Mechanism and regulation of incisions during DNA interstrand cross-link repair

A critical step in DNA interstrand cross-link repair is the programmed collapse of replication forks that have stalled at an ICL. This event is regulated by the Fanconi anemia pathway, which suppresses bone marrow failure and cancer. In this perspective, we focus on the structure of forks that have stalled at ICLs, how these structures might be incised by endonucleases, and how incision is regulated by the Fanconi anemia pathway.     

SUMOylation and PARylation cooperate to recruit and stabilize SLX4 at DNA damage sites

SUMOylation plays important roles in the DNA damage response. However, whether it is important for interstrand crosslink repair remains unknown. We report that the SLX4 nuclease scaffold protein is regulated by SUMOylation. We have identified three SUMO interaction motifs (SIMs) in SLX4, mutating all of which abrogated the binding of SLX4 to SUMO-2 and covalent SLX4 SUMOylation. An SLX4 mutant lacking functional SIMs is not recruited to PML nuclear bodies nor stabilized at laser-induced DNA damage sites. Additionally, we elucidated a novel role for PARylation in the recruitment of SLX4 to sites of DNA damage. Combined, our results uncover how SLX4 is regulated by post-translational modifications.     

SLX2 interacting with BLOS2 is differentially expressed during mouse oocyte meiotic maturation

Gametogenesis is a complex biological process of producing cells for sexual reproduction. Xlr super family members containing a conserved COR1 domain play essential roles in gametogenesis. In the present study, we identified that Slx2, a novel member of Xlr super family, is specifically expressed in the meiotic oocytes, which is demonstrated by western blotting and immunohistochemistry studies. In the first meiotic prophase, SLX2 is unevenly distributed in the nuclei of oocytes, during which phase SLX2 is partly co-localized with SYCP3 in synaptonemal complex and γH2AX in the nucleus of oocytes. Interestingly, the localization of SLX2 was found to be switched into the cytoplasm of oocytes after prometaphase I during oocyte maturation. Furthermore, yeast two-hybrid and coimmunoprecipitation studies demonstrated that SLX2 interacts with BLOS2, which is a novel centrosome-associated protein, and co-localized with γ-Tubulin, which is a protein marker of chromosome segregation in meiosis. These results indicated that SLX2 might get involved in chromosomes segregation during meiosis by interaction with BLOS2. In conclusion, SLX2 might be a novel gametogenesis-related protein that could play multiple roles in regulation of meiotic processes including synaptonemal complex assembly and chromosome segregation.     

Identification and characterization of MUS81 point mutations that abolish interaction with the SLX4 scaffold protein

MUS81-EME1 is a conserved structure-selective endonuclease with a preference for branched DNA substrates in vitro that correspond to intermediates of DNA repair. Cells lacking MUS81 or EME1 show defects in the repair of DNA interstrand crosslinks (ICL) resulting in hypersensitivity to agents such as mitomycin C. In metazoans, a proportion of cellular MUS81-EME1 binds the SLX4 scaffold protein, which is itself instrumental for ICL repair. It was previously reported that mutations in SLX4 that abolished interaction with MUS81 affected ICL repair in human cells but not in murine cells. In this study we looked the other way around by pinpointing amino acid residues in MUS81 that when mutated abolish the interaction with SLX4. These mutations fully rescued the mitomycin C hypersensitivity of MUS81 knockout murine cells, but they were unable to rescue the sensitivity of two different human cell lines defective in MUS81. These data support an SLX4-dependent role for MUS81 in the repair, but not the induction of ICL-induced double-strand breaks. This study sheds light on the extent to which MUS81 function in ICL repair requires interaction with SLX4.     

Nuclease Delivery: Versatile Functions of SLX4/FANCP in Genome Maintenance

As a scaffold, SLX4/FANCP interacts with multiple proteins involved in genome integrity. Although not having recognizable catalytic domains, SLX4 participates in diverse genome maintenance pathways by delivering nucleases where they are needed, and promoting their cooperative execution to prevent genomic instabilities. Physiological importance of SLX4 is emphasized by the identification of causative mutations of SLX4 genes in patients diagnosed with Fanconi anemia (FA), a rare recessive genetic disorder characterized by genomic instability and predisposition to cancers. Recent progress in understanding functional roles of SLX4 has greatly expanded our knowledge in the repair of DNA interstrand crosslinks (ICLs), Holliday junction (HJ) resolution, telomere homeostasis and regulation of DNA damage response induced by replication stress. Here, these diverse functions of SLX4 are reviewed in detail.     

