细胞调亡是半胱天冬酶参与的复杂过程

自从发现线虫(Caenorhabditis elegan)的CED蛋白与哺乳动物的白介素-1β转换酶(ICE)有相似作用以来[1],已有13种半胱天冬酶家族成员先后被发现或克隆[2](表1).半胱天冬酶(caspase)分为启动型和执行型,前者接受死亡信号、启动凋亡或激活下游的分子,后者则降解细胞骨架、蛋白质、核酸等.     

Caspase的活化及其在细胞凋亡中的作用

Caspase是执行细胞凋亡的主要酶类,目前已鉴定的哺乳动物Caspase有14种。Caspase以酶原的形式合成,催化活性很低,必须激活以后才能发挥作用。活化的Caspase通过特异性的裂解一套底物而导致细胞凋亡。与Caspase有关的细胞凋亡通路至少有三种：线粒体／细胞色素c通路、死亡受体通路和内质网通路。Caspase总是与其抑制剂共存,以防止Caspase酶原意外激活而对正常细胞造成损伤。     

The Role of Vimentin Intermediate Filaments in Cortical and Cytoplasmic Mechanics

The mechanical properties of a cell determine many aspects of its behavior, and these mechanics are largely determined by the cytoskeleton. Although the contribution of actin filaments and microtubules to the mechanics of cells has been investigated in great detail, relatively little is known about the contribution of the third major cytoskeletal component, intermediate filaments (IFs). To determine the role of vimentin IF (VIF) in modulating intracellular and cortical mechanics, we carried out studies using mouse embryonic fibroblasts (mEFs) derived from wild-type or vimentin^−/− mice. The VIFs contribute little to cortical stiffness but are critical for regulating intracellular mechanics. Active microrheology measurements using optical tweezers in living cells reveal that the presence of VIFs doubles the value of the cytoplasmic shear modulus to ∼10 Pa. The higher levels of cytoplasmic stiffness appear to stabilize organelles in the cell, as measured by tracking endogenous vesicle movement. These studies show that VIFs both increase the mechanical integrity of cells and localize intracellular components.     

The Role of Vimentin Intermediate Filaments in Cortical and Cytoplasmic Mechanics

The mechanical properties of a cell determine many aspects of its behavior, and these mechanics are largely determined by the cytoskeleton. Although the contribution of actin filaments and microtubules to the mechanics of cells has been investigated in great detail, relatively little is known about the contribution of the third major cytoskeletal component, intermediate filaments (IFs). To determine the role of vimentin IF (VIF) in modulating intracellular and cortical mechanics, we carried out studies using mouse embryonic fibroblasts (mEFs) derived from wild-type or vimentin^−/− mice. The VIFs contribute little to cortical stiffness but are critical for regulating intracellular mechanics. Active microrheology measurements using optical tweezers in living cells reveal that the presence of VIFs doubles the value of the cytoplasmic shear modulus to ∼10 Pa. The higher levels of cytoplasmic stiffness appear to stabilize organelles in the cell, as measured by tracking endogenous vesicle movement. These studies show that VIFs both increase the mechanical integrity of cells and localize intracellular components.     

Caspases: A Molecular Switch Node in the Crosstalk between Autophagy and Apoptosis

Autophagy and apoptosis are two important catabolic processes contributing to the maintenance of cellular and tissue homeostasis. Autophagy controls the turnover of protein aggregates and damaged organelles within cells, while apoptosis is the principal mechanism by which unwanted cells are dismantled and eliminated from organisms. Despite marked differences between these two pathways, they are highly interconnected in determining the fate of cells. Intriguingly, caspases, the primary drivers of apoptotic cell death, play a critical role in mediating the complex crosstalk between autophagy and apoptosis. Pro-apoptotic signals can converge to activate caspases to execute apoptotic cell death. In addition, activated caspases can degrade autophagy proteins (i.e., Beclin-1, Atg5, and Atg7) to shut down the autophagic response. Moreover, caspases can convert pro-autophagic proteins into pro-apoptotic proteints to trigger apoptotic cell death instead. It is clear that caspases are important in both apoptosis and autophagy, thus a detailed deciphering of the role of caspases in these two processes is still required to clarify the functional relationship between them. In this article, we provide a current overview of caspases in its interplay between autophagy and apoptosis. We emphasized that defining the role of caspases in autophagy-apoptosis crosstalk will provide a framework for more precise manipulation of these two processes during cell death.     

