水稻黄单胞菌hrp基因簇中致病相关基因hpaB的鉴定

由水稻黄单胞菌引起的水稻白叶枯病是水稻最严重的细菌性病害。通过筛选18000个XooTn5转座子插入突变体,得到其中一个致病力缺失的突变体XOG11。TAIL-PCR方法分离该突变体中插入转座子的侧翼序列,发现转座子插入到位于hrp基因簇的hpaB基因中。对该基因进一步的分析表明该基因编码一个含有156个氨基酸,等电点为4.28,亮氨酸含量为14.4%的蛋白HpaB。Southern blot和PCR验证表明Tn5在该突变体中为单拷贝插入且未发生转座子携带侧翼序列的转移。将hpaB克隆到具有广泛寄主的质粒pHM1中,转化重组质粒进入突变体后,突变体恢复了在其寄主水稻IR24上的致病力,而转化空质粒pHM1后的突变体仍然表现为致病力缺失。证实了水稻黄单胞菌中hpaB基因与该细菌的致病力相关,在侵染水稻的过程中起着不可缺失的作用。     

野油菜黄单胞菌野油菜致病变种8004菌株wxcA基因与EPS的产量有关

在以前的工作中,采用转座子Tn5 gusA5对野油菜黄单胞菌野油菜致病变种(Xcc)8004菌株进行诱变,获得一批胞外多糖(EPS)合成减少的突变体,对这些突变体的Tn5 gusA5的插入位点进行分析后,发现有两株突变体是wxcA基因不同插入位点的突变体。以前认为wxcA基因与脂多糖(LPS)的O-抗原合成有关而与EPS的合成无关。为明确wxc4基因的功能,对8004菌株的wxcA基因进行缺失,获得的△wxcA突变体的EPS产量与野生型菌株相比,减少了50％,并且一段PCR合成的包含wxcA基因的DNA片段能反式互补△wxcA突变体,恢复突变体的EPS产量。这证实了8004菌株的wxcA基因与EPS的合成产量有关。     

水稻白叶枯病菌pxo_04104基因功能的初步分析

水稻白叶枯病菌(Xanthomonas oryzae pv.oryzae,Xoo)是一种重要的植物病原细菌,可以引起水稻白叶枯病,使水稻减产。本研究通过对Xoo K74 Tn5插入突变体库进行致病力检测、质粒拯救定位发现pxo_04104基因与Xoo致病相关,pxo_04104基因编码periplasmic beta-glucosidase(周质β-葡萄糖苷酶)。该基因的缺失突变体及其互补菌株生理生化表型检测显示缺失突变体致病力、抗渗透压能力显著下降,其互补菌株致病力可恢复到野生型水平的84.2%,抗渗透压能力也可恢复。本研究为深入研究pxo_04104基因致病分子机理提供了线索。     

TAIL-PCR方法快速分离Xcc致病相关基因序列

以mini-Tn5 gfp-km转座子中nptⅡ片段作为探针,对已获得的五株野油菜黄单胞菌野油菜黑腐病致病型（Xcc)非致病突变体进行了Southern blot分析,结果表明,这五株突变体确由mini-Tn5 gfp-km转座子插入致病相关基因所致,且为单拷贝不同位点的插入。提取这五株突变体总DNA作为模板,采用改进的热不对称交错PCR（TAIL－PCR）方法从其中克隆到了各自转座子插入区侧翼序列,对这些侧翼序列进行了序列测定并将分析结果与GenBank database及Xcc全基因组序列做了比较,结果表明,五个侧翼序列所在的基因确与Xcc致病性有关。这种改进后的TAIL－PCR方法为突变体特别是转座子插入突变体中目的基因的克隆提供了一种简要高效的新方法。     

