Oximic compounds as potential inhibitors of metacaspase-2 (TbMCA2) of Trypanosoma brucei.

Metacaspases are a distinct class of cysteine proteases predominantly found in plants, fungi, and protozoa, crucial for regulating programmed cell death (PCD). They possess unique structural features and differ markedly from caspases in their activation mechanisms and substrate specificities, with a notable preference for binding basic residues in substrates. In this study, we introduced vanillin-derived oximic compounds to explore their pharmaceutical potential. We evaluated these compounds for their inhibitory effects on TbMCA2, a metacaspase in Trypanosoma brucei, identifying AO-7, AO-12, and EO-20 as promising inhibitors. AO-12 showed significant potential as a non-competitive inhibitor with notable IC50 values. Molecular docking studies were also conducted to evaluate the binding affinity of these compounds for TbMCA2. This research is particularly relevant given the urgent need for more effective and less toxic treatments for trypanosomiasis, a parasitic disease caused by trypanosomes. The absence of available vaccines and the limitations imposed by drug toxicity underscore the importance of these findings. Our study represents a significant advancement in developing therapeutic agents targeting metacaspases in trypanosomatids and highlights the necessity of understanding metacaspase regulation across various species. It provides valuable insights into inhibitor sensitivity and potential species-specific therapeutic strategies. In conclusion, this research opens promising avenues for novel therapeutic agents targeting metacaspases in trypanosomatids, addressing a critical gap in combating neglected diseases associated with these pathogens. Further research is essential to refine the efficacy and safety profiles of these compounds, aiming to deliver more accessible and effective therapeutic solutions to populations afflicted by these debilitating diseases.

Cell Death of P. vivax Blood Stages Occurs in Absence of Classical Apoptotic Events and Induces Eryptosis of Parasitized Host Cells.

Elucidation of pathways regulating parasite cell death is believed to contribute to identification of novel therapeutic targets for protozoan diseases, and in this context, apoptosis-like cell death has been reported in different groups of protozoa, in which metacaspases seem to play a role. In the genus Plasmodium, apoptotic markers have been detected in P. falciparum and P. berghei, and no study focusing on P. vivax cell death has been reported so far. In the present study, we investigated the susceptibility of P. vivax to undergo apoptotic cell death after incubating mature trophozoites with the classical apoptosis inducer staurosporine. As assessed by flow cytometry assays, staurosporine inhibited parasite intraerythrocytic development, which was accompanied by a decrease in cell viability, evidenced by reduced plasmodial mitochondrial activity. However, typical signs of apoptosis, such as DNA fragmentation, chromatin condensation, and nuclear segregation, were not detected in the parasites induced to cell death, and no significant alteration in metacaspase gene expression (PvMCA1) was observed under cell death stimulus. Interestingly, dying parasites positively modulated cell death (eryptosis) of host erythrocytes, which was marked by externalization of phosphatidylserine and cell shrinkage. Our study shows for the time that P. vivax blood stages may not be susceptible to apoptosis-like processes, while they could trigger eryptosis of parasitized cells by undergoing cell death. Further studies are required to elucidate the cellular machinery involved in cell death of P. vivax parasites as well as in the modulation of host cell death.

Metacaspase of Saccharomyces cerevisiae (ScMCA-Ia) presents different catalytic cysteine in a processed and non-processed form.

Metacaspases are cysteine proteases belonging to the CD clan of the C14 family. They possess important characteristics, such as specificity for cleavage after basic residues (Arg/Lys) and dependence on calcium ions to exert their catalytic activity. They are defined by the presence of a large subunit (p20) and a small subunit (p10) and are classified into types I, II, and III. Type I metacaspases have a characteristic pro-domain at the N-terminal of the enzyme, preceding a region rich in glutamine and asparagine. In the yeast Saccharomyces cerevisiae, a type I metacaspase is found. This organism encodes a single metacaspase that participates in the process of programmed cell death by apoptosis. The study focuses on cloning, expressing, and mutating Saccharomyces cerevisiae metacaspase (ScMCA-Ia). Mutations in Cys155 and Cys276 were introduced to investigate autoprocessing mechanisms. Results revealed that Cys155 plays a crucial role in autoprocessing, initiating a conformational change that activates ScMCA-Ia. Comparative analysis with TbMCA-IIa highlighted the significance of the N-terminal region in substrate access to the active site. The study proposes a two-step processing mechanism for type I metacaspases, where an initial processing step generates the active form, followed by a distinct intermolecular processing step. This provides new insights into ScMCA-Ia's activation and function. The findings hold potential implications for understanding cellular processes regulated by metacaspases. Overall, this research significantly advances knowledge in metacaspase biology.

