NMR Structure and Dynamics of the C-Terminal Domain from Human Rev1 and Its Complex with Rev1 Interacting Region of DNA Polymerase η

Rev1 is a translesion synthesis (TLS) DNA polymerase essential for DNA damage tolerance in eukaryotes. In the process of TLS stalled high-fidelity replicative DNA polymerases are temporarily replaced by specialized TLS enzymes that can bypass sites of DNA damage (lesions), thus allowing replication to continue or postreplicational gaps to be filled. Despite its limited catalytic activity, human Rev1 plays a key role in TLS by serving as a scaffold that provides an access of Y-family TLS polymerases polη, ι, and κ to their cognate DNA lesions and facilitates their subsequent exchange to polζ that extends the distorted DNA primer-template. Rev1 interaction with the other major human TLS polymerases, polη, ι, κ, and the regulatory subunit Rev7 of polζ, is mediated by Rev1 C-terminal domain (Rev1-CT). We used NMR spectroscopy to determine the spatial structure of the Rev1-CT domain (residues 1157-1251) and its complex with Rev1 interacting region (RIR) from polη (residues 524-539). The domain forms a four-helix bundle with a well-structured N-terminal β-hairpin docking against helices 1 and 2, creating a binding pocket for the two conserved Phe residues of the RIR motif that upon binding folds into an α-helix. NMR spin-relaxation and NMR relaxation dispersion measurements suggest that free Rev1-CT and Rev1-CT/polη-RIR complex exhibit μs-ms conformational dynamics encompassing the RIR binding site, which might facilitate selection of the molecular configuration optimal for binding. These results offer new insights into the control of TLS in human cells by providing a structural basis for understanding the recognition of the Rev1-CT by Y-family DNA polymerases.     

Candidacidal effects of Rev (11–20) derived from HIV-1 Rev protein

Rev is an essential regulatory protein for HIV-1 replication. Rev (11–20) is known as the significant region regarding the function of a nuclear entry inhibitory signal (NIS) of Rev. In this study, anticandidal effects and mechanism of action of Rev (11–20) were investigated. The result exhibited that Rev (11–20) contained candidacidal activities. To understand target site(s) of Rev (11–20), the intracellular localization of the peptide was investigated. The result showed that Rev (11–20) rapidly accumulated in the fungal cell surface. The cell wall regeneration test also indicated that Rev (11–20) exerted its anticandidal activity to fungal plasma membrane rather than cell wall. The fluorescent study using 1,6-diphenyl-1,3,5-hexatriene (DPH) further confirmed the membrane-disruption mechanism(s) of Rev (11–20). The present study suggests that Rev (11–20) possesses significant potential regarding therapeutic agents for treating fungal diseases caused by Candida species in humans.     

Specificity of the Yeast Rev3Δ Antimutator and Rev3 Dependency of the Mutator Resulting from a Defect (Rad1Δ) in Nucleotide Excision Repair

The yeast REV3 gene has been predicted to encode a DNA polymerase specializing in translesion synthesis. This polymerase likely participates in spontaneous mutagenesis, as rev3 mutants have an antimutator phenotype. Translesion synthesis also may be necessary for the mutator caused by a RAD1 (nucleotide excision repair) deletion (rad1Δ). To further examine the role of REV3 in spontaneous mutagenesis, we characterized SUP4-o mutations that arose spontaneously in strains having combinations of normal or mutant REV3 and RAD1 alleles. The largest fraction of the rev3Δ-dependent mutation rate decrease was observed for single base-pair substitutions and deletions, although the rates of all mutational classes detected in the RAD1 background were reduced by at least 30%. Interestingly, inactivation of REV3 was associated with a doubling of the number of sites at which the retrotransposon Ty inserted. rev3Δ also greatly diminished the magnitude of the rad1Δ mutator, but not to the rev3Δ antimutator level, implicating REV3-dependent and independent processes in the rad1Δ mutator effect. However, the specificity of the rev3Δ antimutator suggested that the same REV3-dependent processes gave rise to the majority of spontaneous mutations in the RAD1 and rad1Δ strains.     

