Genes of cathepsin L-like proteases in Trypanosoma rangeli isolates: markers for diagnosis, genotyping and phylogenetic relationships.

We have sequenced genes encoding cathepsin L-like (CatL-like) cysteine proteases from isolates of Trypanosoma rangeli from humans, wild mammals and Rhodnius species of Central and South America. Phylogenetic trees of sequences encoding mature CatL-like enzymes of T. rangeli and homologous genes from other trypanosomes, Leishmania spp. and bodonids positioned sequences of T. rangeli (rangelipain) closest to T. cruzi (cruzipain). Phylogenetic tree of kinetoplastids based on sequences of CatL-like was totally congruent with those derived from SSU rRNA and gGAPDH genes. Analysis of sequences from the CatL-like catalytic domains of 17 isolates representative of the overall phylogenetic diversity and geographical range of T. rangeli supported all the lineages (A-D) previously defined using ribosomal and spliced leader genes. Comparison of the proteolytic activities of T. rangeli isolates revealed heterogeneous banding profiles of cysteine proteases in gelatin gels, with differences even among isolates of the same lineage. CatL-like sequences proved to be excellent targets for diagnosis and genotyping of T. rangeli by PCR. Data from CatL-like encoding genes agreed with results from previous studies of kDNA markers, and ribosomal and spliced leader genes, thereby corroborating clonal evolution, independent transmission cycles and the divergence of T. rangeli lineages associated with sympatric species of Rhodnius.

Bioactivity of crude extracts and some constituents of Blutaparon portulacoides (Amaranthaceae).

Crude extracts (aerial parts and roots, both dried), methylenedioxyflavonol, and a mixture of acyl steryl glycosides isolated from Blutaparon portulacoides, were assayed for their toxicity against Trypanosoma cruzi trypomastigotes and Leishmania amazonensis amastigotes from axenic cultures. The antimicrobial activity was also investigated, in a screening conducted using fifteen strains of Gram-positive and Gram-negative bacteria, along with the yeasts, Candida albicans and Candida tropicalis. To assess the antibacterial activity of the isolated compounds, the minimum inhibitory concentrations (MICs) were determined. There are no reports of acyl steryl glycosides in the genus Blutaparon and their biological activities are being evaluated for the first time.

Proteinase activities in total extracts and in medium conditioned by Acanthamoeba polyphaga trophozoites.

Acanthamoeba species can cause granulomatous encephalitis and keratitis in man. The mechanisms that underlie tissue damage and invasion by the amoebae are poorly understood, but involvement of as yet uncharacterized proteinases has been suggested. Here, we employed gelatin-containing gels and azocasein assays to examine proteinase activities in cell lysates and in medium conditioned by Acanthamoeba polyphaga trophozoites. Azocasein hydrolysis by cell lysates was optimally detected at pH 4.0-5.0 and was predominantly associated with the activity of cysteine proteinases. Compatible with enzyme activation during secretion, culture supernatants additionally contained a prominent azocasein hydrolyzing activity attributable to serine proteinases; these enzymes were better detected at pH 6.0 and above, and resolved at 47, 60, 75, 100, and >110 kDa in overlay gelatin gels. Although a similar banding profile was observed in gels of trophozoite lysates, intracellular serine proteinases were shown to be activated during electrophoresis and to split the substrate during migration in sodium dodecyl sulfate gels. Blockage of serine proteinases with phenylmethylsulfonylfluoride prior to electrophoresis permitted the detection of 43-, 59-, 70-, and 100-130-kDa acidic cysteine proteinases in cell lysates, and of 3 (43, 70, and 130 kDa) apparently equivalent enzymes in culture supernatants. Under the conditions employed, no band associated with a metalloproteinase activity could be depicted in substrate gels, although the discrete inhibition of supernatants' azocaseinolytic activity by 1,10-phenanthroline suggested secretion of some metalloproteinase.

Axenic cultivation and partial characterization of Leishmania braziliensis amastigote-like stages.

