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 potential endemic strain in China: NADC34‑like porcine reproductive and respiratory syndrome virus

Porcine respiratory and reproductive syndrome virus (PRRSV) causes an economically important disease affecting commercial pork production worldwide. NADC34‐like PRRSV has had a strong impact on the U.S. and Peruvian pig industries in recent years and also emerged in northeastern China in 2017. However, the endemic status of NADC34‐like PRRSV in China is unclear. In this study, we examined 650 tissue samples collected from 16 Provinces in China from 2018 to 2019. Six NADC34‐like PRRSV strains were detected in samples from three Provinces, and the complete genomes of four of these strains were sequenced. Phylogenetic analysis showed that these novel PRRSV strains belong to sublineage 1.5 (or NADC34‐like PRRSV), forming two groups in China. Sequence alignment suggested that these novel strains share the same 100‐aa deletion in the Nsp2 protein that was identified in IA/2014/NADC34 isolated from the United States in 2014. Recombination analysis revealed that five of eight complete genome sequences are derived from recombination between IA/2014/NADC34 and ISU30 or NADC30. The number and distribution of NADC34‐like PRRSVs is increasing in China. Importantly, compared with the currently endemic strain NADC30‐like PRRSV, NADC34‐like PRRSV has the potential to be an endemic strain in China. This study will help us understand the epidemic status of NADC34‐like PRRSV in China and provide data for further monitoring this type of PRRSV in China.     

Porcine reproductive and respiratory syndrome virus NADC30‐like strain accelerates Streptococcus suis serotype 2 infection in vivo and in vitro

Porcine reproductive and respiratory syndrome (PRRS), an economically significant pandemic disease, commonly results in increased impact of bacterial infections, including those by Streptococcus suis (S. suis). In recent years, PRRS virus (PRRSV) NADC30‐like strain has emerged in different regions of China, and coinfected with S. suis and PRRSV has also gradually increased in clinical performance. However, the mechanisms involved in host innate responses towards S. suis and their implications of coinfection with NADC30‐like strain remain unknown. Therefore, the pathogenicity of NADC30‐like strain and S. suis serotype 2 (SS2) coinfection in vivo and in vitro was investigated in this study. The results showed that NADC30‐like increased the invasion and proliferation of SS2 in blood and tissues, resulting in more severe pneumonia, myocarditis, and peritonitisas well as higher mortality rate in pigs. In vitro, NADC30‐like strain increased the invasion and survival of SS2 in porcine alveolar macrophages (PAM) cells, causing more drastic expression of inflammatory cytokines and activation of NF‐ĸB signalling. These results pave the way for understanding the interaction of S. suis with the swine immune system and their modulation in a viral coinfection.     

A novel NADC30‐like porcine reproductive and respiratory syndrome virus (PRRSV) plays a limited role in the pathogenicity of porcine circoviruses (PCV2 and PCV3) and PRRSV co‐infection

Co‐infection of porcine reproductive and respiratory syndrome virus (PRRSV) and porcine circoviruses (PCVs) is commonly observed under field conditions and elicits more severe diseases than any singular infection. In this study, the co‐infection of PRRSV, PCV2 and PCV3 was analyzed in tissue samples collected from 150 pigs from April 2016 to April 2018. PRRSV, PCV2 and PCV3 was detected in 55 (36.67%), 43 (28.67%) and 3 (2%) of 150 pigs respectively. Remarkably, one lung sample (SD17‐36) collected from a diseased pig was co‐infected with PRRSV, PCV2 and PCV3. The complete genomes of SD17‐36 viruses of PRRSV, PCV2 and PCV3 were determined, which belong to the subgroups of NADC30‐like PRRSV, PCV2d and PCV3a respectively. Sequence comparison showed that PRRSV SD17‐36 isolate contains a N33 deletion in GP5. Animal challenge study showed that the novel NADC30‐like PRRSV SD17‐36 isolate is low pathogenic. Our results indicate that the co‐infection of PRRSV and PCVs might cause diseases even when PRRSV plays a limited role in the pathogenicity of the co‐infection.     

