Naturally Co‐Infected Boars with both Porcine Reproductive and Respiratory Syndrome Virus and Porcine Circovirus Type 2

In this study, the humoral response against porcine reproductive and respiratory syndrome virus (PRRSV) and porcine circovirus type 2 (PCV2), the presence of the virus in semen and serum and the genetic characteristics of the virus detected in 15 boars from a commercial farm were analysed. The results showed that 53% of the boars presented anti‐PRRSV antibodies and 100% presented anti‐PCV2 antibodies. Porcine reproductive and respiratory syndrome virus was detected in 43% of the boars and 73% were positive to PCV2. The complete ORF5 gene of PRRSV of 14 samples and a fragment of the ORF2 gene of PCV2 of 22 samples were sequenced. Porcine reproductive and respiratory syndrome virus analysis revealed <92% identity in viruses from semen and serum of two boars, whereas in the rest of the boars the identity was >97.5%. As for PCV2, two boars presented an identity <95% in serum and semen and the rest had an identity >96%. The results showed that PRRSV‐ and PCV2‐naturally infected boars can be found, and at least two different strains of viruses from semen and serum can be detected.     

Porcine Reproductive and Respiratory Syndrome Virus Vaccines: Current Status and Strategies to a Universal Vaccine

Porcine reproductive and respiratory syndrome virus (PRRSV) is the causative agent of PRRS, the most significant infectious disease currently affecting swine industry worldwide. In the United States alone, the economic losses caused by PRRS amount to more than 560 million US dollars every year. Due to immune evasion strategies and the antigenic heterogeneity of the virus, current commercial PRRSV vaccines (killed‐virus and modified‐live vaccines) are of unsatisfactory efficacy, especially against heterologous infection. Continuous efforts have been devoted to develop better PRRSV vaccines. Experimental PRRSV vaccines, including live attenuated vaccines, recombinant vectors expressing PRRSV viral proteins, DNA vaccines and plant‐made subunit vaccines, have been developed. However, the genetic and antigenic heterogeneity of the virus limits the value of almost all of the PRRSV vaccines tested. Developing a universal vaccine that can provide broad protection against circulating PRRSV strains has become a major challenge for current vaccine development. This paper reviews current status of PRRSV vaccine development and discusses strategies to develop a universal PRRSV vaccine.     

Two Commercial Type 1 Porcine Reproductive and Respiratory Syndrome Virus (PRRSV)‐Modified Live Vaccines Reduce Seminal Shedding of Type 1 PRRSV but not Type 2 PRRSV in Infected Boars

The objective of this study was to compare the effects of two commercial type 1 porcine reproductive and respiratory syndrome virus (PRRSV)‐modified live vaccines on type 1 and type 2 PRRSV shedding in the semen of experimentally infected boars. Upon challenge with PRRSV, unvaccinated boars exhibited an increase in daily rectal temperature (39.4–39.7°C). Vaccination of boars with type 1 PRRSV significantly reduced the amount of type 1 PRRSV load in blood and semen after challenge with type 1 PRRSV, but barely reduced the amount of type 2 PRRSV load in blood and semen after the type 2 PRRSV challenge. There were no significant differences in the reduction of viremia and seminal shedding of type 1 and type 2 PRRSV between the two commercial vaccines. The seminal shedding of PRRSV is independent of viremia. The reduction of type 1 PRRSV seminal shedding coincided with the appearance of type 1 PRRSV‐specific interferon‐γ secreting cells (IFN‐γ‐SC) in vaccinated type 1 PRRSV‐challenged boars. The frequencies of type 1 PRRSV‐specific IFN‐γ‐SC induced by type 1 PRRSV vaccine are relatively high compared to type 2 PRRSV‐specific IFN‐γ‐SC induced by the same vaccine which may explain why type 1 PRRSV vaccine is more effective in reducing seminal shedding of type 1 PRRSV when compared to type 2 PRRSV in vaccinated challenged boars. These results provide clinical information on how to reduce seminal shedding of type 1 PRRSV in boars using type 1 PRRSV‐modified live vaccine.     