盐胁迫诱导盐穗木Rev1、Rev3基因的表达分析

根据盐穗木盐胁迫下响应的转录组测序结果,参考盐穗木HcRev1、HcRev3基因的ESTs序列设计荧光定量PCR特异性引物,建立检测盐穗木Revs基因相对表达量的荧光定量PCR方法,分析Rev1和Rev3基因在盐穗木不同浓度盐胁迫处理不同时间的转录水平。结果表明,HcRev1、HcRev3基因具有相似的表达模式,在100 mmol·L^-1 NaCl低盐胁迫下表达稳定,在300、500、700 mmol·L^-1 NaCl胁迫下,随胁迫浓度增高、胁迫时间延长,表达量升高。其中HcRev1在700 mmol·L^-1 NaCl胁迫14 d后达到峰值,是对照组的4.63倍。HcRev3基因在300 mmol·L^-1 NaCl胁迫14 d时,表达量迅速升高,是对照组的15.55倍,表达差异极显著。研究结果说明HcRev1、HcRev3基因都受盐胁迫诱导表达,提示HcRev1、HcRev3基因虽然表达量存在差异,但在盐胁迫过程中参与了DNA损伤修复。研究有助于阐明Rev1、Rev3基因在DNA损伤修复和植物耐盐性间的调控功能作用。     

Rev蛋白: 抗HIV-1感染的新靶点

病毒颗粒蛋白表达调节因子(regulatorofvirionproteinexpression,Rev)是HIV-1转录过程中不可缺少的调控蛋白。Rev与病毒mRNA的Rev应答元件(revresponseelement,RRE)相互作用,加速mRNA向核外转运。Rev缺乏或者不能进入细胞核,未剪接和部分剪接的mRNA将在核内完全降解,导致HIV-1的复制被阻断。Rev在HIV-1复制周期中起着重要的反式调节作用,是寻找新作用机制和不易产生耐药性的抗艾滋病药物的新靶点。该文介绍Rev介导的核质转运过程和Rev蛋白的相关抑制剂。     

The C-terminal domain of human Rev1 contains independent binding sites for DNA polymerase η and Rev7 subunit of polymerase ζ

Human Rev1 is a translesion synthesis (TLS) DNA polymerase involved in bypass replication across sites of DNA damage and postreplicational gap-filling. Rev1 plays an essential structural role in TLS by providing a binding platform for other TLS polymerases that insert nucleotides across DNA lesions (polη, polι, polκ) and extend the distorted primer-terminus (pol?). We use NMR spectroscopy to demonstrate that the Rev1 C-terminal domain utilizes independent interaction interfaces to simultaneously bind a fragment of the ’inserter’ polη and Rev7 subunit of the ’extender’ pol?, thereby serving as a cassette that may accommodate several polymerases making them instantaneously available for TLS.

Structured summary of protein interactions

REV1, REV3 and REV7physically interact by nuclear magnetic resonance (View interaction), molecular sieving (View interaction) and isothermal titration calorimetry (View interaction).REV3 and REV7bind by molecular sieving (View interaction)REV1 and Polη-RIR peptidebind by nuclear magnetic resonance (View interaction)REV1, REV3, REV7 and Polη-RIR peptidephysically interact by nuclear magnetic resonance (View interaction).     

稳定表达HIV-1辅助蛋白Rev的THP-1细胞模型的建立和鉴定

Human immunodeficiency virus-1(HIV-1)辅助蛋白在其感染和艾滋病发病过程中起着非常重要的作用.Regulator of expression of virion proteins(Rev)作为HIV-1辅助蛋白之一,可以调节病毒结构蛋白mRNA出核转运和蛋白表达,对于病毒的复制至关重要.为研究Rev蛋白对靶细胞表犁和功能的影响,本实验采用电穿孔的方法,将HIV-1的rev基因导入THP-1细胞,通过流式分选结合G418筛选的方法建立稳定表达Rev蛋白的细胞模型;并通过RT-PCR、荧光观察及流式检测的方法,在mRNA和蛋白两个水平对所建立的细胞模犁进行鉴定.结果证实rev基凶成功导入了THP-1细胞并稳定表达,为后续rev基因产物与细胞相互作用的研究提供了平台.     

