Real-time RT-qPCR assay to detect sequences in the Piscine orthoreovirus-1 genome segment S1 associated with heart and skeletal muscle inflammation in Atlantic salmon

During the last decade, Piscine orthoreovirus was identified as the main causative agent of heart and skeletal muscle inflammation (HSMI) in Atlantic Salmon, Norway. A recent study showed that PRV-1 sequences from salmonid collected in North Atlantic Pacific Coast (NAPC) grouped separately from the Norwegian sequences found in Atlantic Salmon diagnosed with HSMI. Currently, the routine assay used to screen for PRV-1 in NAPC water and worldwide cannot differentiate between the two groups of PRV-1. Therefore, this study aimed at developing a real-time polymerase chain reaction (RT-qPCR) assay to target the PRV-1 genome segments specific for variants associated with HSMI. The assay was optimized and tested against 71 tissue samples collected from different regions including Norway, Chile and both coast of Canada and different hosts farmed Atlantic Salmon, wild Coho Salmon and escaped Atlantic Salmon collected in British Columbia, West Coast of Canada. This assay has the potential to be used for screening salmonids and non-salmonids that may carry PRV-1 potentially causing HSMI.     

不同地区楼葱栽培种的性状与品质分析

为了研究不同地区楼葱的特性,试验对我国不同地区12个楼葱栽培种的数量性状和品质性状进行了测定分析。14个数量性状的相关分析结果显示,主成分分析数量指标后,单株质量、株高、假茎质量、花葶高、叶形指数和假茎指数影响分类;相关性分析说明主要数量指标间具有极显著相关性(P<0.01)。聚类分析后,遗传距离为3.1时可将楼葱种质根据所得主要数量性状分为4个类群。测定不同地区楼葱6个品质指标后,相关性分析结果表明,紧实度与蛋白质含量、干物质率、香辛油含量、总糖含量、游离氨基酸总量存在着极显著正相关或相关性,主成分分析表明主成分反映了89.99%的原有信息量,楼葱的干物质率与紧实度为主要成分;应用灰色关联度分析了品质与数量性状的关系,假茎直径、出叶孔间距、单株质量这3个数量性状对楼葱品质的影响居前3位。研究表明楼葱种质材料具有极其丰富的遗传多样性,宁夏同心2个地区黄水桥HSQ、石羊圈SYJ的楼葱种质距其他种质资源间亲缘关系最远且干物质率含量及紧实度最高。     

柑橘脉突病毒基因组全长cDNA克隆及其侵染性鉴定

【目的】构建柑橘脉突病毒（citrus vein enation virus,CVEV）侵染性克隆,为从分子水平解析其致病机理打下基础。【方法】利用SMARTer^? RACE(rapid amplification of cDNA ends)试剂盒对CVEV的5′序列进行RACE,并依据序列分析结果及CVEV分离株VE-1保守序列,设计CVEV基因组全长cDNA扩增引物。以CVEV毒源植株的总RNA为模板,通过EV25-F/EV5983-R引物扩增CVEV基因组全长cDNA。利用In-Fusion重组连接线性化pXT1和CVEV全长cDNA。通过菌液PCR及测序分析鉴定CVEV基因组全长cDNA克隆。通过农杆菌介导的真空浸润接种摩洛哥酸橙（Citrus aurantium）、邓肯葡萄柚（C. paradisi）、尤力克柠檬（C.limon）、枳柚（C. paradisi×Poncirus trifoliata)、Rusk枳橙（P. trifoliata×C. sinensis）、枣阳小叶枳(P. trifoliata),进一步通过RT-PCR检测、症状观察鉴定所构建CVEV全长cDNA克隆的侵染性。【结果】建立了CVEV的基因组全长RT-PCR扩增体系,获得基于双元载体pXT1的CVEV基因组全长cDNA克隆10个。随机选取的6个全长cDNA克隆CVEV1901—CVEV1906的序列一致性为99.35%。其中,CVEV1901基因组全长5 983 nt,由5个开放阅读框、5′端207 nt和3′端198 nt的两个非翻译区、以及ORF2和ORF3之间122 nt的基因间隔区组成。序列分析结果显示,CVEV1901与浙江分离株XZG及四川SM分离株的序列一致性分别为99.98%和99.11%;与西班牙VE-1分离株、美国加州VE701分离株和日本IBK分离株基因组序列一致性在96.89%—98.61%;与同属中豌豆耳突花叶病毒（pea enation mosaic virus）和紫花苜蓿耳突病毒（alfalfa enamovirus）的序列一致性约90%。通过农杆菌介导的真空浸润将CVEV1901接种至6个不同的柑橘品种,接种后120 d的RT-PCR检测结果表明摩洛哥酸橙、邓肯葡萄柚、尤力克柠檬、枳柚、Rusk枳橙和枣阳小叶枳阳性植株/接种植株（阳性率）分别为16/17（94.12%）、12/14（85.71%）、16/21（76.19%）、15/19（78.95%）、13/14（92.86%）和0/18（0）。其中,部分摩洛哥酸橙出现典型CVEV侵染症状,叶片侧脉和支脉产生耳状小突起,叶背有相应的凹陷;部分邓肯葡萄柚和尤力克柠檬出现叶片皱缩现象。【结论】建立了CVEV的基因组全长RT-PCR扩增体系,获得了CVEV基因组全长cDNA侵染性克隆,通过农杆菌介导的真空浸润接种可引起摩洛哥酸橙、邓肯葡萄柚和尤力克柠檬的CVEV侵染症状。     

