Expression of the catalytic subunits of pol α and pol δ from fission yeast<Emphasis Type="Italic">Schizosaccharomyces pombe</Emphasis>

This paper reports on expression and posttranslational modifications of the catalytic subunits of pol α and pol δ from fission yeastSchizosaccharomyces pombe. Okadaic acid treatment ofS. pombe spheroplasts in amounts known to inhibit phosphatases, 1 and 2A resulted in decreased proteolysis of both pol α and pol δ. Computer analysis of pol α and pol δ sequences confirmed the presence of consensus motifs for protein phosphorylation. Indirect immunofluorescence microscopy ofS. pombe cells showed nuclear location of both proteins in wild type cells. However, whereas cells transformed with a vector expressing pol α produced a clear increase of the nuclear signal no increase was detectable in cells transformed with pol δ. This observation suggests the existence of a mechanism limiting thecell concentration of pol δ in the cell. Constitutive expression ofS. pombe pol δ inE. coli was possible only with vectors containing truncated forms of its gene, indicating a toxic effect of pol δ onE. coli growth.     

人类polⅡ启动子的识别

依据基因启动子区和非启动子区碱基分布的特征,应用基于多样性增量的二次判别分析 (IDQD),对人类polⅡ启动子进行识别,识别精度达到90％以上的水平,优于其他已发表的 (包括SVM分类器等) 识别算法. 使用IDQD算法也能对转录起始位点 (TSS) 进行较准确的预测,10-fold交叉检验结果的敏感性和特异性分别为86％和91％. 这些结果表明IDQD是一个有效的分类器.     

理论预测果蝇polⅡ启动子

基于果蝇polⅡ启动予的序列特征,利用结合了离散增量和位置权重矩阵的贝叶斯判别函数对果蝇启动予进行了预测。对预测算法进行10交叉检验。通过比较不同大小训练集对结果的影响,说明了参数选取的合理性和算法的预测能力。同时比较了不同参数的选取对预测结果的影响,从而获得最佳启动子预测结果。预测结果显示成功率达到93％,相互关联系数达到83％。     

The primary DNA-binding subsite of the rat pol β. Energetics of interactions of the 8-kDa domain of the enzyme with the ssDNA

Interactions of the 8-kDa domain of the rat pol β and the intact enzyme with the ssDNA have been studied, using the quantitative fluorescence titration technique. The 8-kDa domain induces large topological changes in the bound DNA structure and engages much larger fragments of the DNA than when embedded in the intact enzyme. The DNA affinity of the domain is predominantly driven by entropy changes, dominated by the water release from the protein. The thermodynamic characteristics dramatically change when the domain is embedded in the intact polymerase, indicating the presence of significant communication between the 8-kDa domain and the catalytic 31-kDa domain. The diminished water release from the 31-kDa domain strongly contributes to its dramatically lower DNA affinity, as compared to the 8-kDa domain. Unlike the 8-kDa domain, the DNA binding of the intact pol β is driven by entropy changes, originating from the structural changes of the formed complexes.     

DNA polymerase zeta （pol ζ） in higher eukaryotes

Most current knowledge about DNA polymerase zeta （pol ζ） comes from studies of the enzyme in the budding yeast Saccharomyces cerevisiae, where pol ζ consists of a complex of the catalytic subunit Rev3 with Rev7, which associates with Revl. Most spontaneous and induced mutagenesis in yeast is dependent on these gene products, and yeast pol can mediate translesion DNA synthesis past some adducts in DNA templates. Study of the homologous gene products in higher eukaryotes is in a relatively early stage, but additional functions for the eukaryotic proteins are already apparent. Suppression of vertebrate REV3L function not only reduces induced point mutagenesis but also causes larger-scale genome instability by raising the frequency of spontaneous chromosome translocations. Disruption of Rev3L function is tolerated in Drosophila, Arabidopsis, and in vertebrate cell lines under some conditions, but is incompatible with mouse embryonic development. Functions for REV3L and REV7（MAD2B） in higher eukaryotes have been suggested not only in translesion DNA synthesis but also in some forms of homologous recombination, repair of interstrand DNA crosslinks, somatic hypermutation of immunoglobulin genes and cell-cycle control. This review discusses recent developments in these areas.     