Refolding of metacaspase 5 from Trypanosoma cruzi, structural characterization and the influence of c-terminal in protein recombinant production.

Metacaspases are known to have a fundamental role in apoptosis-like, a programmed cellular death (PCD) in plants, fungi, and protozoans. The last includes several parasites that cause diseases of great interest to public health, mostly without adequate treatment and included in the neglected tropical diseases category. One of them is Trypanosoma cruzi which causes Chagas disease and has two metacaspases involved in its PCD: TcMCA3 and TcMCA5. Their roles seemed different in PCD, TcMCA5 appears as a proapoptotic protein negatively regulated by its C-terminal sequence, while TcMCA3 is described as a cell cycle regulator. Despite this, the precise role of TcMCA3 and TcMCA5 and their atomic structures remain elusive. Therefore, developing methodologies to allow investigations of those metacaspases is relevant. Herein, we produced full-length and truncated versions of TcMCA5 and applied different strategies for their folded recombinant production from E. coli inclusion bodies. Biophysical assays probed the efficacy of the production method in providing a high yield of folded recombinant TcMCA5. Moreover, we modeled the TcMCA5 protein structure using experimental restraints obtained by XLMS. The experimental design for novel methods and the final protocol provided here can guide studies with other metacaspases. The production of TcMCA5 allows further investigations as protein crystallography, HTS drug discovery to create potential therapeutic in the treatment of Chagas' disease and in the way to clarify how the PCD works in the parasite.

Proteolytic cleavage of Arabidopsis thaliana phosphoenolpyruvate carboxykinase-1 modifies its allosteric regulation.

Phosphoenolpyruvate carboxykinase (PEPCK) plays a crucial role in gluconeogenesis. In this work, we analyze the proteolysis of Arabidopsis thaliana PEPCK1 (AthPEPCK1) in germinating seedlings. We found that the amount of AthPEPCK1 protein peaks at 24-48 h post-imbibition. Concomitantly, we observed shorter versions of AthPEPCK1, putatively generated by metacaspase-9 (AthMC9). To study the impact of AthMC9 cleavage on the kinetic and regulatory properties of AthPEPCK1, we produced truncated mutants based on the reported AthMC9 cleavage sites. The Δ19 and Δ101 truncated mutants of AthPEPCK1 showed similar kinetic parameters and the same quaternary structure as the wild type. However, activation by malate and inhibition by glucose 6-phosphate were abolished in the Δ101 mutant. We propose that proteolysis of AthPEPCK1 in germinating seedlings operates as a mechanism to adapt the sensitivity to allosteric regulation during the sink-to-source transition.

Plasmodium vivax metacaspase 1 (PvMCA1) catalytic domain is conserved in field isolates from Brazilian Amazon

In the present study, we investigated the genetic diversity of Plasmodium vivax metacaspase 1 (PvMCA1) catalytic domain in two municipalities of the main malaria hotspot in Brazil, i.e., the Juruá Valley, and observed complete sequence identity among all P. vivax field isolates and the Sal-1 reference strain. Analysis of PvMCA1 catalytic domain in different P. vivax genomic sequences publicly available also revealed a high degree of conservation worldwide, with very few amino acid substitutions that were not related to putative histidine and cysteine catalytic residues, whose involvement with the active site of protease was herein predicted by molecular modeling. The genetic conservation presented by PvMCA1 may contribute to its eligibility as a druggable target candidate in vivax malaria.

Programmed cell death in soybean seed coats.

Seed coat is the tissue which establishes an interface between the seed inner tissues and external environment. Our group has shown that cowpea seed coat undergoes coordinated events of programmed cell death (PCD) during development. In relation to germinating seed coats, little is known on PCD events. The goal here was to investigate the biochemical aspects of germinating soybean seed coat, focusing on proteolytic activities related to PCD. In gel and in solution activity profiles of quiescent and germinating seed coat extracts revealed a complex pattern of caspase- and metacaspase-like cysteine protease activities. Trypsin inhibitor and reserve proteins were revealed as potential substrates for these proteases. A pancaspase inhibitor (z-VAD-CHO) affected the radicle length of seeds germinated under its presence. Ultrastructural analysis showed the absence of cell organelles in all seed coat layers after imbibition, while oligonucleosome fragments peaked at 72 h after imbibition (HAI). Altogether, the data suggest the presence of biochemical PCD hallmarks in germinating soybean seed coat and point to the involvement of the detected protease activities in processes such as reserve protein mobilization and weakening of seed coat.