Leishmania braziliensis strain M2903 was adapted for growth and serially maintained as amastigotes at 34 degrees C in modified UM-54 medium, with growth curves exhibiting typical log and stationary phases. In late passages, amastigote growth took place in the absence of supplementary haemin and was unaffected when the initial medium pH was adjusted between 5.4 and 6.3. In contrast to promastigotes, which were elongated and exhibited very long free flagella endowed with the paraflagellar rod (PFR), axenic amastigotes were rounded to ovoid and displayed a short flagellum restricted to the pocket area. The absence of PFR in axenic amastigotes was confirmed in Western blots and confocal immunofluorescence microscopy, by lack of reactivity with mAb 1B10. The antibody, which specifically labelled the paraflagellar structure, recognized a 70/72 kDa doublet in Trypanosoma cruzi epimastigotes and two 70/74 kDa related proteins in L. braziliensis promastigotes. Surface 125I-labelling experiments identified promastigote-specific components (> 100, 74, 45/47 and 28 kDa) and at least 1, a 76 kDa polypeptide was specific for the amastigote stage. While axenic amastigotes were agglutinated by both peanut (PNA) and Lens culinaris (LCA) agglutinins, respectively at 50 and 12.5 micrograms/ml, promastigotes were not agglutinated by PNA and agglutinated in the presence of LCA at concentrations of 100 micrograms/ml and higher. Axenic amastigotes infected rat bone marrow-derived macrophages and were avidly taken up by J774 cells, from which numerous organisms, able to proliferate at 34 degrees C in UM-54 medium, could be recovered 48 h later.

Uptake of Z-Tyr[125I]-AlaCHN2, an irreversible cysteine proteinase inhibitor, by lesion amastigotes, axenic amastigotes and promastigotes of Leishmania mexicana.

Radioiodinated N-benzyloxycarbonyl-tyrosyl-alanyl diazomethane (Z-Tyr[125I]-AlaCHN2) was previously shown to selectively label two (28 and 31 kDa) Leishmania mexicana cysteine proteinases common to both the promastigote and the amastigote stages. Here we have confirmed the specificity of the compound towards two similar enzymes of axenic L. mexicana amastigotes and demonstrated that lesion amastigotes, axenic amastigotes and stationary promastigotes internalized the 125I-labeled inhibitor at different rates. Uptake of Z-Tyr[125I]-AlaCHN2 by the parasites, which was not significantly modified by changing the medium pH, was clearly correlated with the binding of the compound to the 28- and 31-kDa cysteine proteinases, as judged by the specificity of enzyme labeling in gelatin gels and the recovery of 75% or more parasite-associated radioactivity in TCA-insoluble fractions. For all three developmental stages, uptake markedly increased with time and linearly up to 60 min, but throughout the period examined, radiolabel accumulation occurred more efficiently in amastigotes. By 5 h, when values were near or at saturation, radioactivity (in cpm/microgram of total protein) associated with lesion amastigotes was 1.8- and 2.9-times that recovered from axenic amastigotes and stationary promastigotes, respectively. Pulse-chase experiments, in which cysteine proteinases were fully blocked with Z-Phe-AlaCHN2 prior to the pulse with Z-Tyr[125I]-AlaCHN2, showed that labeling of the amastigote enzymes could be partially restored, whereas labeling of promastigote proteinases could not, after a 5-h chase period in inhibitor-free medium.

Uptake of Z-Tyr{125I}-AlaCHN2, an irreversible cysteine proteinase inhibitor, by lesion amastigotes, axenic amastigotes and promastigotes of Leishmania mexicana