Lesion bypass activity of DNA polymerase θ (POLQ) is an intrinsic property of the pol domain and depends on unique sequence inserts

DNA polymerase θ (POLQ, polθ) is a large, multidomain DNA polymerase encoded in higher eukaryotic genomes. It is important for maintaining genetic stability in cells and helping protect cells from DNA damage caused by ionizing radiation. POLQ contains an N-terminal helicase-like domain, a large central domain of indeterminate function, and a C-terminal polymerase domain with sequence similarity to the A-family of DNA polymerases. The enzyme has several unique properties, including low fidelity and the ability to insert and extend past abasic sites and thymine glycol lesions. It is not known whether the abasic site bypass activity is an intrinsic property of the polymerase domain or whether helicase activity is also required. Three “insertion” sequence elements present in POLQ are not found in any other A-family DNA polymerase, and it has been proposed that they may lend some unique properties to POLQ. Here, we analyzed the activity of the DNA polymerase in the absence of each sequence insertion. We found that the pol domain is capable of highly efficient bypass of abasic sites in the absence of the helicase-like or central domains. Insertion 1 increases the processivity of the polymerase but has little, if any, bearing on the translesion synthesis properties of the enzyme. However, removal of insertions 2 and 3 reduces activity on undamaged DNA and completely abrogates the ability of the enzyme to bypass abasic sites or thymine glycol lesions.     

Roles of chromosomal and episomal dinB genes encoding DNA pol IV in targeted and untargeted mutagenesis in Escherichia coli

DNA polymerase IV (pol IV) in Escherichia coli is a member of a novel family of DNA polymerases (the DinB/UmuC/Rad30/Rev1 super-family or the DNA polymerase Y family). Although expression of the dinB gene encoding DNA pol IV is known to result in an enhancement of untargeted mutagenesis, it remains uncertain whether DNA pol IV is involved in a variety of lesion-induced mutagenesis (targeted mutagenesis), and the relationship between expression levels of dinB and the mutagenesis that DNA pol IV promotes has not been investigated thoroughly. Here, we report that DNA pol IV is involved in -1 frameshift mutagenesis induced by 4-nitroquinoline N-oxide (4-NQO) and that the expression level of the chromosomal pol IV gene is 6-12 times higher than those for other SOS-inducible DNA polymerases in E. coli, i.e., DNA pol II (PolB) or DNA pol V (UmuDC), respectively. Interestingly, the dinB gene is present not only on the chromosome but also on the F' plasmid in the E. coli CC108 strain. In this strain, 750 molecules of DNA pol IV are expressed from the F' dinB gene in the uninduced state and 250 molecules are expressed from the chromosomal gene. These cellular expression levels strongly affect -1 frameshifts induced by 4-NQO in runs of six guanine bases: mutagenicity was highest in the strain CC108, followed by strains YG2242 (chromosome deltadinB/F' dinB+), YG2247 (chromosome dinB+/F' deltadinB) and FC1243 (chromosome deltadinB/F' deltadinB). The incidence of untargeted -1 frameshifts was reduced by two-thirds on deletion of dinB from the F' episome. The chromosomal dinB gene appeared to have little or no effect on the untargeted mutagenesis. These results suggest that DNA pol IV efficiently mediates targeted mutagenesis by 4-NQO, and that the cellular levels of expression substantially affect targeted and untargeted mutagenesis.     

猴泡沫病毒SFV-1前病毒pol基因克隆及序列分析

采用nested-PCR从猕猴肾组织细胞中获得同源性较高、具有高度保守序列的、长度为465 bp 大小的猴泡沫病毒SFV-1的 pol 基因的cDNA,将其克隆到pMD18-T载体中,并对其进行序列分析,分析结果表明所克隆的基因片断为猴泡沫病毒SFV-1 pol 基因片段,与文献中已发表的来源于灵长类动物SFV-1、SFV-1A、SFV-1B、SFV-2、 SFVmac、SFVkm的 pol 基因核苷酸序列进行比对,显示SFVkm1与上述病毒 pol 基因核苷酸同源性分别为91.06%、90.59%、90.82%、90.21%、89.41%、91.53%.对 pol 基因克隆和序列分析是了解和掌握SFV病毒分子流行病学及其变异趋势的重要手段,7 种不同基因型的泡沫病毒的系统进化树分析显示了SFVkm1与它们之间的相互联系.     

