Purification of Trypanosoma cruzi surface proteins involved in adhesion to host cells

Trypanosoma cruzi dysregulates expression profile of piRNAs in primary human cardiac fibroblasts during early infection phase

Trypanosoma cruzi, the etiological agent of Chagas Disease, causes severe morbidity, mortality, and economic burden worldwide. Though originally endemic to Central and South America, globalization has led to increased parasite presence in most industrialized countries. About 40% of infected individuals will develop cardiovascular, neurological, and/or gastrointestinal pathologies. Accumulating evidence suggests that the parasite induces alterations in host gene expression profiles in order to facilitate infection and pathogenesis. The role of regulatory gene expression machinery during T. cruzi infection, particularly small noncoding RNAs, has yet to be elucidated. In this study, we aim to evaluate dysregulation of a class of sncRNAs called piRNAs during early phase of T. cruzi infection in primary human cardiac fibroblasts by RNA-Seq. We subsequently performed in silico analysis to predict piRNA-mRNA interactions. We validated the expression of these selected piRNAs and their targets during early parasite infection phase by stem loop qPCR and qPCR, respectively. We found about 26,496,863 clean reads (92.72%) which mapped to the human reference genome. During parasite challenge, 441 unique piRNAs were differentially expressed. Of these differentially expressed piRNAs, 29 were known and 412 were novel. In silico analysis showed several of these piRNAs were computationally predicted to target and potentially regulate expression of genes including SMAD2, EGR1, ICAM1, CX3CL1, and CXCR2, which have been implicated in parasite infection, pathogenesis, and various cardiomyopathies. Further evaluation of the function of these individual piRNAs in gene regulation and expression will enhance our understanding of early molecular mechanisms contributing to infection and pathogenesis. Our findings here suggest that piRNAs play important roles in infectious disease pathogenesis and can serve as potential biomarkers and therapeutic targets.

Thrombospondin-1 expression and modulation of Wnt and hippo signaling pathways during the early phase of Trypanosoma cruzi infection of heart endothelial cells

The protozoan parasite, Trypanosoma cruzi, causes severe morbidity and mortality in afflicted individuals. Approximately 30% of T. cruzi infected individuals present with cardiac pathology. The invasive forms of the parasite are carried in the vascular system to infect other cells of the body. During transportation, the molecular mechanisms by which the parasite signals and interact with host endothelial cells (EC) especially heart endothelium is currently unknown. The parasite increases host thrombospondin-1 (TSP1) expression and activates the Wnt/β-catenin and hippo signaling pathways during the early phase of infection. The links between TSP1 and activation of the signaling pathways and their impact on parasite infectivity during the early phase of infection remain unknown. To elucidate the significance of TSP1 function in YAP/β-catenin colocalization and how they impact parasite infectivity during the early phase of infection, we challenged mouse heart endothelial cells (MHEC) from wild type (WT) and TSP1 knockout mice with T. cruzi and evaluated Wnt signaling, YAP/β-catenin crosstalk, and how they affect parasite infection. We found that in the absence of TSP1, the parasite induced the expression of Wnt-5a to a maximum at 2 h (1.73±0.13), P< 0.001 and enhanced the level of phosphorylated glycogen synthase kinase 3β at the same time point (2.99±0.24), P<0.001. In WT MHEC, the levels of Wnt-5a were toned down and the level of p-GSK-3β was lowest at 2 h (0.47±0.06), P< 0.01 compared to uninfected control. This was accompanied by a continuous significant increase in the nuclear colocalization of β-catenin/YAP in TSP1 KO MHEC with a maximum Pearson correlation coefficient of (0.67±0.02), P< 0.05 at 6 h. In WT MHEC, the nuclear colocalization of β-catenin/YAP remained steady and showed a reduction at 6 h (0.29±0.007), P< 0.05. These results indicate that TSP1 plays an important role in regulating β-catenin/YAP colocalization during the early phase of T. cruzi infection. Importantly, dysregulation of this crosstalk by pre-incubation of WT MHEC with a β-catenin inhibitor, endo-IWR 1, dramatically reduced the level of infection of WT MHEC. Parasite infectivity of inhibitor treated WT MHEC was similar to the level of infection of TSP1 KO MHEC. These results indicate that the β-catenin pathway induced by the parasite and regulated by TSP1 during the early phase of T. cruzi infection is an important potential therapeutic target, which can be explored for the prophylactic prevention of T. cruzi infection.

