THE LOSS OF KINETOPLASTIC DNA IN TWO SPECIES OF TRYPANOSOMATIDAE TREATED WITH ACRIFLAVINE

The effects of acriflavine on two species of Trypanosomatidae, Crithidia luciliae and Trypanosoma mega, have been investigated. It has been observed that kinetoplastic (i.e. mitochondrial) DNA is lost in a high percentage of acriflavine-treated cells. Resting flagellates, from stationary-phase or hemin-deficient cultures, are considerably more resistant to the acridine than are flagellates from a log-phase culture. When the kinetoplast has retained some DNA and still remains visible in stained smears, it appears reduced in size, and its ultrastructure is extremely abnormal: the DNA fibrils, clearly visible in normal kinetoplasts, are condensed; they appear as an electron-opaque, apparently homogeneous mass, separated from the membranes by a space of low electron-opacity. Analyses of DNA extracts, with high speed centrifugation in CsCl density gradients, revealed that the satellite band, presumably kinetoplastic DNA, is lost by trypanosomes grown for 5 days in the presence of acriflavine. Radioautography was used to study the effects of acriflavine on thymidine-³H incorporation in C. luciliae. At the concentration which affects the kinetoplast specifically, the dye produces an 87% inhibition of thymidine incorporation in this organelle. The kinetics of this inhibition suggest a direct effect on replication. No decrease in incorporation occurs in the nucleus. These results lead to the conclusion that loss of kinetoplastic DNA is due to continued growth and cell division in the absence of kinetoplastic DNA replication. Several hypotheses are discussed concerning the specificity of the dye's action upon the replication of extrachromosomal DNA.     

EVIDENCE FOR THE RETENTION OF KINETOPLAST DNA IN AN ACRIFLAVINE-INDUCED DYSKINETOPLASTIC STRAIN OF TRYPANOSOMA BRUCEI WHICH REPLICATES THE ALTERED CENTRAL ELEMENT OF THE KINETOPLAST

A pleomorphic dyskinetoplastic strain of Trypanosoma brucei was produced by repeated acriflavine treatment. No kinetoplastic cells reappeared after 2 yr of maintenance in the absence of acriflavine. These dyskinetoplastic cells retained and therefore replicated the central element of the kinetoplast. This element was present in the "condensed" state typical of acriflavine-treated cells rather than the normal fibrillar state. Whole-cell DNA extracted from both normal and dyskinetoplastic strains revealed three bands upon isopycnic sedimentation, and there was no detectable alteration in buoyant density of any of these DNA components in the dyskinetoplastic strain. It seems likely that the dyskinetoplastic strain has retained its kinetoplast DNA but in an altered state.     

Whence comes Trypanosoma lewisi antigen which induces ablastic antibody: Studies in the occult?

I propose that trypanosomes have three antigen compartments: the intracellular, plasma membrane, and extracellular compartments. The intracellular antigens are released when trypanosomes lyse; the plasma membrane antigens are the structural or transport components of the plasma membrane and the adhering surface coat; the extracellular antigens are secreted by the trypanosomes. I further suggest that ablastinogen, the Trypanosoma lewisi antigen which induces ablastic antibody, is a plasma membrane antigen, and that the T. lewisi trypanocidal antigens are in the surface coat. The T. lewisi exoantigens described by D'Alesandro (1972) are, as he stated, different from ablastinogen and trypanocidal antigens. I suggest that the exoantigens are secreted extracellular antigens. Data from the literature are presented to support the hypothesis, and an experimental protocol to test the hypothesis is outlined.     

