Molecular Comparison of the Mitochondrial and Cytoplasmic hsp 70 of Trypanosoma cruzi, Trypanosoma brucei and Leishmania major

ABSTRACT. We compared the expression and localization of the mitochondrial and cytoplasmic hsp70 of the protozoans Trypanosoma cruzi, Trypanosoma brucei and Leishmania major. The mitochondrial protein is encoded by multiple mRNA in all species, while the cytoplasmic protein is encoded by a single mRNA. In all three species, the mitochondrial hsp70 is concentrated in the kinetoplast, a submitochondrial structure that houses the unusual DNA (kDNA) that characterizes this group of organisms, while the cytoplasmic protein is distributed throughout the cell. These results suggest that, in all kinetoplastid species, mt-hsp70 has a specific function in kDNA biology, possibly in the processes of kDNA replication, RNA editing or kinetoplast structure.     

Trypanosoma cruzi Experimental Infection Impacts on the Thymic Regulatory T Cell Compartment

The dynamics of regulatory T cells in the course of Trypanosoma cruzi infection is still debated. We previously demonstrated that acute murine T. cruzi infection results in an impaired peripheral CD4⁺Foxp3⁺ T cell differentiation due to the acquisition of an abnormal Th1-like phenotype and altered functional features, negatively impacting on the course of infection. Moreover, T. cruzi infection induces an intense thymic atrophy. As known, the thymus is the primary lymphoid organ in which thymic-derived regulatory T cells, known as tTregs, differentiate. Considering the lack of available data about the effect of T. cruzi infection upon tTregs, we examined tTreg dynamics during the course of disease. We confirmed that T. cruzi infection induces a marked loss of tTreg cell number associated to cell precursor exhaustion, partially avoided by glucocorticoid ablation- and IL-2 survival factor depletion. At the same time, tTregs accumulate within the CD4 single-positive compartment, exhibiting an increased Ki-67/Annexin V ratio compared to controls. Moreover, tTregs enhance after the infection the expression of signature markers (CD25, CD62L and GITR) and they also display alterations in the expression of migration-associated molecules (α chains of VLAs and chemokine receptors) such as functional fibronectin-driven migratory disturbance. Taken together, we provide data demonstrating profound alterations in tTreg compartment during acute murine T. cruzi infection, denoting that their homeostasis is significantly affected. The evident loss of tTreg cell number may compromise the composition of tTreg peripheral pool, and such sustained alteration over time may be partially related to the immune dysregulation observed in the chronic phase of the disease.     

Cell signalling and Trypanosoma cruzi invasion

Mammalian cell invasion by the protozoan pathogen Trypanosoma cruzi is critical to its survival in the host. To promote its entry into a wide variety of non-professional phagocytic cells, infective trypomastigotes exploit an arsenal of heterogenous surface glycoproteins, secreted proteases and signalling agonists to actively manipulate multiple host cell signalling pathways. Signals initiated in the parasite upon contact with mammalian cells also function as critical regulators of the invasion process. Whereas the full spectrum of cellular responses modulated by T. cruzi is not yet known, mounting evidence suggests that these pathways impinge on a number of cellular processes, in particular the ubiquitous wound-repair mechanism exploited for lysosome-mediated parasite entry. Furthermore, differential engagement of host cell signalling pathways in a cell type-specific manner and modulation of host cell gene expression by T. cruzi are becoming recognized as essential determinants of infectivity and intracellular survival by this pathogen.     

Biochemical Requirements for Intracellular Invasion by Trypanosoma cruzi: Protein Synthesis1

The effects of irreversible inhibition of protein synthesis by pactamycin in either infective forms of Trypanosoma cruzi or mammalian host cells on cellular invasion by this human pathogen were investigated. Treatment of bloodstream forms of T. cruzi with pactamycin markedly reduced their ability to bind either fibroblast-like cells of monkey origin or myoblasts of rat origin. The number of amastigote forms that could be established intracellularly was also significantly decreased with respect to control values obtained when mock-treated (medium alone) trypomastigotes were incubated with the cells. Pactamycin treatment also reduced the infectivity of T. cruzi trypomastigotes for mice as evidenced by both significantly reduced parasitemia levels and mortality rates when compared with those of control mice infected with mock-treated parasites. Inhibition of protein synthesis in the host cells neither prevented cell infection by untreated trypomastigotes nor altered the percentages of infected cells or the magnitude of the infection in vitro. These results indicate that protein synthesis is a requirement for cell invasion by T. cruzi and that the parasite can establish itself and replicate within cells relying on its own protein synthesis ability.     

