Eukaryotic chromatin consisting of nucleosomes connected by linker DNA is organized into higher order structures,which is facilitated by linker histone H1.Formation of chromatin compacts and protects the genome,but al...Eukaryotic chromatin consisting of nucleosomes connected by linker DNA is organized into higher order structures,which is facilitated by linker histone H1.Formation of chromatin compacts and protects the genome,but also hinders DNA transactions.Cells have evolved mechanisms to modify/remodel chromatin resulting in chromatin states suitable for genome functions.The high mobility group box(HMGB)proteins are non-histone chromatin architectural factors characterized by one or more HMGB motifs that bind DNA in a sequence nonspecific fashion.They play a major role in chromatin dynamics.The Saccharomyces cerevisiae(yeast hereafter)HMGB protein Hmo1 contains two HMGB motifs.However,unlike a canonical HMGB protein that has an acidic C-terminus,Hmo1 ends with a lysine rich,basic,C-terminus,resembling linker histone H1.Hmo1 exhibits characteristics of both HMGB proteins and linker histones in its multiple functions.For instance,Hmo1 promotes transcription by RNA polymerases I and II like canonical HMGB proteins but makes chromatin more compact/stable like linker histones.Recent studies have demonstrated that Hmo1 destabilizes/disrupts nucleosome similarly as other HMGB proteins in vitro and acts to maintain a common topological architecture of genes in yeast genome.This minireview reviews the functions of Hmo1 and the underlying mechanisms,highlighting recent discoveries.展开更多
PDRG1 is a small oncogenic protein of 133 residues. In normal human tissues, the p53 and DNA damageregulated gene 1(PDRG1) gene exhibits maximal expression in the testis and minimal levels in the liver. Increased expr...PDRG1 is a small oncogenic protein of 133 residues. In normal human tissues, the p53 and DNA damageregulated gene 1(PDRG1) gene exhibits maximal expression in the testis and minimal levels in the liver. Increased expression has been detected in several tumor cells and in response to genotoxic stress. High-throughput studies identified the PDRG1 protein in a variety of macromolecular complexes involved in processes that are altered in cancer cells. For example, this oncogene has been found as part of the RNA polymerase Ⅱ complex, the splicing machinery and nutrient sensing machinery, although its role in these complexes remains unclear. More recently, the PDRG1 protein was found as an interaction target for the catalytic subunits of methionine adenosyltransferases. These enzymes synthesize S-adenosylmethionine, the methyl donor for, among others, epigenetic methylations that occur on the DNA and histones. In fact, downregulation of S-adenosylmethionine synthesis is the first functional effect directly ascribed to PDRG1. The existence of global DNA hypomethylation, together with increased PDRG1 expression, in many tumor cells highlights the importance of this interaction as one of the putative underlying causes for cell transformation. Here, we will review the accumulated knowledge on this oncogene, emphasizing the numerous aspects that remain to be explored.展开更多
Progression of cells from G2 phase of the cell cycle to mitosis is a tightly regulated cellular process that requires activation of the Cdc2 kinase, which determines onset of mitosis in all eukaryotic cells. In both h...Progression of cells from G2 phase of the cell cycle to mitosis is a tightly regulated cellular process that requires activation of the Cdc2 kinase, which determines onset of mitosis in all eukaryotic cells. In both human and fission yeast (Schizosaccharomyces pombe) cells, the activity of Cdc2 is regulated in part by the phosphorylation status of tyrosine 15 (Tyr15) on Cdc2, which is phosphorylated by Wee1 kinase during late G2 and is rapidly dephosphorylated by the Cdc25 tyrosine phosphatase to