我国部分地区猪繁殖与呼吸综合征病毒分离株ORF5基因的遗传变异分析

参考Genbank发表的猪繁殖与呼吸综合征病毒（PKRSV）ATCC VR-2332的ORF5基因序列，设计并合成了一对引物．对来自福建、浙江、山东等地的PRRSV分离毒株进行RT-PCR扩增．获得约748bp的DNA片断，将其分别克隆入pMD18-T载体中，并进行测序。应用DNAStar软件分析所测序列，并与ATCCVR-2332、CH-1a、MLV、Lv等毒株的ORF5序列进行比较，结果表明：SHDl与F114、MLV、ATCCVR-2332同源性高达98．5％，与CH-1a同源性为91．0％，与其它毒株同源性为86．6％~88．4％；F114与MLV、ATCCVR-2332同源性为99．3％～99．7％．其余分离毒株在遗传关系上和CH-1a又分为明显的两个群．显示近年来各地PRRSV分离毒株与cH-1a株的遗传差异越来越大。     

抗鸡传染性腺胃炎酶标抗体的制备和应用

在前期从患病鸡腺胃内分离到呼肠孤病毒的基础上，以该病毒为免疫原对兔进行免疫制备高免血清，分离纯化IgG，进行辣根过氧化物酶（HRP）标记，并用ELISA双抗体夹心法对山东省青岛、枣庄、泰安等地区采集的传染性腺胃炎的腺胃样品进行检测，结果表明制备的抗鸡传染性腺胃炎呼肠孤病毒的酶标抗体检测传染性腺胃炎特异性强、灵敏度高、较简便。     

生物牛黄中间体的抗病毒作用及对家兔血液流变学指标的影响

运用比较药理学方法研究了生物牛黄中间体与天然牛黄、人工牛黄在抗病毒及对家兔血液流变学指标影响方面的不同。结果显示，生物牛黄中间体以25、50、100mg／kg体质量及人工牛黄50mg／kg体质量灌胃给药的大鼠含药血清，灭活后，在10倍稀释的情况下，在鸡胚成纤维细胞上使新城疫Ⅰ系疫苗毒的TCID50升高1个滴度；生理盐水组、天然牛黄50mg／kg体质量组10倍稀释大鼠含药血清，灭活后，在鸡胚戍纤维细胞上使新城疫Ⅰ系疫苗毒的TCID50降低1.5个滴度。生物牛黄中间体以25、50、100mg／kg体质量灌胃给药，可明显降低高分子右旋糖酐所致“血瘀”家兔的血沉值、血沉方程K值和红细胞聚集指数；天然牛黄50mg／kg体质量组对血沉值和血沉方程K值具有显著降低作用；人工牛黄50mg／kg体质量组时血沉值具有显著降低作用。     

人参提取液体外抑制IHNV作用效果研究

探究人参提取液体外抑制CCB细胞感染IHNV的能力,构建体外CCB细胞模型,运用RTCA技术和MTT法测得不同浓度人参提取液对IHNV抑制作用曲线,并从阻断病毒复制和杀灭病毒两方面讨论人参提取液作用效果。结果表明,4%人参提取液对IHNV具有明显抑制作用,能够在16 h内保护细胞不受IHNV病毒的侵染,其中2 h时对病毒灭活抑制率最高达到51.5%,1~12 h内对病毒复制有持续抑制作用。研究可为IHVN防治药物的研发提供新的思路及参考。     

一株鸭源禽流感病毒（H9N2）全基因序列分析及其排毒规律的研究

为研究一株鸭源H9N2亚型禽流感病毒(JN1株)全基因组的分子特征和遗传进化情况以及感染雏鸭后的排毒规律,对其生物学特性、全基因组序列以及遗传进化进行了分析,通过点眼滴鼻方式感染3周龄健康雏鸭,利用建立的实时荧光定量PCR(RT-PCR)检测鸭的排毒规律,并测定血清抗体效价。JNI株的鸡胚半数感染量为10~(-7.54)/0.2mL,鸡胚最小致死量的平均死亡时间为72h,静脉致病指数为0.266,抗原相关系数为0.47。系统发育分析表明,JN1株的HA与CK/HK/G9/97和DK/HK/Y280/97在同一分支上,NA、M、NP、PA、PB1、PB2基因与SH/F/98同源性较高,NS基因则与H5N1亚型禽流感病毒进化关系较近。HA的裂解位点为PSRSSR↓GL,存在6个潜在糖基化位点,在234位的氨基酸残基为L,NA基因颈部存在缺失。雏鸭在感染该病毒后,饮食正常,精神良好,3~17d均有排毒,咽拭子和泄殖腔棉拭子排毒规律基本一致,分别在第3天和第13天出现排毒高峰。该H9N2亚型禽流感病毒属欧亚大陆分支,为低致病性禽流感,病毒可通过呼吸道和泄殖腔向外界排毒,排毒时间较长。     