A natural recombinant PRRSV between HP‐PRRSV JXA1‐like and NADC30‐like strains

Porcine reproductive and respiratory syndrome virus (PRRSV ) is a major economically significant pathogen that has adversely affected China's swine industry. Currently, a novel type 2 PRRSV , called the NADC 30‐like strain, is epidemic in numerous provinces of China, and commercial vaccines provide limited protection for infected animals. The extensive recombination phenomenon among NADC 30‐like PRRSV s is identified as a unique molecular characteristic of the virus. However, our understanding of how recombination influences NADC 30‐like PRRSV s is largely inadequate. In this study, we analysed the genetic characteristics of a recombinant NADC 30‐like PRRSV (SC ‐d) and examined its pathogenicity compared with a non‐recombinant NADC 30‐like PRRSV (SD ‐A19) and a highly pathogenic PRRSV (HuN4). SC ‐d has three discontinuous deletions in nsp2, consistent with NADC 30 isolated from the United States in 2008. Furthermore, we identified four recombination breakpoints in the SC ‐d genome, which separated the SC ‐d genome into four regions (regions A, B, C and D). Regions A and C are closely related to the JXA 1‐like strain, one of the earliest Chinese HP ‐PRRSV strains, and regions B and D are closely related to the NADC 30 strain. Moreover, SC ‐d inoculated piglets exhibited a persistent fever, moderate weight loss, mild thymus atrophy and obvious microscopic lung lesions. In summary, the recombinant NADC 30‐like PRRSV SC ‐d strain displayed a higher pathogenicity than the non‐recombinant NADC 30‐like PRRSV SD ‐A19 strain; however, the pathogenicity of the NADC 30‐like PRRSV SC ‐d was lower compared with the HP ‐PRRSV HuN4 strain in piglets. Our findings demonstrate that recombination is responsible for the enormous genetic diversity and pathogenicity variance of the NADC 30‐like PRRSV in China. This study provides a theoretical basis for developing a more reasonable PRRSV control and prevention strategy.     

A modified‐live porcine reproductive and respiratory syndrome virus (PRRSV)‐1 vaccine protects late‐term pregnancy gilts against heterologous PRRSV‐1 but not PRRSV‐2 challenge

The objective of this study was to determine the efficacy of a commercially available porcine reproductive and respiratory syndrome virus (PRRSV )‐1 modified‐live virus (MLV ) vaccine against PRRSV ‐1 and PRRSV ‐2 challenge in late‐term pregnancy gilts. Gilts were vaccinated with the PRRSV ‐1 MLV vaccine at 4 weeks prior to breeding and then challenged intranasally with PRRSV ‐1 or PRRSV ‐2 at 93 days of gestation. After PRRSV ‐1 challenge, vaccinated pregnant gilts had a significantly longer gestation period, significantly higher numbers of live‐born and weaned piglets and a significantly lower number of stillborn piglets at birth compared to unvaccinated pregnant gilts. No significant improvement in reproductive performance was observed between vaccinated and unvaccinated pregnant gilts following PRRSV ‐2 challenge. Vaccinated pregnant gilts also exhibited a significantly improved reproductive performance after challenge with PRRSV ‐1 compared to vaccinated pregnant gilts following PRRSV ‐2 challenge. The PRRSV ‐1 MLV vaccine was able to reduce PRRSV ‐1 but not PRRSV ‐2 viremia in pregnant gilts. Vaccinated gilts also showed a significantly higher number of PRRSV ‐1‐specific IFN ‐γ‐secreting cells (IFN ‐γ‐SC ) compared to PRRSV ‐2‐specific IFN ‐γ‐SC . The data presented here suggest that the vaccination of pregnant gilts with a PRRSV ‐1 MLV vaccine provides good protection against PRRSV ‐1 but only limited protection against PRRSV ‐2 challenge in late‐term pregnancy gilts based on improvement of reproductive performance, reduction in viremia and induction of IFN ‐γ‐SC .     