Genetic characterization of a novel recombinant PRRSV2 from lineage 8, 1 and 3 in China with significant variation in replication efficiency and cytopathic effects

There are four major porcine reproductive and respiratory syndrome virus 2 (PRRSV2) lineages circulating in China based on classification system, including lineages 1 (NADC30‐like), 3 (QYYZ‐like), 5.1 (VR2332‐like) and 8 (JXA1‐like/CH‐1a‐Like), which leads to the potential recombination. In the present study, a novel variant of PRRSV2 strain named JS18‐3 was isolated from piglets suffering severe breathing difficulties in Jiangsu Province of China in 2018. Full‐length genome analysis indicated that JS18‐3 shared 86.5%, 87.9%, 84.2%, 82.2% and 86.4% nucleotide similarity with PRRSVs CH‐1a, JXA1, VR2332, QYYZ and NADC30, respectively. 4871–6635 of JS18‐3 shared the highest identity of 99.3% in nucleotide sequence with HP‐PRRSV representative strain JXA1 indicating ongoing evolution to HP‐PRRSV. JS18‐3 was classified into classical lineage 8 of PRRSV2 based on phylogenetic analysis of complete genome and ORF5. Genomic break points in structural (ORF3) and non‐structural (NSP2, NSP3) regions of genomes were detected in recombination analysis. JS18‐3 is a recombinant isolate from lineages 8, 1 and 3. Replication enhancement and severe cytopathic effects caused by JS18‐3 were observed in Marc‐145 cells and porcine alveolar macrophages (PAMs) as compared to JX07, a typical strain of lineage 8. Pathogenicity results indicated that piglets inoculated with JS18‐3 presented persistent fever, dyspnoea, serious microscopic lung lesions and lymph node congestion. The study suggests that lineage 8 of PRRSV2 is involved in continuing evolution by genetic recombination and mutation leading to outbreaks in vaccinated pigs in China.     

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.     

Emergence of a novel highly pathogenic porcine reproductive and respiratory syndrome virus in China

From 2014 to 2015, four novel highly pathogenic PRRS virus (HP‐PRRSV) strains named 14LY01‐FJ, 14LY02‐FJ 15LY01‐FJ, and 15LY02‐FJ were isolated from high morbidity (100%) and mortality (40%–80%) in piglets and sows in Fujian Province. To further our knowledge about these novel virus strains, we characterized their complete genomes and determined their pathogenicity in piglets. Full‐length genome sequencing analysis showed that these four isolates were closely related to type 2 (North American type, NA‐type) isolates, with 88.1%–96.3% nucleotide similarity, but only 60.6%–60.8% homology to the Lelystad virus (LV) (European type, EU‐type). The full length of the four isolates was determined to be 15017 or 15018 nucleotides (nt), excluding the poly(A) tail. Furthermore, the four isolates had three discontinuous deletions (aa 322–432, aa 483, and aa 504–522) within hypervariable region II (HV‐II) of Nsp2, as compared to the reference strain VR‐2332. This deletion pattern in the four isolates is consistent with strain MN184 and strain NADC30 isolated from America. Phylogenetic and molecular evolutionary analyses indicated that these virulent strains originated from a natural recombination event between the JXA1‐like HP‐PRRSV (JXA‐1 is one of the earliest Chinese HP‐PRRSV strains; sublineage 8.7) and the NADC30‐like (lineage 1) PRRSV. Animal experiments demonstrated that these four strains caused significant weight loss and severe histopathological lung lesions as compared to the negative control group. High mortality rate (40% or 80%) was found in piglets infected with any one of the four strains, similar to that found with other Chinese HP‐PRRSV strains. This study showed that the novel variant PRRSV was HP‐PRRSV, and it is therefore critical to monitor PRRSV evolution in China and develop a method for controlling PRRS.     