Growth of Isolated Amastigotes of Trypanosoma cruzi in Cell-Free Medium1

Amastigotes of Trypanosoma cruzi were purified from overlays of infected Vero cell cultures by centrifugation over a discontinuous gradient of metrizamide. Pure amastigote preparations were usually recovered from the pellet under the layer of specific gravity 1.086. The isolated amastigotes grew in cell-free ML-15HA medium. Growth rate for the different strains of T. cruzi were in the order Y > Tulahuan > CL. The generation time of amastigotes in ML-15HA medium was 16.8, 18.0, and 26.4 h for the Y, Tulahuen, and CL strains, respectively, in the presence of 5% CO₂) and 16.8, 31.2, and 36.4 h, respectively, in the absence of CO₂. Intracellular amastigotes did not differ ultrastructurally from amastigotes from either the density-gradient fractionation or culture in cell-free medium.     

细胞周期蛋白E2基因的过度表达与胃腺癌细胞迁徙的关系

从基因芯片筛选出差异表达的基因中一个细胞周期蛋白 (cyclin)E2基因 ,深入研究周期蛋白E2在高转移性胃腺癌细胞系RF 4 8细胞中的生物学作用 .首先通过合成硫代磷酸化修饰的反义、正义和错配寡核苷酸片段 ,使用半定量RT PCR和Western印迹方法分别检测被 3种寡核苷酸转染的RF 4 8细胞在 1～ 5d内周期蛋白E2基因及它可能调控下游靶基因之一FGFR基因和蛋白质的表达 ,检测寡核苷酸转染的RF 4 8细胞周期和凋亡细胞 ,观察寡核苷酸转染RF 4 8细胞的软琼脂集落形成、运动能力和体外侵袭能力 .结果表明 ,修饰的反义寡核苷酸在有效地抑制RF 4 8细胞中周期蛋白E2表达上调后 ,RF 4 8细胞的迁徙能力被显著降低 ,其增殖、运动能力没有变化 .周期蛋白E2基因的主要作用并不是促细胞分裂 ,也与细胞的增殖、运动能力无关 ,周期蛋白E2基因的过度表达与胃腺癌的迁徙性存在相关性 ,其触发肿瘤的侵袭性可能通过某种机制调控其下游靶基因之一成纤维细胞生长因子受体 (FGFR)基因的表达来实现的     

Growth and Differentiation of Trypanosoma cruzi Cultivated with a Triatoma infestans Embryo Cell Line*

SYNOPSIS. Trypanosoma cruzi strain Peru was cultivated in the presence of an established cell line of Triatoma infestans embryo cells (TI-32). Bloodstream trypomastigotes differentiated into amastigote-like cells (first differentiation phase) which multiplied to form large clusters of cells. Because of their clustering nature, a new term, “staphylomastigotes,” has been proposed for this stage. After 10 days of cultivation, 90% of the staphylomastigotes underwent differentiation (2nd differentiation phase) to trypomastigotes (?98%) or epimastigotes (?2%). Bloodstream trypomastigotes cultivated without TI-32 cells underwent the first, but not the 2nd differentiation phase, although occasional epimastigotes were seen (< 1%). The evidence presented suggests that TI-32 cells produce a labile factor(s) important not only for initiation of the 2nd differentiation phase but also for maintaining the parasites in the trypomastigote stage. The pH of the culture medium was not the initiating factor for the 2nd differentiation phase. Infectivity studies indicated that staphylomastigotes were as infective as bloodstream trypomastigotes, but that metacyclic trypomastigotes isolated from culture after the 2nd differentiation phase were slightly more infective than bloodstream forms. Electromicrographs of styphylomastigotes do not provide any evidence of exchange of genetic material between cells.     

