In what area of biology has a “new” type of cell death been discovered?

Cell death is a fundamental physiological process that occurs in all organisms and is crucial to each organism's evolution, ability to maintain a stable internal environment, and the development of multiple organ systems. Disulfidptosis is a new mode of cell death that is triggered when cells with high expression of solute carrier family 7 member 11 (SLC7A11) are exposed to glucose starvation to initiate the process of cell death. The disulfidptosis mechanism is a programmed cell death mode that triggers cell death through reduction–oxidation (REDOX) reactions and disulfur bond formation. In disulfidptosis, disulfur bonds play a crucial role and cause the protein in the cell to undergo conformational changes, eventually leading to cell death. This mode of cell death has unique characteristics and regulatory mechanisms in comparison with other modes of cell death. In recent years, an increasing number of studies have shown that the disulfidptosis mechanism plays a key role in the occurrence and development of a variety of diseases. For example, cancer, cardiovascular diseases, neurodegenerative diseases, and liver diseases are all closely related to cell disulfidptosis mechanisms. Therefore, it is of paramount clinical significance to conduct in-depth research regarding this mechanism. This review summarizes the research progress on the disulfidptosis mechanism, including its discovery history, regulatory mechanism, related proteins, and signaling pathways. Potential applications of the disulfidptosis mechanism in disease therapy and future research directions are also discussed. This mechanism represents another subversive discovery after ferroptosis, and provides both a fresh perspective and an innovative strategy for the treatment of cancer, as well as inspiration for the treatment of other diseases.     

原核生物细胞分裂的调控机制

原核细胞的分裂机制一直是人们研究的热点 ,经过多年来的不懈研究 ,人们发现FtsZ蛋白在细胞分裂过程中发挥着重要作用 ,并且是最早出现在分裂位点的蛋白 ,而且直接参与启始了细胞分裂环的形成 ;此外 ,对ftsQAZ基因簇的深入研究也大大加深了人们对原核细胞分裂的认识。就目前原核生物细胞分裂的调控机制作一综述。     

Constitutive neutrophil apoptosis: regulation by cell concentration via S100 A8/9 and the MEK-ERK pathway

Programmed cell death (PCD) is a fundamental mechanism in tissue and cell homeostasis. It was long suggested that apoptosis regulates the cell number in diverse cell populations; however no clear mechanism was shown. Neutrophils are the short-lived, first-line defense of innate immunity, with an estimated t = 1/2 of 8 hours and a high turnover rate. Here we first show that spontaneous neutrophil constitutive PCD is regulated by cell concentrations. Using a proteomic approach, we identified the S100 A8/9 complex, which constitutes roughly 40% of cytosolic protein in neutrophils, as mediating this effect. We further demonstrate that it regulates cell survival via a signaling mechanism involving MEK-ERK via TLR4 and CD11B/CD18. This mechanism is suggested to have a fine-tuning role in regulating the neutrophil number in bone marrow, peripheral blood, and inflammatory sites.     

Targeted expression of ced-3 and Ice induces programmed cell death in Drosophila

CED-3 is a cysteine protease required for programmed cell death in the nematode, Caenorhabditis elegans, and shares a sequence similarity with mammalian ICE (interleukin-1beta converting enzyme) family proteases. Both CED-3 and ICE family proteases can induce programmed cell death in mammalian cells. Structural and functional similarities between CED-3 and ICE family proteases indicate that the mechanism of cell death is evolutionarily conserved, suggesting the presence of a similar mechanism involving CED-3/ICE-like proteases in Drosophila. Here we determined whether CED-3 or ICE functions to induce programmed cell death in Drosophila. We have generated transformant lines in which ced-3 or Ice is ectopically expressed using the GAL4-UAS system. Expression of CED-3 and ICE can elicit cell death in Drosophila and the cell death was blocked by coexpressing the p35 gene which encodes a viral inhibitor of CED-3/ICE proteases. Results support the idea that the mechanism of programmed cell death controlled by CED-3/ICE is conserved among widely divergent animal species including Drosophila, and the system described provides a tool to dissect cell death mechanism downstream of CED-3/ICE proteases.     