Comparative Analysis of Immune Responses in Pigs to High and Low Pathogenic Porcine Reproductive and Respiratory Syndrome Viruses Isolated in China

The CH‐1a and HuN4 strains of porcine reproductive and respiratory syndrome virus (PRRSV) show different pathogenicities in pigs. To understand host immune responses against these viruses, we investigated the dynamic changes in cytokine levels produced in peripheral blood of piglets infected with the highly pathogenic PRRSV HuN4 strain or the CH‐1a strain. Clinical signs, virus loads and serum cytokine levels [interferon(IFN)‐α, Interleukin (IL)‐1, TNF‐α, IL‐6, IL‐12, IFN‐γ, IL‐10 and TGF‐β] were tested. The results showed that while piglets developed effective cellular immune responses against CH‐1a infection, those infected with HuN4 displayed ineffective cellular immunity, organ lesions and persistent elevated levels of immunoregulatory cytokines (IL‐10 and TGF‐β), which delayed the development of PRRSV‐specific immune responses. These results demonstrated that HuN4 infection induced higher cytokine levels than that of CH‐1a infection induced. The changes in inflammatory cytokines intensified the inflammatory reaction and damaged the tissues and organs.     

Evaluation of the Pathogenicity and Transmissibility of a Chilean Isolate of Porcine Reproductive and Respiratory Syndrome Virus

The objective of this study was to determine clinical features, shedding and transmission of a Chilean Porcine Reproductive and Respiratory Syndrome Virus (PRRSV) strain upon experimental inoculation of 4‐week‐old pigs. Six groups of five animals each were used. The G1 (donor) group was inoculated with PRRSV, maintained in an isolation unit for 35 days, and sampled daily to determine shedding in mucosal secretions and faeces, viraemia and seroconversion. An uninfected control group (G6) was equally maintained and sampled under strict isolation. Four other groups (G2 to G5) were exposed to PRRSV via direct contact with G1 for 5‐day periods in a staggered manner, throughout the 35‐day period, and were later placed in an independent isolation unit to monitor infection status for 7 days. All the animals in G1 and G6 were killed at 35 days post‐inoculation (dpi) and the contact groups at 12 days post‐contact (dpc). Samples were obtained from diverse organs for histopathological, immunohistochemical (IHC) and virological analysis. No clinical symptoms were evident in any group, except for a transient fever observed in G1. Histopathologically, all the animals of G1 had interstitial pneumonia, although scarce PRRSV‐positive cells were detected in the lung using IHC. PRRSV‐positive cells (IHC) were detected in the lymphoid tissue of all animals in infected groups, but especially in G3 and G4. Viraemia was detected in G1 (3–35 dpi) and in the all contact groups (5–12 dpc). Likewise, ranging from 3 to 19 dpi, PRRSV was detected in at least one animal from the tonsils and lungs in all infected groups, in nasal and ocular secretions, saliva or faeces. These results indicate that the donor group excreted infectious PRRSV and was able to transmit the infection to susceptible pigs. The critical shedding period was 7–19 dpi, during which, most likely, transmission took place.     

Differential Expression of Proinflammatory Cytokines in the Lymphoid Organs of Porcine Reproductive and Respiratory Syndrome Virus‐Infected Pigs

Porcine reproductive and respiratory syndrome (PRRS) is considered one of the most important diseases in the swine industry. Although several studies have been carried out to elucidate the host immune response evoked against PRRS virus (PRRSV), there are several aspects that still remain unclear. The aim of this study was to determine the expression of IL‐1α, IL‐6 and TNF‐α in the lymphoid organs (mediastinal and retropharyngeal lymph nodes and tonsil) of PRRSV‐infected pigs and to determine their correlation with the expression of PRRSV antigen. Proinflammatory cytokine expression was different depending on the body compartment examined. Thus, whereas IL‐1α and TNF‐α were the main cytokines expressed in the mediastinal lymph node, IL‐6 was the most highly expressed cytokine in the retropharyngeal lymph node, and no expression of proinflammatory cytokines was observed in the tonsil. These findings may be related to the impairment of the host immune response evoked after PRRSV infection. Therefore, lymphoid organs and proinflammatory cytokines represent an important target of study for clarifying the immunopathogenesis of PRRS.     