Downregulation of Mitochondrial Porin Inhibits Cell Growth and Alters Respiratory Phenotype in Trypanosoma brucei

Porin is the most abundant outer membrane (OM) protein of mitochondria. It forms the aqueous channel on the mitochondrial OM and mediates major metabolite flux between mitochondria and cytosol. Mitochondrial porin in Trypanosoma brucei, a unicellular parasitic protozoan and the causative agent of African trypanosomiasis, possesses a β-barrel structure similar to the bacterial OM porin OmpA. T. brucei porin (TbPorin) is present as a monomer as well as an oligomer on the mitochondrial OM, and its expression is developmentally regulated. In spite of its distinct structure, the TbPorin function is similar to those of other eukaryotic porins. TbPorin RNA interference (RNAi) reduced cell growth in both procyclic and bloodstream forms. The depletion of TbPorin decreased ATP production by inhibiting metabolite flux through the OM. Additionally, the level of trypanosome alternative oxidase (TAO) decreased, whereas the levels of cytochrome-dependent respiratory complexes III and IV increased in TbPorin-depleted mitochondria. Furthermore, the depletion of TbPorin reduced cellular respiration via TAO, which is not coupled with oxidative phosphorylation, but increased the capacity for cyanide-sensitive respiration. Together, these data reveal that TbPorin knockdown reduced the mitochondrial ATP level, which in turn increased the capacity of the cytochrome-dependent respiratory pathway (CP), in an attempt to compensate for the mitochondrial energy crisis. However, a simultaneous decrease in the substrate-level phosphorylation due to TbPorin RNAi caused growth inhibition in the procyclic form. We also found that the expressions of TAO and CP proteins are coordinately regulated in T. brucei according to mitochondrial energy demand.Trypanosoma brucei belongs to a group of parasitic protozoa that possess a single tubular mitochondrion with a concatenated structure of mitochondrial DNA known as kinetoplast (30). T. brucei is the infectious agent of the disease African trypanosomiasis, which is spread from one mammal to another by the bite of the tsetse fly (53). During transmission from the insect vector to the mammalian host and vice versa, the parasite undergoes various developmental stages accompanied by dramatic changes in mitochondrial activities (15). The bloodstream form that grows in mammalian blood uses glucose as its energy source and suppresses many mitochondrial activities. The bloodstream-form mitochondria lack cytochromes; thus, respiration in this form is solely dependent on the cytochrome-independent trypanosome alternative oxidase (TAO) (15). In contrast, the procyclic form that lives in the insect''s midgut possesses a developed mitochondrion with a full complement of the cytochrome-dependent respiratory system and a reduced level of TAO. The procyclic-form mitochondria produce ATP by both oxidative and substrate-level phosphorylations (7). On the other hand, the bloodstream-form mitochondria do not produce ATP but hydrolyze ATP to maintain the inner membrane (IM) potential (10, 33, 39, 48). Many of the mitochondrial IM- and matrix-localized proteins in T. brucei are well characterized (11, 29, 34, 43, 45). However, the mitochondrial outer membrane (OM) proteins in this group of parasitic protozoa have been poorly explored.Mitochondrial porin, which is also known as the voltage-dependent anion-selective channel (VDAC), is the most abundant protein in the OM (17, 28). The sizes and the secondary structures of this protein are very similar among different organisms. The VDAC possesses a N-terminal α-helical domain, and the rest of the protein consists of a number of amphiphilic β-strands, which form a barrel-like structure that integrates into the lipid bilayer (16, 17, 28). Recently, the three-dimensional structure of the human VDAC has been elucidated by nuclear magnetic resonance spectroscopy and X-ray crystallography, which showed a β-barrel architecture composed of 19 β-strands and the N-terminal α-helix located horizontally midway in the pore (5). Saccharomyces cerevisiae and Neurospora crassa VDACs also possess 16 to 19 β-strands, similar to the mammalian VDAC (17).The VDAC exists as different isomeric forms in different species (16, 19). In yeasts, there are two forms: VDAC1 and VDAC2. Only VDAC1 has the channel activity and is abundantly expressed (22, 23). Animals have three isoforms: VDAC1 to VDAC3. These isoforms showed more than 80% sequence homology among themselves. However, their expression levels and tissue specificities are different (16). Plants also have multiple isoforms of the VDAC with various expression levels under different pathological conditions (19). The VDAC plays a crucial role in regulated transport of ADP, ATP, Ca²⁺, and other metabolites in and out of mitochondria (17, 28, 41). Two ATP-binding sites found at the N- and C-terminal regions in the VDAC are critical for its function (54). Downregulation of VDAC expression disrupts mitochondrial energy production (22, 25). In contrast, overexpression of the VDAC in metazoa induces apoptosis, which can be blocked by compounds that inhibit its channel activity (1, 47).The OM of gram-negative bacteria also consists of various types of porins (24, 32, 40). Based on their structures and functions, they are divided into five groups. OmpA belongs to the small β-barrel integral membrane protein family, which is composed of eight β-strands. It is highly abundant and ubiquitous among most gram-negative bacteria (21). Other types of porins include general porin OmpF, which consists of 16 β-strands; substrate-specific porins, such as LamB or maltoporin, which contains 18 β-strands; receptor-type porin FhuA, the largest β-barrel, with 22 β-strands; and phospholipase A or OMPLA, an integral membrane enzyme containing 12 β-strands (21, 24, 32, 40). The OmpA plays important roles in bacterial conjugation, adhesion, invasion, and immune evasion and also acts as the receptor for several bacteriophages through its surface-exposed loops (44).Here, we show that the T. brucei mitochondrial porin (TbPorin) possesses a predicted β-barrel structure that has fewer β-strands than other mitochondrial porins but is similar to bacterial OmpA. TbPorin is crucial for mitochondrial energy production via both oxidative and substrate-level phosphorylations. The depletion of TbPorin reduced cell growth of the procyclic form as well as the bloodstream form. Furthermore, it reveals that depletion of mitochondrial ATP level by downregulation of porin alters the electron flow via TAO and the cytochrome-dependent pathway (CP) as well as the levels of proteins in these pathways.     