四川地区猕猴桃病毒1的RT-PCR检测及外壳蛋白基因序列分析

为了明确近期新西兰报道的侵染猕猴桃的新病毒——猕猴桃病毒1（Actinidia virus 1，AcV-1）在四川地区猕猴桃上的发生情况及其分子特性，采用RT-PCR对来自四川6个地区疑似感染病毒的90份猕猴桃主栽品种‘红阳’和‘金果’的叶片样品进行检测。结果表明，22份样品为AcV-1阳性，检出率为24.4%。将获得的5个AcV-1分离物和已报道的新西兰分离物K75的外壳蛋白（coat protein，CP）基因序列进行比对，结果表明，分离物间核苷酸序列和氨基酸序列的相似性分别为84.8% ~ 97.1%和89.7% ~ 99.6%，其中除邛崃分离物HYH5与新西兰分离物K75的核苷酸序列相似性较高（97.1%）外，其余4个分离物均低于91%。系统进化分析结果显示，这些分离物主要聚集在3个分支上，分离物HYH5与新西兰分离物K75位于同一分支，其余分离物位于另外2个分支。     

苹果花脸病田间病情发展及ASSVd在组培条件下的传播

为了明确苹果锈果类病毒（apple scar skin viroid，ASSVd）引起的苹果花脸病在田间的病情发展情况以及ASSVd在组培条件下的传播方式，2012—2015年对河北省顺平南神南村3个果园进行持续调查和检测。结果显示，果园A、B、C的显症率分别从3.00%、19.35%和10.00%上升至10.00%、34.41%和22.00%，带毒率分别从11.00%、20.43%和14.00%上升至23.00%、37.63%和30.00%，带毒率和显症率都逐年增加，而且带毒率大于显症率，即有些带毒果树不显症。发病果树田间分布有明显的发病中心。通过高通量测序发现显症果树ASSVd vsiRNA reads数是带毒未显症reads数的4.08倍，同时实时荧光定量PCR检测发现显症树ASSVd病毒积累量显著高于带毒未显症树。以携带ASSVd的组培苗和无毒组培苗为试材，利用RT-PCR检测明确了ASSVd可通过伤口沾染带毒汁液、组培剪污染、含毒培养基、根系接触进行传播，其中根系接触传染率较高。     

金花茶组叶片生化成分评价及其最佳采收期研究

本研究以26份来源于6种金花茶组植物、不同表型防城金花茶和不同月份采收的防城金花茶的成熟叶片为材料,建立同时测定芦丁、槲皮素、木犀草素、山奈酚4种黄酮成分的HPLC法,以及优化了测定茶多酚、总黄酮、总多糖和总皂苷成分含量的紫外分光光度法,基于以上8种成分含量,结合主成分综合评分和聚类分析的化学计量学方法,对不同来源金花茶叶片生化成分进行综合评价。结果表明：8种成分含量在不同来源金花茶叶片中存在差异,其中无名金花茶8种成分含量均较高,四季金花茶、防城金花茶次之;8年生1—12月份采收的防城金花茶叶片中,总皂苷、总黄酮和总多糖含量均表现为升-降-升-降的变化规律,并在10月含量达到最高;5年生不同种（S1~S14）主成分综合评分顺序为：无名金花茶>四季金花茶>防城金花茶（花蕾大、花多、不抗寒、花黄且大、尖果）>显脉金花茶>凹脉金花茶>小果金花茶;8年生不同月份（S15~S26）主成分综合评分顺序为：10月采>2月采>3月采>4月采>5月采>7月采>6月采>1月采>8月采>12月采>11月采>9月采,其中无名金花茶、四季金花茶及防城金花茶中花蕾大、花多、花黄且大等表型的金花茶叶片与2—4月份和10月份采集的8年生金花茶叶片的多指标综合评分排序位列前10;聚类分析结果将供试26份样品分为5类。综上所述,金花茶叶片的生化成分与金花茶植物种类和采收期有关,无名金花茶、四季金花茶和防城金花茶中花蕾大、花多、不抗寒、花黄且大的表现型的综合生化成分较高,初步确定防城金花茶叶片的适宜采收期为2—4月份和10月份,所建立的多指标定量结合化学计量学分析方法为金花茶组植物叶片的生化成分评价提供依据。     