小黑麦与黑麦花序结构和籽粒特性比较

植物的花序结构及其形态特征是影响种子生产性能的重要因素。对于禾本科植物而言,其花序大小、小穗数、小花数及小花的外稃、内稃和芒的性状特征直接影响种子形成和产量。本研究通过测定小黑麦品系C2、C35和黑麦品系C13、C33的花序结构特征,得到以下结果:小黑麦花序[(14.30±0.52) cm×(1.24±0.09) cm]明显大于黑麦[(13.20±0.35) cm×(0.82±0.02) cm],小黑麦花序长而粗,黑麦花序短而细;小黑麦花序的小穗数[(21.35±1.47)个]少于黑麦[(30.20±0.79)个];小黑麦每个小穗的小花数较多,为3~4朵,黑麦的小花数趋于稳定,每个小穗有2朵小花。从花序中部小穗的小花结构看,小黑麦下位护颖长[(1.27±0.11) cm]和宽[(0.26±0.03) cm]、上位护颖长[(1.30±0.09) cm]和宽[(0.23±0.04) cm]均显著大于黑麦下位护颖长[(1.04±0.05) cm]和宽[(0.08±0.01) cm]、上位护颖长[(0.94±0.10) cm]和宽[(0.06±0.01) cm];小黑麦中部小穗第1小花的外稃宽[(0.32±0.03) cm]、外稃高[(0.24±0.03) cm]和芒长[(8.35±0.51) cm]、第2小花的外稃宽[(0.35±0.04) cm]、外稃高[(0.25±0.05) cm]和芒长[(8.37±1.19) cm]极显著大于黑麦相应值[(0.26±0.01),(0.15±0.01),(5.50±0.19),(0.25±0.01),(0.17±0.01)和(5.18±0.23) cm];第1和第2小花的外稃长[(1.35±0.06),(1.37±0.06) cm]和内稃长[(0.84±0.04),(1.41±0.06) cm]均小于黑麦的外稃长[(1.49±0.05),(1.47±0.05) cm]和内稃长[(1.45±0.05),(1.47±0.04) cm]。小黑麦的穗粒数[(52.50±1.80)粒]显著低于黑麦[(58.50±2.50)粒] (P<0.05),但其穗粒重[(2.08±0.04) g]、粒重[(0.04±0.00) g]和籽粒宽[(3.04±0.32) mm]均极显著高于黑麦 (P<0.01),每个花序的籽粒不仅体积大,而且质量较重,其籽粒的生产性能高于黑麦。小黑麦籽粒呈椭圆形或长卵圆形,浅黄色,表皮皱缩,饱满度差;黑麦籽粒呈窄纺锤形,青灰色,表皮光滑,籽粒饱满。小黑麦和黑麦花序结构与籽粒性状的Pearson相关分析表明,小黑麦花序宽和花序基部小穗数与籽粒长显著正相关(P<0.05),花序长与籽粒宽极显著正相关(P<0.01),花序中部小穗的下、上位护颖宽分别与穗粒重和穗粒数极显著正相关(P<0.01);黑麦花序中部小穗第2小花的内稃长与籽粒长显著正相关(P<0.05),外稃高与穗粒数极显著负相关(P<0.01)。研究小黑麦和黑麦的花序结构和籽粒特征,对正确区分二者和了解其籽粒的生产性能具有重要意义,同时有利于小黑麦的示范推广。     

豆科与禾本科牧草间作的生长互作效应及对氮、磷养分吸收的影响

为了解牧草间作对作物生长和养分吸收的影响,以及为不同牧草优化配置、豆科和禾本科牧草间作提高结氮量提供理论依据,本试验采用随机区组试验设计,研究了间作对柱花草、扭黄茅和孔颖草的生物量和氮磷吸收的影响。结果表明,由于柱花草生物固氮,对扭黄茅和孔颖草养分吸收和生长有促进作用,与柱花草间作后的扭黄茅和孔颖草与禾本科牧草单作模式相比,能获得高的养分吸收量和产量。与各自单作对比,间作体系中的禾本科牧草生物量高于单作0.06%和26.78%;与柱花草单作对比,两个间作体系中的柱花草生物量低于单作9.70%和12.83%。扭黄茅与柱花草间作后,对氮磷的吸收量高于单作扭黄茅24.26%和35.18%,对氮磷的吸收量高于单作孔颖草40.64%和47.50%。相对于单作而言,柱花草分别与扭黄茅和孔颖草间作,对氮吸收量分别降低8.31%和28.94%,磷吸收量分别降低3.56%和20.58%。而且两种间作模式当量比均大于1,具有间作优势;柱花草/扭黄茅间作系统生产力、种间竞争能力高于柱花草/孔颖草,具有产量优势。在株行距为50 cm种植密度下,间作体系中禾本科牧草生长旺盛,柱花草的生长受到抑制,在与两个禾本科牧草间作中为弱竞争作物。结果表明,在合理的种植密度下,适合的牧草配置能够充分利用各种资源,促进种间有益作用,提高单位面积牧草产量和禾本科牧草氮磷的吸收,有利于改善牧草品质。     