Multifaceted recognition of vertebrate Rev1 by translesion polymerases ζ and κ

Translesion synthesis is a fundamental biological process that enables DNA replication across lesion sites to ensure timely duplication of genetic information at the cost of replication fidelity, and it is implicated in development of cancer drug resistance after chemotherapy. The eukaryotic Y-family polymerase Rev1 is an essential scaffolding protein in translesion synthesis. Its C-terminal domain (CTD), which interacts with translesion polymerase ζ through the Rev7 subunit and with polymerases κ, ι, and η in vertebrates through the Rev1-interacting region (RIR), is absolutely required for function. We report the first solution structures of the mouse Rev1 CTD and its complex with the Pol κ RIR, revealing an atypical four-helix bundle. Using yeast two-hybrid assays, we have identified a Rev7-binding surface centered at the α2-α3 loop and N-terminal half of α3 of the Rev1 CTD. Binding of the mouse Pol κ RIR to the Rev1 CTD induces folding of the disordered RIR peptide into a three-turn α-helix, with the helix stabilized by an N-terminal cap. RIR binding also induces folding of a disordered N-terminal loop of the Rev1 CTD into a β-hairpin that projects over the shallow α1-α2 surface and creates a deep hydrophobic cavity to interact with the essential FF residues juxtaposed on the same side of the RIR helix. Our combined structural and biochemical studies reveal two distinct surfaces of the Rev1 CTD that separately mediate the assembly of extension and insertion translesion polymerase complexes and provide a molecular framework for developing novel cancer therapeutics to inhibit translesion synthesis.     

人免疫缺陷病毒1型Rev单链抗体细胞内免疫抗病毒基因治疗研究

应用抗ＨＩＶ－１Ｒｅｖ单链抗体细胞内免疫方法,研究在人Ｔ细胞和周围血淋巴单核细胞内抗病毒复制的效果,探讨细胞内免疫抗ＨＩＶ－１基因治疗的可行性。克隆抗ＨＩＶ－１Ｒｅｖ单链抗抗体（ｓＦｖ）基因,以逆转录病毒为基因载体,将名装后的含靶基因的逆转录病毒转导至人ＣＤ４阳性Ｔ－细胞株ＣＥＭ和ＳｕｐＴ１,以及ＨＩＶ－１阴性自愿者的周围血淋巴单核细胞（ＰＢＭＣ）,再分别用不同剂量（ＭＯＩ）的ＨＩＶ－１病毒株ＰＮ     

An Intrabody Based on a Llama Single-domain Antibody Targeting the N-terminal α-Helical Multimerization Domain of HIV-1 Rev Prevents Viral Production

The human immunodeficiency virus, type 1 (HIV-1)-encoded Rev protein is essential for the expression of late viral mRNAs. Rev forms a large organized multimeric protein-protein complex on the Rev response element of these viral mRNA species and transports them from the nucleus to the cytoplasm, exploiting the CRM1-mediated cellular machinery. Here we report the selection of a nanobody, derived from a llama heavy-chain only antibody, that efficiently blocks the assembly of Rev multimers. The nanobody inhibits HIV-1 replication in cells and specifically suppresses the Rev-dependent expression of partially spliced and unspliced HIV-1 RNA. In HIV-susceptible cells, this nanobody thus has potential as an effective anti-HIV agent using genetic immunization strategies. Its binding site was mapped to Rev residues Lys-20 and Tyr-23 located in the N-terminal α-helical multimerization domain. In the presence of this nanobody, we observed an accumulation of dimeric Rev species, supporting a head-to-head/tail-to-tail molecular model for Rev assembly. The results indicate that the oligomeric assembly of Rev follows an ordered stepwise process and identify a new epitope within Rev that could guide strategies for the development of novel HIV inhibitors.     

HIV-1B′/C亚型Rev蛋白的表达、纯化与抗体制备

目的:为方便实验室工作中对HIV-1 B′/C亚型Rev蛋白的检测,制备相应的Rev蛋白及其抗体.方法:将我国HIV-1 B′/C亚型流行株的rev基因按大肠杆菌优势密码子进行改造后人工合成,在原核系统中与pET30a(+)载体中的His·Tag、Trx·Tag及S·Tag进行融合表达,目的蛋白经Ni2+金属螯合层析柱纯化后用于免疫家兔,制备多克隆抗体.结果与结论:合成基因在原核系统中融合表达得到相对分子质量约18×103的融合蛋白,目的蛋白的表达量约占菌体总蛋白量的36%;用纯化后的融合蛋白免疫家兔,制备了多克隆抗体,Western印迹及间接免疫荧光检测结果显示,获得的多克隆抗体与HIV-1 B′/C亚型的Rev蛋白能产生特异性反应,可用于检测HIV-1 B′/C亚型Rev蛋白的表达.     

