PCNA泛素化修饰对DNA损伤应答途径的调控

机体细胞在多种化学物质和内外环境不断攻击下会诱发DNA损伤。为了维持基因组的稳定性,细胞内拥有一系列完善而精确的细胞应答机制来保护基因组DNA的完整性。细胞首先通过DNA损伤检测点,然后通过一系列细胞信号转导通路,启动细胞周期阻滞,进而介导细胞修复或凋亡。大量研究表明泛素化作为一种重要的蛋白质翻译后修饰方式,参与调控了多种细胞生理过程。近期研究表明,DNA损伤导致复制应激可诱发PCNA的翻译后泛素化修饰,泛素化修饰的PCNA可能参与了多种DNA损伤应激过程,影响细胞选择不同的DNA损伤应答途径,导致细胞截然不同的转归。因此,更好地了解PCNA泛素化的作用及其影响DNA损伤应答通路可为我们更深入地了解人类细胞如何调控异常的DNA代谢过程和癌症的发生和发展机制提供依据。     

PCNA泛素化修饰对DNA损伤应答途径的调控

机体细胞在多种化学物质和内外环境不断攻击下会诱发DNA损伤。为了维持基因组的稳定性,细胞内拥有一系列完善而精确的细胞应答机制来保护基因组DNA的完整性。细胞首先通过DNA损伤检测点,然后通过一系列细胞信号转导通路,启动细胞周期阻滞,进而介导细胞修复或凋亡。大量研究表明泛素化作为一种重要的蛋白质翻译后修饰方式,参与调控了多种细胞生理过程。近期研究表明,DNA损伤导致复制应激可诱发PCNA的翻译后泛素化修饰,泛素化修饰的PCNA可能参与了多种DNA损伤应激过程,影响细胞选择不同的DNA损伤应答途径,导致细胞截然不同的转归。因此,更好地了解PCNA泛素化的作用及其影响DNA损伤应答通路可为我们更深入地了解人类细胞如何调控异常的DNA代谢过程和癌症的发生和发展机制提供依据。     

Focus: 50 Years of DNA Repair: The Yale Symposium Reports: Triplex-Induced DNA Damage Response

Cellular DNA damage response is critical to preserving genomic integrity following exposure to genotoxic stress. A complex series of networks and signaling pathways become activated after DNA damage and trigger the appropriate cellular response, including cell cycle arrest, DNA repair, and apoptosis. The response elicited is dependent upon the type and extent of damage sustained, with the ultimate goal of preventing propagation of the damaged DNA. A major focus of our studies is to determine the cellular pathways involved in processing damage induced by altered helical structures, specifically triplexes. Our lab has demonstrated that the TFIIH factor XPD occupies a central role in triggering apoptosis in response to triplex-induced DNA strand breaks. We have shown that XPD co-localizes with γH2AX, and its presence is required for the phosphorylation of H2AX tyrosine142, which stimulates the signaling pathway to recruit pro-apoptotic factors to the damage site. Herein, we examine the cellular pathways activated in response to triplex formation and discuss our finding that suggests that XPD-dependent apoptosis plays a role in preserving genomic integrity in the presence of excessive structurally induced DNA damage.     

Edge vulnerability in neural and metabolic networks

Biological networks, such as cellular metabolic pathways or networks of corticocortical connections in the brain, are intricately organized, yet remarkably robust toward structural damage. Whereas many studies have investigated specific aspects of robustness, such as molecular mechanisms of repair, this article focuses more generally on how local structural features in networks may give rise to their global stability. In many networks the failure of single connections may be more likely than the extinction of entire nodes, yet no analysis of edge importance (edge vulnerability) has been provided so far for biological networks. We tested several measures for identifying vulnerable edges and compared their prediction performance in biological and artificial networks. Among the tested measures, edge frequency in all shortest paths of a network yielded a particularly high correlation with vulnerability and identified intercluster connections in biological but not in random and scale-free benchmark networks. We discuss different local and global network patterns and the edge vulnerability resulting from them.     

