49 research outputs found
Proteomic-based approach to gain insight into reprogramming of THP-1 cells exposed to Leishmania donovani over an early temporal window
Leishmania donovani, a protozoan parasite, is the causative agent of visceral leishmaniasis. It lives and multiplies within the harsh environment of macrophages. In order to investigate how intracellular parasite manipulate the host cell environment, we undertook a quantitative proteomic study of human monocyte-derived macrophages (THP-1) following infection with L. donovani. We used the isobaric tags for relative and absolute quantification (iTRAQ) method and liquid chromatography-tandem mass spectrometry (LC-MS/MS) to compare expression profiles of noninfected and L. donovani-infected THP-1 cells. We detected modifications of protein expression in key metabolic pathways, including glycolysis and fatty acid oxidation, suggesting a global reprogramming of cell metabolism by the parasite. An increased abundance of proteins involved in gene transcription, RNA splicing (heterogeneous nuclear ribonucleoproteins [hnRNPs]), histones, and DNA repair and replication was observed at 24 h postinfection. Proteins involved in cell survival and signal transduction were more abundant at 24 h postinfection. Several of the differentially expressed proteins had not been previously implicated in response to the parasite, while the others support the previously identified proteins. Selected proteomics results were validated by real-time PCR and immunoblot analyses. Similar changes were observed in L. donovani-infected human monocyte-derived primary macrophages. The effect of RNA interference (RNAi)-mediated gene knockdown of proteins validated the relevance of the host quantitative proteomic screen. Our findings indicate that the host cell proteome is modulated after L. donovani infection, provide evidence for global reprogramming of cell metabolism, and demonstrate the complex relations between the host and parasite at the molecular level
Germ cell apoptosis: relevance to infertility and contraception
Spermatogenesis is a dynamic process in which stem spermatogonia through a series of events become mature spermatozoa. Not all germ cells achieve maturity and cell death by apoptosis appears to be a constant feature of normal spermatogenesis in a variety of mammalian species to maintain proper germ cell numbers. It is because of the obvious importance of the germ cells in the context of species propagation, the testis has very active prosurvival and proapoptotic systems that together regulate the extent of germ cell apoptosis. A growing body of evidence demonstrates that both spontaneous and increased germ cell death are triggered by various regulatory stimuli, including deprivation of gonadotropins and intratesticular testosterone by gonadotropin-releasing hormone antagonist or by estradiol or testosterone treatment, exposure to local testicular heating, toxicants, and chemotherapeutic agents. This review focuses on the cell death events that occur in testis under various conditions and provide an assessment of the knowledgebase existing on the role of pro and anti-apoptotic proteins and involvement of the cell death receptor and the mitochondrial pathway during germ cell apoptosis. Various knockout or mutant models of pro and anti-apoptotic proteins are discussed with an aim to provide an overview of requirement of various genes in germ cell apoptosis
An Exciting Journey in Science: From Stars to Cells
14-17Schools should proactively encourage girl students to take up science by demonstrating the excitement and prospects of the field. Such proactive steps will eventually help to fill up the gender gap that we have in STEM fields
Apoptosis in Leishmania species & its relevance to disease pathogenesis
Apoptosis is a morphologically distinct form of cell death necessary for embryogenesis, tissue homeostasis and disease control in metazoans. Earlier, it was thought that apoptosis is the prerogative of multicellular organisms. However, it is now evident that unicellular organisms are also capable of undergoing apoptosis. In the context of Leishmania spp., a unicellular eukaryote responsible for causing leishmaniasis, the process of apoptosis is important for successful survival. The flagellated promastigote form of the parasite resides in the midgut of the insect vector, the female sandfly and at this niche; the cell fittest to survive to pass onto the pharynx of the fly is selected by eliminating unfit cells through apoptosis. Within the mammalian host, inside the macrophage, apoptosis is necessary to regulate cell numbers and to minimize immune reactions. With most apoptosis inducing stimuli, L. donovani shows typical features of apoptotic death like cell shrinkage, nuclear condensation and DNA fragmentation. Agents capable of precipitating apoptosis in this parasite include anti-leishmanial drugs like antimony, amphotericin B, pentamidine and miltefosine. Other agents like heat shock, treatment with staurosporine, knocking out centrin gene also precipitate apoptosis of the parasites. A pivotal role in cellular apoptosis is played by the single mitochondrion of Leishmania spp., where a fall or increase in mitochondrial potential leads to cell death by apoptosis. Ca2+ appears to be a vital ion involved in Leishmania apoptosis and partial inhibition of cytosolic Ca2+ increase achieved by chelating extracellular or intracellular Ca2+ during oxidative stress results in significant rescue of the fall of the mitochondrial membrane potential and consequently apoptosis. Elucidation of the molecular events linked to apoptotic death of Leishmania spp. might help define a more comprehensive view of the cell death machinery in terms of evolutionary origin and identify new target molecules for chemotherapeutic drug development and therapeutic intervention