Overexpression of a Zn2+-sensitive soluble exopolyphosphatase from Trypanosoma cruzi depletes polyphosphate and affects osmoregulation

We report the cloning, expression, purification, and characterization of the Trypanosoma cruzi exopolyphosphatase (TcPPX). The product of this gene (TcPPX), has 383 amino acids and a molecular mass of 43.1 kDa. TcPPX differs from most exopolyphosphatases in its preference for short-chain polyphosphate (poly P). Heterologous expression of TcPPX in Escherichia coli produced a functional enzyme that had a neutral optimum pH and was dramatically inhibited by low concentrations of Zn2+, high concentrations of basic amino acids (lysine and arginine), and heparin. TcPPX is a processive enzyme and does not hydrolyze ATP, pyrophosphate, or p-nitrophenyl phosphate, although it hydrolyzes guanosine 5'-tetraphosphate very efficiently. Overexpression of TcPPX resulted in a dramatic decrease in total short-chain poly P and partial decrease in long-chain poly P. This was accompanied by a delayed regulatory volume decrease after hyposmotic stress. These results support the role of poly P in T. cruzi osmoregulation.     

Proteolytic Activities in Cell Extracts of Trypanosoma cruzi*

SYNOPSIS. Cell extracts of culture forms of Trypanosoma cruzi are capable of hydrolysing substances belonging to 4 different groups of protease substrates: (a) substrates for trypsin-like enzymes: benzoyl-arginine-p-nitroanilide and benzoylarginine-naphtylamide: (b) substrates for aminopeptidases: leucyl. lysyl and glutamyl-β-naphtylamide; (c) a substrate for chymotrypsin-like enzymes: carbobenzoxy-L-tyrosine-p-nitrophenylester, and (d) a nonspecific substrate for a broad range of proteases: azocasein. Some physico-chemical characteristics of each enzymic reaction were studied. They were found to be distinct enough to allow attributing each hydrolytic activity to a separate enzyme.     