Compartmentalization of the SUMO/RNF4 pathway by SLX4 drives DNA repair

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BLM and SLX4 play opposing roles in recombination‐dependent replication at human telomeres

Alternative lengthening of telomeres (ALT) is a telomere lengthening pathway that predominates in aggressive tumors of mesenchymal origin; however, the underlying mechanism of telomere synthesis is not fully understood. Here, we show that the BLM–TOP3A–RMI (BTR) dissolvase complex is required for ALT‐mediated telomere synthesis. We propose that recombination intermediates formed during strand invasion are processed by the BTR complex, initiating rapid and extensive POLD3‐dependent telomere synthesis followed by dissolution, with no overall exchange of telomeric DNA. This process is counteracted by the SLX4–SLX1–ERCC4 complex, which promotes resolution of the recombination intermediate, resulting in telomere exchange in the absence of telomere extension. Our data are consistent with ALT being a conservative DNA replication process, analogous to break‐induced replication, which is dependent on BTR and counteracted by SLX4 complex‐mediated resolution events.     

NPC1L1:固醇脂质吸收的关键蛋白质

NPC1L1是最近发现的一种与NPC1同源的蛋白质。在体内的分布有物种差异性,其亚细胞定位存在很大争议。近些年发现NPC1L1在固醇类脂质代谢途径中起着重要作用,是肠道吸收固醇类脂质尤其是胆固醇的关键蛋白质,这项新发现使得人们对固醇类脂质的吸收机制有了了解。高胆固醇血症是心血管系统疾病的一个高危因子,因此,对NPC1L1的研究具有重大的实际意义,正逐渐成为研究的热点。     

Stoichiometry studies reveal functional properties of KDC1 in plant shaker potassium channels

Functional heteromeric plant Shaker potassium channels can be formed by the assembly of subunits from different tissues, as well as from diverse plant species. KDC1 (K(+) Daucus carota 1) produces inward-rectifying currents in Xenopus oocytes when coexpressed with KAT1 and other subunits appertaining to different plant Shaker subfamilies. Owing to the presence of KDC1, resulting heteromeric channels display slower activation kinetics, a shift of the activation threshold toward more negative membrane potentials and current potentiation upon the addition of external zinc. Despite available information on heteromerization of plant Shaker channels, very little is known to date on the properties of the various stoichiometric configurations formed by different subunits. To investigate the functional properties of heteromeric nKDC1/mKAT1 configurations, we realized a series of dimeric constructs combining KDC1 and KAT1 alpha-subunits. We found that homomeric channels, formed by monomeric or dimeric alpha-subunit constructs, show identical biophysical characteristics. Coinjections of diverse tandem constructs, instead, displayed significantly different currents proving that KDC1 has high affinity for KAT1 and participates in the formation of functional channels with at most two KDC1 subunits, whereas three KDC1 subunits prevented the formation of functional channels. This article brings a contribution to the understanding of the molecular mechanisms regulating plant Shaker channel functionality by association of modulatory subunits.     

Variation in salinity tolerance and shoot sodium accumulation in Arabidopsis ecotypes linked to differences in the natural expression levels of transporters involved in sodium transport

Salinity tolerance can be attributed to three different mechanisms: Na⁺ exclusion from the shoot, Na⁺ tissue tolerance and osmotic tolerance. Although several key ion channels and transporters involved in these processes are known, the variation in expression profiles and the effects of these proteins on Na⁺ transport in different accessions of the same species are unknown. Here, expression profiles of the genes AtHKT1;1, AtSOS1, AtNHX1 and AtAVP1 are determined in four ecotypes of Arabidopsis thaliana. Not only are these genes differentially regulated between ecotypes, the expression levels of the genes can be linked to the concentration of Na⁺ in the plant. An inverse relationship was found between AtSOS1 expression in the root and total plant Na⁺ accumulation, supporting a role for AtSOS1 in Na⁺ efflux from the plant. Similarly, ecotypes with high expression levels of AtHKT1;1 in the root had lower shoot Na⁺ concentrations, due to the hypothesized role of AtHKT1;1 in retrieval of Na⁺ from the transpiration stream. The inverse relationship between shoot Na⁺ concentration and salinity tolerance typical of most cereal crop plants was not demonstrated, but a positive relationship was found between salt tolerance and levels of AtAVP1 expression, which may be related to tissue tolerance.     

