Deficiency of pro-apoptotic Hrk attenuates programmed cell death in the developing murine nervous system but does not affect Bcl-x deficiency-induced neuron apoptosis

The BCL-2 family includes both pro- and anti-apoptotic proteins, which regulate programmed cell death during development and in response to various apoptotic stimuli. The BH3-only subgroup of pro-apoptotic BCL-2 family members is critical for the induction of apoptotic signaling, by binding to and neutralizing anti-apoptotic BCL-2 family members. During embryonic development, the anti-apoptotic protein BCL-X(L) plays a critical role in the survival of neuronal populations by regulating the multi-BH domain protein BAX. In this study, the authors investigated the role of Harakiri (HRK), a relatively recently characterized BH3-only molecule in disrupting the BAX-BCL-X(L) interaction during nervous system development. Results indicate that HRK deficiency significantly reduces programmed cell death in the nervous system. However, HRK deficiency does not significantly attenuate the widespread apoptosis seen in the Bcl-x (-/-) embryonic nervous system, indicating that other BH3-only molecules, alone or in combination, may regulate BAX activation in immature neurons.     

The BCL-2 protein family: opposing activities that mediate cell death

BCL-2 family proteins, which have either pro- or anti-apoptotic activities, have been studied intensively for the past decade owing to their importance in the regulation of apoptosis, tumorigenesis and cellular responses to anti-cancer therapy. They control the point of no return for clonogenic cell survival and thereby affect tumorigenesis and host-pathogen interactions and regulate animal development. Recent structural, phylogenetic and biological analyses, however, suggest the need for some reconsideration of the accepted organizational principles of the family and how the family members interact with one another during programmed cell death. Although these insights into interactions among BCL-2 family proteins reveal how these proteins are regulated, a unifying hypothesis for the mechanisms they use to activate caspases remains elusive.     

Apoptosis pathways and their therapeutic exploitation in pancreatic cancer

Resistance to apoptosis (programmed cell death) is a characteristic feature of human malignancies including pancreatic cancer, which is one of the leading causes of cancer deaths in the western world. Defects in this intrinsic cell death program can contribute to the multistep process of tumorigenesis, because too little cell death can disturb tissue homeostasis. Further, blockade of apoptosis pathways can cause treatment failure, because intact apoptosis signalling cascades largely mediate therapy-induced cytotoxicity. The elucidation of apoptosis pathways in pancreatic carcinoma over the last decade has resulted in the identification of various molecular defects. How apoptosis pathways can be exploited for the treatment of pancreatic cancer will be discussed in this review.     

BCL-2 family proteins: Regulators of cell death involved in the pathogenesis of cancer and resistance to therapy

The BCL-2 gene was first discovered because of its involvement in the t(14;18) chromosomal translocations commonly found in lymphomas, which result in deregulation of BCL-2 gene expression and cause inappropriately high levels of Bcl-2 protein production. Expression of the BCL-2 gene can also become altered in human cancers through other mechanisms, including loss of the p53 tumor suppressor which normally functions as a repressor of BCL-2 gene expression in some tissues. Bcl-2 is a blocker of programmed cell death and apoptosis that contributes to neoplastic cell expansion by preventing cell turnover caused by physiological cell death mechanisms, as opposed to accelerating rates of cell division. Overproduction of the Bcl-2 protein also prevents cell death induced by nearly all cytotoxic anticancer drugs and radiation, thus contributing to treatment failures in patients with some types of cancer. Several homologs of Bcl-2 have recently been discovered, some of which function as inhibitors of cell death and others as promoters of apoptosis that oppose the actions of the Bcl-2 protein. Many of these Bcl-2 family proteins can interact through formation of homo- and heterotypic dimers. In addition, several nonhomologous proteins have been identified that bind to Bcl-2 and that can modulate apoptosis. These protein-protein interactions may eventual serve as targets for pharmacologically manipulating the physiological cell death pathway for treatment of cancer and several other diseases. © 1996 Wiley-Liss, Inc.     

细胞焦亡参与肿瘤发生分子机制的研究进展

细胞焦亡是一种依赖gasdermin家族蛋白的成孔活性,由半胱氨酸-天冬氨酸特异性蛋白激酶1、4、5、11等介导的以细胞肿胀、质膜穿孔及炎性小分子的释放为特征的新的裂解性、促炎性程序性细胞死亡.目前发现,细胞焦亡参与了多种疾病的发生与发展过程,特别是对肿瘤及肿瘤微环境的形成具有促进及抑制的双重功能,使焦亡成为抗肿瘤药物...     