Trypanosoma cruzi Modulates PIWI-Interacting RNA Expression in Primary Human Cardiac Myocytes during the Early Phase of Infection

Trypanosoma cruzi dysregulates the gene expression profile of primary human cardiomyocytes (PHCM) during the early phase of infection through a mechanism which remains to be elucidated. The role that small non-coding RNAs (sncRNA) including PIWI-interacting RNA (piRNA) play in regulating gene expression during the early phase of infection is unknown. To understand how T. cruzi dysregulate gene expression in the heart, we challenged PHCM with T. cruzi trypomastigotes and analyzed sncRNA, especially piRNA, by RNA-sequencing. The parasite induced significant differential expression of host piRNAs, which can target and regulate the genes which are important during the early infection phase. An average of 21,595,866 (88.40%) of clean reads mapped to the human reference genome. The parasite induced 217 unique piRNAs that were significantly differentially expressed (q ≥ 0.8). Of these differentially expressed piRNAs, 6 were known and 211 were novel piRNAs. In silico analysis showed that some of the dysregulated known and novel piRNAs could target and potentially regulate the expression of genes including NFATC2, FOS and TGF-β1, reported to play important roles during T. cruzi infection. Further evaluation of the specific functions of the piRNAs in the regulation of gene expression during the early phase of infection will enhance our understanding of the molecular mechanism of T. cruzi pathogenesis. Our novel findings constitute the first report that T. cruzi can induce differential expression of piRNAs in PHCM, advancing our knowledge about the involvement of piRNAs in an infectious disease model, which can be exploited for biomarker and therapeutic development.

Thrombospondin-1 Plays an Essential Role in Yes-Associated Protein Nuclear Translocation during the Early Phase of Trypanosoma cruzi Infection in Heart Endothelial Cells

The protozoan parasite Trypanosoma cruzi is the causative agent of Chagas disease. This neglected tropical disease causes severe morbidity and mortality in endemic regions. About 30% of T. cruzi infected individuals will present with cardiac complications. Invasive trypomastigotes released from infected cells can be carried in the vascular endothelial system to infect neighboring and distant cells. During the process of cellular infection, the parasite induces host cells, to increase the levels of host thrombospondin-1 (TSP-1), to facilitate the process of infection. TSP-1 plays important roles in the functioning of vascular cells, including vascular endothelial cells with important implications in cardiovascular health. Many signal transduction pathways, including the yes-associated protein 1 (YAP)/transcriptional coactivator, with PDZ-binding motif (TAZ) signaling, which are upstream of TSP-1, have been linked to the pathophysiology of heart damage. The molecular mechanisms by which T. cruzi signals, and eventually infects, heart endothelial cells remain unknown. To evaluate the importance of TSP-1 expression in heart endothelial cells during the process of T. cruzi infection, we exposed heart endothelial cells prepared from Wild Type and TSP-1 Knockout mouse to invasive T. cruzi trypomastigotes at multiple time points, and evaluated changes in the hippo signaling cascade using immunoblotting and immunofluorescence assays. We found that the parasite turned off the hippo signaling pathway in TSP-1KO heart endothelial cells. The levels of SAV1 and MOB1A increased to a maximum of 2.70 ± 0.23 and 5.74 ± 1.45-fold at 3 and 6 h, respectively, in TSP-1KO mouse heart endothelial cells (MHEC), compared to WT MHEC, following a parasite challenge. This was accompanied by a significant continuous increase in the nuclear translocation of downstream effector molecule YAP, to a maximum mean nuclear fluorescence intensity of 10.14 ± 0.40 at 6 h, compared to wild type cells. Furthermore, we found that increased nuclear translocated YAP significantly colocalized with the transcription co-activator molecule pan-TEAD, with a maximum Pearson's correlation coefficient of 0.51 ± 0.06 at 6 h, compared to YAP-Pan-TEAD colocalization in the WT MHEC, which decreased significantly, with a minimum Pearson's correlation coefficient of 0.30 ± 0.01 at 6 h. Our data indicate that, during the early phase of infection, upregulated TSP-1 is essential for the regulation of the hippo signaling pathway. These studies advance our understanding of the molecular interactions occurring between heart endothelial cells and T. cruzi, in the presence and absence of TSP-1, providing insights into processes linked to parasite dissemination and pathogenesis.