KINETOPLAST DEOXYRIBONUCLEIC ACID OF THE HEMOFLAGELLATE TRYPANOSOMA LEWISI

Cesium chloride centrifugation of DNA extracted from cells of blood strain Trypanosoma lewisi revealed a main band, ρ = 1.707, a light satellite, ρ = 1.699, and a heavy satellite, ρ = 1.721. Culture strain T. lewisi DNA comprised only a main band, ρ = 1.711, and a light satellite, ρ = 1.699. DNA isolated from DNase-treated kinetoplast fractions of both the blood and culture strains consisted of only the light satellite DNA. Electron microscope examination of rotary shadowed preparations of lysates revealed that DNA from kinetoplast fractions was mainly in the form of single 0.4 µ circular molecules and large masses of 0.4 µ interlocked circles with which longer, often noncircular molecules were associated. The 0.4 µ circular molecules were mainly in the covalently closed form: they showed a high degree of resistance to thermal denaturation which was lost following sonication; and they banded at a greater density than linear DNA in cesium chloride-ethidium bromide gradients. Interpretation of the large masses of DNA as comprising interlocked covalently closed 0.4 µ circles was supported by the findings that they banded with single circular molecules in cesium chloride-ethidium bromide gradients, and following breakage of some circles by mild sonication, they disappeared and were replaced by molecules made up of low numbers of apparently interlocked 0.4 µ circles. When culture strain cells were grown in the presence of either ethidium bromide or acriflavin, there was a loss of stainable kinetoplast DNA in cytological preparations. There was a parallel loss of light satellite and of circular molecules from DNA extracted from these cells.     

PCR identification of Trypanosoma lewisi,a common parasite of laboratory rats

Trypanosoma (Herpetosoma) lewisi is a trypanosome of the sub-genus Herpetosoma (Stercoraria section), parasite of rats (Rattus rattus and Rattus norvegicus) transmitted by fleas. T. lewisi has a stringent species specificity and cannot grow in other rodents such as mice. Rats are infected principally by oral route, through contamination by flea faeces or ingestion of fleas. Trypanosoma lewisi infections in rat colonies can interfere with research protocols and fleas of wild rats are often the source of such infections. Currently, diagnosis of T. lewisi in rats is performed by microscopic observation of stained blood smears. In the course of a research project at CIRDES, a T. lewisi infection was detected in the rat colony. In this study we evaluated PCR primer sets for their ability to diagnose multiple species of trypanosomes with a single amplification. We show that the use of ITS1 sequence of ribosomal DNA provides an efficient and sensitive assay for detection and identification of T. lewisi infection in rats and recommend the use of this assay for monitoring of T. lewisi infections in rat colonies.     

Trypanosoma lewisi: comparative activity of a feral isolate in two strains of rats assessed by measurement of cell population, reproductive development and respiratory activity.

Lee C. M., Harris L. M. and Aboko-Cole G. F. 1978. Trypanosoma lewisi: comparative activity of a feral isolate in two strains of rats assessed by measurement of cell population, reproductive development and respiratory activity. International Journal for Parasitclogy8: 187–192. Comparative respiratory behaviour, population growth and host antibody formation were examined for a feral isolate of Trypanosoma lewisi grown in albino and black rats. Oxygen uptake was measured for endogenous, glucose or normal homologous rat serum substrates. Trypanosomes from albino rats respired 72% faster endogenously, 70% faster with glucose, and 60% faster with rat serum than parasites from black rats. Greater oxygen consumption of T. lewisi from albino rat hosts correlated well with the fact that the trypanosome developed greater parasitemias in albino than in black rats. Parasitemias were patent longer in albino rats and peak populations were found 2 days later in these hosts than in black rats. On the average, higher coefficients of variability in cell length continued five days longer in albino rats than in black animals. Delay in reproductive development was indicated by continued low variability in trypanosome cell sizes in albino and black rats.     

Trypanosoma lewisi: accumulation of antigen-specific host IgG as a component of the surface coat during the course of infection in the rat.

Naturally acquired host IgG, adsorbed to the surface of Trypanosoma lewisi during the course of infection in the rat, was labeled with fluorescein-conjugated rabbit IgG, or Fab fragments of this IgG, directed against rat IgG. The intensity of fluorescent labeling increases with time, concomitant with the increase in anti-T. lewisi activity of host plasma. Trypanosomes harvested from immunosuppressed hosts lack detectable surface IgG. Trypanosomes having little or no detectable surface IgG (harvested from immunosuppressed hosts or early in the infection from immunocompetent hosts) can adsorb IgG from serum with ablastic activity only (obtained from other infected rats between the first and second crises and adsorbed to remove trypanocidal antibodies), but not from normal serum. Therefore, the absence of detectable surface IgG on such cells is not caused by the parasites' inability to adsorb host IgG, but rather results from the immune state of the host. Hence surface IgG on T. lewisi is specific antibody. Host albumin is nonspecifically adsorbed, in contrast to IgG. Trypanosomes from immuno-suppressed and immunocompetent rats were positive and visually indistinguishable from each other when labeled with anti-rat albumin, and were equally agglutinable with anti-rat albumin serum.     