利用支持向量机和马氏判别式预测人类polⅡ启动子

通过选取人类启动子与非启动子序列中不同的k-mer作为预测算法的基础特征,分别以三个区域（-249～-1;0～＋50;-30～＋30）的6-mer频数作为离散源参数构建离散增量,同时选取24个位点（-31～-21;-4-＋2;＋25-＋29）的3-mer频数作为位置打分函数的参数,分别利用支持向量机和马氏判别式为判别函数对启动子进行预测。用10折叠交叉检验来衡量两种算法的预测能力,预测结果成功率分别达到87．0％和87．9％。对于独立检验集,敏感性分别为62．7％和76．0％,特异性分别为77．5％和66.8％。     

靶向HIV-1pol的高效人工miRNA的构建与体外抗病毒能力评价

RNAi技术在抗HIV-1治疗研究中已显示出巨大潜力,获得可高效特异抑制HIV-1的RNAi元件是进行相关研究的重要基础。miRNA在抑制和表达方式上相比siRNA具有更多的优势。本研究即探讨构建可高效特异靶向HIV-1的人工miRNA元件。选择以保守性较好的HIV-1pol基因为靶区筛选高效保守的RNAi序列,设计了16个可靶向pol区高保守区段的RNAi靶点,构建表达载体与HIV-1感染性克隆进行共转染抑制实验,筛选显示pol1026序列兼具高保守性及高抑制效率特点。以天然miR-30a为基础骨架构建了靶向pol1026靶点的人工miRNA元件,通过与HIV-1感染性克隆质粒的共转染抑制实验验证获得了可有效抑制HIV-1表达的人工miRNA元件(miR-1026E)。通过与携带靶序列的报告质粒的共转染实验证明miR-1026E具有良好的靶点特异性。本研究进一步构建了携带miR-1026E表达元件的重组慢病毒,转导MT-4细胞并对转导后细胞进行克隆化筛选,获得稳定整合miR-1026E表达元件的MT-4-miR1026E细胞克隆,该细胞在体外攻毒实验中可高效抑制HIV-1的复制,具有显著的抑制HIV-1的能力。同时应用实时RT-PCR方法检测显示,miR-1026E在细胞中不会影响内源性代表miRNA(miR-181与miR-16)的表达水平和干扰素效应相关基因stat1的表达水平,具有良好的特异性。所获得的可特异高效抑制HIV-1复制的人工miRNA元件可为抗HIV-1研究提供重要参考。     

南宁市HIV-1/AIDS人群治疗前pol区遗传特性及蛋白结构分析

为探讨南宁市某县艾滋病病毒1型(HIV-1)感染人群中治疗前pol区遗传特性及蛋白结构变化情况,本研究通过RT-PCR扩增pol区部分序列并进行测序,将序列同源比对构建系统进化树;分型确定毒株亚型和斯坦福大学HIV耐药性数据库比对,分析耐药相关位点;SWISS-MODEL蛋白质同源数据库进行建模分析氨基酸的突变对蛋白质结构和功能的影响。本研究在90份HIV-1标本中获得46个pol区有效序列,共发现4种亚型,其中CRF01_AE占76.08%(35/46)、CRF08_BC占15.22%(7/46)、CRF07_BC占(3/46)6.52%、CRF59_01B1占2.17%(1/46);46个序列中有4例(8.69%)出现耐药突变位点,没有针对核苷酸反转录酶抑制剂(NRTI)的耐药突变;针对蛋白酶类抑制剂(PIs)1例,PR蛋白酶的柔性部位I47V位点发生突变,β折叠结构的I84V位点发生突变,都是异亮氨酸突变为缬氨酸;针对非核苷酸反转录酶抑制剂(NNRTI)有3例,2例位于活性中心的Y181C位点由酪氨酸突变为半胱氨酸,1例位于转角处的E138G位点由谷氨酸突变为甘氨酸。研究表明,南宁市某县HIV-1病毒CRF01_AE重组亚型比例最大,未经抗病毒治疗HIV1感染者中已经出现pol区耐药突变株,突变位点主要位于活性中心及柔性部位,传播水平已经处于中等流行状态。深入分析蛋白质与抑制剂相互作用机制,有助于为艾滋病抗病毒及耐药性监测方案提供科学依据。     

