Nucleotide Binding Domain Interactions During the Mechanochemical Reaction Cycle of ATP-Binding Cassette Transporters

ATP-binding cassette (ABC) transporters serve as importers and exporters for a wide variety of solutes in both prokaryotes and eukaryotes, and are implicated in microbial drug resistance and a number of significant human genetic disorders. Initial crystal structures of the soluble nucleotide binding domains (NBDs) of ABC transporters, while a significant step towards understanding the coupling of ATP binding and hydrolysis to transport, presented researchers with important questions surrounding the role of the signature sequence residues, the composition of the nucleotide binding sites, and the mode of NBD dimerization during the transport reaction cycle. Recent studies have begun to address these concerns. This mini-review summarizes the biochemical and structural characterizations of two archaebacterial NBDs from Methanocaldococcus jannaschii, MJ0796 and MJ1267, and offers current perspectives on the functional mechanism of ABC transporters.     

Consecutive incorporation of fluorophore-labeled nucleotides by mammalian DNA polymerase β

In the present study, we investigated mammalian polymerases that consecutively incorporate various fluorophore-labeled nucleotides. We found that rat DNA polymerase β (pol β) consecutively incorporated fluorophore-labeled nucleotides to a greater extent than four bacterial polymerases, Sequenase Version 2.0, Vent_R (exo-), DNA polymerase IIIα and the Klenow fragment, and the mammalian polymerases DNA polymerase α and human DNA polymerase δ, under mesophilic conditions. Furthermore, we investigated the kinetics of correct or mismatched incorporation with labeled nucleotides during synthesis by rat pol β. The kinetic parameters K_m and k_cat were measured and used for evaluating: (i) the discrimination against correct pair incorporation of labeled nucleotides relative to unlabeled nucleotides; and (ii) the fidelity for all nucleotide combinations of mismatched pairs in the presence of labeled or unlabeled nucleotides. We also investigated the effect of fluorophore-labeled nucleotides on terminal deoxynucleotidyl transferase activity of rat pol β. We have demonstrated for the first time that mammalian pol β can consecutively incorporate various fluorophore-labeled dNTPs. These findings suggest that pol β is useful for high-density labeling of DNA probes and single-molecule sequencing for high-speed genome analysis.     

DNA损伤修复机制——解读2015年诺贝尔化学奖

Tomas Lindahl, Paul Modrich和Aziz Sancar三位科学家因发现“DNA损伤修复机制”获得了2015年诺贝尔化学奖．Lindahl首次发现Escherichia Coli中参与碱基切除修复的第一个蛋白质--尿嘧啶 DNA糖基化酶（UNG）; Modrich重建了错配修复的体外系统,从大肠杆菌到哺乳动物深入探究了错配修复的机制; Sancar利用纯化的UvrA、UvrB、UvrC重建了核苷酸切除修复的关键步骤,阐述了核苷酸切除修复的分子机制．DNA损伤是由生物所处体外环境和体内因素共同导致的,面对不同种类的损伤,机体启动多种不同的修复机制修复损伤,保护基因组稳定性．这些修复机制包括：光修复(light repairing);核苷酸切除修复（nucleotide excision repair, NER）;碱基切除修复（base excision repair, BER）;错配修复（mismatch repair, MMR）;以及DNA双链断裂修复（DNA double strand breaks repair, DSBR）．其中DNA双链断裂修复又分同源重组（homologous recombination, HR）和非同源末端连接（non homologous end joining, NHEJ）两种方式．本文将对上述几种修复的机制进行总结与讨论．     

Adenine nucleotide content and energy charge in dry cells and cysts of Azotobacter vinelandii

Abstract The levels of intracellular adenine nucleotides, energy charge, oxygen consumption and poly-β-hydroxybutyric acid stored, have been investigated in dry vegetative cells and cysts of Azotobacter vinelandii . The data show that under desiccation conditions the cysts retain viability at energy charge values of 0.20 and an ATP/ADP ratio of 0.24, whereas under the same desiccation conditions, vegetative cells die at energy charge values <0.5 and an ATP/ADP ratio of <0.6.     