The kinetoplast DNA of the Australian trypanosome,Trypanosoma copemani,shares features with Trypanosoma cruzi and Trypanosoma lewisi

Kinetoplast DNA (kDNA) is the mitochondrial genome of trypanosomatids. It consists of a few dozen maxicircles and several thousand minicircles, all catenated topologically to form a two-dimensional DNA network. Minicircles are heterogeneous in size and sequence among species. They present one or several conserved regions that contain three highly conserved sequence blocks. CSB-1 (10?bp sequence) and CSB-2 (8?bp sequence) present lower interspecies homology, while CSB-3 (12?bp sequence) or the Universal Minicircle Sequence is conserved within most trypanosomatids. The Universal Minicircle Sequence is located at the replication origin of the minicircles, and is the binding site for the UMS binding protein, a protein involved in trypanosomatid survival and virulence. Here, we describe the structure and organisation of the kDNA of Trypanosoma copemani, a parasite that has been shown to infect mammalian cells and has been associated with the drastic decline of the endangered Australian marsupial, the woylie (Bettongia penicillata). Deep genomic sequencing showed that T. copemani presents two classes of minicircles that share sequence identity and organisation in the conserved sequence blocks with those of Trypanosoma cruzi and Trypanosoma lewisi. A 19,257?bp partial region of the maxicircle of T. copemani that contained the entire coding region was obtained. Comparative analysis of the T. copemani entire maxicircle coding region with the coding regions of T. cruzi and T. lewisi showed they share 71.05% and 71.28% identity, respectively. The shared features in the maxicircle/minicircle organisation and sequence between T. copemani and T. cruzi/T. lewisi suggest similarities in their process of kDNA replication, and are of significance in understanding the evolution of Australian trypanosomes.     

Immunosuppression and ablastin

Ablastin formed by animals in response to infections by rodent trypanosomes possesses the characteristics of an antibody. Partial resistance to Trypanosoma lewisi is demonstrable in animals previously injected with live Trypanosoma musculi. Antisera from T. musculi infected mice do not inhibit reproduction by T. lewisi bloodstream forms in vitro as efficiently as homologous antisera collected at similar times during infections, indicating a degree of specificity. Ablastin activity in antisera is not altered by treatment with 2-mercaptoethanol or by heatng at 60 °C for 3 hr. Sephadex G-200 gel filtration of early and late antisera from T. lewisi infected rats and assays with bloodstream forms cultured at 37 °C detect ablastin activity in the second major fraction eluted from the columns. Ablastin appears to be an antibody of the immunoglobulin G species.Immunosuppressant procedures utilized in studies of the host responses to rodent trypanosomes are reviewed and include: chemical agents, irradiation, splenectomy, reticuloendothelia blockade and thymectomy, and treatment with antilymphocyte and antithymocyte sera. Evaluation of the results of the application of these procedures to rodent parasite systems indicates ablastin is an antibody and supports the concept that the inhibition of trypanosome reproduction is separate and distinct from the first trypanocidal event responsible for the decreasing parasitemias observed during the infections. Recent studies concur and suggest that the first crisis in the infections is mediated by the combined actions of a thymus-dependent ablastin and a thymus-independent trypanocidal antibody.     

