Negative feedback regulation of activated macrophages via Fas-mediated apoptosis

Apoptosis is a critical event for eliminatingactivated macrophages. Here we show that Fas-mediated apoptosismay participate in the mechanism of negative feedback regulation ofactivated macrophages. Cytokine-activated macrophages releasedhigh levels of nitric oxide (NO) that induced apoptosis in macrophagesthemselves. This NO-induced macrophage apoptosis was inhibited by aFas-Fc chimeric molecule that binds to Fas ligand (FasL) and prevents its interaction with endogenous cell surface Fas. High levels of NOstimulated the release of the soluble form of FasL that wasinhibited by a matrix metalloproteinase inhibitor KB-8301. High levelsof NO also upregulated the expression of Fas mRNA in macrophages.In addition, macrophages isolated from Fas-lacking mice were resistantto NO-induced apoptosis. Finally, inhibition of apoptosis by a caspaseinhibitor augmented peroxide production from activated macrophages.These findings suggest that high levels of NO released fromactivated macrophages may promote the Fas-mediated macrophage apoptosisthat may be a negative feedback mechanism for elimination and thedownregulation of activated macrophages in the vessel wall.

     

Negative regulation of yeast WASp by two SH3 domain-containing proteins

BACKGROUND: WASp family proteins promote actin filament assembly by activating Arp2/3 complex and are regulated spatially and temporally to assemble specialized actin structures used in diverse cellular processes. Some WASp family members are autoinhibited until bound by activating ligands; however, regulation of the budding yeast WASp homolog (Las17/Bee1) has not yet been explored. RESULTS: We isolated full-length Las17 and characterized its biochemical activities on yeast Arp2/3 complex. Purified Las17 was not autoinhibited; in this respect, it is more similar to SCAR/WAVE than to WASp proteins. Las17 was a much stronger activator of Arp2/3 complex than its carboxyl-terminal (WA) fragment. In addition, actin polymerization stimulated by Las17-Arp2/3 was much less sensitive to the inhibitory effects of profilin compared to polymerization stimulated by WA-Arp2/3. Two SH3 domain-containing binding partners of Las17, Sla1 and Bbc1, were purified and were shown to cooperate in inhibiting Las17 activity. The two SLA1 SH3 domains required for this inhibitory activity in vitro were also required in vivo, in combination with BBC1, for cell viability and normal actin organization. CONCLUSIONS: Full-length Las17 is not autoinhibited and activates Arp2/3 complex more strongly than its WA domain alone, revealing an important role for the Las17 amino terminus in Arp2/3 complex activation. Two of the SH3 domain-containing ligands of Las17, Sla1 and Bbc1, cooperate to inhibit Las17 activity in vitro and are required for a shared function in actin organization in vivo. Our results show that, like SCAR/WAVE, WASp proteins can be controlled by negative regulation through the combined actions of multiple ligands.     

Negative regulation of mitosis by two functionally overlapping PTPases in fission yeast.

We have identified a third protein tyrosine phosphatase (PTPase) gene in fission yeast, pyp2, encoding an 85 kDa protein. Disruption of pyp2 has no impact on cell viability, but pyp2 is essential in strains lacking the 60 kDa pyp1 PTPase. The two pyp PTPases are approximately 42% identical in their C-terminal catalytic domains and share weak homology in their N-terminal regions. Both genes play a role in inhibiting the onset of mitosis. Disruption of either gene rescues the G2 arrest caused by mutation of the cdc25 mitotic inducer, though the effect of pyp1-disruption is more pronounced. Disruption of pyp1 advances mitosis, suppresses overexpression of the tyrosine kinase encoded by the wee1 mitotic inhibitor, and causes lethal mitotic catastrophe in cdc25 overproducer cells. Cells bearing inactive wee1 are unresponsive to disruption of pyp1. Overexpression of pyp1 or pyp2 delays the onset of mitosis by a wee1-dependent mechanism. These data reveal an unexpected second role for protein tyrosine phosphorylation in the mitotic control that acts by promoting the inhibitory wee1 pathway.     

Caspase-independent apoptosis in yeast

Apoptosis is a highly regulated cellular suicide program crucial for metazoan development. Yeast counterparts of central metazoan apoptotic regulators, such as metacaspase Yca1p, have been identified. In spite of the importance of Yca1p in yeast apoptotic process, many other factors such as Aif1p, orthologs of EndoG, AMID and cyclophilin D play important roles in caspase-independent apoptotic pathways. This review summarized recent progress about studies of various intrinsic and extrinsic apoptotic stimuli that may induce yeast cell death via caspase-independent apoptosis.     