Involvement of HbMC1-mediated cell death in tapping panel dryness of rubber tree (Hevea brasiliensis).

Tapping panel dryness (TPD) causes a significant reduction in the latex yield of rubber tree (Hevea brasiliensis Muell. Arg.). It is reported that TPD is a typical programmed cell death (PCD) process. Although PCD plays a vital role in TPD occurrence, there is a lack of detailed and systematic study. Metacaspases are key regulators of diverse PCD in plants. Based on our previous result that HbMC1 was associated with TPD, we further elucidate the roles of HbMC1 on rubber tree TPD in this study. HbMC1 was up-regulated by TPD-inducing factors including wounding, ethephon and H2O2. Moreover, the expression level of HbMC1 was increased along with TPD severity in rubber tree, suggesting a positive correlation between HbMC1 expression and TPD severity. To investigate its biological function, HbMC1 was overexpressed in yeast (Saccharomyces cerevisiae) and tobacco (Nicotiana benthamiana). Transgenic yeast and tobacco overexpressing HbMC1 showed growth retardation compared with controls under H2O2-induced oxidative stress. In addition, overexpression of HbMC1 in yeast and tobacco reduced cell survival after high-concentration H2O2 treatment and resulted in enhanced H2O2-induced leaf cell death, respectively. A total of 11 proteins, rbcL, TM9SF2-like, COX3, ATP9, DRP, HbREF/Hevb1, MSSP2-like, SRC2, GATL8, CIPK14-like and STK, were identified and confirmed to interact with HbMC1 by yeast two-hybrid screening and co-transformation in yeast. The 11 proteins mentioned above are associated with many biological processes, including rubber biosynthesis, stress response, autophagy, carbohydrate metabolism, signal transduction, etc. Taken together, our results suggest that HbMC1-mediated PCD plays an important role in rubber tree TPD, and the identified HbMC1-interacting proteins provide valuable information for further understanding the molecular mechanism of HbMC1-mediated TPD in rubber tree.

DNA-damage inducible protein 1 is a conserved metacaspase substrate that is cleaved and further destabilized in yeast under specific metabolic conditions.

Metacaspases, distant relatives of metazoan caspases, have been shown to participate in programmed cell death in plants and in progression of the cell cycle and removal of protein aggregates in unicellular eukaryotes. However, since natural proteolytic substrates have scarcely been identified to date, their roles in these processes remain unclear. Here, we report that the DNA-damage inducible protein 1 (Ddi1) represents a conserved protein substrate for metacaspases belonging to divergent unicellular eukaryotes (trypanosomes and yeasts). We show that although the recognized cleavage sequence is not identical among the different model organisms tested, in all of them the proteolysis consequence is the removal of the ubiquitin-associated domain (UBA) present in the protein. We also demonstrate that Ddi1 cleavage is tightly regulated in vivo as it only takes place in yeast when calcium increases but under specific metabolic conditions. Finally, we show that metacaspase-mediated Ddi1 cleavage reduces the stability of this protein which can certainly impact on the many functions ascribed for it, including shuttle to the proteasome, cell cycle control, late secretory pathway regulation, among others.

Necrotic and apoptotic cell death induced by Captan on Saccharomyces cerevisiae.

Captan is one of the most widely used broad-spectrum fungicide applied to control several early and late diseases of grapes, apples, and other fruits and vegetables, and as other phthalimide fungicides is defined as a multisite compound with thiol-reactivity. Captan can affect non-target organisms as yeasts, modifying microbial populations and fermentation processes. In this study, we asked whether Captan thiol-reactivity and other mechanisms are involved in acute Captan-induced cell death on aerobic growing Saccharomyces cerevisiae. Thus for, we analyze cellular protein and non-protein thiols, cell membrane integrity, reactive oxygen species accumulation, phosphatidylserine externalization, and apoptotic mutants behavior. The results showed that when submitted to acute Captan treatment most cells lost their membrane integrity and died by necrosis due to Captan reaction with thiols. However, part of the cells, even maintaining their membrane integrity, lost their culture ability. These cells showed an apoptotic behavior that may be the result of non-protein thiol depletion and consequent increase of reactive oxygen species (ROS). ROS accumulation triggers a metacaspase-dependent apoptotic cascade, as shown by the higher viability of the yca1-deleted mutant. Together, necrosis and apoptosis are responsible for the high mortality detected after acute Captan treatment of aerobically growing cells of S. cerevisiae.