Development of universal and quadruplex real‐time RT‐PCR assays for simultaneous detection and differentiation of porcine reproductive and respiratory syndrome viruses

Porcine reproductive and respiratory syndrome virus 1 (PRRSV1) and 2 (PRRSV2) (including 3 major subtypes: classical (CA‐PRRSV2), highly pathogenic (HP‐PRRSV2) and NADC30‐like (NL‐PRRSV2)) are currently coexisting in Chinese swine herds but with distinct virulence. Reliable detection and differentiation assays are crucial to monitor the prevalence of PRRSV and to adopt effective control strategies. However, current diagnostic methods cannot simultaneously differentiate the four major groups of PRRSV in China. In this study, universal and quadruplex real‐time RT‐PCR assays using TaqMan‐MGB probes were developed for simultaneous detection and differentiation of Chinese PRRSV isolates. The newly developed real‐time RT‐PCR assays exhibited good specificity, sensitivity, repeatability and reproducibility. In addition, the newly developed real‐time RT‐PCR assays were further validated by comparing with a universal PRRSV conventional RT‐PCR assay on the detection of 664 clinical samples collected from 2016 to 2019 in China. Based on the clinical performance, the agreements between the universal and quadruplex real‐time RT‐PCR assays and the conventional RT‐PCR assay were 99.55% and 99.40%, respectively. Totally 90 samples were detected as PRRSV‐positive, including 2 samples that were determined to be co‐infected with NL‐PRRSV2 and HP‐PRRSV2 isolates by the quadruplex real‐time RT‐PCR assay. ORF5 sequencing confirmed the real‐time RT‐PCR results that 2, 6, 27 and 57 of the 92 sequences were PRRSV1, CA‐PRRSV2, NL‐PRRSV2 and HP‐PRRSV2, respectively. This study provides promising alternative tools for simultaneous detection and differentiation of PRRSV circulating in Chinese swine herds.     

Pathogenicity and Molecular Characterization of Emerging Porcine Reproductive and Respiratory Syndrome Virus in Vietnam in 2007

In 2007, Vietnam experienced swine disease outbreaks causing clinical signs similar to the ‘porcine high fever disease’ that occurred in China during 2006. Analysis of diagnostic samples from the disease outbreaks in Vietnam identified porcine reproductive and respiratory syndrome virus (PRRSV) and porcine circovirus type 2 (PCV‐2). Additionally, Escherichia coli and Streptococcus equi subspecies zooepidemicus were cultured from lung and spleen, and Streptococcus suis from one spleen sample. Genetic characterization of the Vietnamese PRRSV isolates revealed that this virus belongs to the North American genotype (type 2) with a high nucleotide identity to the recently reported Chinese strains. Amino acid sequence in the nsp2 region revealed 95.7–99.4% identity to Chinese strain HUN4, 68–69% identity to strain VR‐2332 and 58–59% identity to strain MN184. A partial deletion in the nsp2 gene was detected; however, this deletion did not appear to enhance the virus pathogenicity in the inoculated pigs. Animal inoculation studies were conducted to determine the pathogenicity of PRRSV and to identify other possible agents present in the original specimens. Pigs inoculated with PRRSV alone and their contacts showed persistent fever, and two of five pigs developed cough, neurological signs and swollen joints. Necropsy examination showed mild to moderate bronchopneumonia, enlarged lymph nodes, fibrinous pericarditis and polyarthritis. PRRSV was re‐isolated from blood and tissues of the inoculated and contact pigs. Pigs inoculated with lung and spleen tissue homogenates from sick pigs from Vietnam developed high fever, septicaemia, and died acutely within 72 h, while their contact pigs showed no clinical signs throughout the experiment. Streptococcus equi subspecies zooepidemicus was cultured, and PRRSV was re‐isolated only from the inoculated pigs. Results suggest that the cause of the swine deaths in Vietnam is a multifactorial syndrome with PRRSV as a major factor.     

Visual detection of porcine reproductive and respiratory syndrome virus using CRISPR‐Cas13a

Porcine reproductive and respiratory syndrome virus (PRRSV) has varied constantly and circulated in the pig industry worldwide. The prevention and control of porcine reproductive and respiratory syndrome (PRRS) is complicated. A visual, sensitive and specific diagnostic method is advantageous to the control of PRRS. The collateral cleavage activity of LwCas13a is activated to degrade non‐targeted RNA, when crRNA of LwCas13a bond to target RNA. The enhanced Cas13a detection is the combination of collateral cleavage activity of LwCas13a and recombinase polymerase amplification (RPA). In this study, the enhanced Cas13a detection for PRRSV was established. The novel method was an isothermal detection at 37°C, and the detection can be used for real‐time analysis or visual readout. The detection limit of the enhanced Cas13a detection was 172 copies/μl, and there were no cross‐reactions with porcine circovirus 2, porcine parvovirus, classical swine fever virus and pseudorabies virus. The enhanced Cas13a detection can work well in clinical samples. In summary, a visual, sensitive and specific nucleic acid detection method based on CRISPR‐Cas13a was developed for PRRSV.     