Testing of a potential mechanism for E. coli temporal cycle imprecision with a structural model

A structured model for E. coli B/r-A was used to test a potential mechanism for cell cycle temporal imprecision. The mechanism assumes that variations in the activity of septation enzymes can occur. Such variations result in D period imprecision while the chromosome replication schedule is not directly affected. The main results of inserting the mechanism were the predicted ratio of cell doubling time to fission size coefficient of variations agreed with reported data as did the predicted negative correlation between parent-offspring cycle times. Consequently, the proposed mechanism, which suggests that D period fluctuations are the primary source of cell cycle variations, appears consistent with observed cell behavior.     

植物原生质体的细胞壁再生

细胞壁作为植物细胞重要的组成部分,在决定细胞形状、维持机械支撑、吸收养分等方面发挥重要功能.因此,揭示植物细胞壁合成的调控机制具有重大的生物学意义.基于植物组织水平研究细胞壁的生物合成具有难以控制时间尺度、观察空间狭小等局限性.原生质体作为去除细胞壁的单个细胞是研究细胞壁再生的理想系统.在过去的几十年里报道了大量关于植...     

Photolon, a chlorin e6 derivative, triggers ROS production and light-dependent cell death via necrosis

Photolon is a photosensitiser with demonstrated potential as an anti-tumour agent. In this study, an in vitro investigation was performed to determine the mechanism of Photolon-induced cell death. Cell killing was observed in a light-dependent manner and light-activated Photolon resulted in a significant production of reactive oxygen species (ROS), which could be blocked by type I ROS scavengers. Inhibition of ROS production using Trolox prevented Photolon-induced cell death. Light-activated Photolon caused no increase in caspase-3/7 activity, but a rapid increase in lactate dehydrogenase (LDH) release suggesting a loss of membrane integrity and subsequent cell death by necrosis. We conclude that the mechanism of Photolon-induced cell death involves the induction of ROS via a type I mechanism, which is ultimately responsible for cell killing by necrosis.     

A mathematical model of the mechanism of vertebrate somitic segmentation.

A mathematical model for the mechanism of periodic pattern formation in the process of somitogenesis is proposed. It is assumed that the metameric arrangement first appears before somite formation at the stage of transition of mesodermal cells into a polarized state. The model is based on the assumption that besides the mechanism of contact cell polarization there exists a mechanism of polarization suppression due to excretion of some chemical substance by polarized cells. Periodicity appears as a result of interaction of a kinematic wave of somitogenic cell determination with the cell cycles of mesodermal cells.     

The adhesion of BHK and PyBHK cells to the substratum

The adhesion of BHK 21/13 cells and their polyoma-transformed derivatives was studied by detaching them from plastic dishes with EGTA. The PyBHK cells were less adhesive, and the possibility that cyclic nucleotides might play a role in cell adhesion was examined. Both cAMP and cGMP increase cell adhesion through a mechanism involving microtubules, but glucocorticoids act to increase cell adhesion through an independent mechanism.We also examined the role of membrane fluidity in cell adhesion, and the results are discussed in terms of a general model for cell adhesion and locomotion.     

诱导性多潜能干细胞(iPS细胞)的研究进展

通过转染特定的基因组合可以将已分化的体细胞重编程为多潜能干细胞,这种干细胞称为诱导性多潜能干细胞(induced pluripotent stem cells,iPS cells)。这是近年来干细胞研究领域最令人瞩目的一项新的干细胞制备技术。iPS细胞的出现不仅为体细胞重编程去分化机制的研究提供了新的模型,而且为疾病发生发展相关机制研究与特异的细胞治疗带来了新的希望。就当前获取iPS细胞的方法、影响iPS细胞转化率和多能性维持的一些因素及其研究进展进行综述。     

Autophagy and Caspases: A New Cell Death Program

Autophagy is used to degrade components of the cytoplasm and functions as a cell survival mechanism during nutrient deprivation. Autophagic structures have also been observed in many types of dying cells, but experimental evidence for autophagy playing a role in the regulation of programmed cell death is limited. We have recently shown that the autophagy genes Atg7 and Beclin1 are required for the death of certain cells, thus demonstrating that this mechanism of proteolysis is involved in both survival and death. The factors that enable autophagy to regulate distinct cell survival and death responses are not clear, and future work is needed to determine the mechanism(s) that regulate autophagic cell death.     

