of the. parasites in the chloroquine-treated group were shrivelled (results of this observation not shown). All the trophozoites had completely disintegrated. The previously infected red cells had large amounts of purple staining Schiiffer’s stippling. The proportion of trophozoites remained at the same level in the desferrioxamine B- treated mice. Structural and morphological damages were the same as those after twelve hours of treatment. Control mice had increased parasitemia and of both male and female gametocytes occured with a higher frequency. 55 University of Ghana http://ugspace.ug.edu.gh Thirty-six hours after drug injection. Parasites in the chloroquine-treated group had disintegrated completely. The cytoplasm, where observable, was thread-like and the nuclei were vesicled. Most of the red cells had also regained their normal sizes and even the proportion of red cells with Schuffer’s dot: had reduced. Desferrioxamine B-treated cells show an increase in the proportion of young trophozoites in parasitised red cells. Some of the previously disintegrating cytoplasm had become continuous and had begun to pick up stain. ' 1 1 ' iForty-eight hours after drug iniection. All parasites in the chloroquine-treated group had been almost cleared. Most of the red cells had regained normal shapes and morphology, and only few parasitised cells show Schuffer’s dots. In the case desferrioxamine B-treated mice, a high proportion of trophozoites and schizonts were observed in the red blood cells at this point. Here, the red cells had also become enlarged again and more than one parasite could be observed in most of them compared to the control. 56 University of Ghana http://ugspace.ug.edu.gh Figure 3-6 a; Control Chloroquine-treated mice Desferrioxamine B-treated mice Structural changes observed after drug treatment. T = 6 Hrs University of Ghana http://ugspace.ug.edu.gh Control Figure 3-6 b: Chloroquine-treated mice Desferrioxamine B-treated mice Structural changes observed after drug treatment. = 36 Hrs ' = 48 Hrs 58 University of Ghana http://ugspace.ug.edu.gh INHIBITION OF HEME POLYMERIZATION. Heme was polymerised under acidic conditions. Concentrations o f hematin in microplates were determined from a standard curve constructed using the absorbances of known concentrations of unpolymerised hematin dissolved in 2Q0|liL of 0.1M NaOH (Figure 3-7). Figure 3-7: Hematin standard carve. Both desferrioxamine B and chloroquine inhibited the polymerisation of heme into |3- hematin. Inhibitions of 66.25%, 77.63% and 98.96% were observed for desferrioxamine and chloroquine (at 2mM and 5mM) respectively. There was no significant inhibition of heme polymerisation (P < 0.05) by citrate at a concentration ten times greater than that of desferrioxamine (table 3-2). 59 University of Ghana http://ugspace.ug.edu.gh Table 3-2: Extent of Inhibition of Heme Polymerisation by the Various Compounds Tested. Compound Hematin Cone. (mM) Mean* Hematin Cone. (mM) Percentage Inhibition Control 2.53xl0'2 2.53xl0-2 2.53xl0'2 2.53 x 10'2± 0.0001 0.00 Citrate (0.5M) 2 .6 9 x l 0 2 2.69xl0'2 2 .6 9 x l0 "2 2.70 x l0 '2 + 0.0001 6 .7 2 DF (5mM) 8 .6 0 x l0 ‘3 8.54x10'3 8,54x1 O'3 8 .5 4 x 10‘3 ± 0.0000 66.25 Chloroquine at (2mM) 5.66xl0‘3 5.66xl0'3 5.66xl0'3 5.66 x 10'3 ± 0.0001 77 .63 Chloroquine at (5mM) 2.63X10"4 2.60x10“® 2.63X10"4 2.63 x 10-4 ± 0.0000 9 8 .% * Mean hematin concentration = hematin concentration ± standard deviation of three separate determinations There was a clear and significant inhibition of heme polymerisation when desferrioxamine B at (5mM) and chloroquine at 2mM and 5mM were used. Although an iron chelator, citrate did not inhibit heme polymerisation to a significant extent (P < 0.05). Inhibition produced by desferrioxamine B at 5mM was not significantly different from that produced by 2mM chloroquine (P = 0.004) but significantly lower than that produced by 5mM chloroquine. As compared to the control, percentage inhibition o f heme polymerisation in the presence of desferrioxamine B and at the two concentrations of chloroquine were significant (table 3-3). 60 University of Ghana http://ugspace.ug.edu.gh Tabic 3-3. Statistical Comparison in Percentage Inhibition of Heme Polymerisation Produced Chloroquine, Citrate and Desferrioxamine B. Compound Percentage inhibition Critical Value* P-Value Difference Citrate 6.72 0.05 0.037 NS Df (5mM) 66.25 0,041 0.066 S Chloroquine (2mM) 77.63 0.040 0.077 S Chloroquine (5mM) 98.96 0.032 0.100 S * One-tailed te?t at 95% confidence interval. S sig lificant NS not significant Other monodentate iron chelators namely acetohydroxamic acid, benzohydroxamic acid and rhodotorulic acid were also tested for their inhibitory effect on heme polymerisation 61 University of Ghana http://ugspace.ug.edu.gh Table 3-4: Inhibition of Heme Polymerisation Produced by Monodentatc Iron Chelators. Compound Mean P-Hematin Percentage Critical P-Value Difference Concentration (mM) Inhibition Value* Control 4.917 x 10 0.00 Acetohydroxamic 2 .1 1 2 x l0 '2 57.05 0.014 0.066 acid 'hydro acid Benzohydroxamic 2.443 x 10"2 50.31 0.041 0.067 Rhodoturulic Acid 2.151 x 10’2 56.25 0.032 0.100 * One-tailed test at 95% confidence Interval, s significant ns not significant Benzohydroxamic acid and acetohydroxamic acid are monodentate and together with rhodoturulic acid, a bidentate iron chelator, proved to be very rjood inhibitors of heme polymerisation. 62 University of Ghana http://ugspace.ug.edu.gh Tabic 3-5: Wavelengths of Maximum Absorption Exhibited by Hematin, Desferrio.iamine B, Chloroquine and their Combinations from the W -Visible spectra. Compound*. Wavelength of maximum absorption (nm). Hematin 407 Desferrioxamine B 300 Chloroquine 315 Df + Hematin 370 Chloroquine + Hematin 402 All compounds were prepared in O.IMNaOH There was a large shift in the wavelength of maximum absorption (peak maximum) of hematin from 407nm to 370nm (a shift of 37nm towards wavelengths of higher energy) when desferrioxamine B was added to hematin. However, only a small shift in peak absorption was observed (from 407nm to 402nm, a shift of 5nm) in the hematin spectrum on addition of chloroquine to hematin (table 3-5). 63 University of Ghana http://ugspace.ug.edu.gh % Transmittance Wavelength (nm) Hematin , Hematin + Chloroquine Figure 3-9: Electronic absorption spectra of hematin and a combination of hematin and chloroquine. 65 University of Ghana http://ugspace.ug.edu.gh Infra red Spectroscopy. From the infrared spectrum of figure 3-10, the following important peaks could be assigned to the hematin spectrum Table 3-6: Peaks Assignments in the Infrared Spectrum of Hematin. Band (cm1) Assignment Inference 1565 and 1250 C-O bending vibrat