Trypanosoma lewisi: antibody classes which mediate precipitation, agglutination, and the inhibition of reproduction

Sera from Trypanosoma lewisi-infected and uninfected rats were applied to Protein A-Sepharose CL-4B columns. The absorbed fractions of antisera which contained only IgG molecules were reacted in microimmunodiffusion analyses with the exoantigens of T. lewisi in plasma collected from irradiated infected rats, and formed one precipitin line. These sera were also applied to T. lewisi extract immunoabsorbent columns and bound proteins were eluted and analyzed by immunodiffusion against antisera specific for rat immunoglobulins. IgG₁, IgG_2a, IgG_2b, IgG_2c, and IgM were absorbed by the immuno-absorbent columns. Absorption of the rat antisera with anti-rat IgG or anti-rat IgM removed one of the two precipitin lines against extracts prepared from parasites collected from irradiated infected animals. The absorbed IgG fractions and nonabsorbed fractions of antisera which were collected after Protein A-Sepharose CL-4B column chromatography agglutinated trypanosomes. After treatment of antisera with 2-mercaptoethanol, the agglutinin titers were lower than those of the control antisera suggesting both IgG and IgM are involved in the agglutination. The ablastic activity of the fractions eluted from Protein A-Sepharose CL-4B Chromatographic columns was assayed in cultures of bloodstream forms ofT. lewisi. Ablastic activity of proteins of antisera absorbed by the columns was demonstrated indicating they belonged to the IgG class of antibodies.     

Atypical Human Infections by Animal Trypanosomes

The two classical forms of human trypanosomoses are sleeping sickness due to Trypanosoma brucei gambiense or T. brucei rhodesiense, and Chagas disease due to T. cruzi. However, a number of atypical human infections caused by other T. species (or sub-species) have been reported, namely due to T. brucei brucei, T. vivax, T. congolense, T. evansi, T. lewisi, and T. lewisi-like. These cases are reviewed here. Some infections were transient in nature, while others required treatments that were successful in most cases, although two cases were fatal. A recent case of infection due to T. evansi was related to a lack of apolipoprotein L-I, but T. lewisi infections were not related to immunosuppression or specific human genetic profiles. Out of 19 patients, eight were confirmed between 1974 and 2010, thanks to improved molecular techniques. However, the number of cases of atypical human trypanosomoses might be underestimated. Thus, improvement, evaluation of new diagnostic tests, and field investigations are required for detection and confirmation of these atypical cases.

Key Learning Points

• The classical human trypanosomoses are human African trypanosomosis (HAT) or sleeping sickness, and Chagas disease, the Latin American human trypanosomosis.
• Atypical human infections caused by Trypanosoma species that normally are restricted to animals have been reported. These cases of atypical human trypanosomoses (a-HT) are mostly transient, but some require treatment and can be fatal.
• Only a few cases of a-HT have been fully confirmed, especially in Asia, leading to the hypothesis that the actual prevalence is probably underestimated.
• The detection of a case of a-HT should be based on observation of the parasite by direct microscopy. Evaluating/improving the diagnoses through serological and PCR assays would help in detecting and identifying atypical trypanosomosis infections in humans. These laboratory research and field activities are needed to evaluate the actual occurrence of atypical cases.

Top Five Papers

1. Verma A, Manchanda S, Kumar N, Sharma A, Goel M, et al. (2011) Trypanosoma lewisi or Trypanosoma lewisi-like infection in a 37-day-old infant. Am J Trop Med Hyg 85: 221–224.
2. Deborggraeve S, Koffi M, Jamonneau V, Bonsu FA, Queyson R, et al. (2008) Molecular analysis of archived blood slides reveals an atypical human Trypanosoma infection. Diagn Microbiol Infect Dis 61: 428–433.
3. Vanhollebeke B, Truc P, Poelvoorde P, Pays A, Joshi PP, et al. (2006) Human Trypanosoma evansi infection linked to a lack of apolipoprotein L-I. N Engl J Med 355: 2752–2756.
4. Joshi PP, Shegokar V, Powar S, Herder S, Katti R, et al. (2005) Human trypanosomiasis caused by Trypanosoma evansi in India: the first case report. Am J Trop Med Hyg 73: 491–495.
5. Howie S, Guy M, Fleming L, Bailey W, Noyes H, et al. (2006) A Gambian infant with fever and an unexpected blood film. PLoS Med 3: e355. doi:10.1371/journal.pmed.0030355.

