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。     

2011年-2013年滨州及其周边地区4种猪病毒性疾病的流行情况分析

通过对滨州及其周边地区2011年-2013年316个场次采集病料进行猪瘟病毒、猪繁殖与呼吸综合征病毒、猪伪狂犬病病毒与猪圆环病毒2型的检测,并对检测结果进行了统计分析,了解滨州及其周边地区上述4种疫病的流行状况。     

Pathogen Analysis of Goat's Respiratory Diseases

To investigate the pathogens of goat's respiratory disease from a goat farm in Guangxi province, the epidemiological investigation, clinic observation, pathological examination, bacterium isolation and identification, biochemical test, PCR and animal experiment test were conducted.The preventive and control measures were taken on the basis of pathogen epidemiological characteristics and drug sensitive test results.The results showed that Mycoplasma, influenza virus and parasite were negative by isolation and culture or PCR, however, two strains of gram-negative bacteria named MS1 and MS2 were isolated from lung.MS1 was identified as Serratia marcescens by biochemical test and 16S rRNA sequencing, which shared 99% nucleotide homology with other Serratia marcescens in GenBank.And MS2 was identified as E.coil by the same methods that shared 99% nucleotide homology with other E.coli in GenBank.Animal experiment showed that two strains could cause death in mice.The drug sensitive tests showed two strains were highly sensitive to spectinomycin, amikacin, kanamicin and neomycin.Kanamycin and dexamethasone were used to treat the sick goats, and achieved good results.     

Detection of Ureaplasma diversum in the upper airways of Australian feedlot cattle

Bovine respiratory disease (BRD) exerts a major impact on the beef cattle industry nationally and worldwide, with a range of aetiological factors impacting its pathogenesis. Previous research has focussed on an increasing number of bacteria and viruses that have been shown to play a role in eliciting disease. Recently, additional agents have been emerging as potential contributors to BRD, including the opportunistic pathogen Ureaplasma diversum. To determine if U. diversum was present in Australian feedlot cattle and if that presence was linked to BRD, nasal swabs were collected from a cohort of 34 hospital pen animals and compared to 216 apparently healthy animals sampled contemporaneously at feedlot induction and again after 14 days on feed at an Australian feedlot. All samples were subjected to a de novo polymerase chain reaction (PCR) assay targeting U. diversum in combination with other BRD agents. U. diversum was detected at a low prevalence in cattle at induction (Day 0: 6.9%, Day 14: 9.7%), but in a significantly greater proportion of cattle sampled from the hospital pen (58.8%). When considering the presence of other BRD-associated agents, co-detection of U. diversum and Mycoplasma bovis was most common in hospital pen animals receiving treatment for BRD. These findings suggest that U. diversum may be an opportunistic pathogen involved in the aetiology of BRD in Australian feedlot cattle, in combination with other agents, with further studies are warranted to identify if a causal relationship exists.     

Sequence and unique phylogeny of G genes of bovine respiratory syncytial viruses circulating in Japan

Bovine respiratory syncytial virus (BRSV) is an etiologic agent of bovine respiratory disease. The rapid evolutionary rate of BRSV contributes to genetic and antigenic heterogeneity of field strains and causes occasional vaccine failure. We conducted molecular epidemiologic characterization of BRSV circulating in Japan to obtain genetic information for vaccine-based disease control. Phylogenetic analysis of G and F gene sequences revealed that all of the isolated Japanese BRSV strains clustered in the same genetic subgroup, which was distinct from the 9 known groups. We assigned the Japanese group to subgenotype X. The Japanese isolates formed 2 temporal clusters: isolates from 2003 to 2005 clustered in lineage A; isolates from 2017 to 2019 formed lineage B. The alignment of the deduced amino acid sequences of the G gene revealed that the central hydrophobic region responsible for viral antigenicity is conserved in all of the isolates; unique amino acid mutations were found mainly in mucin-like regions. Our results suggest that BRSV has evolved uniquely in Japan to form the new subgenotype X; the antigenic homogeneity of the viruses within this group is inferred.     