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 .     

Evidence of porcine circovirus‐like virus P1 in piglets with an unusual congenital tremor

Outbreaks of trembling and shaking were reported among pigs at two pig farms in Jiangsu Province, China. Serum and tissue samples tested positive for porcine circovirus‐like virus P1 and negative for classical swine fever virus, porcine circovirus type 2, astrovirus and porcine pestivirus using PCR/RT‐PCR and immunohistochemical techniques. High P1 viral genome loads were identified in sera, brain and lymph node tissue samples by qPCR. In addition, one of the most notable pathological changes was dissolution of the nucleus in Purkinje cells. The results of this study provide molecular evidence of an association between congenital tremor in pigs and P1 virus.     

Epidemiologic and Phylogenetic Characteristics of Porcine Reproductive and Respiratory Syndrome Viruses in Conventional Swine Farms of Jeju Island as a Candidate Region for PRRSV Eradication

Jeju island is the biggest island in Korea. The imports of pigs or their relatives from mainland Korea to this island has been banned since 1998. With this unique geographical and epidemiological context, epidemiology of porcine reproductive and respiratory syndrome virus (PRRSV) was investigated on the island. While all investigated farms showed 100% of seropositive rate for PRRSV, pigs on 37.2% (16/43) of the farms had viremia with type II PRRSV. The seropositive and viremia‐positive rates for PRRSV in 30‐ to 60‐day‐old pigs were significantly higher in the western area (‘swine farm complex’ area) than the eastern area (‘Scattered swine farm’ area) of Jeju island. When 21 ORF5 sequences obtained from viremic sera were phylogenetically analysed, lineage 5 and Kor (newly termed in this study) of type II PRRSV were only found in Jeju island without changes from a previous report (2002–2003). Because other lineages of type II PRRSV (lineage 1 and 3) and type I PRRSV have recently emerged in mainland Korea, the banning of pigs’ movement might be effective to protect the island from the introduction of these new PRRSV genotypes. Under this epidemiological condition (no introduction of new strains except for the modified‐live vaccine (MLV) strain), the positive selection sites were analysed based on ORF5 of the virus. The amino acid 58 of GP5 (located on the hypervariable region) was predicted as a strong positive selection site. Although 51.2% (22/43) of the investigated farms had applied MLV, field strains of type II PRRSV were still circulating with strong positive selection. However, the restricted population of type II PRRSV (lineage 5 and Kor) without introduction of type I PRRSV or the other lineages of type II PRRSV indicate that the island has an effective quarantine system, which would allow PRRSV eradication.     

Porcine circovirus‐like virus P1 in cattle,goats and rabbits in China

Porcine circovirus‐like virus P1, a novel single‐stranded circular DNA virus, is a potential causative agent of post‐weaning multisystemic wasting syndrome in swine. In this study, we detected P1 strains in serum samples from cattle, goats and rabbits suffering different clinical symptoms, in Jiangsu Province, China. We sequenced the whole genomes of six P1 strains, which showed 99.4%–100% nucleotide sequence similarity and were closely related to other porcine‐origin P1 isolates. The sequences of six non‐porcine‐origin P1 viruses were most closely phylogenetically related to other porcine‐origin P1 sequences. Therefore, the P1 virus has a wide host range in China.     