受体相互作用蛋白3——细胞凋亡与坏死的调节阀

综述了受体相互作用蛋白(RIPs)蛋白结构和RIP3调控细胞凋亡与坏死机制的研究进展．受体相互作用蛋白3(receptor-interacting protein 3, RIP3)是丝/苏氨酸蛋白激酶家族成员之一,该蛋白质家族包含一类高度保守的丝/苏氨酸激酶结构域．RIP家族激酶作为细胞应激传感分子,在调控细胞凋亡、细胞坏死和存活通路中发挥重要作用．近年发现,RIP3参与肿瘤坏死因子TNFα诱导的细胞程序化坏死的生物学过程．认识RIP3调控TNFα诱导的细胞凋亡与坏死不同死亡途径转换的分子机制,有助于发现肿瘤治疗的新策略．     

Sequential Activation of Caspases and Serine Proteases (Serpases) During Apoptosis

Analogous to caspases, serine (Ser) proteases are involved in protein degradation during apoptosis. It is unknown, however, whether Ser proteases are activated concurrently, sequentially, or as an alternative to the activation of caspases. Using fluorescent inhibitors of caspases (FLICA) and Ser proteases (FLISP), novel methods to detect activation of of these enzymes in apoptotic cells, we demonstrate that two types of Ser protease sites become accessible to these inhibitors during apoptosis of HL-60 cells. The prior exposure to caspases inhibitor Z-VAD-FMK markedly diminished activation of both Ser protease sites. However, the unlabeled inhibitor of Ser-proteases TPCK had modest suppressive effect- while TLCK had no effect- on the activation of caspases. Activation of caspases, thus, appears to be an upstream event and likely a prerequisite for activation of FLISP- reactive sites. Differential labeling with the red fluorescing sulforhodamine-tagged VAD-FMK and the green fluorescing FLISP allowed us to discriminate, within the same cell, between activation of caspases and Ser protease sites. Despite a certain degree of co-localization, the pattern of intracellular caspase- vs FLISP- reactive sites, was different. Also different were relative proportions of activated caspases vs Ser protease sites in individual cells. The observed induction of FLISP-binding sites we interpret as revealing activation of at least two different apoptotic Ser proteases; by analogy to caspases we denote them serpases. Their apparent molecular weight (62-65 kD) suggests that they are novel enzymes.

Key Words:

Serpases, Caspases, Apoptosis, Enzymatic center, Chymotrypsin, FLICA, FLISP, Cell necrobiology     

Caspases: preparation and characterization

Caspases and their involvement in programmed cell death have been an area of significant interest since their initial identification in 1992. To facilitate the search for new components involved in cell death, and to aid researchers in understanding the interactions between currently known cell death proteins, we describe a number of techniques commonly used in the preparation and characterization of caspases.     

Relationships Between Cytoplasmic Filaments and Nuclear Envelope in Teleost (Pimelodus maculatus) Endothelial Cells

In the present report a characteristic pattern showed by cytoplasmic filaments (intermediate-sized and actin-like) in the perinuclear area of a freshwater teleost (Pimelodus maculatus) endothelial cells is described for the first time. Thus, many intermediate-sized filaments are directly inserted in the nuclear envelope, but others are connected to one another and to the nucleus through microfilaments. It is suggested that these particular relationships between the nucleus and cytoplasmic filaments are responsible not only for nuclear anchorage, but also for nuclear movements     

新型细胞骨架分隔丝的结构和功能研究进展

细胞骨架是细胞内的蛋白纤维网状结构,包括人们熟知的微管、微丝和中间纤维.目前研究表明分隔丝(septin filaments)是一类在真核生物中广泛分布的蛋白纤维,逐渐被认为是一种新型细胞骨架结构.分隔丝由可结合GTP的分隔丝蛋白单体(Septin)聚合形成异源复合体,进一步组装成纤维丝.分隔丝可形成纤维束,环状或笼状等结构,并与细胞膜或其他细胞骨架成分发生相互作用.在细胞内,分隔丝参与胞质分裂、细胞迁移、神经元发育和免疫等重要生理及病理过程.分隔丝结构或功能的异常与多种人类疾病如肿瘤等密切相关.本文将从分隔丝的结构、组装调控、功能及与人类疾病的关系等方面综述近年的研究进展.     