An Equatorial Contractile Mechanism Drives Cell Elongation but not Cell Division

Cell shape changes and proliferation are two fundamental strategies for morphogenesis in animal development. During embryogenesis of the simple chordate Ciona intestinalis, elongation of individual notochord cells constitutes a crucial stage of notochord growth, which contributes to the establishment of the larval body plan. The mechanism of cell elongation is elusive. Here we show that although notochord cells do not divide, they use a cytokinesis-like actomyosin mechanism to drive cell elongation. The actomyosin network forming at the equator of each notochord cell includes phosphorylated myosin regulatory light chain, α-actinin, cofilin, tropomyosin, and talin. We demonstrate that cofilin and α-actinin are two crucial components for cell elongation. Cortical flow contributes to the assembly of the actomyosin ring. Similar to cytokinetic cells, membrane blebs that cause local contractions form at the basal cortex next to the equator and participate in force generation. We present a model in which the cooperation of equatorial actomyosin ring-based constriction and bleb-associated contractions at the basal cortex promotes cell elongation. Our results demonstrate that a cytokinesis-like contractile mechanism is co-opted in a completely different developmental scenario to achieve cell shape change instead of cell division. We discuss the occurrences of actomyosin rings aside from cell division, suggesting that circumferential contraction is an evolutionally conserved mechanism to drive cell or tissue elongation.     

Can retinal adhesion mechanisms determine cell-sorting patterns: a test of the differential adhesion hypothesis

Embryonic chick neural retina cells possess two classes of adhesion mechanism, one Ca2+-independent, one Ca2+-dependent, responsible for short-term cell aggregation. This study investigates the role of these mechanisms in the long-term cell sorting potentially relevant to in vivo histogenesis. Retina cells are prepared either with both (E cells) or with only one mechanism (TC cells, CD; LTE cells, CI), respectively. The two types of cell preparations are differentially labelled using fluorescein or rhodamine isothiocyanate, mixed and allowed to aggregate in the presence or absence of cycloheximide at 0.5 microgram ml-1 to retard metabolic recovery of the removed adhesive mechanism. When observed by fluorescence and phase-contrast microscopy, the aggregates formed in cycloheximide show cell sorting, the cells with both mechanisms assuming a more interior position relative to those with a single adhesion mechanism. In parallel hanging-drop experiments, preformed aggregates of cells with a single adhesion mechanism are seen to spread upon aggregates of cells with both mechanisms. No sorting occurs amongst cells from a given stage prepared using any single dissociation protocol. The observed cell sorting would thus seem to derive exclusively from differential cell adhesiveness dependent upon the different dissociation conditions and maintained in the presence of cycloheximide. The experiments support the hypothesis that the dual CI and CD adhesion mechanisms in question can play a central role in governing cell-sorting behaviour during normal histogenesis.     

Polarization of endosomal SNX27 in migrating and tumor-engaged natural killer cells

Polarization is a critical mechanism for the proper functioning of many cell types. For lymphocytes, it is essential in a variety of processes, including migration from the blood to other tissue sites and vice versa. In NK cells and CTLs, the cytotoxic granule delivery mechanism requires polarization for granule movement to the immunological synapse (IS), in killing tumor and virus-infected cells. Recently, it has become apparent that endosomes are also involved in the cytotoxic mechanism. Using an in vitro conjugation approach, we show that in NK-92 cells, endosomal Sorting Nexin 27 (SNX27) polarizes to the IS during tumor cell engagement in a distinct compartment adjacent to the cytotoxic granules. We also show that SNX27 polarizes to the apical membrane, opposite the uropod, during NK cell migration. These previously unreported results indicate that SNX27 is a participant in NK cell polarization, as a mediator or target of the mechanism.     