人骨髓间充质干细胞向神经细胞分化过程中Notch通路信号分子表达的变化

本研究探讨Noah信号通路在人骨髓间充质干细胞（human mesenchymal stem cells,hMSCs）体外增殖及向神经细胞分化过程中的作用。采集健康自愿者骨髓,体外培养获得hMSCs,取第3代hMSCs,在诱导剂（β-ME,DMSO,BHA）作用下向神经细胞分化。诱导后用免疫细胞化学鉴定神经元特异性烯醇化酶（neuron-specific enolase,NSE）和尼氏体的表达以确定诱导效果：用流式细胞术检测细胞生长周期时相的变化。在诱导前后,用免疫荧光和RT-PCR方法检测Notch通路中Notch1受体蛋白、配体Jagged1（JAG1）、调节蛋白活化相关物早老素1（presenilin 1,PS1）、靶基因hairy and enhancer of split1（HES1）信号分子表达的变化。结果显示：诱导前,处于G0/G1期的hMSCs占58．5％,S＋G2/M期的细胞占41．5％;诱导后,G0/G1期细胞比例升高,而S＋G2/M期细胞比例下降,NSE阳性细胞率达（77±0．35）％,细胞质中可见深蓝色的块状或颗粒状尼氏体。免疫荧光显示,诱导前后hMSCs内Notch1和JAG1均呈阳性表达,但RT-PCR检测发现诱导后Notch1、JAG1、PSl和HES1 mRNA表达量较诱导前明显降低（均P〈0．05）。结果表明,诱导hMSCs向神经细胞分化能抑制Notch信号分子表达,低水平的Notch信号激活可能有利于神经细胞的分化。     

Carboxamide SIRT1 inhibitors block DBC1 binding via an acetylation-independent mechanism

SIRT1 is an NAD⁺-dependent deacetylase that counteracts multiple disease states associated with aging and may underlie some of the health benefits of calorie restriction. Understanding how SIRT1 is regulated in vivo could therefore lead to new strategies to treat age-related diseases. SIRT1 forms a stable complex with DBC1, an endogenous inhibitor. Little is known regarding the biochemical nature of SIRT1-DBC1 complex formation, how it is regulated and whether or not it is possible to block this interaction pharmacologically. In this study, we show that critical residues within the catalytic core of SIRT1 mediate binding to DBC1 via its N-terminal region, and that several carboxamide SIRT1 inhibitors, including EX-527, can completely block this interaction. We identify two acetylation sites on DBC1 that regulate its ability to bind SIRT1 and suppress its activity. Furthermore, we show that DBC1 itself is a substrate for SIRT1. Surprisingly, the effect of EX-527 on SIRT1-DBC1 binding is independent of DBC1 acetylation. Together, these data show that protein acetylation serves as an endogenous regulatory mechanism for SIRT1-DBC1 binding and illuminate a new path to developing small-molecule modulators of SIRT1.     

Enhancement of hepatic microsomal drug oxidation and glucuronidation in rat by 1,1,1-trichloro-2,2-bis(p-chlorophenyl)ethane (DDT)

A single dose of 1,1,1-trichloro-2,2-bis(p-chlorophenyl)ethane (DDT) (160 mg/kg i.p.) enhanced the monooxygenase step of drug biotransformation in rat liver. The O-demethylation of p-nitroanisole was especially increased, a peak in activity approximately 5-fold compared with controls being attained in 7 days. On the other hand, there was only a 2-fold increase in aryl hydrocarbon hydroxylase activity.DDT increased the cytochrome P-450 content of the liver, this increase coincided well with that in p-nitroanisole O-demethylation activity.The UDPglucuronosyltransferase activity of liver microsomes was not enhanced by DDT administration, unless the microsomes were pretreated to reveal latent activity prior to assay. After trypsin digestion of microsomes a maximum increase in activity of approximately 3-fold was observed as a result of DDT dosage. The canonic surfactant cetylpyridinium chloride was less active in revealing the latent UDP-glucuronosyltransferase activity, and two other membrane perturbants, the detergent digitonin and phospholipase A, were unable to show enhancement in UDPglucuronosyltransferase as a result of DDT dosage.     