Radioiodinated N-benzyloxycarbonyl-tyrosyl-alanyl diazomethane (Z-Tyr[l25I]-AlaCHN2) was previously shown to selectively label two (28 and 31 kDa) Leishmania mexicana cysteine proteinases common to both the promastigote and the amastigote stages. Here we have confirmed the specificity of the compound towards two similar enzymes of axenic L. mexicana amastigotes and demonstrated that lesion amastigotes, axenic amastigotes and stationary promastigotes internalized the l25I-labeled inhibitor at different rates. Uptake of Z-Tyr[l25I]-AlaCHN2 by the parasites, which was not significantly modified by changing the medium pH, was clearly correlated with the binding of the compound to the 28- and 3l-kDa cysteine proteinases, as judged by the specificity of enzyme labeling in gelatin gels and the recovery of 75 per cent or more parasite-associated radioactivity in TCA-insoluble fractions. For all three developmental stages, uptake markedly increased with time and linearly up to 60 min, but throughout the period examined, radiolabel accumulation occurred more efficiently in amastigotes. By 5 h, when values were near or at saturation, radioactivity (in cpm/mug of total protein) associated with lesion amastigotes was 1.8- and 2.9-times that recovered from axenic amastigotes and stationary promastigotes, respectively. Pulse-chase experiments, in which cysteine proteinases were fully blocked with Z-Phe-AlaCHN2 prior to the pulse with Z-Tyr[l25I]-AlaCHN2, showed that labeling of the amastigote enzymes could be partially restored, whereas labeling of promastigote proteinases could not, after a 5-h chase period in inhibitor-free medium.

A radioiodinated peptidyl diazomethane detects similar cysteine proteinases in amastigotes and promastigotes of Leishmania (L.) mexicana and L. (L.) amazonensis.

Cysteine proteinase activities were examined in lesion amastigotes as well as in stationary-phase promastigotes of Leishmania (L.) mexicana and Leishmania (L.) amazonensis isolates. Enzyme detection in gelatin gels revealed that amastigotes of three L. (L.) mexicana isolates (M379, IOC-0561, and IP) shared similar proteinases, including the multiple low-molecular-weight (25-35 kDa) cysteine proteinases. High cysteine proteinase activity was also observed in L. (L.) amazonensis amastigotes, but the banding profile was different in two of the isolates examined. Promastigotes displayed fewer low-molecular-weight proteinase bands, and these were much less intense as compared with those of lesion amastigotes. Independently of the Leishmania isolates and developmental stages examined, incubation of the parasites for 2 h with 0.2 microM radioiodinated N-benzyl-oxycarbonyl-tyrosyl-alanyl diazomethane (Z-Tyr[125I]-AlaCHN2) markedly and selectively labeled bands comigrating with the 28- and 31-kDa cysteine proteinases. Under reducing conditions, labeling was associated with four similar polypeptides (29-34 kDa), which were also detected when incubation with Z-Tyr[125I]-AlaCHN2 was carried out after cell lysis. Labeling was completely abolished if lysates were first incubated with 20 microM E-64 and then exposed to the 125I-tagged inhibitor, thus confirming the specificity of the compound toward cysteine proteinases.

Trypanosoma cruzi: identification of proteinases in shed components of trypomastigote forms.

Trypanosoma cruzi trypomastigotes were shown to predominantly release high molecular weight components (above 50 kDa) when allowed to shed for 1 hour in protein-free media. Under these conditions, parasites were not damaged or lysed, as was indicated by: (a) their normal mobility; (b) their retaining of some of the labelled proteins; (c) the unchanged pattern of biotinylated surface proteins after shedding. Shed components were shown to display proteinase activities, detected at 97 and 50/60 kDa in gelatin gels. These proteolytic activities were completely inhibited by E-64, indicating that they were due to cysteine proteinases.

Leishmania mexicana: proteinase activities and megasomes in axenically cultivated amastigote-like forms.