核酸、氨基酸分类和蛋白质二级结构关系的分析与分子设计

核酸序列中包含一定的蛋白质结构信息。根据通常情况下遗传密码表中密码子中间位的碱基配对时产生的氢键数目,尝试将20种氨基酸划分为两类,并用自编的计算机软件对蛋白质二级结构数据库中两类氨基酸的类聚现象进行了统计分析。结果表明,使用这种方法对氨基酸进行划分后,氨基酸残基具有较大概率与划入同一类的氨基酸残基相邻出现,并且这种聚集体对二级结构具有一定的偏好性。最后按照该方法设计了一段氨基酸序列并给出了预测服务器预测得到的结构。     

不同性别类型黄瓜ACC合酶基因的单核苷酸多态性标记和酶切扩增长度多态性标记

黄瓜的性别分化与乙烯密切相关,1-氨基环丙烷-1-羧酸(ACC)合酶是乙烯生物合成过程中的关键酶.根据ACC合酶基因家族的保守序列设计PCR引物,从8个不同性别类型(雌雄同株、强雌性和全雌性)黄瓜品种中克隆了长度为1188bp的ACC合酶基因(CS-ACS2)片段(GenBank登记号为:DQ115884～DQ115886和DQ115875～DQ115879).经测序分析,3个雌雄同株性别类型品种的序列完全相同.与之相比,5个强雌性和全雌性品种中存在8个单核苷酸多态性(SNPs)标记,SNPs标记为4个A←→G和4个T←→C之间的转换.在8个SNPs中,有1个SNP位于内含子区域,其余7个SNPs都位于外显子区域.在7个位于外显子区域的SNPs中,有3个为非编码区的SNPs,4个为cSNPs.而在4个cSNPs中,有3个导致了编码的氨基酸序列改变.研究结果表明,与雌雄同株性别类型相比,雌性系中均存在单核苷酸的变异,这提示ACC合酶基因CS-ACS2的单核苷酸变异可能与黄瓜雌性系的发生形成有关.另一方面,根据SNP多态性还发展了一个酶切扩增长度多态性(CAPS)标记C-MT700.利用CAPS标记C-MT700能将强雌性优良品种MT-705与其他黄瓜品种相区别,该标记在黄瓜育种生产上具有一定的应用价值.此外,研究获得的SNPs标记和CAPS标记丰富了黄瓜的分子标记种类.     

Novel A14841G mutation is associated with high penetrance of LHON/C4171A family

We report the clinical and genetic characterization of a Chinese LHON family carrying an ND1/C4171A mutation. This family has high penetrance of visual impairment and extremely low frequency of vision recovery, which is in marked contrast to previously reported results for Korean LHON families with the same mutation. Sequence analysis of the complete mtDNA in the partially defined East Asian haplogroup N9a1 revealed the presence of 29 other variants. A novel heteroplasmic A14841G mutation, one of the variants with a serine substituted for a highly conserved asparagine at amino acid 32 of Cytochrome b (Cytb), may play a synergistic role with the C4171A mutation, leading to significantly different clinical manifestations of LHON among these families. The study further confirmed that C4171A was a rare primary LHON mutation, and the mtDNA background could also contribute to the clinical manifestation of the LHON/C4171A mutation.     

Identification of glyoxalase 1 polymorphisms associated with enzyme activity

The glyoxalase system and its main enzyme, glyoxalase 1 (GLO1), protect cells from advanced glycation end products (AGEs), such as methylglyoxal (MG) and other reactive dicarbonyls, the formation of which is increased in diabetes patients as a result of excessive glycolysis. MG is partly responsible for harmful protein alterations in living cells, notably in neurons, leading to their dysfunction, and recent studies have shown a negative correlation between GLO1 expression and tissue damage. Neuronal dysfunction is a common diabetes complication due to elevated blood sugar levels, leading to high levels of AGEs. The aim of our study was to determine whether single nucleotide polymorphisms (SNPs) in the GLO1 gene influence activity of the enzyme. In total, 125 healthy controls, 101 type 1 diabetes, and 100 type 2 diabetes patients were genotyped for three common SNPs, rs2736654 (A111E), rs1130534 (G124G), and rs1049346 (5′-UTR), in GLO1. GLO1 activity was determined in whole blood lysates for all participants of the study.