CYP1A1基因单核苷酸多态性与肺癌的相关性研究

目的:探讨代谢酶CYP1A1基因MspI位点多态性与新疆汉族人群肺癌遗传易感性之间的相关性.方法:应用聚合酶链式反应(PCR)-限制性片段长度多态性(RFLP)技术检测59例新疆汉族肺癌和84例新疆汉族健康人的CYP1A1基因MspI位点多态性分布频率,并分析了CYP1A1基因MspI位点多态性与新疆汉族人群肺癌遗传易感性和患者性别之间的相关性.结果:(1)CYP1A1基因MspI位点3种多态基因型分布频率在两组间比较差异有统计学意义(χ2=6.682,P=0.035),CC基因型在病例组的分布频率显著高于正常对照组.(2)携带突变CC基因型的个体较携带TT基因型的个体患肺癌的危险性增加(OR=3.759.95%CI=1.228-11.494,P=0.035).(3)男女肺癌患者的CYP1A1基因MspI位点基因型及等位基因频率的差异均无显著性(P>0.05).结论:(1)CC突变基因型可能是新疆汉族人群的肺癌易感因素.(2)CYP1A1基因MspI位点多态性可能与新疆汉族肺癌患者的性别无关.     

粘膜系统鳞状细胞癌(SCC)相关蛋白(DCUN1D1)的表达、纯化和晶体生长

目的:SCCRO/RP42/DCUN1D1是粘膜系统鳞片状细胞癌(SCC)发生时人类基因组3q区域扩增的潜在靶标之一,其蛋白作用机制尚不清楚,本文拟通过表达并大量纯化SCC相关蛋白DCUN1D1用于蛋白结晶以求获得其三维结构。方法:使用人肝脑组织RNA反转录产物为模板扩增出DCUN1D1基因cDNA片断并将其克隆至原核表达载体PGEX-6P-1中,通过IPTG诱导获得大量可溶性表达,再经过GST亲和层析和Sephadex G-200层析柱纯化。结果:获得了纯度95%以上的蛋白,采用悬滴气相扩散法筛选蛋白晶体,获得显微镜下可见的微晶。结论:初步得出DCUN1D1晶体生长条件及范围,为解析DCUN1D1的三维结构并进一步认识其生物功能奠定了基础。     

细胞色素P450 1A1基因多态性与我国某些肿瘤遗传易感性

近年来有关细胞色素P450基因多态性与肿瘤遗传易感性的研究正日益吸引越来越多的关注,本文对我国近年来有关细胞色素P450 1A1(CYP1Al)基因多态性与几种肿瘤遗传易感性的研究进行探讨,推测我国几种高发病率肿瘤的发生与我国CYP1A1基因多态分布状况有关,以此为进一步研究CYP1A1与肿瘤的关系作参考。     

一个中国Gilbert综合征家系的遗传学分析

对一个中国汉族Gilbert综合征遗传家系致病基因突变位点进行鉴定,以期了解该病的分子遗传学基础。首先提取先证者基因组DNA,PCR扩增尿苷二磷酸葡萄糖醛酸转移酶UGT1A1基因的5个外显子,以琼脂糖电泳鉴定PCR产物,纯化后直接测序鉴定。基因扫描显示,与血清胆红素水平密切相关的UGT1A1基因在第1和第5外显子存在纯合突变,而 UGT1A1基因启动子区域和内含子/外显子剪接边界位点序列未检测到突变。进一步对其他家系成员该基因的相应位点进行突变检测,结果显示他们在第1和第5外显子也存在杂合突变,其中还有两个成员在启动子区域检测到(TA)插入突变。对家系成员未抗凝新鲜血液进行生化检测证实了基因突变分析的结果。综合以上结果发现该家系三种突变并存,致病因素为第1和/或第5外显子突变,为显性遗传,两种突变位点纯合导致先证者出现严重胆红素代谢功能障碍。该家系因此成为Gilbert综合征突变位点及其致病机理研究的一个典型临床病例。