Early Regulation of Profibrotic Genes in Primary Human Cardiac Myocytes by Trypanosoma cruzi

The molecular mechanisms of Trypanosoma cruzi induced cardiac fibrosis remains to be elucidated. Primary human cardiomyoctes (PHCM) exposed to invasive T. cruzi trypomastigotes were used for transcriptome profiling and downstream bioinformatic analysis to determine fibrotic-associated genes regulated early during infection process (0 to 120 minutes). The identification of early molecular host responses to T. cruzi infection can be exploited to delineate important molecular signatures that can be used for the classification of Chagasic patients at risk of developing heart disease. Our results show distinct gene network architecture with multiple gene networks modulated by the parasite with an incline towards progression to a fibrogenic phenotype. Early during infection, T. cruzi significantly upregulated transcription factors including activator protein 1 (AP1) transcription factor network components (including FOSB, FOS and JUNB), early growth response proteins 1 and 3 (EGR1, EGR3), and cytokines/chemokines (IL5, IL6, IL13, CCL11), which have all been implicated in the onset of fibrosis. The changes in our selected genes of interest did not all start at the same time point. The transcriptome microarray data, validated by quantitative Real-Time PCR, was also confirmed by immunoblotting and customized Enzyme Linked Immunosorbent Assays (ELISA) array showing significant increases in the protein expression levels of fibrogenic EGR1, SNAI1 and IL 6. Furthermore, phosphorylated SMAD2/3 which induces a fibrogenic phenotype is also upregulated accompanied by an increased nuclear translocation of JunB. Pathway analysis of the validated genes and phospho-proteins regulated by the parasite provides the very early fibrotic interactome operating when T. cruzi comes in contact with PHCM. The interactome architecture shows that the parasite induces both TGF-β dependent and independent fibrotic pathways, providing an early molecular foundation for Chagasic cardiomyopathy. Examining the very early molecular events of T. cruzi cellular infection may provide disease biomarkers which will aid clinicians in patient assessment and identification of patient subpopulation at risk of developing Chagasic cardiomyopathy.

Thrombospondin-1 interacts with Trypanosoma cruzi surface calreticulin to enhance cellular infection

Trypanosoma cruzi causes Chagas disease, which is a neglected tropical disease that produces severe pathology and mortality. The mechanisms by which the parasite invades cells are not well elucidated. We recently reported that T. cruzi up-regulates the expression of thrombospondin-1 (TSP-1) to enhance the process of cellular invasion. Here we characterize a novel TSP-1 interaction with T. cruzi that enhances cellular infection. We show that labeled TSP-1 interacts specifically with the surface of T. cruzi trypomastigotes. We used TSP-1 to pull down interacting parasite surface proteins that were identified by mass spectrometry. We also show that full length TSP-1 and the N-terminal domain of TSP-1 (NTSP) interact with T. cruzi surface calreticulin (TcCRT) and other surface proteins. Pre-exposure of recombinant NTSP or TSP-1 to T. cruzi significantly enhances cellular infection of wild type mouse embryo fibroblasts (MEF) compared to the C-terminal domain of TSP-1, E3T3C1. In addition, blocking TcCRT with antibodies significantly inhibits the enhancement of cellular infection mediated by the TcCRT-TSP-1 interaction. Taken together, our findings indicate that TSP-1 interacts with TcCRT on the surface of T. cruzi through the NTSP domain and that this interaction enhances cellular infection. Thus surface TcCRT is a virulent factor that enhances the pathogenesis of T. cruzi infection through TSP-1, which is up-regulated by the parasite.

Perspectives on the Trypanosoma cruzi-host cell receptor interactions

Chagas disease is caused by the parasite Trypanosoma cruzi. The critical initial event is the interaction of the trypomastigote form of the parasite with host receptors. This review highlights recent observations concerning these interactions. Some of the key receptors considered are those for thromboxane, bradykinin, and for the nerve growth factor TrKA. Other important receptors such as galectin-3, thrombospondin, and laminin are also discussed. Investigation into the molecular biology and cell biology of host receptors for T. cruzi may provide novel therapeutic targets.