HIV-1 B’/C亚型Rev蛋白的表达、纯化与抗体制备

目的:为方便实验室工作中对HIV-1 B’/C亚型Rev蛋白的检测,制备相应的Rev蛋白及其抗体。方法:将我国HIV-1 B’/C亚型流行株的rev基因按大肠杆菌优势密码子进行改造后人工合成,在原核系统中与pET30a(+)载体中的His.Tag、Trx.Tag及S.Tag进行融合表达,目的蛋白经Ni2+金属螯合层析柱纯化后用于免疫家兔,制备多克隆抗体。结果与结论:合成基因在原核系统中融合表达得到相对分子质量约18×103的融合蛋白,目的蛋白的表达量约占菌体总蛋白量的36%;用纯化后的融合蛋白免疫家兔,制备了多克隆抗体,Western印迹及间接免疫荧光检测结果显示,获得的多克隆抗体与HIV-1 B’/C亚型的Rev蛋白能产生特异性反应,可用于检测HIV-1 B’/C亚型Rev蛋白的表达。     

HIV-1 Rev transactivator: A β-subunit directed substrate and effector of protein kinase CK2

The phosphorylation of HIV-1 Rev by protein kinase CK2 is strictly dependent on the regulatory subunit of the kinase and is deeply affected by conformational changes of the substrate outside the phosphorylation site [12]. Here we show that Rev modulates a variety of CK2 properties, including autophosphorylation, catalytic activity toward calmodulin, and susceptibility to polycationic effectors, whose common denominator is the involvement of the subunit. Rev's two major CK2 sites are located at its N-terminus, immediately adjacent to a helix-loop-helix motif. By comparing the behaviour of full-size Rev with that of synthetic peptides reproducing, with suitable modifications, its N-terminal 26 amino acids including the phosphoacceptor site (Ser 5, Ser 8) and amphipathic helix-1, it appears that the functional interaction of the N-terminal portion of Rev with the N-terminal domain of the subunit must rely on both electrostatic and hydrophobic interactions. The former mainly involve Rev's arginine-rich domain (residues 35–50) in helix-2, while the latter are mostly mediated by residues 12–24 of helix-1. These data disclose the possibility that, besides displaying protective, regulatory and targeting properties with respect to the catalytic subunit, the CK2 subunit also plays a role as a docking site for a subset of CK2 substrates.     

Rev3, the catalytic subunit of Polζ, is required for maintaining fragile site stability in human cells

It has been long speculated that mammalian Rev3 plays an important, yet unknown role(s) during mammalian development, as deletion of Rev3 causes embryonic lethality in mice, whereas no other translesion DNA synthesis polymerases studied to date are required for mouse embryo development. Here, we report that both subunits of Polζ (Rev3 and Rev7) show an unexpected increase in expression during G₂/M phase, but they localize independently in mitotic cells. Experimental depletion of Rev3 results in a significant increase in anaphase bridges, chromosomal breaks/gaps and common fragile site (CFS) expression, whereas Rev7 depletion primarily causes lagging chromosome defect with no sign of CFS expression. The genomic instability induced by Rev3 depletion seems to be related to replication stress, as it is further enhanced on aphidicolin treatment and results in increased metaphase-specific Fanconi anemia complementation group D type 2 (FANCD2) foci formation, as well as FANCD2-positive anaphase bridges. Indeed, a long-term depletion of Rev3 in cultured human cells results in massive genomic instability and severe cell cycle arrest. The aforementioned observations collectively support a notion that Rev3 is required for the efficient replication of CFSs during G₂/M phase, and that the resulting fragile site instability in Rev3 knockout mice may trigger cell death during embryonic development.     