"Omic" approaches for unraveling signaling networks

Signaling pathways are crucial for cell differentiation and response to cellular environments. Recently, a large number of approaches for the global analysis of genes and proteins have been described. These have provided important new insights into the components of different pathways and the molecular and cellular responses of these pathways. This review covers genomic and proteomic (collectively referred to as "omic") approaches for the global analysis of cell signaling, including gene expression profiling and analysis, protein-protein interaction methods, protein microarrays, mass spectroscopy and gene-disruption and engineering approaches.     

DNA damage responses: mechanisms and roles in human disease: 2007 G.H.A. Clowes Memorial Award Lecture

Significant progress has been made in recent years in elucidating the molecular controls of cellular responses to DNA damage in mammalian cells. Much of our understanding of the mechanisms involved in cellular DNA damage response pathways has come from studies of human cancer susceptibility syndromes that are altered in DNA damage responses. Ataxia-telangiectasia mutated (ATM), the gene mutated in the disorder ataxia-telangiectasia, codes for a protein kinase that is a central mediator of responses to DNA double-strand breaks (DSB) in cells. Once activated, ATM phosphorylates numerous substrates in the cell that modulate the response of the cell to the DNA damage. We recently developed a novel system to create DNA DSBs at defined endogenous sites in the human genome and used this system to detect protein recruitment and loss at and around these breaks by chromatin immunoprecipitation. Results from this system showed the functional importance of ATM kinase activity and phosphorylation in the response to DSBs and supported a model in which ordered chromatin structure changes that occur after DNA breakage and that depend on functional NBS1 and ATM facilitate DNA DSB repair. Insights about these pathways provide us with opportunities to develop new approaches to benefit patients. Examples and opportunities for developing inhibitors that act as sensitizers to chemotherapy or radiation therapy or activators that could improve responses to cellular stresses, such as oxidative damage, are discussed. Relevant to the latter, we have shown benefits of an ATM activator in disease settings ranging from metabolic syndrome to cancer prevention.     

ATM and ATR: networking cellular responses to DNA damage

Maintenance of genome stability depends on the appropriate response to DNA damage. This response is based on complex networks of signaling pathways that activate numerous processes and lead ultimately to damage repair and cellular survival - or apoptosis. The protein kinases ATM and ATR are master controllers of some of these networks, acting either in concert or separately to orchestrate the responses to specific types of DNA damage or stalled replication. Understanding their mode of action is essential to our understanding of how cells cope with genotoxic stress.     

Protein interaction networks in medicine and disease

The physical interaction of proteins is subject to intense investigation that has revealed that proteins are assembled into large densely connected networks. In this review, we will examine how signaling pathways can be combined to form higher order protein interaction networks. By using network graph theory, these interaction networks can be further analyzed for global organization, which has revealed unique aspects of the relationships between protein networks and complex biological phenotypes. Moreover, several studies have shown that the structure and dynamics of protein networks are disturbed in complex diseases such as cancer progression. These relationships suggest a novel paradigm for treatment of complex multigenic disease where the protein interaction network is the target of therapy more so than individual molecules within the network.     

Programs for Cell Death: Apoptosis is Only One Way to Go

Cell death programs are major players in tissue homeostasis, development and cellular stress responses. A prominent cause of malignant transformation is the cumulative genetic alterations in pathways that regulate cellular growth and death. The processes that govern cell death following genotoxic stress are a major focus of basic research and are also very relevant to translational research in clinical oncology: understanding cell death following cancer therapy is essential for designing new treatment modalities. Cell death is usually, and sometimes automatically, linked with one of its major programs, apoptosis. Recent advances have led, however, to the emergence of additional, non-apoptotic cell death pathways, each with its triggers and readouts. Genotoxic stress appears to induce several cell death pathways, only part of which fall within the classical definition of apoptosis. Accordingly, solid tumor cells that are refractive to apoptosis were shown to die via non-apoptotic mechanisms. Recently we demonstrated that mitotic cell death induced by DNA damage in cells with defective G2/M checkpoint is mechanistically distinct from apoptosis. This review outlines recent advances in the understanding of molecular networks operative in apoptotic and non-apoptotic cell death mechanisms and their cross-talks.     