trigger entry into mitosis. These Cdc2 regulators are the downstream targets of two well- characterized G2/M checkpoint pathways which prevent cells from entering mitosis when cellular DNA is damaged or when DNA replication is inhibited. Increasing evidence suggests that Cdc2 is also commonly targeted by viral proteins, which modulate host cell cycle machinery to benefit viral survival or replication. In this review, we describe the effect of viral protein R (Vpr) encoded by human immunodeficiency virus type 1 (HIV-1) on cell cycle G2/M regulation. Based on our current knowledge about this viral effect, we hypothesize that Vpr induces cell cycle G2 arrest through a mechanism that is to some extent different from the classic G2/M checkpoints. One the unique features distinguishing Vpr-induced G2 arrest from the classic checkpoints is the role of phosphatase 2A (PP2A) in Vpr-induced G2 arrest. Interestingly, PP2A is targeted by a number of other viral proteins including SV40 small T antigen, polyomavirus T antigen, HTLV Tax and adenovirus E4orf4. Thus an in-depth understanding of the molecular mechanisms underlying Vpr-induced G2 arrest will provide additional insights into the basic biology of cell cycle G2/M regulation and into the biological significance of this effect during host-pathogen interactions.展开更多
目的探讨DNA损伤应答蛋白1(regulated in development and DNA damage responses-1,REDD1)在幽门螺杆菌(Helicobacter pylori,H.pylori)感染中的表达及调控机制。方法建立H.pylori感染C57小鼠及胃上皮细胞模型,运用实时荧光定量PCR、免...目的探讨DNA损伤应答蛋白1(regulated in development and DNA damage responses-1,REDD1)在幽门螺杆菌(Helicobacter pylori,H.pylori)感染中的表达及调控机制。方法建立H.pylori感染C57小鼠及胃上皮细胞模型,运用实时荧光定量PCR、免疫组织化学染色和Western blot检测REDD1 mRNA和蛋白的表达;并在细胞模型中采用信号通路抑制剂的方法探讨H.pylori感染诱导REDD1上调的机制。结果相对于未感染组,H.pylori感染小鼠胃黏膜中的REDD1水平显著增高;而相对于野生型(Wild Type,WT)全毒株,敲除cagA基因后,H.pylori感染诱导REDD1上调的能力则显著下降(P<0.05);H.pylori感染可诱导胃上皮细胞AGS REDD1表达上调,并具有时间、感染菌量以及cagA依赖性(P<0.05);P38/MAPK信号通路阻断可显著抑制H.pylori感染诱导的REDD1上调表达(P<0.05)。结论H.pylori依赖磷酸化的cagA蛋白激活MAPKp38通路诱导REDD1表达增高。展开更多
Polo-like kinase 1(Plk1),a well-characterized member of serine/threonine kinases Plk family,has been shown to play pivotal roles in mitosis and cytokinesis in eu-karyotic cells.Recent studies suggest that Plk1 not onl...Polo-like kinase 1(Plk1),a well-characterized member of serine/threonine kinases Plk family,has been shown to play pivotal roles in mitosis and cytokinesis in eu-karyotic cells.Recent studies suggest that Plk1 not only controls the process of mitosis and cytokinesis,but also,going beyond those previously described functions,plays critical roles in DNA replication and Pten null prostate cancer initiation.In this review,we briefly summarize the functions of Plk1 in mitosis and cytokinesis,and then mainly focus on newly discov-ered functions of Plk1 in DNA replication and in Pten-null prostate cancer initiation.Furthermore,we briefly introduce the architectures of human and mouse pros-tate glands and the possible roles of Plk1 in human prostate cancer development.And finally,the newly chemotherapeutic development of small-molecule Plk1 inhibitors to target Plk1 in cancer treatment and their translational studies are also briefly reviewed.展开更多
Histones package DNA in all eukaryotes and play key roles in regulating gene expression. Approximately 150 base pairs of DNA wraps around an octamer of core histones to form the nucleosome, the basic unit of chromatin...Histones package DNA in all eukaryotes and play key roles in regulating gene expression. Approximately 150 base pairs of DNA wraps around an octamer of core histones to form the nucleosome, the basic unit of chromatin. Linker histones compact chromatin further by binding to and neutralizing the charge of the DNA between nucleosomes. It is well established that chromatin packing is regulated by a complex pattern of posttranslational modifications (PTMs) to core histones, but linker histone function is less well understood. In this review, we describe the current understand- ing of the many roles that linker histones play in cellular processes, including gene regulation, cell division, and devel- opment, while putting the linker histone in the context of other nuclear proteins. Although intriguing roles for plant linker histones are beginning to emerge, much of our current understanding comes from work in animal systems. Many unanswered questions remain and additional work is required to fully elucidate the complex processes mediated by linker histones in plants.展开更多