Processing of metacaspase 2 from Trypanosoma brucei (TbMCA2) broadens its substrate specificity.

Metacaspases are members of the cysteine peptidase family and may be implicated in programmed cell death in plants and lower eukaryotes. These proteases exhibit calcium-dependent activity and specificity for arginine residues at P1. In contrast to caspases, they do not require processing or dimerization for activity. Indeed, unprocessed metacaspase-2 of Trypanosoma brucei (TbMCA2) is active; however, it has been shown that cleavages at Lys55 and Lys268 increase TbMCA2 hydrolytic activity on synthetic substrates. The processed TbMCA2 comprises 3 polypeptide chains that remain attached by non-covalent bonds. Replacement of Lys55 and Lys268 with Gly via site-directed mutagenesis results in non-processed but enzymatically active mutant, TbMCA2 K55/268G. To investigate the importance of this processing for the activity and specificity of TbMCA2, we performed activity assays comparing the non-processed mutant (TbMCA2 K55/268G) with the processed TbMCA2 form. Significant differences between TbMCA2 WT (processed form) and TbMCA2 K55/268G (non-processed form) were observed. Specifically, we verified that although non-processed TbMCA2 is active when assayed with small synthetic substrates, the TbMCA2 form does not exhibit hydrolytic activity on large substrates such as azocasein, while processed TbMCA2 is able to readily digest this protein. Such differences can be relevant for understanding the physiological regulation and function of TbMCA2.

Genome-wide identification and expression analysis of the metacaspase gene family in Hevea brasiliensis.

Metacaspases, a family of cysteine proteases, have been suggested to play important roles in programmed cell death (PCD) during plant development and stress responses. To date, no systematic characterization of this gene family has been reported in rubber tree (Hevea brasiliensis). In the present study, nine metacaspase genes, designated as HbMC1 to HbMC9, were identified from whole-genome sequence of rubber tree. Multiple sequence alignment and phylogenetic analyses suggested that these genes were divided into two types: type I (HbMC1-HBMC7) and type II (HbMC8 and HbMC9). Gene structure analysis demonstrated that type I and type II HbMCs separately contained four and two introns, indicating the conserved exon-intron organization of HbMCs. Quantitative real-time PCR analysis revealed that HbMCs showed distinct expression patterns in different tissues, suggesting the functional diversity of HbMCs in various tissues during development. Most of the HbMCs were regulated by drought, cold, and salt stress, implying their possible functions in regulating abiotic stress-induced cell death. Of the nine HbMCs, HbMC1, HbMC2, HbMC5, and HbMC8 displayed a significantly higher relative transcript accumulation in barks of tapping panel dryness (TPD) trees compared with healthy trees. In addition, the four genes were up-regulated by ethephon (ET) and methyl jasmonate (MeJA), indicating their potential involvement in TPD resulting from ET- or JA-induced PCD. In summary, this work provides valuable information for further functional characterization of HbMC genes in rubber tree.

Caspases in plants: metacaspase gene family in plant stress responses.

Programmed cell death (PCD) is an ordered cell suicide that removes unwanted or damaged cells, playing a role in defense to environmental stresses and pathogen invasion. PCD is component of the life cycle of plants, occurring throughout development from embryogenesis to the death. Metacaspases are cysteine proteases present in plants, fungi, and protists. In certain plant-pathogen interactions, the PCD seems to be mediated by metacaspases. We adopted a comparative genomic approach to identify genes coding for the metacaspases in Viridiplantae. We observed that the metacaspase was divided into types I and II, based on their protein structure. The type I has a metacaspase domain at the C-terminus region, presenting or not a zinc finger motif in the N-terminus region and a prodomain rich in proline. Metacaspase type II does not feature the prodomain and the zinc finger, but has a linker between caspase-like catalytic domains of 20 kDa (p20) and 10 kDa (p10). A high conservation was observed in the zinc finger domain (type I proteins) and in p20 and p10 subunits (types I and II proteins). The phylogeny showed that the metacaspases are divided into three principal groups: type I with and without zinc finger domain and type II metacaspases. The algae and moss are presented as outgroup, suggesting that these three classes of metacaspases originated in the early stages of Viridiplantae, being the absence of the zinc finger domain the ancient condition. The study of metacaspase can clarify their assignment and involvement in plant PCD mechanisms.