Genetic and Structural Analyses of Cytoplasmic Filaments of Wild-Type Treponema phagedenis and a Flagellar Filament-Deficient Mutant

Unique cytoplasmic filaments are found in the treponeme genus of spirochete bacteria. Their function is unknown, but their location underneath the periplasmic flagellar filaments (PFF) suggests a role in motility and/or cell structure. To better understand these unique structures, the gene coding for the cytoplasmic filaments, cfpA, was identified in various treponemal species. Treponema phagedenis cfpA was 2,037 nucleotides long, and the encoded polypeptide showed 78 to 100% amino acid sequence identity with the partial sequence of CfpA from T. denticola, T. vincentii, and T. pallidum subsp. pertenue. Wild-type T. phagedenis and a PFF-deficient isolate were analyzed by electron microscopy to assess the structural relationship of the cytoplasmic filaments and the PFF. The number of cytoplasmic filaments per cell of T. phagedenis (mean, 5.7) was compared with the number of PFF at each end of the cell (mean, 4.7); the results suggest that there is no direct one-to-one correlation at the cell end. Moreover, a structural link between these structures could not be demonstrated. The cytoplasmic filaments were also analyzed by electron microscopy at different stages of cell growth; this analysis revealed that they are cleaved before or during septum formation and before the nascent formation of PFF. A PFF-deficient mutant of T. phagedenis possessed cytoplasmic filaments similar to those of the wild type, suggesting that intact PFF are not required for their assembly and regulation. The extensive conservation of CfpA among pathogenic spirochetes suggests an important function, and structural analysis suggests that it is unlikely that the cytoplasmic filaments and the flagellar apparatus are physically linked.     

A Novel 95-kD Protein Is Located in a Linker between Cytoplasmic Microtubules and Basal Bodies in a Green Flagellate and Forms Striated Filaments In Vitro

The flagellar basal apparatus comprises the basal bodies and the attached fibrous structures, which together form the organizing center for the cytoskeleton in many flagellated cells. Basal apparatus were isolated from the naked green flagellate Spermatozopsis similis and shown to be composed of several dozens of different polypeptides including a protein band of 95 kD. Screening of a cDNA library of S. similis with a polyclonal antibody raised against the 95-kD band resulted in a full-length clone coding for a novel protein of 834 amino acids (90.3 kD). Sequence analysis identified nonhelical NH₂- and COOH-terminal domains flanking a central domain of ~650 residues, which was predicted to form a series of coiled-coils interrupted by short spacer segments. Immunogold labeling using a polyclonal antibody raised against the bacterially expressed 95-kD protein exclusively decorated the striated, wedge-shaped fibers, termed sinister fibers (sf-fibers), attached to the basal bodies of S. similis. Striated fibers with a periodicity of 98 nm were assembled in vitro from the purified protein expressed from the cloned cDNA indicating that the 95-kD protein could be a major component of the sf-fibers. This structure interconnects specific triplets of the basal bodies with the microtubular bundles that emerge from the basal apparatus. The sf-fibers and similar structures, e.g., basal feet or satellites, described in various eukaryotes including vertebrates, may be representative for cytoskeletal elements involved in positioning of basal bodies/centrioles with respect to cytoskeletal microtubules and vice versa.     

Drosophila Spaghetti and Doubletime Link the Circadian Clock and Light to Caspases,Apoptosis and Tauopathy