BCL-2 in the crosshairs: tipping the balance of life and death

The discovery of B-cell lymphoma-2 (BCL-2) over 20 years ago revealed a new paradigm in cancer biology: the development and persistence of cancer can be driven by molecular roadblocks along the natural pathway to cell death. The subsequent identification of an expansive family of BCL-2 proteins provoked an intensive investigation of the interplay among these critical regulators of cell death. What emerged was a compelling tale of guardians and executioners, each participating in a molecular choreography that dictates cell fate. Ten years into the BCL-2 era, structural details defined how certain BCL-2 family proteins interact, and molecular targeting of the BCL-2 family has since become a pharmacological quest. Although many facets of BCL-2 family death signaling remain a mechanistic mystery, small molecules and peptides that effectively target BCL-2 are eliminating the roadblock to cell death, raising hopes for a medical breakthrough in cancer and other diseases of deregulated apoptosis.     

Chromosome instability and tumor lethality suppression in carcinogenesis

The maintenance and survival of each organism depends on its genome integrity. Alterations of essential genes, or aberrant chromosome number and structure lead to cell death. Paradoxically, cancer cells, especially in solid tumors, contain somatic gene mutations and are chromosome instability (CIN), suggesting a mechanism that cancer cells have acquired to suppress the lethal mutations and/or CIN. Herein we will discuss a tumor lethality suppression concept based on the studies of yeast genetic interactions and transgenic mice. During the early stages of the multistep process of tumorigenesis, incipient cancer cells probably have adopted genetic and epigenetic alterations to tolerate the lethal mutations of other genes that ensue, and to a larger extent CIN. In turn, CIN mediated massive gain and loss of genes provides a wider buffer for further genetic reshuffling, resulting in cancer cell heterogeneity, drug resistance and evasion of oncogene addiction, thus CIN may be both the effector and inducer of tumorigenesis. Accordingly, interfering with tumor lethality suppression could lead to cancer cell death or growth defects. Further validation of the tumor lethality suppression concept would help to elucidate the role of CIN in tumorigenesis, the relationship between CIN and somatic gene mutations, and would impact the design of anticancer drug development.     

BCL-2 is involved in preventing oxidant-induced cell death and in decreasing oxygen radical production

It has been hypothesized that programmed cell death is mediated, in part, through the formation of free radicals via oxidative pathways. Furthermore, it has been proposed that BCL-2 acts to inhibit cell death by interfering with the production of oxygen-derived free radicals induced by a wide variety of stimuli. In order to examine the antioxidant function of BCL-2, we transfected mouse epidermal cells JB6 clone 41 with the expression vector pD5-Neo-BCL-2 and studied the effect of BCL-2 overexpression on oxidant-induced cell death and on the production of reactive oxygen species. Compared to Neo control cells, BCL-2-expressing cells are more resistant to the killing and growth retardation induced by hydrogen peroxide, superoxide, or by the oxygen radical-generating quinone-containing compounds menadione, diaziquone and adriamycin. The latter compounds generate reactive oxygen species during bioreductive metabolism. In addition, the exposed cells die by necrosis rather than apoptosis. Hydroxyl radical levels generated by the quinone-containing agents were low in BCL-2-expressing JB6 cells compared to control Neo cells. BCL-2, however, does not change the activities of the major cellular antioxidant enzymes superoxide dismutase, catalase or glutathione peroxidase. On the other hand, the glutathione concentrations increased in BCL-2 overexpressing cells after oxidative challenge, while the opposite was true for control cells. Thus, our results suggest that BCL-2 inhibition of oxidant-induced cell death is mediated, at least in part, through an antioxidant pathway, and that this pathway involves glutathione.     

Reduced expression of DRAM2/TMEM77 in tumor cells interferes with cell death

Although the role of autophagy in tumorigenesis remains controversial, recent reports support the notion that inhibition of autophagy promotes tumor formation. Damage-regulated autophagy regulator (DRAM) has been identified as an effector molecule that is critical for p53-mediated apoptosis, and we investigated whether there might be other DRAM-like molecules linking autophagy and apoptosis. In this study, we cloned a novel DRAM-homologous protein, DRAM2, and showed that the expression of DRAM2 is down-regulated in ovarian tumors. DRAM2 is mainly localized in the lysosome, and co-localizes with DRAM. While expression of DRAM or DRAM2 individually did not induce cell death, co-expression of DRAM2 with DRAM significantly induced cell death, while the silencing of endogenous DRAM2 attenuated cell death, suggesting that DRAM2 is involved in cell death. Thus, we propose that reduced expression of DRAM2 may contribute to enhanced cell survival in tumor cells.     

Mutation of BCL-2 Family Proteins in Cancer

Apoptosis is a genetically controlled cell death process that is required for normal development and tissue homeostasis. Suppression of apoptosis can confer a growth advantage to cells and contribute to cancer; many cancers are relatively resistant to apoptosis, including that induced by radiation or chemotherapeutics. Mutations which inactivate pro-apoptotic or activate anti-apoptotic proteins in cancer cells are therefore likely to be responsible for some of these differences. BCL-2 family proteins are key regulators of apoptosis and there is evidence supporting a role for mutation of BCL-2 family proteins in cancer. This includes well established events such as activation of BCL-2 via translocations in follicular lymphoma, as well as more recent observations implicating activation of Bcl-X_L expression and frameshift and missense mutations of BAX and BCL-2 in cancer.     