Proteinase activities and megasomes were examined in axenically cultivated amastigote-like forms, freshly isolated lesion amastigotes, and promastigotes. Megasomes were absent in promastigotes and present in both amastigote stages, but they seemed to be less numerous and more homogeneous in cultured amastigote-like forms. Contrasting with the poor detection of proteinase activities in promastigote lysates, both types of amastigotes shared multiple proteinases, which were classified in two groups: (a) 60 to > 100 kDa, o-phenanthroline-sensitive activities; and (b) 23- to 40-kDa cysteine proteinases, of which those resolving as 35- to 40-kDa bands in gelatin gels were more clearly visualized in lysates of cultured amastigote-like forms. Incubation of both kinds of amastigotes with 0.25 to 1.0 microM of either Z-Phe-AlaCHN2 or Z-Tyr-AlaCHN2 selectively inactivated cysteine proteinases, but not the 35- to 40-kDa activities, which, again, were detected with higher intensity in cultured amastigote-like forms. The expression of the 35- to 40-kDa proteinases progressively increased when promastigotes were allowed to transform into amastigote-like forms or when lesion amastigotes were incubated at 34 degrees C for different time periods prior to exposure to Z-Phe-AlaCHN2; activities comparable to those of amastigote-like forms were attained within 24 to 48 hr. The activities resistant to Z-Phe-AlaCHN2 in vivo were fully inhibited by E-64 or Z-Phe-AlaCHN2 during gelatin digestion, suggesting that the 35- to 40-kDa proteinases were mainly inactive before cell lysis. The presence of cycloheximide (at 10, 50, and 100 micrograms/ml) during the pulse with Z-Phe-AlaCHN2 abolished the 35- to 40-kDa activities of lesion amastigotes and significantly reduced gelatin digestion by the similar enzymes of cultured amastigote-like forms. In the latter, the 35- to 40-kDa proteinases were no more detected when cycloheximide was given 60 min prior to Z-Phe-AlaCHN2. The results indicate higher rates of synthesis of the 35- to 40-kDa enzymes, and the existence of a more representative pool of inactive enzyme precursors, in cultured amastigote-like forms.

Leishmania amazonensis: specific labeling of amastigote cysteine proteinases by radioiodinated N-benzyloxycarbonyl-tyrosyl-alanyl diazomethane.

Living Leishmania amazonensis amastigotes were incubated with radioiodinated N-benzyloxycarbonyl-L-tyrosyl-L-alanyl diazomethane (Z-Tyr-AlaCHN2), an irreversible inhibitor of mammalian cathepsins B and L. Parasite lysates were subjected to electrophoresis in gelatin-containing sodium dodecyl sulfate-acrylamide gels to detect regions of proteolytic activity, and the distribution of the inhibitor was ascertained by autoradiography. Of the three main bands of proteolysis associated with cysteine proteinases, two, with apparent molecular weights of 28 and 31 kDa, were shown to be labeled. The third enzyme activity, detected at the 35-kDa region in substrate gels, was only faintly labeled. The distribution of labeled bands was similar when lysates of untreated parasites were electrophoresed and the gels incubated with the radioiodinated inhibitor. Under reducing conditions, the inhibitor bound to polypeptides of 29, 31, 32, and 34 kDa, of which the first and the last were the most intensely labeled. Polypeptides with the same apparent molecular weights were labeled when amastigote lysates were incubated with the 125I inhibitor. Uptake of radioactivity by the parasites was time and concentration-dependent and more than 80% of the total counts could be precipitated with trichloroacetic acid. Radioactivity associated with the amastigotes was quite stable after they were pulsed with labeled inhibitor and chased for up to 24 hr in inhibitor-free medium. Both total uptake and labeling of cysteine proteinases were markedly reduced in parasites preincubated with Z-Phe-AlaCHN2 prior to exposure to Z-Tyr(125I)-AlaCHN2. However, more radioiodinated inhibitor was taken up by parasites preincubated with cold inhibitor and chased in inhibitor-free medium, suggesting de novo synthesis or processing of inactive enzyme precursors.

Intracellular differentiation of Leishmania amazonensis promastigotes to amastigotes: presence of megasomes, cysteine proteinase activity and susceptibility to leucine-methyl ester.