甘蓝型油菜pol CMS育性恢复基因对orf224/atp6的转录调控

用 10个线粒体基因探针对波里马细胞质雄性不育 (polimaCMS)三系 1141A(pol) ,1141B(nap)和 1141R(pol)的花蕾线粒体RNA进行了Northern检测。结果表明 ,只有 3个探针atp6、orf2 2 4和orf2 2 2检测到转录本的差异。atp6在可育的 1141B中只转录产生一个丰度很高的 1 1kb转录本 ,在雄性不育的 1141A和pol胞质恢复系 1141R中 ,这个转录本的丰度明显减少并出现了分子量较大的 2个转录本 2 2kb、1 9kb转录本。与 1141A相比 ,恢复系1141R的 2 2kb和 1 9kb转录本丰度明显减少 ,并伴随着两个新的转录本 1 4kb和 1 3kb。表明orf2 2 4 atp6的表达与polCMS有关 ,并且其转录受到恢复基因Rfp的调控。同时通过对杂种F1 ( 1141A× 1141R)与另一个恢复系RS35 (pol)的比较证实 ,Rfp对orf2 2 4 atp6的调控与Rfp纯合与否无关。orf2 2 4 atp6在 1141A的苗期叶片中还转录产生育性恢复特异的 1 4kb转录本 ,这可能与细胞核基因型和相对低温条件有关。     

尖毛虫属Actin Ⅰ、α-TBP和DNA pol α乱序基因的模式研究

研究旨在对尖毛虫属内现有物种的3种乱序小核基因结构进行比较,探讨其乱序模式。于湛江湖光红树林水域中采集到一个尖毛虫属物种Oxytricha sp.（ZJ）,成功扩增了其肌动蛋白Ⅰ（ActinⅠ）、端粒结合蛋白（α-TBP）、DNA聚合酶α（DNA pol α）3个乱序基因的完整大核基因序列和完整/部分小核基因序列,并结合已有资料对比研究了尖毛虫属这3个乱序基因的进化。结果表明:（1）Oxytricha sp.（ZJ）与O.nova的小核Actin Ⅰ基因具有相同的乱序模式,区别于其余的尖毛虫属物种;在增加尖毛虫属物种的基础上,对前人推测提出了质疑,我们认为MDS-IES接合处移动现象在乱序MDSs之间并非比非乱序MDSs之间更保守。（2）Oxytricha sp.（ZJ）与O.nova的小核α-TBP基因具有相同乱序模式和相似长度的IESs。（3）Oxytricha sp.（ZJ）的小核DNA pol α基因乱序模式,区别于任一已报道物种,与属内O. trifallax最为相近。基于序列分析,在DNA pol α基因中发现了一例IES转换为MDS的痕迹,以及由此导致原先MDS的丢失。研究发现在编码区内IES向MDS的转变,使得本应删除的序列成为基因组永久保留的一部分。     

Destabilization of Yeast Micro- and Minisatellite DNA Sequences by Mutations Affecting a Nuclease Involved in Okazaki Fragment Processing (rad27) and DNA Polymerase δ (pol3-t)