Lipoxygenase and oxidative damage in cold-stressed maize

Abstract

It has been hypothesized that programmed cell death is mediated, in part, through the formation of free radicals via oxidative pathways. Furthermore, it has been proposed that BCL-2 acts to inhibit cell death by interfering with the production of oxygen-derived free radicals induced by a wide variety of stimuli. In order to examine the antioxidant function of BCL-2, we transfected mouse epidermal cells JB6 clone 41 with the expression vector pD₅-Neo-BCL-2 and studied the effect of BCL-2 overexpression on oxidant-induced cell death and on the production of reactive oxygen species. Compared to Neo control cells, BCL-2-expressing cells are more resistant to the killing and growth retardation induced by hydrogen peroxide, superoxide, or by the oxygen radical-generating quinone-containing compounds menadione, diaziquone and adriamycin. The latter compounds generate reactive oxygen species during bioreductive metabolism. In addition, the exposed cells die by necrosis rather than apoptosis. Hydroxyl radical levels generated by the quinone-containing agents were low in BCL-2-expressing JB6 cells compared to control Neo cells. BCL-2, however, does not change the activities of the major cellular antioxidant enzymes superoxide dismutase, catalase or glutathione peroxidase. On the other hand, the glutathione concentrations increased in BCL-2 overexpressing cells after oxidative challenge, while the opposite was true for control cells. Thus, our results suggest that BCL-2 inhibition of oxidant-induced cell death is mediated, at least in part, through an antioxidant pathway, and that this pathway involves glutathione.     

The rheostat in the membrane: BCL-2 family proteins and apoptosis

Apoptosis, a mechanism for programmed cell death, has key roles in human health and disease. Many signals for cellular life and death are regulated by the BCL-2 family proteins and converge at mitochondria, where cell fate is ultimately decided. The BCL-2 family includes both pro-life (e.g. BCL-XL) and pro-death (e.g. BAX, BAK) proteins. Previously, it was thought that a balance between these opposing proteins, like a simple ‘rheostat'', could control the sensitivity of cells to apoptotic stresses. Later, this rheostat concept had to be extended, when it became clear that BCL-2 family proteins regulate each other through a complex network of bimolecular interactions, some transient and some relatively stable. Now, studies have shown that the apoptotic circuitry is even more sophisticated, in that BCL-2 family interactions are spatially dynamic, even in nonapoptotic cells. For example, BAX and BCL-XL can shuttle between the cytoplasm and the mitochondrial outer membrane (MOM). Upstream signaling pathways can regulate the cytoplasmic–MOM equilibrium of BAX and thereby adjust the sensitivity of cells to apoptotic stimuli. Thus, we can view the MOM as the central locale of a dynamic life–death rheostat. BAX invariably forms extensive homo-oligomers after activation in membranes. However, recent studies, showing that activated BAX monomers determine the kinetics of MOM permeabilization (MOMP), perturb the lipid bilayer and form nanometer size pores, pose questions about the role of the oligomerization. Other lingering questions concern the molecular mechanisms of BAX redistribution between MOM and cytoplasm and the details of BAX/BAK–membrane assemblies. Future studies need to delineate how BCL-2 family proteins regulate MOMP, in concert with auxiliary MOM proteins, in a dynamic membrane environment. Technologies aimed at elucidating the structure and function of the full-length proteins in membranes are needed to illuminate some of these critical issues.     

Neuronal cell life,death, and axonal degeneration as regulated by the BCL-2 family proteins

Axonal degeneration and neuronal cell death are fundamental processes in development and contribute to the pathology of neurological disease in adults. Both processes are regulated by BCL-2 family proteins which orchestrate the permeabilization of the mitochondrial outer membrane (MOM). MOM permeabilization (MOMP) results in the activation of pro-apoptotic molecules that commit neurons to either die or degenerate. With the success of small-molecule inhibitors targeting anti-apoptotic BCL-2 proteins for the treatment of lymphoma, we can now envision the use of inhibitors of apoptosis with exquisite selectivity for BCL-2 family protein regulation of neuronal apoptosis in the treatment of nervous system disease. Critical to this development is deciphering which subset of proteins is required for neuronal apoptosis and axon degeneration, and how these two different outcomes are separately regulated. Moreover, noncanonical BCL-2 family protein functions unrelated to the regulation of MOMP, including impacting necroptosis and other modes of cell death may reveal additional potential targets and/or confounders. This review highlights our current understanding of BCL-2 family mediated neuronal cell death and axon degeneration, while identifying future research questions to be resolved to enable regulating neuronal survival pharmacologically.Subject terms: Cell biology, Chemical tools, Neuroscience, Neurological disorders