     

Cell cycle and cleavage events during in vitro cultivation of bloodstream forms of Trypanosoma lewisi,a zoonotic pathogen

Trypanosoma (Herpetosoma) lewisi is a globally distributed rat trypanosome, currently considered as a zoonotic pathogen; however, a detailed understanding of the morphological events occurring during the cell cycle is lacking. This study aimed to investigate the cell cycle morphology and cleavage events of Trypanosoma lewisi (T. lewisi) during in vitro cultivation. By establishing in vitro cultivation of T. lewisi at 37°C, various cell morphologies and stages could be observed. We have provided a quantitative analysis of the morphological events during T. lewisi proliferation. We confirmed a generation time of 12.14 ± 0.79 hours, which is similar to that in vivo (12.21 ± 0.14 hours). We also found that there are two distinct cell cycles, with a two-way transformation connection in the developmental status of this parasite, which was contrasted with the previous model of multiple division patterns seen in T. lewisi. We quantified the timing of cell cycle phases (G1_n, 0.56 U; S_n, 0.14 U; G2_n, 0.16 U; M, 0.06 U; C, 0.08 U; G1_k, 0.65 U; S_k, 0.10 U; G2_k, 0.17 U; D, 0.03 U; A, 0.05 U) and their morphological characteristics, particularly with respect to the position of kinetoplast(s) and nucleus/nuclei. Interestingly, we found that both nuclear synthesis initiation and segregation in T. lewisi occurred prior to kinetoplast, different to the order of replication found in Trypanosoma brucei and Trypanosoma cruzi, implicating a distinct cell cycle control mechanism in T. lewisi. We characterized the morphological events during the T. lewisi cell cycle and presented evidence to support the existence of two distinct cell cycles with two-way transformation between them. These results provide insights into the differentiation and evolution of this parasite and its related species.     

Trypanosoma lewisi: Enhanced resistance in naive lactating rats and their suckling pups

Lactating rats and their suckling offspring were shown to have a naturally occurring resistance to Trypansoma lewisi which was greater than that seen in normal adult rats and was not dependent on previous exposure to the parasite. In the case of the pups maximum protection was dependent on suckling being the sole source of nutriment and also on the peak of the parasitemia falling within the nursing period. Supplementary solid food reduced survival rates in concurrent Hemobartonella muris—T. lewisi infections: pups infected at 10 days of age and totally dependent on nursing showed 82.5% survival but only 6.6% survival when solid food was allowed to supplement milk. However, supplementary food did not reduce survival in pups infected with only T. lewisi. When pups were totally dependent upon nursing until the normal time of weaning (21 days of age), infection with H. muris—T. lewisi at the following days of age allowed the indicated mean survival rates: 10 days (82.5%), 20 (32.5%), 30 (14.3%), and 40 (100%). Infection with T. lewisi alone at the following days of age allowed the indicated mean survival rates: 10 days (100%), 15 (76%), 17 (52%), 20 (100%), and 30 (100%). Lactating rat serum agglutinated “adult forms” of T. lewisi, which correlated well with the observed sudden resolution of parasitemia in lactating animals at the time of the antigenic transition from “juvenile” to “adult” type. The “adult” stage parasitemia in suckling pups was selectively reduced when compared to that of nonlactating adult rats. The lactating rat serum factor could be passively transferred with lactating rat serum to animals already weaned.     

Trypanosoma lewisi and T. cruzi: Effect of infection on gestation in the rat

Termination of pregnancy occurred in the rat after infection with Trypanosoma lewisi early in gestation. Rats were inoculated on Day 2 of pregnancy and the uteri were excised and examined on Days 10 and 14 of gestation. There were no detectable differences in size in the fetuses of infected and control females at Day 10, but by Day 14 young of infected females were being reabsorbed, and their weight was markedly less than that of control young.A bioassay of estrogens and progestogens based on the decidual cell response indicated that there was a sufficient hormone level to maintain pregnancy beyond Day 10, so the mechanism of action by which fetal death was produced did not appear to be hormone depletion. The crucial changes in fetal weight occurred between Days 12 and 14 of gestation in rats infected with T. lewisi on Day 2 of gestation.Trypanosoma cruzi caused little or no pathologic change in the pregnant laboratory rat throghout the period of gestation and infected females gave birth to apparently normal young.     