红肉蜜柚 PDR 型转运蛋白基因的发掘及 CmPDR11-2 表达与耐草甘膦初步分析

基于红肉蜜柚 RNA-seq 数据库，筛选出 50 个 ABC 转运蛋白家族基因，其中包含 11 条 PDR 型基因。对11 条柚 PDR 基因进行命名和生物信息学分析。同源性分析结果表明：CmPDR11-2 编码的氨基酸序列与拟南芥中转运百草枯除草剂的 AtPDR11 基因同源性最高，达 69.25%，利用 RT-PCR 技术克隆得到 CmPDR11-2 的 ORF 序列。该序列长度为 4 371 bp，编码一个含有 1 456 个氨基酸的蛋白质，分子量 165.138 03 ku，该蛋白属于稳定的亲水性蛋白，无信号肽，具有 12 个跨膜结构，定位于细胞膜。实时荧光定量 PCR 结果表明，草甘膦除草剂胁迫处理条件下，1~15 d 处理组柚叶的 CmPDR11-2 基因相对表达量呈整体上升趋势，且均高于对照组，反应迅速且持久，这表明 CmPDR11-2 基因表达与红肉蜜柚耐草甘膦有关。     

Comparative proteomics analysis of maize (Zea mays) leaves infected by small brown planthopper (Laodelphax striatellus)

Maize rough dwarf disease (MRDD) is a viral disease caused by brown planthopper infestation, and leads to great yield loss, especially in China. Comparative proteomics was performed using maize inbred line Zheng 58 and LN 287. MRDD pathogen was detected as rice black-streaked dwarf virus (RBSDV) by quantitative real time PCR (qRT-PCR) in Shandong Province, China. The modified trichloroacetic acid (TCA)/acetone method was used for soluble protein extraction from leaves. Two-dimensional electrophoresis (2-DE) analysis was performed on 24-cm long, pH 4–7 linear immobilized pH gradient (IPG) strips, and gels were stained with silver and coomassie brilliant blue. We identified 944 proteins expressed in RBSDV infected maize leaves by proteomics approaches. Among these, 44 protein spots that revealed a 1.5-fold difference in intensity were identified by mass spectrometry between mock-inoculated and RBSDV infected samples. Among these, 17 and 26 spots were up-regulated, and 27 and 18 spots were down-regulated in the virus infected samples of Zheng 58 and LN 287, respectively. Differential protein spots were analyzed by mass spectrometry identification, which could be divided into six categories. Furthermore, the expression of stress-related proteins was detected and confirmed by qRT-PCR. This study lays the foundation for further investigations, enabling the enhancement of MRDD resistance in maize.     

苏粳815机插高产形成特点及其配套精确定量栽培技术

通过综合高产试验和机插行株距规格与氮肥组合试验,分析了苏粳815高产形成的特点,明确了其高产产量结构及其形成的主要生育指标,提出了目标产量650~700 kg/667 m~2相配套的精确定量栽培技术。     

Genomewide association analysis of salt tolerance in soybean [Glycine max (L.) Merr.]

Salinity is a common abiotic stress causing soybean [Glycine max (L.) Merr.] yield loss worldwide. The use of tolerant cultivars is an effective and economic approach to coping with this stress. Towards this, research is needed to identify salt‐tolerant germplasm and better understand the genetic and molecular basis of salt tolerance in soybean. The objectives of this study were to identify salt‐tolerant genotypes, to search for single‐nucleotide polymorphisms (SNPs) and QTLs associated with salt tolerance. A total of 192 diverse soybean lines and cultivars were screened for salt tolerance in the glasshouse based on visual leaf scorch scores after 15–18 days of 120 mM NaCl stress. These genotypes were further genotyped using the SoySNP50K iSelect BeadChip. Genomewide association mapping showed that 62 SNP markers representing six genomic regions on chromosomes (Chr.) 2, 3, 5, 6, 8 and 18, respectively, were significantly associated with salt tolerance (p < 0.001). A total of 52 SNP markers on Chr. 3 are mapped at or near the major salt tolerance QTL previously identified in S‐100 (Lee et al., 2014). Three SNPs on Chr. 18 map near the salt tolerance QTL previously identified in Nannong1138‐2 (Chen, Cui, Fu, Gai, & Yu, 2008). The other significant SNPs represent four putative minor QTLs for salt tolerance, newly identified in this study. The results above lay the foundation for fine mapping, cloning and molecular breeding for soybean salt tolerance.