Drug-induced apoptosis in yeast

In order to alter the impact of diseases on human society, drug development has been one of the most invested research fields. Nowadays, cancer and infectious diseases are leading targets for the design of effective drugs, in which the primary mechanism of action relies on the modulation of programmed cell death (PCD). Due to the high degree of conservation of basic cellular processes between yeast and higher eukaryotes, and to the existence of an ancestral PCD machinery in yeast, yeasts are an attractive tool for the study of affected pathways that give insights into the mode of action of both antitumour and antifungal drugs. Therefore, we covered some of the leading reports on drug-induced apoptosis in yeast, revealing that in common with mammalian cells, antitumour drugs induce apoptosis through reactive oxygen species (ROS) generation and altered mitochondrial functions. The evidence presented suggests that yeasts may be a powerful model for the screening/development of PCD-directed drugs, overcoming the problem of cellular specificity in the design of antitumour drugs, but also enabling the design of efficient antifungal drugs, targeted to fungal-specific apoptotic regulators that do not have major consequences for human cells.     

Mitochondria-dependent apoptosis in yeast

Mitochondrial involvement in yeast apoptosis is probably the most unifying feature in the field. Reports proposing a role for mitochondria in yeast apoptosis present evidence ranging from the simple observation of ROS accumulation in the cell to the identification of mitochondrial proteins mediating cell death. Although yeast is unarguably a simple model it reveals an elaborate regulation of the death process involving distinct proteins and most likely different pathways, depending on the insult, growth conditions and cell metabolism. This complexity may be due to the interplay between the death pathways and the major signalling routes in the cell, contributing to a whole integrated response. The elucidation of these pathways in yeast has been a valuable help in understanding the intricate mechanisms of cell death in higher eukaryotes, and of severe human diseases associated with mitochondria-dependent apoptosis. In addition, the absence of obvious orthologues of mammalian apoptotic regulators, namely of the Bcl-2 family, favours the use of yeast to assess the function of such proteins. In conclusion, yeast with its distinctive ability to survive without respiration-competent mitochondria is a powerful model to study the involvement of mitochondria and mitochondria interacting proteins in cell death.     

Caspase-dependent apoptosis in yeast

Damaging environment, certain intracellular defects or heterologous expression of pro-apoptotic genes induce death in yeast cells exhibiting typical markers of apoptosis. In mammals, apoptosis can be directed by the activation of groups of proteases, called caspases, that cleave specific substrates and trigger cell death. In addition, in plants, fungi, Dictyostelium and metazoa, paracaspases and metacaspases have been identified that share some homologies with caspases but showing different substrate specificity. In the yeast Saccharomyces cerevisiae, a gene (MCA1/YCA1) has been identified coding for a metacaspase involved in the induction of cell death. Metacaspases are not biochemical, but sequence and functional homologes of caspases, as deletion of them rescues entirely different death scenarios. In this review we will summarize the current knowledge in S. cerevisiae on apoptotic processes, induced by internal and external triggers, which are dependent on the metacaspase gene YCA1.     

血小板功能负性调控机制

在血液循环系统中,血小板在抑制因子的作用下,处于静息状态。当机体出血或外界因素刺激时,血小板活化,产生聚集、黏附和释放反应,释放出二磷酸腺苷(ADP)、花生四烯酸(AA)、血小板活化因子和5-羟色胺等物质,招募更多的血小板黏附于出血处,从而启动凝血过程,发挥止血作用。当止血反应完成后,血小板发生解聚,恢复到静息状态。然而,在病理条件下,血小板的内在解聚能力下降,形成过度活化的血小板,产生病理性血栓,导致急性缺血性心血管疾病的发生。临床使用抗血小板药物控制血小板的活化,治疗急性缺血性心血管疾病。然而,目前临床上常用的抗血小板药物发挥抗血小板活化作用的同时,影响了血小板正常的生理性止血作用,产生出血等副作用。因此,我们需要研发新型抗血小板药物,使其既能发挥抗血小板作用,又能减少出血等副作用。本文将对血小板负性调控机制进行综述,为进一步研究抗血小板药物提供思路。     

Chronological aging-induced apoptosis in yeast

Saccharomyces cerevisiae is the simplest among the major eukaryotic model organisms for aging and diseases. Longevity in the chronological life span paradigm is measured as the mean and maximum survival period of populations of non-dividing yeast. This paradigm has been used successfully to identify several life-regulatory genes and three evolutionary conserved pro-aging pathways. More recently, Schizosaccharomyces pombe has been shown to age chronologically in a manner that resembles that of S. cerevisiae and that depends on the activity of the homologues of two pro-aging proteins previously identified in the budding yeast. Both yeast show features of apoptotic death during chronological aging. Here, we review some fundamental aspects of the genetics of chronological aging and the overlap between yeast aging and apoptotic processes with particular emphasis on the identification of an aging/death program that favors the dedifferentiation and regrowth of a few better adapted mutants generated within populations of aging S. cerevisiae. We also describe the use of a genome-wide screening technique to gain further insights into the mechanisms of programmed death in populations of chronologically aging S. cerevisiae.     