水稻条斑病菌胞外多糖相关基因的鉴定

摘要:【目的】前期研究中从Tn5 转座子插入的水稻条斑病菌突变体库中获得了17 个胞外多糖改变的突变体。【方法】本文对这些突变体的Tn5 插入位点和基因类型进行了鉴定。【结果】结果显示,胞外多糖减少的11 个突变体中多数为Tn5 插入在已知的gum、xan 和wxoc 基因簇上,Xoryp_4217、Xoryp_2488 和Xoryp_0918为未知的与胞外多糖产生有关的基因,属首次报道;6 个胞外多糖增多的突变体中,fimO、pilY 和xopQ 与胞外多糖产生有关,但在水稻条斑病菌中未见报道;Xoryp2392、Xoryp_4221 和Xoryp_3511 为首次鉴定,其中Xoryp_3511 仅在水稻黄单胞菌中存在。毒性测定结果显示,胞外多糖减少的突变体在水稻上的毒性变弱,而胞外多糖增加的突变体在水稻上的毒性没有显著变化。【结论】这些结果为进一步分析水稻条斑病菌胞外多糖代谢途径以及与水稻的互作关系奠定了基础。     

柑橘溃疡病菌II型分泌通道基因xpsD突变体的鉴定及功能分析

【目的】鉴定柑橘溃疡病菌胞外水解酶减弱突变体Mxac56-20的Tn5插入位点,及其在柑橘上的致病力。【方法】采用质粒拯救方法获得Tn5旁侧序列,与基因组信息比对后明确突变体的插入位点;构建功能互补载体对突变体进行功能互补,检测互补菌株胞外蛋白水解酶、纤维素酶和淀粉酶的恢复情况;在寄主植物柑橘上观察致病力变化。【结果】Mxac56-20的Tn5插入位点是II型分泌系统xpsD基因,所构建的互补载体使突变体的胞外水解酶活性和致病力得到恢复。【结论】柑橘溃疡病菌xpsD基因的突变,导致胞外水解酶活性降低,在寄主上的致病力减弱,说明柑橘溃疡病菌的II型分泌系统在与寄主互作过程中起到致病因子的作用。     

野油菜黄单胞菌野油菜致病变种8004菌株wxcA基因与EPS的产量有关

在以前的工作中,采用转座子Tn5gusA5对野油菜黄单胞菌野油菜致病变种(Xcc) 8004菌株进行诱变,获得一批胞外多糖(EPS)合成减少的突变体,对这些突变体的Tn5gusA5的插入位点进行分析后,发现有两株突变体是wxcA基因不同插入位点的突变体。以前认为wxcA基因与脂多糖(LPS)的O抗原合成有关而与EPS的合成无关。为明确wxcA基因的功能,对8004菌株的wxcA基因进行缺失,获得的ΔwxcA突变体的EPS产量与野生型菌株相比,减少了50%,并且一段PCR合成的包含wxcA基因的DNA片段能反式互补ΔwxcA突变体,恢复突变体的EPS产量。这证实了8004菌株的wxcA基因与EPS的合成产量有关。     

TAIL-PCR方法快速分离Xcc致病相关基因序列

以miniTn5gfp-km转座子中nptII片段作为探针,对已获得的五株野油菜黄单胞菌野油菜黑腐病致病型（Xcc）非致病突变体进行了Southern blot分析,结果表明,这五株突变体确由mini-Tn5gfp-km转座子插入致病相关基因所致,且为单拷贝不同位点的插入。提取这五株突变体总DNA作为模板,采用改进的热不对称交错PCR （TAIL-PCR）方法从其中克隆到了各自转座子插入区侧翼序列,对这些侧翼序列进行了序列测定并将分析结果与GenBank database及Xcc全基因组序列做了比较,结果表明,五个侧翼序列所在的基因确与Xcc致病性有关。这种改进后的TAIL-PCR方法为突变体特别是转座子插入突变体中目的基因的克隆提供了一种简便高效的新方法。     

野油菜黄单胞菌野油菜致病变种中一个与EPS合成有关的新基因的鉴定

用转座子Tn5gusA5对野油菜黄单胞菌野油菜致病变种(Xanthomonas campestris pv.campestris,简称Xcc)野生型菌株8004进行诱变,分离到一批胞外多糖(EPS)合成减少的突变体。采用TAIL-PCR(thermal asymmetric interlaced PCR)分析突变体的Tn5gusA5插入位点,发现其中一株编号为151D09的突变体的插入位点位于Xcc 8004菌株的基因组编号为XC3695的ORF内,该ORF功能尚未见报道。序列分析表明,该ORF演绎的编码产物与Serratia marcescens的kdtX基因和Klebsiella pneumoniae的waaE基因演绎的编码产物分别具有52%和50%的相似性,并具有第2家族糖基转移酶的功能域, 因此暂将该ORF命名为waxE基因。用同源双交换方法构建了waxE基因的缺失突变体,并采用PCR和Southern杂交的方法对突变体进行了验证。waxE基因缺失突变体在营养丰富培养基的生长繁殖不受影响,但其EPS产量与野生型菌株8004相比,降低35%左右,并且一段PCR合成的包含waxE基因的DNA片段能反式互补waxE基因缺失突变体,恢复缺失突变体的EPS产量,表明Xcc waxE基因与EPS的生物合成有关。     