Downregulation of Antigen‐Presenting Cells in Tonsil and Lymph Nodes of Porcine Reproductive and Respiratory Syndrome Virus‐Infected Pigs

Porcine reproductive and respiratory syndrome virus (PRRSV) can persist in different organs of infected pigs, which suggests a failure in the immune response. Antigen‐presenting cells (APCs) play a pivotal role in the induction of effective T‐ and B‐cell responses. In this study, we investigated the changes in the different APC subpopulations and T‐ and B‐cell counts in the tonsil, retropharyngeal and mediastinal lymph nodes of pigs experimentally infected with a European PRRSV field isolate. Our results demonstrated that the expression of S100, SWC3, HLA‐DR molecule and CD3 was diminished in the studied organs throughout the study, observing a significant negative correlation between viral antigen and HLA‐DR expression in both retropharyngeal and mediastinal lymph nodes. In contrast, λ‐light chains showed an increase during the study. Taking all into account, after PRRSV infection, no enhancement in the number of APCs and T cells was observed, suggesting an impairment of the immune function which may allow the persistence of PRRSV into the organism.     

A Bayesian Phylogeographical Analysis of Type 1 Porcine Reproductive and Respiratory Syndrome Virus (PRRSV)

Understanding viral transmission is an important factor for the effective prevention one of the most devastating swine diseases, porcine reproductive and respiratory syndrome. Focusing on molecular epidemiology of type 1 PRRSV, this study analysed a large ORF5 dataset collected worldwide from 1991 to 2012 using a coalescent‐based Bayesian Markov chain Monte Carlo approach. The results suggested that the virus diversified into unique subpopulations in Russia & Belarus and Italy approximately 100 years ago. Previously unreported consecutive diffusions of the virus were identified, which showed that some countries, such as Spain and Germany, acted as distribution sources to some extent. This study also provided statistical evidence for the existence of an ORF5‐based phylogeographical structure of type 1 PRRSV, in which the virus tended to cluster by geographical locations more tightly than expected by chance. In contrast to this tight geographical structure, the evolution of the ORF5 gene, based on mapping of non‐synonymous/synonymous substitutions, was best described by a non‐homogeneous process that could be implicated as a mechanism for viral immune evasion.     

Fresh Pork and Porcine Reproductive and Respiratory Syndrome Virus: Factors Related to the Risk of Disease Transmission

Porcine reproductive and respiratory syndrome virus (PRRS) is a highly infectious virus. Experimentally, the disease can be induced in naïve pigs by the oral, intranasal and intramuscular routes. Depending on the virulence of the strain of the virus and the age of the pig, peak viremia can occur within 7 days of infection, and live virus can be isolated from blood or lymph nodes for several months post‐infection. Young pigs tend to develop higher titres of viremia than older pigs infected by the same route and dose with the same strain of virus. Porcine reproductive and respiratory syndrome virus survives in pork harvested from infected pigs for extended periods at temperatures of −20 or −70°C. In experimentally infected pigs, survival of PRRS virus in muscle held at 4°C has been demonstrated for at least 7 days, and infectivity of the virus in these samples was confirmed by bioassay. The optimal pH range for the survival of PRRS virus is thought to be 6.0 to 7.5. The elevated pH of non‐meat tissues (generally one pH unit higher) is likely to favour extended survival of PRRS virus in pig carcasses from which all superficial and deep lymph nodes have not been removed. It is likely that exsanguinated carcasses held at 4°C retain sufficient blood or lymph tissue to contain infective doses of PRRS virus. Porcine reproductive and respiratory syndrome virus is rapidly inactivated by heat, providing a predictable method to ensure that pork tissues are free of viable virus and feeding of cooked swill or garbage should not constitute a risk to pigs. While the probability of viable PRRS virus being present in a pig carcass may be low, the risk is not zero. The importation of raw pork into countries where PRRS is not endemic represents a hazard with potentially severe economic consequences.     