Antibody-induced changes on rabbit sperm surface inhibit gamete interaction
Interaction of specific ligands with cell surface molecules may induce reorganization of surface components. A monoclonal antibody (B-12) against sperm surface antigens of 40kDa size induced molecules on the plasma membrane overlying the acrosome of rabbit sperm to cluster in small aggregates at 0°C (patching). At an elevated temperature of 37°C these clusters of antigen antibody complexes collected into a large aggregate on one pole of the cell forming a cap (capping). This cap-like structure showed a reduction in size over a period of time and eventually disappeared from the sperm surface. Inhibition of capping by sodium azide indicated that it is an energy-dependent process. Patching of antigens did not require energy. Involvement of sperm head cytoskeleton in the process of capping was evident from potentiation of cap formation by cytoskeleton disrupting agents like cytochalasin B and D. Patching of antigen antibody complexes was not affected by either of the agents. The loss of antigen antibody complexes from sperm surface was mainly due to shedding of the complexes in the surrounding media. Sperm with patches of antigen antibody complexes did not adhere to oocytes. Sperm from the group where a majority of the sperm were denuded of the antigen antibody complexes also did not bind to oocytes
Apoptotic death in Leishmania donovani promastigotes in response to respiratory chain inhibition - Complex II inhibition results in increased pentamidine cytotoxicity
The biochemical changes consequent to respiratory chain inhibition and their relationship to cell death in Leishmania spp. remain elusive. Inhibitors of respiratory chain complexes I, II, and III were able to induce apoptotic death of the bloodstream form of Leishmania donovani. Complex I inhibition resulted in mitochondrial hyperpolarization that was preceded by increased superoxide production. Limitation of electron transport by thenoyltrifluoroacetone and antimycin A, inhibitors of complexes II and III, respectively, resulted in dissipation of mitochondrial membrane potential that was sensitive to cyclosporin A, a blocker of mitochondrial permeability transition pore. Further studies conducted with thenoyltrifluoroacetone showed maximal generation of hydrogen peroxide with a moderate elevation of superoxide levels. Complex III inhibition provoked superoxide generation only. Interference with complex II but not complexes I and III increased intracellular Ca2+. A tight link between Ca2+ and reactive oxygen species was demonstrated by antioxidant-induced diminution of the Ca2+ increase. However, chelation of extracellular Ca2+ could not abrogate the early increase of reactive oxygen species, providing evidence that Ca2+ elevation was downstream to reactive oxygen species generation. Ca2+ influx occurred through nonselective cation and L-type channels and Na+/Ca2+ exchanger-like pathways. Antioxidants such as glutathione and Ca2+ channel blockers reduced apoptotic death. This study provides a new possibility that concurrent inhibition of respiratory chain complex II with pentamidine administration increases cytotoxicity of the drug. This increased cytotoxicity was connected to a 4-fold elevation in intracellular Ca2+ that was pooled only from intracellular sources. Therefore, inhibition of complexes I, II, and III leads to apoptosis and complex II inhibition in parallel with pentamidine administration-enhanced drug efficacy
Mechanism of metalloid-induced death in Leishmania spp.: role of iron, reactive oxygen species, Ca<SUP>2+</SUP>, and glutathione
There is growing evidence that metalloid-induced cell death in protozoan parasites is due to oxidative injury; however, the biochemical changes related to this event are not fully understood. Leishmania spp. demonstrated cross-resistance to two related metalloids, arsenic and antimony, and both metalloids induced cell death accompanied by cell shrinkage and DNA fragmentation that was preceded by an increase in reactive oxygen species. Both drugs caused mitochondrial dysfunction in terms of loss of membrane potential and a drop in ATP levels. Arsenic treatment resulted in an elevation of intracellular Ca2+ levels that did not occur with antimony exposure. Cellular glutathione level was reduced after antimony treatment but arsenic did not affect glutathione. Inhibition of Ca2+ influx during arsenic treatment reduced cell death, whereas supplementation of glutathione during antimony treatment rescued cell loss. Under iron-depleted conditions, the cytotoxic effects of arsenic and antimony did not occur and cell survival increased; in contrast, the presence of excess iron resulted in higher cell death. Therefore, this study provides a new possibility that iron can potentiate parasite death induced by metalloids like arsenic and antimony. In addition, an important observation is that the two similar metalloids produce toxicity by very different mechanisms