We examined the effects of mutations in the Saccharomyces cerevisiae RAD27 (encoding a nuclease involved in the processing of Okazaki fragments) and POL3 (encoding DNA polymerase δ) genes on the stability of a minisatellite sequence (20-bp repeats) and microsatellites (1- to 8-bp repeat units). Both the rad27 and pol3-t mutations destabilized both classes of repeats, although the types of tract alterations observed in the two mutant strains were different. The tract alterations observed in rad27 strains were primarily additions, and those observed in pol3-t strains were primarily deletions. Measurements of the rates of repetitive tract alterations in strains with both rad27 and pol3-t indicated that the stimulation of microsatellite instability by rad27 was reduced by the effects of the pol3-t mutation. We also found that rad27 and pol3-01 (an allele carrying a mutation in the “proofreading” exonuclease domain of DNA polymerase δ) mutations were synthetically lethal.All eukaryotic genomes thus far examined contain many simple repetitive DNA sequences, tracts of DNA with one or a small number of bases repeated multiple times (48). These repetitive regions can be classified as microsatellites (small repeat units in tandem arrays 10 to 60 bp in length) and minisatellites (larger repeat units in tandem arrays several hundred base pairs to several kilobase pairs in length). In this paper, arrays with repeat units 14 bp or less will be considered microsatellites and arrays with longer repeat units will be considered minisatellites.Previous studies show that simple repetitive sequences are unstable relative to “normal” DNA sequences, frequently undergoing additions or deletions of repeat units, in Escherichia coli (24), Saccharomyces cerevisiae (12), and mammals (59). This mutability has two important consequences. First, it results in polymorphic loci that are useful in genetic mapping and forensic studies (15, 59). Second, although these repetitive tracts are usually located outside of coding sequences, alterations in the lengths of microsatellites or minisatellites located within coding sequences can produce frameshift mutations or novel protein variants (20, 22, 26).From studies of the effects of various mutations on microsatellite stability in yeast and E. coli (40) and the analysis of mutational changes caused by DNA polymerase in vitro (21), it is likely that most alterations reflect DNA polymerase slippage events (47). These events involve the transient dissociation of the primer and template strands during the replication of a microsatellite (Fig. ​(Fig.1).1). If the strands reassociate to yield an unpaired repeat on the primer strand, the net result is an addition of repeats (following a second round of DNA replication). Unpaired repeats on the template strand would result in a deletion by the same mechanism. Open in a separate windowFIG. 1“Classical” model for the generation of microsatellite alterations by DNA polymerase slippage. Two single strands of a replicating DNA molecule are shown, with each repeat unit indicated by a rectangle. Arrows indicate the 3′ ends of the strand, and the top and bottom strands represent the elongating primer strand and the template strand, respectively. Step 1, the primer and template strand dissociate; step 2, the primer and template strands reassociate in a misaligned configuration, resulting in an unpaired repeat on either the template strand (left side) or primer strand (right side); step 3, DNA synthesis is completed. If the unpaired repeats are not excised by the DNA mismatch repair system, after the next round of DNA synthesis one DNA molecule will be shortened by one repeat (left side) or lengthened by one repeat (right side).A number of mutations have been shown to elevate microsatellite instability. In E. coli (24, 46), yeast (44, 45), and mammalian cells (27), mutations in genes affecting DNA mismatch repair dramatically elevate the instability of a dinucleotide microsatellite. The most likely explanation of this result is that the DNA mismatches (unpaired repeats) resulting from DNA polymerase slippage events are efficiently removed from the newly synthesized strand by the DNA mismatch repair system. Thus, in the absence of mismatch repair, tract instability is elevated. From genetic studies, it has been found that mismatch repair in yeast efficiently corrects DNA mismatches involving 1- to 14-base loops (the size of the repeat units in microsatellites) but fails to correct mismatches involving loops larger than 16 bases (the size of the repeat units in minisatellites) (3, 41, 53). An inefficient mechanism, not involving the classical DNA mismatch repair system, is capable of correcting large DNA loops formed during meiotic recombination (19).In addition to mutations affecting DNA mismatch repair, some mutations affecting DNA replication in yeast destabilize microsatellites. Yeast strains bearing a null mutation in the RAD27 (RTH1) gene have high levels of instability of the dinucleotide poly(GT) and the trinucleotide CAG, specifically elevating single-repeat insertions (18, 39). RAD27 encodes the homolog of the mammalian FEN-1 protein, a 5′-to-3′ exonuclease (10, 11, 33). This nuclease activity is required for removing the terminal ribonucleotide residue from the 5′ end of the Okazaki fragment (9, 14, 35, 54, 55, 57); this step is necessary for the two adjoining fragments to be ligated together. FEN-1 appears to be active as either an exonuclease in the presence of a single-stranded gap upstream of the 5′ terminus or an endonuclease on a 5′ flap structure (13, 34). Since yeast strains that contain a null mutation in RAD27 grow poorly but are viable (38, 43), it is likely that less efficient nuclease activities that are also capable of 5′ Okazaki fragment processing are present in yeast. In addition to destabilizing dinucleotide microsatellites, rad27 strains have high levels of spontaneous mitotic recombination, elevated rates of forward mutation, and increased sensitivity to the alkylating agent methyl methanesulfonate (MMS) (18, 38, 43). In contrast to the mutations normally seen in mismatch repair mutants, i.e., point mutations or small frameshifts, the types of mutations observed in the absence of Rad27p are duplications of sequences flanked by short direct repeats (4 to 7 bp in length) (49). These duplications were not affected by the DNA mismatch repair system.The same class of sequences that are duplicated in the rad27 strains show an elevated rate (up to 1,000-fold) of deletion in strains containing a temperature-sensitive allele (pol3-t) of the yeast gene encoding DNA polymerase δ (52, 53). This mutant (initially named tex1) was isolated in a strain that exhibited an increased excision rate of a bacterial transposon with long terminal repeats inserted within a yeast gene (7). The pol3-t allele, which encodes a mutation (Gly₆₄₁ to Ala₆₄₁) (51) located near the putative nucleotide binding and active-site domains of the enzyme (58), is thought to diminish the rate of lagging-strand synthesis resulting in long stretches of single-stranded DNA on the lagging-strand template (8). This single-stranded DNA may have the potential to form intrastrand base-paired structures, creating interactions between short direct repeats. These interactions would result in an increased frequency of deletions caused by DNA polymerase slippage.Since rad27 and pol3-t mutations elevate the rates of duplications and deletions associated with short separated repeats in nonrepetitive DNA sequences, Kunkel et al. (22) suggested that these mutations could also destabilize minisatellites. In this paper, we examine the effects of rad27 and pol3-t mutations on the stability of simple repeats in which the repeat unit length varies between 1 and 20 bp. Our results show that both mutations destabilize both microsatellites and minisatellites, but that the mechanisms involved in the destabilization are different for the two mutations.     