While circadian dysfunction and neurodegeneration are correlated, the mechanism for this is not understood. It is not known if age-dependent circadian dysfunction leads to neurodegeneration or vice-versa, and the proteins that mediate the effect remain unidentified. Here, we show that the knock-down of a regulator (spag) of the circadian kinase Dbt in circadian cells lowers Dbt levels abnormally, lengthens circadian rhythms and causes expression of activated initiator caspase (Dronc) in the optic lobes during the middle of the day or after light pulses at night. Likewise, reduced Dbt activity lengthens circadian period and causes expression of activated Dronc, and a loss-of-function mutation in Clk also leads to expression of activated Dronc in a light-dependent manner. Genetic epistasis experiments place Dbt downstream of Spag in the pathway, and Spag-dependent reductions of Dbt are shown to require the proteasome. Importantly, activated Dronc expression due to reduced Spag or Dbt activity occurs in cells that do not express the spag RNAi or dominant negative Dbt and requires PDF neuropeptide signaling from the same neurons that support behavioral rhythms. Furthermore, reduction of Dbt or Spag activity leads to Dronc-dependent Drosophila Tau cleavage and enhanced neurodegeneration produced by human Tau in a fly eye model for tauopathy. Aging flies with lowered Dbt or Spag function show markers of cell death as well as behavioral deficits and shortened lifespans, and even old wild type flies exhibit Dbt modification and activated caspase at particular times of day. These results suggest that Dbt suppresses expression of activated Dronc to prevent Tau cleavage, and that the circadian clock defects confer sensitivity to expression of activated Dronc in response to prolonged light. They establish a link between the circadian clock factors, light, cell death pathways and Tau toxicity, potentially via dysregulation of circadian neuronal remodeling in the optic lobes.     

The Roles of ROS and Caspases in TRAIL-Induced Apoptosis and Necroptosis in Human Pancreatic Cancer Cells

Death signaling provided by tumor necrosis factor (TNF)-related apoptosis-inducing ligand (TRAIL) can induce death in cancer cells with little cytotoxicity to normal cells; this cell death has been thought to involve caspase-dependent apoptosis. Reactive oxygen species (ROS) are also mediators that induce cell death, but their roles in TRAIL-induced apoptosis have not been elucidated fully. In the current study, we investigated ROS and caspases in human pancreatic cancer cells undergoing two different types of TRAIL-induced cell death, apoptosis and necroptosis. TRAIL treatment increased ROS in two TRAIL-sensitive pancreatic cancer cell lines, MiaPaCa-2 and BxPC-3, but ROS were involved in TRAIL-induced apoptosis only in MiaPaCa-2 cells. Unexpectedly, inhibition of ROS by either N-acetyl-L-cysteine (NAC), a peroxide inhibitor, or Tempol, a superoxide inhibitor, increased the annexin V-/propidium iodide (PI)⁺ early necrotic population in TRAIL-treated cells. Additionally, both necrostatin-1, an inhibitor of receptor-interacting protein kinase 1 (RIP1), and siRNA-mediated knockdown of RIP3 decreased the annexin V^-/PI⁺ early necrotic population after TRAIL treatment. Furthermore, an increase in early apoptosis was induced in TRAIL-treated cancer cells under inhibition of either caspase-2 or -9. Caspase-2 worked upstream of caspase-9, and no crosstalk was observed between ROS and caspase-2/-9 in TRAIL-treated cells. Together, these results indicate that ROS contribute to TRAIL-induced apoptosis in MiaPaCa-2 cells, and that ROS play an inhibitory role in TRAIL-induced necroptosis of MiaPaCa-2 and BxPC-3 cells, with caspase-2 and -9 playing regulatory roles in this process.     

Caspase Cleavage of Keratin 18 and Reorganization of Intermediate Filaments during Epithelial Cell Apoptosis

Keratins 8 (K8) and 18 (K18) are major components of intermediate filaments (IFs) of simple epithelial cells and tumors derived from such cells. Structural cell changes during apoptosis are mediated by proteases of the caspase family. During apoptosis, K18 IFs reorganize into granular structures enriched for K18 phosphorylated on serine 53. K18, but not K8, generates a proteolytic fragment during drug- and UV light–induced apoptosis; this fragment comigrates with K18 cleaved in vitro by caspase-6, -3, and -7. K18 is cleaved by caspase-6 into NH₂-terminal, 26-kD and COOH-terminal, 22-kD fragments; caspase-3 and -7 additionally cleave the 22-kD fragment into a 19-kD fragment. The cleavage site common for the three caspases was the sequence VEVD/A, located in the conserved L1-2 linker region of K18. The additional site for caspases-3 and -7 that is not cleaved efficiently by caspase-6 is located in the COOH-terminal tail domain of K18. Expression of K18 with alanine instead of serine at position 53 demonstrated that cleavage during apoptosis does not require phosphorylation of serine 53. However, K18 with a glutamate instead of aspartate at position 238 was resistant to proteolysis during apoptosis. Furthermore, this cleavage site mutant appears to cause keratin filament reorganization in stably transfected clones. The identification of the L1-2 caspase cleavage site, and the conservation of the same or very similar sites in multiple other intermediate filament proteins, suggests that the processing of IFs during apoptosis may be initiated by a similar caspase cleavage.     