Allosteric Modulation of the Activity of the Glucagon-like Peptide-1 (GLP-1) Metabolite GLP-1 9–36 Amide at the GLP-1 Receptor

Glucagon-like peptide-1 (GLP-1) released from intestinal L cells in response to nutrients has many physiological effects but particularly enhances glucose-dependent insulin release through the GLP-1 receptor (GLP-1R). GLP-1 7–36 amide, the predominant circulating active form of GLP-1, is rapidly truncated by dipeptidyl peptidase-4 to GLP-1 9–36 amide, which is generally considered inactive. Given its physiological roles, the GLP-1R is targeted for treatment of type 2 diabetes. Recently ‘compound 2’ has been described as both an agonist and positive allosteric modulator of GLP-1 7–36 amide affinity, but not potency, at the GLP-1R. Importantly, we demonstrated previously that exendin 9–39, generally considered a GLP-1R antagonist, enhances compound 2 efficacy (or vice versa) at the GLP-1R. Given that GLP-1 9–36 amide is the major circulating form of GLP-1 post-prandially and is a low affinity weak partial agonist or antagonist at the GLP-1R, we investigated interaction between this metabolite and compound 2 in a cell line with recombinant expression of the human GLP-1R and the rat insulinoma cell line, INS-1E, with native expression of the GLP-1R. We show compound 2 markedly enhances efficacy and potency of GLP-1 9–36 amide for key cellular responses including AMP generation, Ca²⁺ signaling and extracellular signal-regulated kinase. Thus, metabolites of peptide hormones including GLP-1 that are often considered inactive may provide a means of manipulating key aspects of receptor function and a novel therapeutic strategy.     

A Potential Link between the C5a Receptor 1 and the β1-Adrenoreceptor in the Mouse Heart

Purpose

Inflammation may contribute to the pathogenesis of specific cardiovascular diseases, but it is uncertain if mediators released during the inflammatory process will affect the continued efficacy of drugs used to treat clinical signs of the cardiac disease. We investigated the role of the complement 5a receptor 1 (C5aR1/CD88) in the cardiac response to inflammation or atenolol, and the effect of C5aR1 deletion in control of baseline heart rate in an anesthetized mouse model.

Methods

An initial study showed that PMX53, an antagonist of C5aR1 in normal C57BL6/J (wild type, WT) mice reduced heart rate (HR) and appeared to have a protective effect on the heart following induced sepsis. C5aR1 knockout (CD88-/-) mice had a lower HR than wild type mice, even during sham surgery. A model to assess heart rate variability (HRV) in anesthetized mice was developed to assess the effects of inhibiting the β₁-adrenoreceptor (β₁-AR) in a randomized crossover study design.

Results

HR and LF Norm were constitutively lower and SDNN and HF Norm constitutively higher in the CD88-/- compared with WT mice (P< 0.001 for all outcomes). Administration of atenolol (2.5 mg/kg) reduced the HR and increased HRV (P< 0.05, respectively) in the wild type but not in the CD88-/- mice. There was no shift of the sympathovagal balance post-atenolol in either strains of mice (P> 0.05), except for the reduced LF/HF (Lower frequency/High frequency) ratio (P< 0.05) at 60 min post-atenolol, suggesting increased parasympathetic tone of the heart due to the effect of atenolol administration. The HR of the WT mice were lower post atenolol compared to the CD88-/- mice (P = 0.001) but the HRV of CD88-/- mice were significantly increased (P< 0.05), compared with WT mice.

Conclusion

Knockout of the C5aR1 attenuated the effect of β₁-AR in the heart, suggesting an association between the β₁-AR and C5aR1, although further investigation is required to determine if this is a direct or causal association.     

Is the IS1-flanked r-determinant of the R plasmid NR1 a transposon?

The 23 kilobase multiple drug resistance r-determinant (r-det) of the R plasmid NR1 is an IS1-mediated transposon, Tn2671. Drug-resistant Escherichia coli transductants isolated after infection with bacteriophage P1::Tn2671 derivatives carry the intact r-det in their chromosomes. Independently isolated transductants carry the r-det at different locations on the chromosome. From the E. coli chromosome, Tn2671 can transpose to various locations on the phage P7 genome. Throughout these processes, r-det is maintained as a stable unit. Various possible molecular mechanisms, which all might contribute with characteristic frequencies to the transposition of Tn2671, are discussed. The results presented are relevant to the understanding of mechanisms for a wide spreading of drug resistance genes.