Intracellular differentiation of Leishmania promastigotes to amastigotes is a critical step in the establishment of infection. In this report three related features of mexicana subspecies amastigotes were used to follow the differentiation of the parasites within macrophages. Early after infection, (a) parasites did not contain ultrastructurally recognizable megasomes, (b) cysteine proteinase activity of parasite lysates was not detected in gelatin-containing acrylamide gels, and (c) parasites were essentially resistant to L-leucine-methyl ester (Leu-OMe). Typical megasomes were first identified on the 5th day, were more prevalent on day 7, and underwent swelling in macrophages exposed to Leu-OMe. Cysteine proteinase activity was first detected on day 3 and increased thereafter. Susceptibility to Leu-OMe of parasites studied in situ or isolated from infected macrophages increased with time of intracellular residence and by 7 days approached that of amastigotes isolated from mouse lesions. In contrast, parasites derived from either promastigotes or amastigotes were equally susceptible to another leishmanicidal compound, tryptophanamide (Trp-NH2). The results provide additional support for the involvement of megasomes and their cysteine proteinases in parasite killing by Leu-OMe, and highlight the slow pace of the intracellular differentiation of L. amazonensis promastigotes to amastigotes.

Leishmania amazonensis: involvement of cysteine proteinases in the killing of isolated amastigotes by L-leucine methyl ester.

L-leucine-methyl ester (Leu-OMe) kills Leishmania mexicana amazonensis amastigotes by a mechanism which requires proteolytic cleavage of the ester. N-Benzyloxycarbonyl-phenylalanyl-alanyl diazomethane (Z-Phe-AlaCHN2), a specific and irreversible inhibitor of cysteine proteinases, was used to characterize the enzymes involved in parasite destruction. It was shown that (1) amastigotes preincubated with micromolar concentrations of Z-Phe-AlaCHN2 survived challenge with Leu-OMe concentrations lethal to control parasites; (2) the proteolytic activity of 25- to 33-kDa cysteine proteinases in parasite lysates subjected to electrophoresis in gelatin-containing acrylamide gels was selectively inhibited in parasites pretreated with Z-Phe-AlaCHN2 and chased in inhibitor-free medium; and (3) cysteine proteinase activity was also inhibited in gels incubated with amino acid and dipeptide esters, possibly because the compounds were acting either as substrates (e.g., Leu-Leu-OMe) or as inhibitors (e.g., Ile-OMe) of the enzyme. The results support the involvement of low molecular weight cysteine proteinases in the destruction of amastigotes by Leu-OMe. Characterization of the structure and substrate specificity of the enzymes may permit the rational development of more selectively leishmanicidal amino acid derivatives.

Proteinase inhibitors protect Leishmania amazonensis amastigotes from destruction by amino acid esters.

Lysosomotropic amino acid esters and amides kill Leishmania amazonensis amastigotes by a mechanism which probably involves enzymatic hydrolysis of the compounds and rapid accumulation of less permeant amino acid within the parasites. We show here that, in agreement with this model, the proteinase inhibitors antipain and chymostatin prevented the killing of intracellular and isolated parasites by L-leucine methyl ester (Leu-OMe). Survival of Leishmania within macrophages was assessed microscopically, and that of isolated amastigotes was measured by tetrazolium (MTT) reduction. Near maximal protection of intracellular parasites was obtained after 24 h incubation of macrophage cultures with 50 micrograms ml-1 antipain or chymostatin. Incubation for greater than 1 h with chymostatin or greater than 4 h with antipain alone resulted in loss of viability of the parasites. Protective activity was only slightly diminished by 20 h chase of isolated parasites in inhibitor-free medium. Two synthetic chymostatin analogues, Z-Val-Phe-Sc and Z-Ile-Phe-Sc, protected isolated amastigotes at 4 or 10 micrograms ml-1. With the exception of Trp-NH2, the toxicity of which was only minimally inhibited, antipain and chymostatin also prevented parasite destruction by other amino acid derivatives. Finally, in concentration-dependent fashion, the inhibitors reduced the accumulation of [3H]leucine in isolated amastigotes incubated with [3H]Leu-OMe. Since uptake of labelled ester was unaffected, we postulate that protection involves inhibition of the parasite enzymes which hydrolyse the amino acid derivatives.

