Mass spectrometry characterization of trypanothione and novel peptides of medical importance isolated from Acanthamoeba polyphaga.

This paper presents unequivocal results about the presence of trypanothione and its precursor glutathionespermidine from the opportunistic human pathogen Acanthamoeba polyphaga. They were isolated by RP-HPLC as thiolbimane derivatives and characterized using matrix-assisted laser desorption ionization-time-of-flight (MALDI-TOF/TOF). Additionally RP-HPLC demonstrated that thiol-bimane compounds corresponding to cysteine and glutathione were also present in A. polyphaga. Besides trypanothione, we want to report four new peptides in trophozoites, a tetrapeptide, a hexapeptide, a heptapeptide and a nonapeptide. Trypanothione and two of the thiol peptides, the hexapeptide and heptapeptide, are oxidized since the reduced forms increase in amount when the normal extract is treated by DTT or by electrolytic reduction that convert the oxidized forms to reduced ones. On the other hand, they disappear when the amoeba extract is treated with NEM or when the amoeba culture is treated with various inhibitors of NADPH-dependent disulfidereducing enzymes. Comparison of the thiol peptides, including trypanothione from A. polyphaga with extracts from human lymphocytes showed that they are not present in the latter. Therefore, some of the peptides here reported could be used as antigens for rapid detection of these parasites. In regard to the presence of the enzymes that synthesize and reduce trypanothione in A. polyphaga we suggest that they can be used as drug targets.

Proteomic analysis of Trypanosoma cruzi epimastigotes subjected to heat shock.

Trypanosoma cruzi is exposed to sudden temperature changes during its life cycle. Adaptation to these variations is crucial for parasite survival, reproduction, and transmission. Some of these conditions may change the pattern of genetic expression of proteins involved in homeostasis in the course of stress treatment. In the present study, the proteome of T. cruzi epimastigotes subjected to heat shock and epimastigotes grow normally was compared by two-dimensional gel electrophoresis followed by mass spectrometry for protein identification. Twenty-four spots differing in abundance were identified. Of the twenty-four changed spots, nineteen showed a greater intensity and five a lower intensity relative to the control. Several functional categories of the identified proteins were determined: metabolism, cell defense, hypothetical proteins, protein fate, protein synthesis, cellular transport, and cell cycle. Proteins involved in the interaction with the cellular environment were also identified, and the implications of these changes are discussed.

Glycolipid ester-type heterodimers from Ipomoea tyrianthina and their pharmacological activity.

Tyrianthins A (1) and B (2), two new partially acylated glycolipid ester-type heterodimers were isolated from Ipomoea tyrianthina. Scammonic acid A was determined as the glycosidic acid in both monomeric units. Tyrianthin A (1) (IC(50) 0.24+/-0.09 microM and E(max) 81.80+/-0.98%), and tyrianthin B (2) (IC(50) 0.14+/-0.08 microM and E(max) 87.68+/-0.72%) showed significant in vitro relaxant effect on aortic rat rings, in endothelium- and concentration-dependent manners. Also, these compounds were able to increase the release of GABA and glutamic acid in brain cortex, and displayed weak antimycobacterial activity.

Naegleria fowleri: a free-living highly pathogenic amoeba contains trypanothione/trypanothione reductase and glutathione/glutathione reductase systems.

This paper presents definitive data showing that the thiol-bimane compound isolated and purified by HPLC from Naegleria fowleri trophozoites unequivocally corresponds by matrix assisted laser-desorption ionization-time-of-flight MS, to the characteristic monoprotonated ion of trypanothione-(bimane)(2) [M(+)H(+)] of m/z 1104.57 and to the trypanothione-(bimane) of m/z 914.46. The trypanothione disulfide T(S)(2) was also found to have a molecular ion of m/z 723.37. Additionally HPLC demonstrated that thiol-bimane compounds corresponding to cysteine and glutathione were present in Naegleria. The ion patterns of the thiol-bimane compounds prepared from commercial trypanothione standard, Entamoeba histolytica and Crithidia luciliae are identical to the Naegleria thiol-bimane compound. Partially purified extracts from N. fowleri showed the coexistence of glutathione and trypanothione reductases activities. There is not doubt that the thiol compound trypanothione, which was previously thought to occur only in Kinetoplastida, is also present in the human pathogens E. histolytica and N. fowleri, as well as in the non-pathogenic euglenozoan E. gracilis. The presence of the trypanothione/trypanothione reductase system in N. fowleri creates the possibility of using this enzyme as a new "drug target" for rationally designed drugs to eliminate the parasite, without affecting the human host.

Identification of trypanothione from the human pathogen Entamoeba histolytica by mass spectrometry and chemical analysis.