Trypanosoma cruzi uses a 45-kDa mucin for adhesion to mammalian cells

A set of monoclonal antibodies that recognizes a Trypanosoma cruzi 45-kDa protein was produced and used to characterize this molecule and study its role in trypanosome adhesion to heart myoblasts. We found that the 45-kDa protein is a surface mucin, is expressed only in invasive trypomastigotes, but not in noninvasive epimastigotes or amastigotes, and is released by the trypanosome in culture medium. One of the monoclonal antibodies (Mab B5) from this set inhibits the attachment of trypomastigotes to heart myoblasts preventing trypanosome entry, whereas the others (Mabs B4 and F1) do not. This inhibition was seen with the B5 hybridoma culture supernatant, with the purified Mab B5 IgG or with Mab B5 Fab fragments. These novel findings identify the 45-kDa mucin as a new T. cruzi ligand that is used by invasive forms of this organism to adhere to heart myoblasts.

A ligand that Trypanosoma cruzi uses to bind to mammalian cells to initiate infection

We purified a soluble gp83 trans-sialidase (gp83-TSA), from phospholipase C-treated Trypanosoma cruzi trypomastigote membranes, which binds to myoblasts, fibroblasts and macrophages to mediate trypanosome entry. Myoblasts display a single class of receptors for the gp83-TSA present at 4x10(4) per myoblast with a K(d) of 8 nM. Monovalent Fab fragments of the monoclonal antibody 4A4 specific for gp83-TSA inhibit gp83-TSA binding to myoblasts, fibroblasts and macrophages, block the trypanosomes from attaching to and entering these cells and neutralize T. cruzi infection in BALB/c mice. This is the first demonstration that gp83-TSA is a ligand that T. cruzi uses to attach to cells.

Overexpression of neural cell adhesion molecule in Chagas' myocarditis

The expression of the neural cell adhesion molecule (NCAM) was studied in normal human myocardium and in Chagas' disease myocarditis. We found that NCAM is expressed in the conduction system as well as the myocardium in the fetal heart, but its expression is restricted to the conduction system and absent in the adult myocardium. Chagas' disease is an American endemic disease caused by the Trypanosoma cruzi parasite, which produces myocarditis and a blockade of the conduction system, resulting in cardiac dysfunction. We studied the expression of NCAM in paraffin-embedded human heart tissues from 34 autopsies of patients with Chagas' myocarditis and from murine and canine experimental acute Chagas' myocarditis, using a polyclonal anti-NCAM antibody and immunohistochemistry. Our results show a dramatic upregulation of NCAM expression in the intercalated discs of cardiomyocytes in acute and chronic Chagas' myocarditis. Surprisingly, the NCAM signal was detected in intracellular nests of amastigote forms of the parasite, within infected cardiomyocytes of human and experimental Chagas' myocarditis. In contrast, cardiac cell-cell adhesion proteins, N-cadherin and beta-catenin, were found in intercalated discs distorted by the infection but absent from the amastigote nests. Proteins reactive to several antibodies against NCAM were detected by Western immunoblotting in cultured T cruzi parasites and in trypomastigote forms of T cruzi extracted from the blood of infected mice. The upregulation of NCAM in Chagas' myocarditis and the expression of NCAM or a NCAM-like protein by T cruzi suggest that NCAM may act as a receptor for tissue targeting and cellular invasion by T cruzi in Chagas' disease.

Signal transduction in human macrophages by gp83 ligand of Trypanosoma cruzi: trypomastigote gp83 ligand up-regulates trypanosome entry through protein kinase C activation

We found that Trypanosoma cruzi trypomastigote cloned surface ligand (gp83 trans-sialidase) signals macrophages to up-regulate parasite entry by activating protein kinase C (PKC). Incubation of r-gp83 ligand with macrophages activates PKC and this activation is abolished when r-gp83 is depleted by immunoprecipitation with anti-r-gp83 antibodies, which recognize the secreted gp83 of trypomastigotes by immunoblotting. This activation is seen as early as 15 min with maximal activity at 60 min and correlates with the concentration of macrophage cell cytosol. Bisindolylmaleimide I, a PKC inhibitor, abolished the activation of PKC induced by r-gp83 ligand. Incubation of macrophages with r-gp83 ligand significantly enhanced the number of trypanosomes per cell. Bisindolylmaleimide I also inhibited the enhancement of trypomastigote uptake by macrophages induced by the r-ligand. These results demonstrate that T. cruzi uses a novel mechanism to signal cells in the process of trypanosome entry, via a secreted trypanosome ligand which signals macrophages through activation of PKC.