共济失调毛细血管扩张症突变基因与端粒不稳定性关系研究进展

在电离辐射等因素造成的DNA损伤修复信号传导过程中,共济失调毛细血管扩张症突变基因(ATM)起关键作用。同时,ATM属于P13K家族成员,其功能与保持端粒长度有关。端粒是真核细胞内染色体末端的重复的DNA序列,端粒的长短和稳定性决定了细胞的寿命。ATM突变导致端粒的不稳定性,包括端粒连接、端粒染色质结构变化,影响端粒聚集等。     

The aging stress response

Aging is the outcome of a balance between damage and repair. The rate of aging and the appearance of age-related pathology are modulated by stress response and repair pathways that gradually decline, including the proteostasis and DNA damage repair networks and mitochondrial respiratory metabolism. Highly conserved insulin/IGF-1, TOR, and sirtuin signaling pathways in turn control these critical cellular responses. The coordinated action of these signaling pathways maintains cellular and organismal homeostasis in the face of external perturbations, such as changes in nutrient availability, temperature, and oxygen level, as well as internal perturbations, such as protein misfolding and DNA damage. Studies in model organisms suggest that changes in signaling can augment these critical stress response systems, increasing life span and reducing age-related pathology. The systems biology of stress response signaling thus provides a new approach to the understanding and potential treatment of age-related diseases.     

Cellular signaling is potentially regulated by cell density in receptor trafficking networks

Previous work has shown that receptor trafficking is a potential site for the control of signaling pathways. In most biological experiments, the ligand concentration and cell density vary within a wide range among different systems. However, there is less attention to systematically analyze how much cellular signal response is affected by cell densities. Here, we use a quantitative mathematical model to investigate signal responses in different receptor trafficking networks by simultaneous variations of ligand concentration and cell density. Computational analysis of the model revealed that receptor trafficking networks have potential sigmoid responses to ratio between ligand and surface receptor number per cell, which is a key factor to control the signaling responses in receptor trafficking networks. Furthermore, cell density also affects the robustness of dose-response curve upon the variation of binding affinity.     

Enhancing the stress responses of probiotics for a lifestyle from gut to product and back again

Before a probiotic bacterium can even begin to fulfill its biological role, it must survive a battery of environmental stresses imposed during food processing and passage through the gastrointestinal tract (GIT). Food processing stresses include extremes in temperature, as well as osmotic, oxidative and food matrix stresses. Passage through the GIT is a hazardous journey for any bacteria with deleterious lows in pH encountered in the stomach to the detergent-like properties of bile in the duodenum. However, bacteria are equipped with an array of defense mechanisms to counteract intracellular damage or to enhance the robustness of the cell to withstand lethal external environments. Understanding these mechanisms in probiotic bacteria and indeed other bacterial groups has resulted in the development of a molecular toolbox to augment the technological and gastrointestinal performance of probiotics. This has been greatly aided by studies which examine the global cellular responses to stress highlighting distinct regulatory networks and which also identify novel mechanisms used by cells to cope with hazardous environments. This review highlights the latest studies which have exploited the bacterial stress response with a view to producing next-generation probiotic cultures and highlights the significance of studies which view the global bacterial stress response from an integrative systems biology perspective.     

A multidimensional chromatography technology for in-depth phosphoproteome analysis

Protein phosphorylation is a post-translational modification widely used to regulate cellular responses. Recent studies showed that global phosphorylation analysis could be used to study signaling pathways and to identify targets of protein kinases in cells. A key objective of global phosphorylation analysis is to obtain an in-depth mapping of low abundance protein phosphorylation in cells; this necessitates the use of suitable separation techniques because of the complexity of the phosphoproteome. Here we developed a multidimensional chromatography technology, combining IMAC, hydrophilic interaction chromatography, and reverse phase LC, for phosphopeptide purification and fractionation. Its application to the yeast Saccharomyces cerevisiae after DNA damage led to the identification of 8764 unique phosphopeptides from 2278 phosphoproteins using tandem MS. Analysis of two low abundance proteins, Rad9 and Mrc1, revealed that approximately 50% of their phosphorylation was identified via this global phosphorylation analysis. Thus, this technology is suited for in-depth phosphoproteome studies.