Novel reassortant H5N6 highly pathogenic influenza A viruses in Vietnamese quail outbreaks

Avian influenza A H5N6 virus is a highly contagious infectious agent that affects domestic poultry and humans in South Asian countries. Vietnam may be an evolutionary hotspot for influenza viruses and therefore could serve as a source of pandemic strains. In 2015, two novel reassortant H5N6 influenza viruses designated as A/quail/Vietnam/CVVI01/2015 and A/quail/Vietnam/CVVI03/2015 were isolated from dead quails during avian influenza outbreaks in central Vietnam, and the whole genome sequences were analyzed. The genetic analysis indicated that hemagglutinin, neuraminidase, and polymerase basic protein 2 genes of the two H5N6 viruses are most closely related to an H5N2 virus (A/chicken/Zhejiang/727079/2014) and H10N6 virus (A/chicken/Jiangxi/12782/2014) from China and an H6N6 virus (A/duck/Yamagata/061004/2014) from Japan. The HA gene of the isolates belongs to clade 2.3.4.4, which caused human fatalities in China during 2014–2016. The five other internal genes showed high identity to an H5N2 virus (A/chicken/Heilongjiang/S7/2014) from China. A whole-genome phylogenetic analysis revealed that these two outbreak strains are novel H6N6-like PB2 gene reassortants that are most closely related to influenza virus strain A/environment/Guangdong/ZS558/2015, which was detected in a live poultry market in China. This report describes the first detection of novel H5N6 reassortants in poultry during an outbreak as well as genetic characterization of these strains to better understand the antigenic evolution of influenza viruses.     

Differential gene expression of Eph‐ephrin A1 and LEPR‐LEP with high or low number of embryos in pigs during implantation

The objective of this study was to ascertain whether mRNA and protein expressions of implantation‐related genes (erythropoietin‐producing hepatocellular receptor–ligand A1, Eph‐ephrin A1 and leptin receptor–leptin, LEPR‐LEP) differed between pigs with high and low number of embryos, and whether these differences in gene expression might affect embryo implantation. Experimental pig groups (n = 24) for high and low number of embryos were prepared by altering the number of eggs ovulated in pre‐pubertal gilts treated with 1.5 × (High) or 1.0 × (Low) PG600 ([400 IU PMSG + 200 IU hCG]/dose, AKZO‐NOBEL). Gilts expressing oestrus were artificially inseminated twice and maintained in breeding and gestation until the reproductive tract was collected on day 22 of pregnancy. At slaughter, the reproductive tracts from each pregnant gilt from each treatment were immediately processed to collect samples for RNA and protein analysis. Within each gilt, three conceptus points were sampled, one from each horn and then a random conceptus within the tract. At each conceptus point, endometrial attachment site, chorion–allantois and embryo were collected and immediately frozen in liquid nitrogen. Number of corpus luteum (CL) (35.4 vs. 12.6) and total embryo number (18.8 vs. 10.2) were greater in the high‐embryo compared to the low‐embryo group, respectively (p < .05). Real‐time qPCR results showed that Eph‐ephrin A1 mRNA expression was less in the high‐embryo (p < .05) compared to the low‐embryo group. In addition, Western blotting analysis indicated that Eph‐ephrin A1 and LEP protein expression at endometrial attachment site in high‐embryo was less (p < .05) compared to low‐embryo group. It was also noted that mRNA expression of Eph‐ephrin A1 and LEPR‐LEP was greater in pregnant than non‐pregnant gilts (p < .05). Moreover, mRNA expression of Eph‐ephrin A1 (p < .05) and LEPR‐LEP was greatest at endometrial attachment site among all three tissues. There was a positive correlation between expressions of Eph‐ephrin A1, LEPR‐LEP and embryo length with the correlation coefficient 0.31–0.59. For Eph‐ephrin A1, the highest correlation coefficient appeared between Eph A1 expression and normal embryo number, between ephrin A1 expression and embryo length. For LEPR‐LEP, the highest correlation coefficient appeared between LEPR‐LEP expression and ovary weight (0.79 for both, p < .05), followed by embryo length and weight. The results of this study suggest that low expression of Eph‐ephrin A1 and LEPR‐LEP is somehow related to increased embryo number during implantation and that endometrial attachment site might be the main target tissue of these gene products. Yet, the increased expression of Eph‐ephrin A1 and LEPR‐LEP appeared associated with increased embryo growth (length and weight) and ovary weight, Eph‐ephrin A1 and LEPR‐LEP might play roles in the regulation of embryo implantation in pigs.