Our genomic DNA is under constant assault from endogenous and exogenous sources,which needs to be resolved to maintain cellular homeostasis.The eukaryotic DNA repair enzyme Tyrosyl-DNA phosphodiesterase I(Tdp1)catalyz...Our genomic DNA is under constant assault from endogenous and exogenous sources,which needs to be resolved to maintain cellular homeostasis.The eukaryotic DNA repair enzyme Tyrosyl-DNA phosphodiesterase I(Tdp1)catalyzes the hydrolysis of phosphodiester bonds that covalently link adducts to DNA-ends.Tdp1 utilizes two catalytic histidines to resolve a growing list of DNA-adducts.These DNA-adducts can be divided into two groups:small adducts,including oxidized nucleotides,RNA,and non-canonical nucleoside analogs,and large adducts,such as(drug-stabilized)topoisomerase-DNA covalent complexes or failed Schiff base reactions as occur between PARP1 and DNA.Many Tdp1 substrates are generated by chemotherapeutics linking Tdp1 to cancer drug resistance,making a compelling argument to develop small molecules that target Tdp1 as potential novel therapeutic agents.Tdp1’s unique catalytic cycle,which is centered on the formation of Tdp1-DNA covalent reaction intermediate,allows for two principally different targeting strategies:(1)catalytic inhibition of Tdp1 catalysis to prevent Tdp1-mediated repair of DNA-adducts that enhances the effectivity of chemotherapeutics;and(2)poisoning of Tdp1 by stabilization of the Tdp1-DNA covalent reaction intermediate,which would increase the half-life of a potentially toxic DNA-adduct by preventing its resolution,analogous to topoisomerase targeted poisons such as topotecan or etoposide.The catalytic Tdp1 mutant that forms the molecular basis of the autosomal recessive neurodegenerative disease spinocerebellar ataxia with axonal neuropathy best illustrates this concept;however,no small molecules have been reported for this strategy.Herein,we concisely discuss the development of Tdp1 catalytic inhibitors and their results.展开更多
文摘Eukaryotic chromatin consisting of nucleosomes connected by linker DNA is organized into higher order structures,which is facilitated by linker histone H1.Formation of chromatin compacts and protects the genome,but also hinders DNA transactions.Cells have evolved mechanisms to modify/remodel chromatin resulting in chromatin states suitable for genome functions.The high mobility group box(HMGB)proteins are non-histone chromatin architectural factors characterized by one or more HMGB motifs that bind DNA in a sequence nonspecific fashion.They play a major role in chromatin dynamics.The Saccharomyces cerevisiae(yeast hereafter)HMGB protein Hmo1 contains two HMGB motifs.However,unlike a canonical HMGB protein that has an acidic C-terminus,Hmo1 ends with a lysine rich,basic,C-terminus,resembling linker histone H1.Hmo1 exhibits characteristics of both HMGB proteins and linker histones in its multiple functions.For instance,Hmo1 promotes transcription by RNA polymerases I and II like canonical HMGB proteins but makes chromatin more compact/stable like linker histones.Recent studies have demonstrated that Hmo1 destabilizes/disrupts nucleosome similarly as other HMGB proteins in vitro and acts to maintain a common topological architecture of genes in yeast genome.This minireview reviews the functions of Hmo1 and the underlying mechanisms,highlighting recent discoveries.