Pathology and Virus Distribution in the Lung and Lymphoid Tissues of Pigs Experimentally Inoculated with Three Distinct Type 1 PRRS Virus Isolates of Varying Pathogenicity

Porcine reproductive and respiratory syndrome (PRRS) continues to be the most economically important disease of swine worldwide. The appearance of highly pathogenic PRRS virus (PRRSV) strains in Europe and Asia has raised concerns about this disease and initiated increased efforts to understand the pathogenesis. In this study, we have compared the pathology and the virus distribution in tissues of pigs experimentally inoculated with three different genotype 1 PRRSV isolates. Sixty 5‐week‐old pigs were inoculated intranasally with a) the Lelystad virus (LV), b) a field strain from the UK causing respiratory clinical signs (UK) or c) a highly pathogenic strain from Belarus (BE). Sixteen animals were mock‐infected and used as controls. The animals were euthanized at 3, 7 and 35 days post‐infection (dpi), and lung and lymphoid tissues collected for histopathological examination and PRRSV detection by immunohistochemistry (IHC). Histopathological lesions consisted of interstitial pneumonia with mononuclear cell infiltrates in the lungs, lymphoid depletion, apoptosis and follicular hyperplasia in the spleen, lymph nodes and tonsil and lymphoid depletion in the thymus. Porcine reproductive and respiratory syndrome virus was detected mainly in monocytes–macrophages. BE‐infected animals showed the highest pathological scores and the highest presence of virus at 3 and 7 dpi, followed by the UK field strain and then LV. Moderate lesions were observed at 35 dpi with lesser detection of PRRSV by IHC in each infected group. The highly pathogenic BE strain induced more severe pathology in both lungs and lymphoid organs of pigs compared with the classic field isolate and the prototype LV. The increased severity of pathology was in correlation with the presence of a higher number of PRRSV‐infected cells in the tissues.     

Sequence and Phylogenetic Analyses of the Nsp2 and ORF5 Genes of Porcine Reproductive and Respiratory Syndrome Virus in Boars from South China in 2015

Porcine reproductive and respiratory syndrome virus (PRRSV) is highly genetically diverse; however, little is known about the molecular epidemiology of PRRSV in the boar farms of South China. In this study, 367 samples were collected from boar farms in South China in 2015. The Nsp2 hypervariable region and ORF5 gene were PCR amplified from 66 PRRSV‐positive samples, followed by sequencing and analysis. The percentage of PRRSV antigen‐positive samples was 17.98%; 8.72% were positive for highly pathogenic PRRSV (HP‐PRRSV), and 9.26% were positive for low pathogenic PRRSV (LP‐PRRSV). Sequence alignment and phylogenetic tree analyses revealed three novel patterns of deletion in the hypervariable region of Nsp2, which had not been identified previously. Furthermore, numerous amino acid substitutions were identified in the putative signal peptide and extravirion regions of GP5. These results demonstrate for the first time that the existence of multiple different strains on the same boar farm, and extensive genetic mutation and high infection rate of PRRSV in boars from South China. Our research contributes to the understanding of the epidemiology and genetic characteristics of PRRSV on boar farms.     