Signal transduction in human macrophages by gp83 ligand of Trypanosoma cruzi: trypomastigote gp83 ligand up-regulates trypanosome entry through the MAP kinase pathway

We found that Trypanosoma cruzi trypomastigote cloned surface ligand (gp83 trans-sialidase) signals human macrophages to up-regulate parasite entry by inducing tyrosine phosphorylation of MAP kinase. Preincubation of human macrophages with r-gp83 transsialidase significantly enhanced both the percentage of phagocytosed trypanosomes and the number of trypanosomes per cell in a concentration dependent fashion. Incubation of r.gp83 with macrophages induced tyrosine phosphorylation of several macrophage proteins. This enhancement was inhibited by genistein, a tyrosine kinase inhibitor. The r-trypanosome ligand enhanced tyrosine phosphorylation of ERK1 and this enhancement was specifically inhibited by the inhibitor of MAP kinase phosphorylation, PD 98059, or by genistein. PD 98050 or genistein also inhibited the enhancement of trypomastigote uptake by macrophages induced by the r-ligand. These results indicate that T. cruzi uses a novel mechanism to signal cells in the process of trypanosome entry, via a secreted trypanosome ligand which signals macrophages through the MAP kinase pathway.

A protein secreted by Trypanosoma cruzi capable of inducing the entry of inert particles into HeLa cells

Trypanosoma cruzi requires an intracellular environment to multiply within its mammalian host. We describe the purification and some properties of a protein secreted exclusively by the metacyclic (infective) forms of the parasite. This permeabilizing protein (relative molecular mass 64,000) was secreted under our experimental conditions only when the parasites interacted with HeLa cells, HeLa membranes, or wheat-germ lectin. The protein is thermostable, and its biological activity is inhibited by formaldehyde but not by ethanol or acetone. At low concentrations and over short treatment times, this protein acts as a permeabilizer and induces endocytosis. No significant protease or neuraminidase activity was found. When adsorbed onto bentonite particles and incubated in the presence of non-phagocytic cells the protein facilitated the penetration of the particles into the cells. Immune serum directed against the protein neutralized its cytotoxic action and reduced the rate of penetration of metacyclic forms into both macrophages and non-phagocytic cells. Our results suggest that the protein secreted by the parasite plays a key role in the penetration of its infective form into the host cell.

Characterization of carbohydrate binding proteins in Trypanosoma cruzi

Trypanosoma cruzi is an obligatory intracellular protozoan parasite that causes Chagas' disease in humans and invades a great variety of mammalian cells. The nature of the ligand(s) and receptor components in both T. cruzi and target cells remains controversial, although it seems to involve an interaction with oligosaccharides. In an attempt to identify possible ligands on the parasite, we have searched for the presence of carbohydrate binding proteins (CBPs) in T. cruzi. By fluorescence-activated cell sorter analysis using a panel of fluoresceinated glyco- and neoglycopeptides with well characterized glycans, the presence of at least two different CBPs was identified on the surface of T. cruzi epimastigotes and trypomastigotes. The specificity of binding of the two CBPs seems to be mediated by galactose and mannose residues. The mannose- and galactose-mediated CBPs from epimastigotes and trypomastigotes were purified to homogeneity by affinity chromatography on immobilized thyroglobulin and identified as 60-70-kDa glycoproteins. Purified CBPs were able to specifically bind with high affinity to murine and human macrophages as well as other cell types susceptible to infection by T. cruzi but not to fat or neuronal cells. This binding was inhibited by the corresponding ligands. Moreover, the mannose-mediated CBP binding was completely abolished by alpha-mannosidase treatment of the cells. These results suggest a possible role for the CBPs in the recognition events between the parasite and target cells and/or in the interaction of the epimastigotes with the insect gut cells.

Purification of a 74-kilodalton surface glycoprotein from heart myoblasts that inhibits binding and entry of Trypanosoma cruzi into heart cells

We have identified and purified a 74 kDa surface glycoprotein from heart myoblasts that specifically binds to Trypanosoma cruzi trypomastigotes, and inhibits the attachment and internalization of trypomastigotes into these cells. The native form of the 74 kDa glycoprotein was purified to apparent homogeneity by preparative scale isoelectrofocusing and anion exchange chromatography. Pre-incubation of trypomastigotes with soluble 74 kDa glycoprotein strongly inhibited the binding and internalization of trypomastigotes into heart myoblast monolayers in a concentration dependent-manner. Pre-incubation of heart myoblast monolayers with antibodies specific to the purified 74 kDa glycoprotein also strongly inhibited trypomastigote binding and internalization into heart cells in a concentration dependent manner. These results support the notion that the surface 74 kDa glycoprotein is a target molecule on heart myoblast cells to which T. cruzi binds in order to invade them.