Structure-Function Relationships in Cellular Organelles Introductory Remarks by the Convener

Cells of the order Kinetoplastida possess a single mitochondrion which contains a large amount of a uniquely organized DNA. This kinetoplastic DNA (K-DNA), representing 10–20% of the total cell DNA in different species, has as its major molecular component a small closed circular molecule present in large numbers. The size and thereby the amount of genetic information carried by the minicircles varies from species to species: Leishmania tarentolae and the Salivarian trypanosomes have the smallest, the Stercorarian trypanosomes Trypanosoma lewisi and Trypanosoma cruzi intermediate, and Crithidia and also Trypanosoma mega the largest minicircles. In L. tarentolae, purified minicircles, which are the size of 1 gene, have been shown by renaturation kinetics to consist of only 1 or 2 classes. L. tarentolae K-DNA also contains another molecular species—a long molecule which may represent up to 30% of the total K-DNA. The minicircles, nevertheless, represent a gene amplification of the order of 10⁴. In all species that have been examined so far, the K-DNA consists of a single sheet of interlocked closed circular molecules which can be isolated in an intact form because of its resistance to shear forces and its high molecular weight. In addition, at least in L. tarentolae, 6–9% of the K-DNA is either free in the mitochondrion or loosely bound. The main K-DNA structure has been termed a “network” and can be seen in the light microscope after staining in solution with acridine orange or after fixing and staining with Giemsa's, or in the electron microscope. The quaternary structure of such networks in terms of the organization of minicircles and long molecules is not understood. Controlled breakdown of networks from L. tarentolae was achieved by sonication, and the release of open and closed monomeric minicircles, catenated dimers, trimers and higher oligomers, and short linear fragments was measured. A maximum of 43% of the total network DNA was released in the form of closed monomers, dimers, and trimers, thus providing a minimal estimate for the percentage of minicircles in K-DNA from this species. K-DNA replicates fairly synchronously with nuclear DNA in all species that have been examined. Replication of DNA molecules in the kinetoplast networks is limited to the periphery, as seen in autoradiographs of networks isolated from cells (L. tarentolae, Crithidia fasciculata) pulsed with ³H-thymidine. The molecular implications of this unusual replication pattern remain an open question, as does the genetic function of the K-DNA itself.     

The latest Miocene Rhinocerotidae from Sahabi (Libya)

The Rhinocerotidae material from the latest Miocene of Sahabi (Libya) is here revised in detail in order to clarify its systematic position and the paleobiogeographic implications. The family is represented by four specimens only at Sahabi, a phalanx, a mandible, a second upper molar (M2), and a second upper premolar (P2). Except for the phalanx, which can be only identified at the family level, the morphology and the dimensions of these specimens have revealed the presence of three taxa: Aceratheriini vel Teleoceratina, Brachypotherium lewisi and ‘Diceros’ sp. The presence of the large-sized B. lewisi has been suggested in several papers, but without a detailed comparison or critical revision. The Brachypotherium from Sahabi also resembles Brachypotherium heinzelini, suggesting a probable synonymy between this species and B. lewisi. A P2 from Sahabi differs from several species belonging to Ceratotherium, including Ceratotherium neumayri, and it resembles the genus Diceros. The rhinoceros association (Brachypotherium and a dicerotine) recognized at Sahabi has been recorded at Lothagam (Kenya), suggesting a biogeographic affinity with the eastern Africa assemblage.     