A Monoclonal Antibody to Alpha Tubulin Recognizes Host Cell and Trypanosoma cruzi Tubulins1

ABSTRACT. A mouse monoclonal anti-α-tubulin antibody was used to investigate the disposition of the cytoskeletal microtubules of three tissue culture cell lines–J774 macrophages, BSC-1, and Vero cells–infected with the Brazil strain of Trypanosoma cruzi. Indirect immunofluorescence light microscopy was used to demonstrate the antigenic response in host cells and parasites, simultaneously. In all morphotypes of T. cruzi, the monoclonal antibody reacted with all subpopulations of microtubules, inclusively, the subpellicular, flagellar, cytopharyngeal, and mitotic. The host cell cytoskeletal microtubule framework was revealed and the redistribution and destruction of the microtubular lattice in response to parasite infection over a 120 h period recorded. Our results show that after the initial inoculation of tissue cultures with trypomastigotes, the parasites penetrate the cells and locate in the perinuclear region of the cell where they multiply. The number and distribution of host cell microtubules were altered during the infection. The normal radial distribution of microtubules extending from the center of the cell to the periphery was destroyed. The remaining microtubules were observed at the periphery encircling, but well removed from the proliferating parasites. The complete transformation of the parasites was monitored throughout the infection with the end result being the liberation of parasites and the near complete destruction of the microtubular framework of the host cell. A residual population of dividing spheromastigotes was observed in cells liberating trypomastigotes. Colloidal gold labeling of thin sections as seen in the electron microscope affirmed the specificity of our monoclonal antibody to all subpopulations of microtubules in T. cruzi.     

Phylogeny of Triatomine Vectors of Trypanosoma cruzi Suggested by Mitochondrial DNA Sequences

The subfamily Triatominae (Hemiptera: Reduviidae) comprises hematophagous insects, most of which are actual or potential vectors of Trypanosoma cruzi, the protozoan agent of Chagas' disease (American trypanosomiasis). DNA sequence comparisons of mitochondrial DNA (mtDNA) genes were used to infer phylogenetic relationships among 32 species of the subfamily Triatominae, 26 belonging to the genus Triatoma and six species of different genera. We analyzed mtDNA fragments of the 12S and 16S ribosomal RNA genes (totaling 848-851 bp) from each of the 32 species, as well as of the cytochrome oxidase I (COI, 1447 bp) gene from nine. The phylogenetic analyses unambiguously supported several clusters within the genus Triatoma. In the morphological classification, T. costalimai was placed tentatively within the infestans complex while T. guazu was not included in any Triatoma complex. The placement of these species in the molecular phylogeny indicated that both belong to the infestans complex. We confirmed with a strong support the inclusion of T. circummaculata, a member of a different complex based on morphology, within the infestans complex. On the other hand, the present phylogenetics analysis did not support the monophyly of the infestans complex species as it was suggested in our previous studies. While no strong inference of polyphyly of the genus Triatoma was provided by the bootstrap analyses, the other species belonging to Triatomini analyzed could not be distinguished from the species of Triatoma.     

Evidence Supporting the Existence of a Host Cell Surface Receptor for Trypanosoma cruzi1

Membrane fragments from trypomastigote forms of Trypanosoma cruzi inhibited the association of intact trypomas- tigotes with rat heart myoblasts whereas a similar preparation from non-invasive epimastigotes did not. Furthermore, killed trypo- mastigotes bound to the host cell surface and prevented the attachment of living organisms. Conversely, the extent of association of killed parasites with the host cells was reduced by the presence of living flagellates. These results suggest the presence of a distinct structure(s) on the surface of rat heart myoblasts to which infective forms of T. cruzi can bind.     

Growth of isolated amastigotes of Trypanosoma cruzi in cell-free medium

Amastigotes of Trypanosoma cruzi were purified from overlays of infected Vero cell cultures by centrifugation over a discontinuous gradient of metrizamide. Pure amastigote preparations were usually recovered from the pellet under the layer of specific gravity 1.086. The isolated amastigotes grew in cell-free ML-15HA medium. Growth rate for the different strains of T. cruzi were in the order Y greater than Tulahuen greater than CL. The generation time of amastigotes in ML-15HA medium was 16.8, 18.0 and 26.4 h for the Y, Tulahuen, and CL strains, respectively, in the presence of 5% CO2, and 16.8, 31.2, and 36.4 h, respectively, in the absence of CO2. Intracellular amastigotes did not differ ultrastructurally from amastigotes from either the density-gradient fractionation or culture in cell-free medium.     