Emergence of Porcine Reproductive and Respiratory Syndrome in Sweden: Detection,Response and Eradication

Porcine reproductive and respiratory syndrome (PRRS) is characterized by reproductive failure in sows and respiratory problems in growing pigs. The disease is present in most countries throughout the world but was not diagnosed in Sweden until the summer of 2007 when it was first detected through the national PRRS surveillance program. The immediate mobilization of veterinary authorities, field veterinarians and the pig industry was a prerequisite for preventing the spread of the disease. Within 10 days seven herds were verified as infected and the measures taken included stamping out, cleaning, disinfection and a vacancy period of 3 weeks before the herds were repopulated. To evaluate the effectiveness of these measures, a national sero‐surveillance was carried out during the autumn of 2007. Approximately 90% of the pig production was covered by this screening and all samples tested were negative with regard to antibodies to PRRS virus.     

Type 2 Porcine Reproductive and Respiratory Syndrome Virus Infection Mediated Apoptosis in B‐ and T‐Cell Areas in Lymphoid Organs of Experimentally Infected Pigs

Porcine Reproductive and Respiratory Syndrome Virus (PRRSV) infection is characterized by persisting in lungs and lymphoid tissue, resulting in systemic lymphoid depletion. The aim of this study was to correlate the histological changes, viral antigen expression and apoptosis phenomena in tonsil, medial retropharyngeal and mediastinal lymph nodes of 12 pigs inoculated with a type 2 PRRSV isolate (Chilean strain 2402). Apoptosis phenomena were observed mainly in lymphocytes and secondly in macrophages of lymph nodes and tonsils of inoculated animals, showing a peak of both apoptotic cells and viral antigen expression at the end of the study (21 dpi). However, the number of apoptotic cells was higher than the number of PRRSV‐positive cells at the end of the study. This finding together with the location of apoptotic cells and PRRSV‐positive cells in different structures of lymphoid organs supports the hypothesis that PRRSV‐positive macrophages might modulate the apoptosis phenomena in other cells, mainly lymphocytes, by means of an indirect mechanism. Furthermore, apoptotic cells were detected both in B‐ and T‐cell areas of lymphoid organs, suggesting that apoptosis phenomena may play a role in the impairment of the host immune response during PRRS.     

The infectious cDNA clone of commercial HP‐PRRS JXA1‐R‐attenuated vaccine can be a potential effective live vaccine vector

Multiple commercial porcine reproductive and respiratory syndrome (PRRS) modified live vaccines are currently utilized in Chinese swine herds due to the limited cross‐protection of vaccines and coexistence of different PRRS viruses. In this study, an infectious cDNA clone of the highly pathogenic PRRS (HP‐PRRS) vaccine JXA1‐R strain was generated. We successfully rescued the virus from direct in vitro DNA transfection of rJXA1‐R clone, which has similar growth kinetics to the parental JXA1‐R virus in Marc‐145 cells. To further evaluate the potential use of the cloned rJXA1‐R virus as a live vector for foreign gene expression, the enhanced green fluorescent protein (EGFP) was inserted between non‐structural and structural genes. Our results showed that the dynamic expression of EGFP can be visualized by live cell imaging system during the infection in Marc‐145 cells. The availability of our cloned JXA1‐R viruses provides a crucial platform to study the fundamental biology of HP‐PRRS virus vaccine and also serves as a potential effective vector for developing live vector vaccines against swine pathogens.     

Evolutionary Dynamics of a Highly Pathogenic Type 2 Porcine Reproductive and Respiratory Syndrome Virus: Analyses of Envelope Protein‐Coding Genes

Porcine reproductive and respiratory syndrome virus (PRRSV) has long been an economically devastating swine viral disease. The recent emergence of a highly pathogenic type 2 PRRSV with high mobility and mortality in China, spreading in Vietnam, Laos, and Thailand has placed neighbouring countries at risk. This study applied a codon‐based extension of the Bayesian relaxed clock model and the fixed effects maximum‐likelihood method to investigate and compare the evolutionary dynamics of type 2 PRRSV for all of known structural envelope protein‐coding genes. By comparing the highly pathogenic type 2 PRRSV clade against the typical type 2 PRRSV clade, this study demonstrated that the highly pathogenic clade evolved at high rates in all of the known structural genes but did not display rapid evolutionary dynamics compared with typical type 2 PRRSV. In contrast, the ORF3, ORF5 and ORF6 genes of the highly pathogenic clade evolved in a qualitatively different manner from the genes of the typical clade. At the population level, several codons of the sequence elements that were involved in viral neutralization, as well as codons that were associated with in vitro attenuation/over‐attenuation, were predicted to be selected differentially between the typical clade and the highly pathogenic clade. The results of this study suggest that the multigenic factors of the envelope protein‐coding genes contribute to diversifying the biological properties (virulence, antigenicity, etc.) of the highly pathogenic clade compared with the typical clade of type 2 PRRSV.     