基金support by the Ministerio Educación y CienciaMinisterio de Economía y Competitividad of Spain(until June 2013)
文摘PDRG1 is a small oncogenic protein of 133 residues. In normal human tissues, the p53 and DNA damageregulated gene 1(PDRG1) gene exhibits maximal expression in the testis and minimal levels in the liver. Increased expression has been detected in several tumor cells and in response to genotoxic stress. High-throughput studies identified the PDRG1 protein in a variety of macromolecular complexes involved in processes that are altered in cancer cells. For example, this oncogene has been found as part of the RNA polymerase Ⅱ complex, the splicing machinery and nutrient sensing machinery, although its role in these complexes remains unclear. More recently, the PDRG1 protein was found as an interaction target for the catalytic subunits of methionine adenosyltransferases. These enzymes synthesize S-adenosylmethionine, the methyl donor for, among others, epigenetic methylations that occur on the DNA and histones. In fact, downregulation of S-adenosylmethionine synthesis is the first functional effect directly ascribed to PDRG1. The existence of global DNA hypomethylation, together with increased PDRG1 expression, in many tumor cells highlights the importance of this interaction as one of the putative underlying causes for cell transformation. Here, we will review the accumulated knowledge on this oncogene, emphasizing the numerous aspects that remain to be explored.
基金supported in part by grants from the National Institute of Health GM89630 and AI63080an endowed Research Scholar Chair by the Medical Research Institute Councilby an internal grant of the University of Maryland Medical Center(RYZ).
文摘Progression of cells from G2 phase of the cell cycle to mitosis is a tightly regulated cellular process that requires activation of the Cdc2 kinase, which determines onset of mitosis in all eukaryotic cells. In both human and fission yeast (Schizosaccharomyces pombe) cells, the activity of Cdc2 is regulated in part by the phosphorylation status of tyrosine 15 (Tyr15) on Cdc2, which is phosphorylated by Wee1 kinase during late G2 and is rapidly dephosphorylated by the Cdc25 tyrosine phosphatase to trigger entry into mitosis. These Cdc2 regulators are the downstream targets of two well- characterized G2/M checkpoint pathways which prevent cells from entering mitosis when cellular DNA is damaged or when DNA replication is inhibited. Increasing evidence suggests that Cdc2 is also commonly targeted by viral proteins, which modulate host cell cycle machinery to benefit viral survival or replication. In this review, we describe the effect of viral protein R (Vpr) encoded by human immunodeficiency virus type 1 (HIV-1) on cell cycle G2/M regulation. Based on our current knowledge about this viral effect, we hypothesize that Vpr induces cell cycle G2 arrest through a mechanism that is to some extent different from the classic G2/M checkpoints. One the unique features distinguishing Vpr-induced G2 arrest from the classic checkpoints is the role of phosphatase 2A (PP2A) in Vpr-induced G2 arrest. Interestingly, PP2A is targeted by a number of other viral proteins including SV40 small T antigen, polyomavirus T antigen, HTLV Tax and adenovirus E4orf4. Thus an in-depth understanding of the molecular mechanisms underlying Vpr-induced G2 arrest will provide additional insights into the basic biology of cell cycle G2/M regulation and into the biological significance of this effect during host-pathogen interactions.