Destruction of Leishmania mexicana amazonensis amastigotes by leucine methyl ester: protection by other amino acid esters.

L-Amino acid esters, such as leucine methyl ester (Leu-OMe) can destroy intracellular as well as isolated amastigotes of Leishmania mexicana amazonensis by a mechanism which may involve ester hydrolysis by parasite enzymes. We show here that several other esters prevented the killing of the amastigotes by Leu-OMe. Destruction of Leishmania within macrophages in culture was assessed microscopically and viability of isolated parasites was monitored by reduction of the tetrazolium MTT. The main features of the protective effect were similar for intracellular and for isolated amastigotes. Thus, (i) effective prevention of parasite killing required that the protective ester be present in the medium prior to and during exposure of infected cells or parasites to Leu-OMe; (ii) the same esters protected intracellular and isolated Leishmania against damage by Leu-OMe. Ranks of protective activity, as determined on isolated amastigotes were: Gly-OBz greater than Tyr-OMe greater than Ile-OMe greater than Met-OMe greater than Val-OMe greater than Ala-OMe greater than Gly-OMe greater than D-Leu-OMe; (iii) several esters were inactive in both systems (Leu-OBz, Trp-OMe and Phe-OMe). Protective activity was associated with leishmanicidal (e.g. Gly-OBz, Tyr-OMe) as well as with non-leishmanicidal (e.g. Ile-OMe, Val-OMe) esters. The results are compatible with the hypothesis that protective esters inhibit the activity of parasite enzyme(s) which hydrolyse Leu-OMe.

From lysosomes to cells, from cells to Leishmania: amino acid esters as potential chemotherapeutic agents.

Amino acid esters can disrupt lysosomes and damage monocytes and certain lymphocyte populations. Lysosomal disruption involves pH trapping of the esters, followed by their hydrolysis by as yet unidentified enzymes. Accumulation of the more polar amino acids is assumed to cause osmotic lysis of the organelles. We have discovered that certain amino acid esters and amides destroy Leishmania mexicana amazonensis amastigotes lodged within macrophages in culture, as well as parasites isolated from mouse lesions. This paper reviews the amino acid specificity of parasite killing, the resistance of amastigotes derived from infection of macrophages with promastigotes, the involvement of an acidified compartment within the parasites, and the protection conferred by other amino acid esters, and by the protease inhibitors antipain and chymostatin, against the destruction of amastigotes by Leucine-methyl ester. Studies with tritiated esters confirm the critical role of ester hydrolysis for leishmanicidal activity and strengthen the view that similar mechanisms underlie disruption of lysosomes and destruction of Leishmania. Characterization of the parasite organelles and of the enzymes involved in the leishmanicidal activity as well as structure-activity studies may permit the design of compounds more selective for the parasites.

From lysosomes to cells, from cells to Leishmania: amino acid esters as potential chemotherapeutic agents

Amino acid esters can disrupt lysosomes and damage monocytes and certain lymphocyte populations. Lysosomal disruption involves pH trapping of the esters, followed by their hydrolyssis by as yet unidentified enzymes. Accumulation of the more polar amino acids is assumed to cause osmotic lysis of the organelles. we have discovered that certain amino acid esters and amides destroy Leishmania mexicana amazonensis amastigores lodged within macrophages in culture, as well as parasites isolated from mouse lesions. This paper reviews the amino acid specificity of parasite killing, the resistance of amastigotes derived from infection of macrophages with promastigotes, the involvement of an acidified compartment within the parasites, and the protection conferred by other amino acid esters, and the protease inhibitors antipain and chymostatin, aginst the destruction of amastigotes by Leucine-methyl ester. Studies with tritiated esters confirm the critical role of ester hydrolysis for leishmanicidal activity and strengthen the view that similar mechanisms underlie disruption of lysosomes and destruction of Leismania. Characterization of the parasite organelles and of the enzymes involved in the leishmanicidal activity as well as structure-activity studies may permit the design of compounds mor selective for the parasites