Trypanosoma lewisi: production of exoantigens during infection in the rat

Exoantigens are produced by Trypanosoma lewisi during infections in the rat. They were detected in rat serum and plasma by gel-diffusion techniques with hyperimmune rat sera and with rabbit antiserum to washed, living trypanosomes. Their parasite origin is indicated by their presence in trypanosome homogenates, which also contain bound antigens, the continued reactivity of rabbit antisera after absorption with normal rat serum, and the reactions of identity obtained with rat and rabbit antisera. Moreover, by immunoelectrophoresis, the exontigens are revealed as new components in infected rat serum with a mobility slightly anodal to the origin. The results also show that the exoantigens are continuously released in vivo and that the trypanosomes avidly bind non-antibody rat serum proteins to their surface. Unlike the complete qualitative changes in exoantigens that accompany antigenic variation of pathogenic species of trypanosomes, at least one exoantigen remains unchanged when antigenic variation occurs with T. lewisi although additional exoantigens may appear and disappear. The relation of the exoantigens to the known ablastic and trypanocidal antibodies is difficult to determine since these antibodies and the exoantigens occur simultaneously in the blood during and after the infection. Although it cannot yet be ruled out that the exoantigens elicit the formation of these antibodies, a review of all the available evidence suggests that the exoantigens of T. lewisi may not be immunogenic during a natural course of infection. Possibly they are hemolysins with a nutritive function.     

Unexpectedly high diversity of trypanosomes in small sub-Saharan mammals

The extremely species-rich genus Trypanosoma has recently been divided into 16 subgenera, most of which show fairly high host specificity, including the subgenus Herpetosoma parasitizing mainly rodents. Although most Herpetosoma spp. are highly host-specific, the best-known representative, Trypanosoma lewisi, has a cosmopolitan distribution and low host specificity. The present study investigates the general diversity of small mammal trypanosomes in East and Central Africa and the penetration of invasive T. lewisi into communities of native rodents. An extensive study of blood and tissue samples from Afrotropical micromammals (1528 rodents, 135 shrews, and five sengis belonging to 37 genera and 133 species) captured in the Central African Republic, Ethiopia, Kenya, Malawi, Mozambique, Tanzania, and Zambia revealed 187 (11.2%) trypanosome-positive individuals. The prevalence of trypanosomes in host genera ranged from 2.1% in Aethomys to 37.1% in Lemniscomys. The only previously known trypanosome detected in our dataset was T. lewisi, newly found in Ethiopia, Kenya, and Tanzania in a wide range of native rodent hosts. Besides T. lewisi, 18S rRNA sequencing revealed 48 additional unique Herpetosoma genotypes representing at least 15 putative new species, which doubles the known sequence-based diversity of this subgenus, and approaches the true species richness in the study area. The other two genotypes represent two new species belonging to the subgenera Ornithotrypanum and Squamatrypanum. The trypanosomes of white-toothed shrews (Crocidura spp.) form a new phylogroup of Herpetosoma, unrelated to flagellates previously detected in insectivores. With 13 documented species, Ethiopia was the richest region for trypanosome diversity, which corresponds to the very diverse environments and generally high biodiversity of this country. We conclude that besides T. lewisi, the subgenus Herpetosoma is highly host-specific (e.g., species parasitizing the rodent genera Acomys and Gerbilliscus). Furthermore, several newly detected trypanosome species are specific to their endemic hosts, such as brush-furred mice (Lophuromys), dormice (Graphiurus), and white-toothed shrews (Crocidura).     

Effects of Ethidium Bromide and Several Acridine Dyes on the Kinetoplast DNA of Leishmania tropica*†

Whole cell DNA from Leishmania tropica has 2 peaks when banded by CsCl equilibrium density centrifugation. The main band has a buoyant density of 1.721 and the satellite band a buoyant density of 1.705, with Clostridium perfringens DNA (ρ= 1.6915) used as a reference. The satellite band has been identified as the kinetoplast DNA by purifying DNA from isolated kinetoplasts. L. tropica has the highest G + C content of both nuclear and kinetoplastic DNA thus far reported for trypanosomatids. The effects of ethidium bromide, acriflavin, proflavin, and 5-aminoacridine on the kinetoplast of L. tropica have been compared. Ethidium bromide and acriflavin, but not proflavin or 5-aminoacridine, induce dyskinetoplasty. L. tropica is one of the most sensitive trypanosomatids to ethidium bromide and acriflavin. Examination of the DNA from drug-treated cells in CsCl gradients revealed a loss of the satellite band after ethidium bromide or acriflavin treatment, but not after proflavin or 5-aminoacridine treatment. Cell division was required to produce these effects on the kinetoplast.