Purification of a Trypanosoma cruzi trypomastigote 60-kilodalton surface glycoprotein that primes and activates murine lymphocytes

We have purified a glycoprotein with a relative molecular mass of 60 kDa and present on the surface of Trypanosoma cruzi trypomastigotes and studied its ability to prime and stimulate the proliferation of murine spleen cells. T. cruzi trypomastigote membrane proteins were separated by preparative isoelectrofocusing. A trypomastigote 60-kDa surface protein with an isoelectric point of 4.2 was enriched by chromatofocusing and was readily purified in native form to homogeneity by gel filtration on a Superose column by use of a fast protein liquid chromatography system. Biotinylated wheat germ agglutinin, Ricinus communis agglutinin, and Datura stramonium agglutinin bound to blots containing the purified trypomastigote 60-kDa surface protein, indicating that this protein was glycosylated. The purified trypomastigote 60-kDa glycoprotein was recognized by antibodies produced during human infection, and immunoglobulin G against the purified glycoprotein immunoprecipitated a biotinylated 60-kDa molecule from the surface of trypomastigotes but not epimastigotes. Specific immunoglobulin G against the 60-kDa glycoprotein also increased the uptake of trypomastigotes and promoted parasite killing by macrophages. The purified 60-kDa glycoprotein was able to specifically activate primed lymphocytes, since there was a significant increase in [3H]thymidine incorporation by spleen cells obtained from CBA mice primed with this glycoprotein, with respect to control values. Furthermore, the 60-kDa glycoprotein did not stimulate unprimed spleen cells, indicating that the lymphoproliferation induced by this glycoprotein was specific and was not due to polyclonal activation. Our findings indicate that this T. cruzi trypomastigote 60-kDa surface glycoprotein primes and activates lymphocytes, which could lead to a beneficial immune response in the host.

Attachment of Trypanosoma cruzi to host cells: a monoclonal antibody recognizes a trypomastigote stage-specific epitope on the gp 83 required for parasite attachment

A set of monoclonal antibodies against the purified surface gp 83 of T. cruzi trypomastigotes was produced and the ability of these monoclonals to inhibit the attachment of trypomastigotes to heart myoblasts was investigated. Western blots of solubilized trypomastigotes, epimastigotes or amastigotes probed with this set of monoclonal antibodies show that the gp 83 is present in invasive trypomastigotes, but not in non-invasive epimastigotes or amastigotes. One monoclonal antibody (Mab 4A4) from this set inhibits the attachment of trypomastigotes to heart myoblasts, whereas the others (MAbs 2H6, 4B9, 2D11) do not. These results show that the Mab 4A4 recognizes an epitope on the gp 83 of invasive trypomastigotes required for parasite binding to host cells.

An 85-kilodalton surface antigen gene family of Trypanosoma cruzi encodes polypeptides homologous to bacterial neuraminidases

We have determined the sequence of a cDNA (Tt34c1) encoding a Trypanosoma cruzi trypomastigote stage-specific 85-kDa surface glycoprotein (gp85). Within the peptide sequence of Tt34c1 are two 8-amino acid motifs, Ser-X-Asp-X-Gly-X-Thr-Trp, that are characteristic of bacterial neuraminidases. Analysis of the Tt34c1 sequence predicts the presence of an amino-terminal signal sequence and a hydrophobic carboxy-terminus that is probably replaced by a glycosyl phosphatidylinositol membrane anchor. Gp85 is encoded by an extensive multigene family that is distributed throughout the genome and can be divided into subsets on the basis of oligonucleotide hybridisation patterns. By sequencing products of polymerase chain reaction (PCR) amplification of the 5' end of trypomastigote gp85 mRNA we show that multiple copies of the gene family are transcribed simultaneously in a trypanosome population. Comparison of the sequence of the PCR clones and another gp85 cDNA showed a highly conserved region 5' of the first methionine extending 180 nt into the coding sequence. Insertions and point mutations were observable outside these homologous sequences demonstrating the variant nature of the gp85 mRNAs.