Selected Swine Viral Pathogens in Indoor Pigs in Spain. Seroprevalence and Farm‐Level Characteristics

A serosurvey on porcine reproductive and respiratory syndrome virus (PRRSV), swine influenza virus (SIV), Aujeszky’s disease virus gE protein (ADV gE), porcine parvovirus (PPV) and porcine circovirus type 2 (PCV2) was carried out in Spanish pig herds. The serosurvey consisted of two studies. First, a retrospective study assessed the proportion of seropositive boar, sow and fattening pig herds and their seroprevalences to PRRSV, SIV, ADV gE and PPV from 2003 to 2005 and to PCV2 from 2000 to 2005. Such information was obtained from routine serologic analyses from two veterinary diagnostic laboratory services. Second, a cross‐sectional study in sow and fattening pig herds from 44 farms (without vaccination interferences on serologic analyses) was performed to provide information on seroprevalences and co‐seropositivity to PRRSV, SIV, ADV gE and PCV2 (PPV was excluded because of widespread vaccination) and to elucidate their relationships with farm characteristics, management and productive parameters. Similar seroprevalences were observed in both studies, although some variations were obtained, probably because of vaccination schedules, number of tested sera, sampling age and regional variations. Percentage of PRRSV and SIV seropositive herds was over 85% for sows, around 80% for fatteners and around 50% for boar studs. The proportion of ADV gE seropositive sow herds decreased from 41% to 30% between 2003 and 2005, whereas such decrease was from 41% to 33% in fattening pig herds and from 13% to 4% in boar studs PCV2 antibodies were widespread as well as those against PPV; in the latter case, if antibodies were elicited by infection and/or vaccination was not assessed. Concurrent presence of PCV2, PRRSV and SIV antibodies was found in 89% and 66% sow and fattening herds, respectively. No statistical associations were obtained between seroprevalences or co‐seropositivity and farm characteristics, management or productive parameters.     

The retrospective identification and molecular epidemiology of porcine circovirus type 3 (PCV3) in swine in Thailand from 2006 to 2017

Porcine circovirus type 3 (PCV3) has recently been detected in pigs worldwide, with similar clinical manifestations to porcine circovirus‐associated disease (PCVAD) from porcine circovirus type 2 (PCV2) infection. Here, we report the identification and molecular epidemiology of PCV3 in swine in Thailand from clinical samples retrieved from 2006 to 2017. The epidemiological data revealed co‐infection with PCV2, PRRSV, and PCV2/PRRSV was common in our samples. Circulating PCV3 from this study shared a high similarity of nucleotide and deduced amino acid sequences of the partial capsid gene (96.7%–100% and 96.7%–100% respectively), indicated the genetic stability of PCV3 in Thailand. Phylogenetic analysis based on the capsid gene revealed scatter clustering with current PCV3 having no relation to the geographical origin of the virus strains. In this retrospective study, results have demonstrated that PCV3 has spread extensively within Thai swine from as early as 2006 and may also be involved in PRDC and PCVAD.     

Isolation and Characterization of a Moderately Virulent Classical Swine Fever Virus Emerging in China

Classical swine fever (CSF) is a devastating infectious disease of pigs caused by classical swine fever virus (CSFV). In China, CSF has been under control owing to extensive vaccination with the lapinized attenuated vaccine (C‐strain) since 1950s, despite sporadic or endemic in many regions. However, recently, CSF outbreaks occurred in a large number of swine herds in China. Here, we isolated 15 CSFV strains from diverse C‐strain‐vaccinated pig farms in China and characterized the genetic variations and antigenicity of the new isolates. The new strains showed unique variations in the E2 protein and were clustered to the subgenotype 2.1d of CSFV recently emerging in China in the phylogenetic tree. Cross‐neutralization test showed that the neutralizing titres of porcine anti‐C‐strain sera against the new isolates were substantially lower than those against both the highly virulent Shimen strain and the subgenotype 2.1b strains that were isolated in China in 2006 and 2009, respectively. In addition, experimental animal infection showed that the HLJZZ2014 strain‐infected pigs displayed lower mortality and less severe clinical signs and pathological changes compared with the Shimen strain‐infected pigs. The HLJZZ2014 strain was defined to be moderately virulent based on a previously established assessment system for CSFV virulence evaluation, and the virus shedding and the viral load in various tissues of the CSFV HLJZZ2014 strain‐infected pigs were significantly lower than those of the Shimen strain‐infected pigs. Taken together, the subgenotype 2.1d isolate of CSFV is a moderately virulent strain with molecular variations and antigenic alterations.     

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.     

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.