文摘目的探讨DNA损伤应答蛋白1(regulated in development and DNA damage responses-1,REDD1)在幽门螺杆菌(Helicobacter pylori,H.pylori)感染中的表达及调控机制。方法建立H.pylori感染C57小鼠及胃上皮细胞模型,运用实时荧光定量PCR、免疫组织化学染色和Western blot检测REDD1 mRNA和蛋白的表达;并在细胞模型中采用信号通路抑制剂的方法探讨H.pylori感染诱导REDD1上调的机制。结果相对于未感染组,H.pylori感染小鼠胃黏膜中的REDD1水平显著增高;而相对于野生型(Wild Type,WT)全毒株,敲除cagA基因后,H.pylori感染诱导REDD1上调的能力则显著下降(P<0.05);H.pylori感染可诱导胃上皮细胞AGS REDD1表达上调,并具有时间、感染菌量以及cagA依赖性(P<0.05);P38/MAPK信号通路阻断可显著抑制H.pylori感染诱导的REDD1上调表达(P<0.05)。结论H.pylori依赖磷酸化的cagA蛋白激活MAPKp38通路诱导REDD1表达增高。
文摘Polo-like kinase 1(Plk1),a well-characterized member of serine/threonine kinases Plk family,has been shown to play pivotal roles in mitosis and cytokinesis in eu-karyotic cells.Recent studies suggest that Plk1 not only controls the process of mitosis and cytokinesis,but also,going beyond those previously described functions,plays critical roles in DNA replication and Pten null prostate cancer initiation.In this review,we briefly summarize the functions of Plk1 in mitosis and cytokinesis,and then mainly focus on newly discov-ered functions of Plk1 in DNA replication and in Pten-null prostate cancer initiation.Furthermore,we briefly introduce the architectures of human and mouse pros-tate glands and the possible roles of Plk1 in human prostate cancer development.And finally,the newly chemotherapeutic development of small-molecule Plk1 inhibitors to target Plk1 in cancer treatment and their translational studies are also briefly reviewed.
文摘Histones package DNA in all eukaryotes and play key roles in regulating gene expression. Approximately 150 base pairs of DNA wraps around an octamer of core histones to form the nucleosome, the basic unit of chromatin. Linker histones compact chromatin further by binding to and neutralizing the charge of the DNA between nucleosomes. It is well established that chromatin packing is regulated by a complex pattern of posttranslational modifications (PTMs) to core histones, but linker histone function is less well understood. In this review, we describe the current understand- ing of the many roles that linker histones play in cellular processes, including gene regulation, cell division, and devel- opment, while putting the linker histone in the context of other nuclear proteins. Although intriguing roles for plant linker histones are beginning to emerge, much of our current understanding comes from work in animal systems. Many unanswered questions remain and additional work is required to fully elucidate the complex processes mediated by linker histones in plants.
基金RCAMvW was in part funded by American Cancer Society UAB ACS-IRG Junior Faculty Development Grant(ACS-IRG-60-001-53)Department of Defense OCRP pilot award W81XWH-15-1-0198the National Institutes of Health Cancer Center Core Support Grant(P30CA013148).
文摘Our genomic DNA is under constant assault from endogenous and exogenous sources,which needs to be resolved to maintain cellular homeostasis.The eukaryotic DNA repair enzyme Tyrosyl-DNA phosphodiesterase I(Tdp1)catalyzes the hydrolysis of phosphodiester bonds that covalently link adducts to DNA-ends.Tdp1 utilizes two catalytic histidines to resolve a growing list of DNA-adducts.These DNA-adducts can be divided into two groups:small adducts,including oxidized nucleotides,RNA,and non-canonical nucleoside analogs,and large adducts,such as(drug-stabilized)topoisomerase-DNA covalent complexes or failed Schiff base reactions as occur between PARP1 and DNA.Many Tdp1 substrates are generated by chemotherapeutics linking Tdp1 to cancer drug resistance,making a compelling argument to develop small molecules that target Tdp1 as potential novel therapeutic agents.Tdp1’s unique catalytic cycle,which is centered on the formation of Tdp1-DNA covalent reaction intermediate,allows for two principally different targeting strategies:(1)catalytic inhibition of Tdp1 catalysis to prevent Tdp1-mediated repair of DNA-adducts that enhances the effectivity of chemotherapeutics;and(2)poisoning of Tdp1 by stabilization of the Tdp1-DNA covalent reaction intermediate,which would increase the half-life of a potentially toxic DNA-adduct by preventing its resolution,analogous to topoisomerase targeted poisons such as topotecan or etoposide.The catalytic Tdp1 mutant that forms the molecular basis of the autosomal recessive neurodegenerative disease spinocerebellar ataxia with axonal neuropathy best illustrates this concept;however,no small molecules have been reported for this strategy.Herein,we concisely discuss the development of Tdp1 catalytic inhibitors and their results.