Negative regulation of the yeast ABC transporter Ycf1p by phosphorylation within its N-terminal extension

The yeast vacuolar membrane protein Ycf1p and its mammalian counterpart, MRP1, belong to the ABCC subfamily of ATP-binding cassette (ABC) transporters that rid cells of toxic endogenous and xenobiotic compounds. Like most members of the ABCC subfamily, Ycf1p contains an N-terminal extension in addition to its ABC "core" domain and transports substrates in the form of glutathione conjugates. Ycf1p is subject to complex regulation to ensure its optimal function. Previous studies showed that Ycf1p activity is stimulated by a guanine nucleotide exchange factor, Tus1p, and is positively regulated by phosphorylation in its ABC core domain at residues Ser-908 and Thr-911. Here we provide evidence that phosphorylation of Ser-251 in the Ycf1p N-terminal extension negatively regulates activity. Mutant Ycf1p-S251A exhibits increased resistance to cadmium in vivo and increased Ycf1p-dependent transport of [(3)H]estradiol-beta-17-glucuronide in vitro as compared with wild-type Ycf1p. Activity is restored to the wild-type level for Ycf1-S251E. To identify kinase(s) that negatively regulate Ycf1p function, we conducted an integrated membrane yeast two-hybrid (iMYTH) screen and identified two kinase genes, CKA1 and HAL5, deletion of which increases Ycf1p function. Genetic evidence suggests that Cka1p may regulate Ycf1p function through phosphorylation of Ser-251 either directly or indirectly. Overall, this study provides compelling evidence that negative, as well as positive, regulation of Ycf1p is mediated by phosphorylation.     

Cytoskeletal induced apoptosis in yeast

The influence of the cytoskeleton reaches into almost every aspect of eukaryotic cell function. It is a little surprise therefore that links between the regulation of the cytoskeleton and apoptosis have been found in a variety of eukaryotic systems. Studies from yeast have made a significant contribution to this new field of research and have highlighted the importance of interactions between the cytoskeleton and mitochondria in determining cell fate. In yeast both the actin and microtubular cytoskeletons have been shown to influence mitochondrial function and the commitment to apoptosis. In this review we discuss the recent advances and speculate that apoptotic mechanisms that feed off the ability of the cytoskeleton to respond to environmental signals may represent a useful mechanism to remove weak or damaged individuals from a population.     

Sugar-induced apoptosis in yeast cells

Sugars induce death of Saccharomyces cerevisiae within a few hours in the absence of additional nutrients to support growth; by contrast, cells incubated in water or in the presence of other nutrients without sugar remain viable for weeks. Here we show that this sugar-induced cell death (SICD) is characterized by rapid production of reactive oxygen species (ROS), RNA and DNA degradation, membrane damage, nucleus fragmentation and cell shrinkage. Addition of ascorbic acid to sugar-incubated cells prevents SICD, indicating that SICD is initiated by ROS. The lack of a protection mechanism against SICD suggests that sugars use to be the limiting nutrients for yeast and are probably depleted before all other nutrients. Being the limiting nutrient, sugars became the growth-stimulating agent, signaling the presence of sufficient nutrients for growth, but in the absence of the complementing nutrients they induce apoptotic death.     

Transcriptional regulation of meiosis in yeast

The genes required for meiosis and sporulation in yeast are expressed at specific points in a highly regulated temporal pathway. Recent experiments using DNA microarrays to examine gene expression during meiosis and the identification of many regulatory factors have provided important advances in our understanding of how genes are regulated at the different stages of meiosis.     

Negative regulation of TGF-β signaling in development

The TGF-β superfamily members have important roles in controlling patterning and tissue formation in both invertebrates and vertebrates. Two types of signal transducers, receptors and Smads, mediate the signaling to regulate expression of their target genes. Despite of the relatively simple signal transduction pathway, many modulators have been found to contribute to a tight regulation of this pathway in a variety of mechanisms. This article reviews the negative regulation of TGF-β signaling with focus on its roles in vertebrate development.