Molecular Characterization of a Novel Family of Trypanosoma cruzi Surface Membrane Proteins (TcSMP) Involved in Mammalian Host Cell Invasion

Background

The surface coat of Trypanosoma cruzi is predominantly composed of glycosylphosphatidylinositol-anchored proteins, which have been extensively characterized. However, very little is known about less abundant surface proteins and their role in host-parasite interactions.

Methodology/ Principal Findings

Here, we described a novel family of T. cruzi surface membrane proteins (TcSMP), which are conserved among different T. cruzi lineages and have orthologs in other Trypanosoma species. TcSMP genes are densely clustered within the genome, suggesting that they could have originated by tandem gene duplication. Several lines of evidence indicate that TcSMP is a membrane-spanning protein located at the cellular surface and is released into the extracellular milieu. TcSMP exhibited the key elements typical of surface proteins (N-terminal signal peptide or signal anchor) and a C-terminal hydrophobic sequence predicted to be a trans-membrane domain. Immunofluorescence of live parasites showed that anti-TcSMP antibodies clearly labeled the surface of all T. cruzi developmental forms. TcSMP peptides previously found in a membrane-enriched fraction were identified by proteomic analysis in membrane vesicles as well as in soluble forms in the T. cruzi secretome. TcSMP proteins were also located intracellularly likely associated with membrane-bound structures. We demonstrated that TcSMP proteins were capable of inhibiting metacyclic trypomastigote entry into host cells. TcSMP bound to mammalian cells and triggered Ca²⁺ signaling and lysosome exocytosis, events that are required for parasitophorous vacuole biogenesis. The effects of TcSMP were of lower magnitude compared to gp82, the major adhesion protein of metacyclic trypomastigotes, suggesting that TcSMP may play an auxiliary role in host cell invasion.

Conclusion/Significance

We hypothesized that the productive interaction of T. cruzi with host cells that effectively results in internalization may depend on diverse adhesion molecules. In the metacyclic forms, the signaling induced by TcSMP may be additive to that triggered by the major surface molecule gp82, further increasing the host cell responses required for infection.     

A Cytoplasmic New Catalytic Subunit of Calcineurin in Trypanosoma cruzi and Its Molecular and Functional Characterization

Parasitological cure for Chagas disease is considered extremely difficult to achieve because of the lack of effective chemotherapeutic agents against Trypanosoma cruzi at different stages of infection. There are currently only two drugs available. These have several limitations and can produce serious side effects. Thus, new chemotherapeutic targets are much sought after. Among T. cruzi components involved in key processes such as parasite proliferation and host cell invasion, Ca²⁺-dependent molecules play an important role. Calcineurin (CaN) is one such molecule. In this study, we cloned a new isoform of the gene coding for CL strain catalytic subunit CaNA (TcCaNA2) and characterized it molecularly and functionally. There is one copy of the TcCaNA2 gene per haploid genome. It is constitutively transcribed in all T. cruzi developmental forms and is localized predominantly in the cytosol. In the parasite, TcCaNA2 is associated with CaNB. The recombinant protein TcCaNA2 has phosphatase activity that is enhanced by Mn²⁺/Ni²⁺. The participation of TcCaNA2 in target cell invasion by metacyclic trypomastigotes was also demonstrated. Metacyclic forms with reduced TcCaNA2 expression following treatment with morpholino antisense oligonucleotides targeted to TcCaNA2 invaded HeLa cells at a lower rate than control parasites treated with morpholino sense oligonucleotides. Similarly, the decreased expression of TcCaNA2 following treatment with antisense morpholino oligonucleotides partially affected the replication of epimastigotes, although to a lesser extent than the decrease in expression following treatment with calcineurin inhibitors. Our findings suggest that the calcineurin activities of TcCaNA2/CaNB and TcCaNA/CaNB, which have distinct cellular localizations (the cytoplasm and the nucleus, respectively), may play a critical role at different stages of T. cruzi development, the former in host cell invasion and the latter in parasite multiplication.