十字花科黑腐病菌中影响致病相关基因XC3814表达的基因鉴定

十字花科黑腐病菌8004菌株的XC3814基因与致病性和胞外多糖合成有关。文章将XC3814的启动子与报告基因sacB融合, 构建了XC3814的表达报告质粒pL3814sac。将该质粒导入野生型菌株8004, 获得了报告菌株8004/pL3814sac。利用转座子EZ::Tn5对报告菌株的基因组进行随机诱变, 分离到3株耐蔗糖的突变体。分析发现其中的1株突变体是由EZ::Tn5插入到编号为XC3882的未知功能的基因所产生的。将由XC3814启动子与报告基因gusA融合得到的报告质粒pGUS3814分别导入8004菌株和XC3882的转座子Tn5gusA5插入突变体, 测定比较pGUS3814的GUS表达水平, 结果显示在XC3882突变体背景下GUS的表达水平比在野生型背景下降低81.3%, 表明XC3814基因的表达水平受XC3882基因的影响。     

Pathotypic variation of Xanthomonas oryzae pv. oryzae in Bangladesh

Bacterial Blight (BB) caused by Xanthomonas oryzae pv. oryzae (Xoo), a destructive disease of rice. Altogether, 96 isolates of Xoo were collected from 19 rice growing districts of Bangladesh in irrigated and rainfed seasons during 2014 to assess pathotypic variation. Pathotypic analyses on a set of 12 Near Isogenic Lines (NILs) of rice containing resistance genes viz. Xa1, Xa2, Xa3, Xa4, Xa5, Xa7, Xa8, Xa10, Xa11, Xa13, Xa14 and Xa21 and two check varieties IR24 and TN1 by leaf clip-inoculation technique. A total of 24 pathotypes were identified based on their virulence patterns on NILs tested. Among these, pathotypes VII, XII, and XIV considered as major, containing maximum number of isolates, (9.38% each) frequently distributed in North to Mid-Eastern districts of Bangladesh. Most virulent pathotype I recorded from Habiganj and Brahmanbaria. This pathotypic variation explained the pathogenic relatedness of X. oryzae pv. oryzae populations from diverse geographic areas in Bangladesh.     

Involvement of Gluconeogenic Pathway in Virulence of Xanthomonas oryzae pv. oryzae

Xanthomonas oryzae pv. oryzae causes bacterial leaf blight, one of the most widespread and destructive bacterial diseases of rice. A phosphoenolpyruvate synthase (ppsA)‐disrupted mutant OSPAM was generated by homologous suicide plasmid integration. The mutant was unable to grow in medium with pyruvate or C₄‐dicarboxylates as the sole carbon source, compared with the wild‐type, indicating a disruption in ppsA function. The mutant showed a reduction in virulence on rice but still induced a hypersensitive response in tobacco. When the mutant was complemented, the response was recovered to wild‐type. These results suggested that X. oryzae pv. oryzae possesses only PPSA route in gluconeogenesis, which is necessary for virulence.     

Status of Streptomycin Resistance Development in Xanthomonas oryzae pv. oryzae and Xanthomonas oryzae pv. oryzicola in China and their Resistance Characters