Emergence of novel recombination lineage 3 of porcine reproductive and respiratory syndrome viruses in Southern China

Lineage 3 of porcine reproductive and respiratory syndrome viruses, which belong to North America type 2, has a long epidemic history in China. The novel lineage 3 viruses constantly emerging in recent years are characterized by a high detection rate and significant pathogenicity. In this study, we investigated the prevalence of lineage 3 in southern China and selected two isolated strains for genome and virulence analyses. A cross‐sectional epidemiology investigation indicated that the prevalence of lineage 3 antigens was 35.68% (95% CI: 27.6–44.3%) among 227 samples collected from over 100 infected farms from January 2016 to July 2017 in southern China. Two novel isolates of lineage 3 were selected. After 20 passages, Marc‐145 cells were not susceptible to those viruses. Full‐length genome analysis indicated that the two strains share 95.2% homology with each other and 95.7%–96.2% with highly pathogenic porcine reproductive and respiratory syndrome viruses (HP‐PRRSVs; JXA1‐like strain, lineage 8.7). Phylogenetic and molecular evolutionary results showed that for the two isolates, HP‐PRRSV provides most of the ORF1 gene. Animal experiment revealed discrepancies in virulence between the strains. Although challenge resulted in 100% morbidity, the isolate carrying most of the HP‐PRRSV ORF1 caused severe clinical symptoms and 40% mortality, whereas the other isolate containing part of the ORF1 gene caused no mortality. Overall, these findings suggest that lineage 3 viruses might be commonly circulating in most of southern China. Frequent recombination events within HP‐PRRSVs of this lineage with changing virulence could represent potential threats to the pig industry.     

Pathogenicity of porcine reproductive and respiratory syndrome virus (ORF5 RFLP 1‐7‐4 viruses) in China

Porcine reproductive and respiratory syndrome virus (PRRSV) is an RNA virus that causes reproductive failure in sows and respiratory problems in piglets. PRRSV infection leads to substantial pig mortality and causing huge economic losses so that disease outbreaks caused by the new PRRSV strain from other regions have caused great concern in China. In this study, we analysed the pathogenicity of the novel ORF5 RFLP 1‐7‐4‐like PRRSV strain, named PRRSV‐ZDXYL‐China‐2018‐1 in pigs. The viral challenge test showed that PRRSV‐ZDXYL‐China‐2018‐1 infection can cause persistent fever, moderate dyspnoea, serum viraemia and interstitial pneumonia in piglets. The levels of viral loads in serum and PRRSV‐specific antigen were also detected in lung tissues were used one‐step Taq‐Man RT‐qPCR and Immunohistochemistry, respectively. At 28dpi, the level of specific antibodies was increased among infected piglets. Importantly, the new virus appeared be a moderately virulent isolate with pathogenicity compared to HP‐PRRSV strain LQ (JXA1‐like strain). Histological examination revealed severe monocyte haemorrhage and interstitial pneumonia associated with monocyte infiltration in the lung tissue of pigs infected with PRRSV‐ZDXYL‐China‐2018‐1 and LQ‐JXA1 strains. Immunohistochemistry (IHC) results showed positive brown‐red epithelial cells and macrophages in pig lungs. Therefore, it is critical to establish an effective strategy to control the spread of PRRSV in China.