In this paper, we present definitive data to show, from ESI (electrospray ionization) studies, that the thiol-bimane compound isolated and purified from Entamoeba histolytica trophozoites, corresponds unequivocally to the structure of trypanothione. Trypanothione disulphide was shown to have a molecular ion of m/z 722. It was further demonstrated by MALDI-TOF (matrix-assisted laser desorption ionization-time-of-flight) MS that this thiol compound also corresponds to the characteristic monoprotonated ion of trypanothione-(bimane)(2), which has a molecular ion of m/z 1103.95. The ion pattern of the thiol-bimane compound prepared from the commercial trypanothione standard is identical with the E. histolytica thiol-bimane compound. After HPLC separation, chemical amino acid analysis by dabsylation and dansylation of the thiol bimane compound from Entamoeba showed the presence of the following trypanothione components: glutamic acid, cysteic acid, glycine and spermidine. We can conclude from these highly reliable MS experiments and chemical analyses that E. histolytica contains the thiol compound trypanothione, which was previously thought to occur only in trypanosomatids.

Trypanothione reductase from the human parasite Entamoeba histolytica: a new drug target.

Although there is a general agreement that the protist Entamoeba histolytica lacks glutathione, it has been a matter of dispute as to whether this human parasite contains the glutathione derivative known as trypanothione. In the present study, we describe a gene for the TR (trypanothione reductase) obtained from E. histolytica by PCR amplification of its DNA. After Northern-blot analysis, the radiolabelled DNA probe from Trypanosoma cruzi hybridizes with the total RNA of Entamoeba, showing that the TR gene is expressed as mRNA. We have demonstrated the presence of the NADPH-dependent TR activity in vitro with partially purified extracts and showed also that the thiol-bimane compound isolated and purified from E. histolytica trophozoites, unequivocally corresponds, by matrix-assisted laser-desorption ionization-time-of-flight MS, to the characteristic monoprotonated ion of trypanothione-(bimane)(2) with m/z 1104.4 and the trypanothione-(bimane) with m/z 914.3. The PCR product consisted of 1476 bp (491 deduced amino acids), has sequences diagnostic for the reducing catalytic site (CVNVGC) as well as domains for binding NADPH, FAD I and FAD II that are present in all members of this group of disulphide-reducing enzymes, as well as those unique to TRs. The putative protein sequence is 86% identical with that of TR from T. cruzi and it is also clearly distinguishable from other related reductases by phylogenetic analysis. We can conclude, from these highly reliable experiments, that E. histolytica contains the TR enzyme and the thiol compound trypanothione that was previously supposed to occur only in trypanosomatids.

Low-molecular-mass thiol compounds from a free-living highly pathogenic amoeba, Naegleria fowleri.

Acid extracts labelled with the fluorescent reagent monobromobimane and separated by HPLC have enabled the detection of low-molecular-mass thiol compounds in Naegleria fowleri for the first time. The amounts detected are expressed in nmol/1 x 10(6) trophozoites cultivated at various stages of growth in the appropriate culture medium. N. fowleri is a highly pathogenic free-living amoeba, in which we found important thiol compounds, some of them in their reduced and oxidized forms. Unlike cysteine and glutathione, a number of these are not represented in normal human lymphocytes. Some of these thiol compounds from Naegleria must have their respective disulphide reductases, although the presence of thiol-disulphide exchange reactions must be considered. Ovothiol A, with antioxidant properties, is an example of a compound that is kept reduced by trypanothione in trypanosomatids, although no disulphide reductase for ovothiol A has yet been discovered. In our case we were unable to detect this biothiol in Naegleria. The presence of thiol compounds that seem to be particular to this pathogen and which are not present in human lymphocytes opens the possibility of searching for disulphide-reducing enzymes that can serve as drug targets.

Thiol compounds from a free-living pathogenic opportunistic amoeba, Acanthamoeba polyphaga.

New bimane-reacting compounds from perchloric acid extracts have been detected by HPLC from Acanthamoeba polyphaga. The main compounds detected are cysteine, glutathione and other novel thiol compounds. All of these compounds must be thiols, since they disappear or decrease substantially when treated by N -ethylmaleimide prior to acetonitrile/bimane derivatization. Cysteine and glutathione increase in quantity when dithiothreitol reduction is applied to the fresh extract. This means that they are likely to be present in their oxidized and reduced form and indicates the possible presence of a corresponding thiol/disulphide enzymic system. There are other compounds that have a different behaviour, since although they can react with bimane, they do not disappear if treated previously by N -ethylmaleimide. This shows that they are not thiols but can react with bimane. The main thiol compounds found to be present, in both the parasite and the host lymphocyte cells, were cysteine and glutathione. We were unable to detect ovothiol A in Acanthamoeba but instead we found another thiol compound that could be structurally related to trypanothione. The new thiol compounds unique to this parasite and not present in lymphocytes will permit the study of disulphide-reducing enzymes as potential drug targets.