2020年新疆地区猪繁殖与呼吸综合征病毒抗体检测与分析

为了解2020年新疆地区猪繁殖与呼吸障碍综合征病毒（PRRSV）抗体水平及其消长规律,本试验采用间接酶联免疫吸附试验（ELISA）法对1 218份血清中PRRSV免疫抗体水平进行检测和分析。结果显示,PRRSV抗体平均阳性率为78.49%（956/1218）,高于国家规定标准（70%）。S/P的平均值为1.22±0.84,变异系数为69.45%。不同类别猪群抗体平均阳性率在59.19%~91.50%之间,有一定的差异。在调查的10个规模化养殖场中,9个场PRRSV免疫抗体阳性率达到国家标准。不同类别猪群PRRSV变异系数较高,需进一步对现有的免疫程序进行调整和完善,确保各猪群健康。     

鸡呼吸道疾病鉴别诊断与防治

呼吸道疾病是目前威胁鸡养殖产业健康发展的一类重大动物疫病,呼吸道疾病的病原种类多种多样,且造成的临床症状大致相同,诊断难度较大,如果没有进行妥善有效的鉴别、诊断,易造成整体的治疗方案缺乏针对性,难以在短时间内控制病情,错过最佳的防控时期。鸡呼吸道疾病常常混合感染并发感染,2种以上的病原相互叠加表现的临床症状复杂,诊断难度更大。该文主要论述鸡呼吸道疾病的鉴别诊断和防治措施。     

Establishment of a Duplex Real-time RT-PCR Assay for the Differential Detection of Nipha Virus and Highly Pathogenic Porcine Reproductive and Respiratory Syndrome Virus

To establish a rapid,sensitive and specific assay for the differential detection of Nipah virus (NiV) and highly pathogenic porcine reproductive and respiratory syndrome virus (HP-PRRSV),a duplex Real-time RT-PCR was developed with specific primers and probes targeting to the special sequences of NiV M gene and HP-PRRSV nsp2 gene by optimization of reaction conditions.The performance of the assay was linear ranging from 4.6×10¹ to 4.6×10⁷ copies/μL for RNA standard control of NiV M (NiV-M-RNA) and from 4.1×10¹ to 4.1×10⁸ copies/μL for RNA standard control of HP-PRRSV nsp2 (HP-PRRSV-nsp2-RNA),and detection limits of the assay was 46 copies for the NiV-M-RNA and 4.1 copies for the HP-PRRSV-nsp2-RNA,respectively.The coefficients of variation (CVs) of both inter-assay and intra-assay repeatability were less than 2.0%,showing good repeatability.The assay was able to specifically detect NiV and HP-PRRSV simultaneously without cross-reaction with classical swine fever virus (CSFV),porcine epidemic diarrhea virus (PEDV),swine influenza virus (SIV),porcine parvovirus (PPV),pseudorabies virus (PRV) and porcine circovirus type 2 (PCV2).Of the 236 samples from pigs for both NiV and HP-PRRSV detection by the established assay,all the samples were negative for NiV,8 samples were HP-PRRSV positive.In conclusion,this assay offers a useful approach for the differential detection of NiV and HP-PRRSV in clinical specimens from the pigs.     

高致病性猪繁殖与呼吸综合征病毒双重液相基因芯片检测方法的建立

为了实现快速检测猪繁殖与呼吸综合征病毒(PRRSV)并同步鉴别高致病性PRRSV毒株(HPPRRSV),根据PRRSV囊膜蛋白GP2基因保守序列和HP-PRRSV特有的Nsp2基因区保守序列设计特异扩增引物和杂交探针,通过双重一步法RT-PCR不对称扩增和双重微球杂交反应,建立了双重液相基因芯片方法。对12株PRRSV以及其他12种猪病原体的检测显示,该法能特异性检测12株PRRSV毒株并准确鉴别其中7株HP-PRRSV,与其他病原体无交叉反应;对PRRSV、HP-PRRSV病毒液的检测低限均小于每个反应0.5TCID_(50);其组内、组间检测变异系数均10%;检测55份疑似临床样品并与商品化荧光RTPCR试剂盒比较检测结果,符合率达98.2%(54/55)。研究结果为适应临床快速检测PRRSV提供了一种新的分子生物学检测方法。