A comparative analysis of karyotypes of three species of Macleaya—producers of a complex of isoquinoline alkaloids

Using a set of methods (C-banding, DAPI-staining, fluorescence hybridization in situ (FISH) with probes of 26S and 5S rDNA, and analysis of meiosis), the first comparative cytogenetic study of three species of Macleaya, producers of complex isoquinoline alkaloids, cordate Macleaya cordata (Willd.) R. Br. (2n = 20), small-fruited Macleaya microcarpa (Maxim.) Fedde (2n = 20) and Macleaya kewensis Turrill (2n = 20), was first carried out. On the basis of morphometric analysis, formulas of karyotypes were made for each species. Species ideograms for M. cordata, M. microcarpa, and M. kewensis were constructed taking into account the polymorphic variants of the C-banding patterns and indicating the location of 26S and 5S rDNA sites. A comparative study revealed that the karyotypes of M. microcarpa and M. kewensis have more in common with each other than with M. cordata. Analysis of meiotic chromosomes suggests of genetic stability of Macleaya genomes. The results of chromosome analysis were used to confirm the close relationship of Macleaya and to clarify their phylogenetic relationships.     

Selection of optimal variants of Gō-like models of proteins through studies of stretching

The Gō-like models of proteins are constructed based on the knowledge of the native conformation. However, there are many possible choices of a Hamiltonian for which the ground state coincides with the native state. Here, we propose to use experimental data on protein stretching to determine what choices are most adequate physically. This criterion is motivated by the fact that stretching processes usually start with the native structure, in the vicinity of which the Gō-like models should work the best. Our selection procedure is applied to 62 different versions of the Gō model and is based on 28 proteins. We consider different potentials, contact maps, local stiffness energies, and energy scales—uniform and nonuniform. In the latter case, the strength of the nonuniformity was governed either by specificity or by properties related to positioning of the side groups. Among them is the simplest variant: uniform couplings with no i, i + 2 contacts. This choice also leads to good folding properties in most cases. We elucidate relationship between the local stiffness described by a potential which involves local chirality and the one which involves dihedral and bond angles. The latter stiffness improves folding but there is little difference between them when it comes to stretching.     

Effect of γ-Irradiation on Development of Lachrymator of Onion

A thermosensitive uracil requiring mutant of Bacillus subtilis Marburg 168 thy trp₂ ts42 was examined as to the colony forming ability at the permissive and nonpermissive temperatures. The viability of the mutant cells decreased rapidly at the restrictive temperature in the modified Woese’s (MW) medium. However, the cells retained viability when sodium succinate or potassium chloride was added to the medium at that temperature although uracil deficiency was unchanged. A little but significant incorporation of adenine-8-¹⁴C into RNA still continued even after the incorporation of N-acetyl-³H-d-glucosamine into acid insoluble fraction of the cells terminated in the MW medium at 48°C. Both incorporations as well as increase of absorbance were slowed down in the presence of sodium succinate at 48°C. This mutant, ts42, was more sensitive to deoxycholate (DOC) than the parent strain. The restoration of colony forming ability after the temperature shift back from 48 to 37°C was suppressed by the addition of DOC to the medium. However, the cell became resistant to DOC when uracil was added to the medium prior to the temperature shift.