Intracytosolic Listeria monocytogenes induces cell death through caspase-1 activation in murine macrophages

Listeria monocytogenes induces apoptosis in vitro and in vivo in a variety of cell types. However, the mechanism of cell death in L. monocytogenes -infected macrophages was initially reported to be distinct from apoptosis. Here, we studied the mechanism of L. monocytogenes -induced cell death using sensitive fluorescent techniques. We found that caspase-1 activation preceded cell death of macrophages infected with L. monocytogenes , using fluorogenic substrates. Caspase-1 activation was diminished after infection with wild-type L. monocytogenes when cells were treated with NH₄Cl, or if they were infected with a listeriolysin mutant that cannot escape from the phagolysosome. Mitochondrial membrane integrity was preserved during the infection. A particular mechanism of cell death, recently termed 'pyroptosis', is associated with infection by intracellular microorganisms, and has an inherent pro-inflammatory character, due to involvement of caspase-1 activation with consequent IL-1β and IL-18 production. Cell death through caspase-1 activation would constitute a defence mechanism of macrophages which induces cell death to eliminate the bacteria's intracytosolic niche and recruits early host's defences through the secretion of inflammatory cytokines.     

骨髓间充质干细胞免疫抑制作用及其机理

近年来间充质干细胞特殊的免疫学特性越来越引起人们的重视,使其成为移植领域的一个研究热点。许多实验室就间充质干细胞的免疫抑制作用和机理做了大量的研究工作,取得了一定的进展。本文简要综述间充质干细胞的免疫抑制作用和机理。     

Dual control of the intracellular pH in aortic smooth muscle cells by a cAMP-sensitive HCO3-/Cl- antiporter and a protein kinase C-sensitive Na+/H+ antiporter

Two mechanisms are involved in the regulation of the intracellular pH (pHi) of aortic smooth muscle cells: the Na+/H+ antiporter and a Na+-independent HCO3-/Cl- antiporter. The Na+/H+ antiporter acts as a cell alkalinizing mechanism. It is activated by vasopressin and by phorbol esters when cells are incubated in the presence of bicarbonate but is not affected in the absence of bicarbonate. The HCO3-/Cl- antiporter acts as a cell acidifying mechanism. Agents such as forskolin, 8-Br-cAMP, and isoproterenol which raise intracellular cAMP levels inhibit the HCO3-/Cl- antiporter by shifting its pHi dependence in the alkaline direction. Thus, within the same cell type, different hormones control pHi variations by acting on different pHi regulating systems. An increase in pHi can be achieved either by a stimulation of a cell alkalinizing mechanism or by inhibition of a cell acidifying mechanism. A change of the activity of one pHi regulating mechanism modifies the responsiveness of the other to regulatory agents. Bicarbonate turns on the HCO3-/Cl- antiporter, decreases pHi and allows its regulation by protein kinase C through the Na+/H+ antiporter. Inhibition of the HCO3-/Cl- antiporter by cAMP increases the pHi and switches off the protein kinase C-mediated regulation.     

Cell cycle suspension: A novel process lurking in G2 arrest

Cell cycle checkpoint is a self-protective mechanism for cells to monitor genome integrity and ensure the high-fidelity transmission of genetic information to daughter cells. Insufficient function of cell cycle checkpoints has been demonstrated to partially account for tumor initiation, promotion and progression. In the ten melanoma cell lines that we tested in preliminary experiments, two human uveal melanoma cell lines, 92-1 and OCM-1, were found to be significantly different in terms of radiosensitivity but similar in DNA repair ability. Evident G₂ arrest was induced in both cell types and the maximum was reached at 16 h after irradiation regardless of X-rays or high-LET carbon beams. OCM-1 cells overrode the G₂ arrest and reentered the cell cycle right after reaching the maximum, whereas 92-1 could not. Upon 10 Gy of radiation, the cell cycle of 92-1 was suspended and remained unchanged for up to 5 d. The cell cycle suspension is a unique process lurking in G₂ arrest and related to cellular radiosensitivity. Its induction is dose-dependent and there is a dose threshold for it. The degradation of Cyclin B1 has been found related to the cell cycle suspension though, the mechanism of cell cycle suspension is still under investigation. Basing on our knowledge, this is the first report on cell cycle suspension and we present here a de novo mechanism to cellular radiosensitivity. Further clarification of the mechanism underlying cell cycle suspension is believed to be of significance in tumor radiosensitization or even direct tumor control.