Inhibition of Caspases Rescues Brown Adipocytes from Apoptosis Downregulating BCL-XS and Upregulating BCL-2 Gene Expression

Serum deprivation of the immortalized brown adipocyte cell line resulted in growth arrest inG₀/G₁phases of the cell cycle and apoptosis, as detected by DNA laddering, nuclei condensation and fragmentation, and an increase in the percentage of hypodiploid cells. In addition, apoptosis in these cells is accompanied by an induction of the expression of the apoptotic form of the Bcl-x gene, the isoform Bcl-xS, and by a decrease of Bcl-2 expression, Bcl-xL remaining almost undetectable. The loss of mitochondrial membrane potential was associated with apoptosis. Z-VAD, a cell-permeable inhibitor of caspases, but not cycloheximide, precludes DNA laddering under serum deprivation. Moreover, Z-VAD rescues serum-deprived brown adipocytes from apoptosis, decreasing the percentage of hypodiploid cells, the percentage of apoptotic cells under Tunnel assay, and the external display of phosphatidylserine. More importantly, Z-VAD survival effects on immortalized brown adipocytes concur with a downregulation of Bcl-xS mRNA/protein and an upregulation of Bcl-2 protein content. Ultimately, Z-VAD prevents the loss of mitochondrial membrane potential.     

Quaternary Structures of Human Cytoplasmic and Nuclear PCNA Are the Same

Properties and mechanisms of PCNA (proliferating cell nuclear antigen) functions have been investigated for a long time and are studied in great detail. As follows from its name, most known PCNA functions (DNA replication, DNA repair, DNA recombination and others) are connected with cell proliferation and localization of this protein in nuclei. In addition, there is good reason to believe that PCNA also performs some functions in the cytoplasm. However, the possible role and mechanisms of PCNA action in the cytoplasm require careful study and clarification. Interestingly, such cells as neutrophils differ in that they are non-dividing on one hand and on the other hand contain a rather large amount of PCNA, which is localized only in the cytoplasm, that is, they are an ideal model for the study of cytoplasmic PCNA. Using cross-linkages with formaldehyde, we showed that this cytoplasmic PCNA is cross-linked in a similar way, that is, organized in the same way as the nuclear PCNA that is present in the proliferating cells. Previously, we showed that PCNA in such cells is organized into a dynamic complex of double trimer on the basis of the back-toback principle. Apparently, such organization of this hub-protein allows it to better coordinate the processes taking place in the cytoplasm as well.     

Failure of Poly(ADP-Ribose) Polymerase Cleavage by Caspases Leads to Induction of Necrosis and Enhanced Apoptosis

Activation of poly(ADP-ribose) polymerase (PARP) by DNA breaks catalyzes poly(ADP-ribosyl)ation and results in depletion of NAD+ and ATP, which is thought to induce necrosis. Proteolytic cleavage of PARP by caspases is a hallmark of apoptosis. To investigate whether PARP cleavage plays a role in apoptosis and in the decision of cells to undergo apoptosis or necrosis, we introduced a point mutation into the cleavage site (DEVD) of PARP that renders the protein resistant to caspase cleavage in vitro and in vivo. Here, we show that after treatment with tumor necrosis factor alpha, fibroblasts expressing this caspase-resistant PARP exhibited an accelerated cell death. This enhanced cell death is attributable to the induction of necrosis and an increased apoptosis and was coupled with depletion of NAD+ and ATP that occurred only in cells expressing caspase-resistant PARP. The PARP inhibitor 3-aminobenzamide prevented the NAD+ drop and concomitantly inhibited necrosis and the elevated apoptosis. These data indicate that this accelerated cell death is due to NAD+ depletion, a mechanism known to kill various cell types, caused by activation of uncleaved PARP after DNA fragmentation. The present study demonstrates that PARP cleavage prevents induction of necrosis during apoptosis and ensures appropriate execution of caspase-mediated programmed cell death.