Rice leaves with bacterial blight or bacterial leaf streak symptoms were collected in southern China in 2007 and 2008. Five hundred and thirty‐four single‐colony isolates of Xanthomonas oryzae pv. oryzae and 827 single‐colony isolates of Xanthomonas oryzae pv. oryzicola were obtained and tested on plates for sensitivity to streptomycin. Four strains (0.75%) of X. oryzae pv. oryzae isolated from the same county of Province Yunnan were resistant to streptomycin, and the resistance factor (the ratio of the mean median effective concentration inhibiting growth of resistant isolates to that of sensitive isolates) was approximately 226. The resistant isolate also showed streptomycin resistance in vivo. In addition to resistant isolates, isolates of less sensitivity were also present in the population of X. oryzae pv. oryzae from Province Yunnan. However, no isolates with decreased streptomycin‐sensitivity were obtained from the population of X. oryzae pv. oryzicola. Mutations in the rpsL (encoding S12 protein) and rrs genes (encoding 16S rRNA) and the presence of the strA gene accounting for streptomycin resistance in other phytopathogens or animal and human pathogenic bacteria were examined on sensitive and resistant strains of X. oryzae pv. oryzae by polymerase chain reaction amplification and sequencing. Neither the presence of the strA gene nor mutations in the rpsL or rrs were found, suggesting that different resistance mechanisms are involved in the resistant isolates of X. oryzae pv. oryzae.     

Rapid inhibition of protein histidine phosphorylation by UV-irradiation in Xanthomonas oryzae pv. oryzae

Abstract Exposure of Xanthomonas oryzae pv. oryzae cells to 254 nm UV radiation resulted in an alteration of protein phosphorylation. Labelling of the phosphohistidine-containing proteins with molecular masses of 81 and 32 kDa, named p81 and p32, was rapidly reduced following UV irradiation in the early exponential cells, but the decrease was not detected in mid-exponential cells. Mitomycin C, a DNA replication inhibitor, and rifampicin, a drug generally used to inhibit RNA synthesis and DNA replication, were also found to reduce the histidyl phosphorylation. However, this alteration of protein phosphorylation was not hindered by chloramphenicol treatment. A possible role for these histidyl phosphopfoteins in sensing UV light is proposed.     

水稻白叶枯病菌的母株与单细胞系的遗传与致病性差异的分析

由水稻白叶枯病菌(Xanthomonas oryxae pv.oryxae)引发的稻白叶枯病是水稻生产上的重要病害.水稻白叶枯菌自然群体是由包括基本无毒性的弱毒菌在内的不同致病型组成的混合群体,代表自然群体的原始菌株的致病力与其毒力结构紧密相关.     

OsSERK1 regulates rice development but not immunity to Xanthomonas oryzae pv. oryzae or Magnaporthe oryzae

Somatic embryogenesis receptor kinase (SERK) proteins play pivotal roles in regulation of plant development and immunity. The rice genome contains two SERK genes, OsSerk1 and OsSerk2. We previously demonstrated that OsSerk2 is required for rice Xa21-mediated resistance to Xanthomonas oryzae pv. oryzae (Xoo) and for normal development. Here we report the molecular characterization of OsSerk1. Overexpression of OsSerk1 results in a semi-dwarf phenotype whereas silencing of OsSerk1 results in a reduced angle of the lamina joint. OsSerk1 is not required for rice resistance to Xoo or Magnaporthe oryzae. Overexpression of OsSerk1 in OsSerk2-silenced lines complements phenotypes associated with brassinosteroid (BR) signaling defects, but not the disease resistance phenotype mediated by Xa21. In yeast, OsSERK1 interacts with itself forming homodimers, and also interacts with the kinase domains of OsSERK2 and BRI1, respectively. OsSERK1 is a functional protein kinase capable of auto-phosphorylation in vitro. We conclude that, whereas OsSERK2 regulates both rice development and immunity, OsSERK1 functions in rice development but not immunity to Xoo and M. oryzae.     

Identification of a H+/glucose and galactose symporter gene glt from Xanthomonas oryzae pv. oryzae

We identified a glucose and galactose transporter gene from the plant-pathogenic bacterium Xanthomonas oryzae pv. oryzae. Sequence analysis indicated that the gene, named glt, encoded a polypeptide of 592 amino acid residues and the product was significantly homologous with members of the Na+/glucose cotransporter (SGLT) family from mammalian and bacterial origin, especially with vSGLT from Vibrio parahaemolyticus (50% identity). GLT functioned as a glucose and galactose transporter in an Escherichia coli mutant deficient in glucose and galactose transport activity. A protonophore inhibited the transport activity, suggesting that GLT is a H+-coupled glucose/galactose symporter.