Before 2012, the subfamily Coronavirinae included three genera (Alphacoronavirus, Betacoronavirus and Gammacoronavirus). However, in 2012, an emerging genus, Deltacoronavirus, was found in many animal species including swine from Hong Kong. At present, more than five different coronaviruses have been described in swine populations. Among them, porcine epidemic diarrhea virus (PEDV), transmissible gastroenteritis virus (TGEV), and porcine respiratory coronavirus (PRCV) belong to the genus Alphacoronavirus; meanwhile, porcine hemagglutinating encephalomyelitis virus (PHEV) and Porcine deltacoronavirus (PDCoV) are assigned to the genus Betacoronavirus and the genus Deltacoronavirus, respectively. Numerous studies have shown that more than half of porcine coronaviruses (including PDCoV) were enteropathogenic and caused acute diarrhea and vomiting in pigs, which resulted in huge economic losses for the global swine industry [2–6].
Currently, PDCoV has been reported in Hong Kong, North America, Mexico, South Korea, Thailand and some provinces of China [1, 7–19]. Despite recent progress, little is known about the prevalence and epidemiology of PDCoV in southern China (including Guangdong province, Hainan province, and Guangxi autonomous region), where major swine production is operated. Therefore, the aim of this study was to investigate the prevalence and sequence properties of PDCoV in this region.
A total of 390 fecal samples (Table 1) were collected from 15 commercial swine farms with reported diarrhea in southern China. Farms A, D, E, J-O were from Guangdong province, Farms B, F, G were from Hainan province, and farms C, H, I were the Guangxi autonomous region. Farms A-I derived 30 samples with the following arrangement: ten samples from suckling piglets (<3 weeks old), ten samples from nursing piglets (between 3 and 9 weeks old), and ten samples from fattening piglets (>9 weeks old). The samples of farms A-I were collected between July and August 2015 and stored at −80 °C until further use. However, the samples of farms J-O were archived samples from 2012 to 2014. Prior to viral RNA extraction, fecal samples were diluted one time using Phosphate Buffered Saline (PBS) (pH: 7.4). The supernatants were then collected by centrifugation at 5000 × g for 5 min. 200 μl of clarified supernatants was used to extract viral RNA following the manufacturer’s recommendations (Axygen Scientific Inc.). RNA samples were stored at −80 °C until further analysis.
Reverse transcription polymerase chain reaction (RT-PCR) detection
To detect PDCoV genome in collected fecal samples, the previously reported RT-PCR primers (41 F: 5’-TTTCAGGTGCTCAAAGCTCA-3’ and 735R: 5’-GCGAAAAGCATTTCCTGAAC-3’) targeting the nucleocapsid (N) gene with reaction conditions (50 °C for 30 min and 95 °C for 15 min for the reverse transcription reaction, followed by 40 cycles of PCR amplification at 95 °C for 15 s, 55 °C for 45 s, and 72 °C for 1 min, with a final extension at 72 °C for 7 min) were used. In addition, molecular detection of the three diarrhea-related enteric viruses (Porcine epidemic diarrhea virus, PEDV; Porcine transmissible gastroenteritis virus, TGEV; Porcine rotavirus group C, Rota C) was performed in accordance with previous methods [20–22] for further evaluation of the possible co-infection status with PDCoV in investigated pig samples.
Amplification of the spike (S) and N genes
To perform in-depth sequence comparison and phylogenetic analysis with known reference sequences (Additional file 1: Table S1), the complete spike (S) and N genes of PDCoV-positive samples were amplified according to previously published methods. For amplification of the full-length S and N genes, previously reported RT-PCR primers (PDCoV-SF2: 5’-AGCGTTGACACCAACCTATT-3’ and PDCoV-SR2: 5’-TCGTCGACTACCATTCCTTAAAC-3’; PDCoV-NF1 : 5’-CCATC GCTCCAAG TCATTCT-3’ and PDCoV-NR1: 5’-TGGGTGGGTTTAACAGACATAG-3’) were used. PCR was carried out at 50 °C 30 min and 95 °C for 5 min, followed by 40 cycles of 98 °C for 10 s, 55 °C for 15 s, and 68 °C for 5 and 2 min for S and N genes, respectively; final extension was performed at 68 °C for 15 min. Positive amplicons were cloned into the pGM-19 T vector (Tiangen Inc. Beijing). Furthermore, all positive recombinant plasmids were submitted to a sequencing company (The Beijing Genomics Institute, BGI) and sequenced at least three times. Five S gene sequences and five N gene sequences were obtained (Additional file 1: Table S1), and have been submitted to GenBank database (accession numbers KU204694-KU204701, KX534090-KX534091).
Phylogenetic analysis of the S and N genes
Sequence alignment analysis was performed using the Clustal W program implemented in DNAStar software. A phylogenetic tree was then constructed by the neighbor-joining method using the Molecular Evolutionary Genetics Analysis (MEGA) software version 5.1 with 1000 bootstrap replications set at 1000. Moreover, the possible recombination event was evaluated in the S and N genes by recombination detection program (RDP) 3.34 software.
A total of 390 pig fecal samples, collected from 15 swine farms with reported diarrhea in southern China, were assessed for the presence of PDCoV and other viral enteric pathogens (PEDV, TGEV, and Rota C) by RT-PCR. As summarized in Table 1, the PDCoV genome was detected in specimens from 4 of 15 swine farms. Interestingly, the PDCoV genome was detected only in nursing piglets, and was absent in suckling piglets and fattening pigs. Although PDCoV was detected in each province/region of southern China, its overall prevalence in the investigated pigs of various age groups (n = 390) was relatively low (5/390, 1.28 %). The positive rate could be higher if only nursing piglets were included (5/150, 3.33 %). In contrast, the prevalence of PEDV, another porcine coronavirus causing epidemic diarrhea, was relatively higher (22.6 %, 88/390). In addition, PEDV was different from PDCoV in that it distributed similarly between nursing (36/150, 24 %) and suckling piglets (47/150, 31.3 %). Five fattening pigs from farms A, D, F and I were also tested positive for the PEDV genome. We also examined whether pigs with diarrhea harbored other enteric viruses such as TGEV and Rota C. Our results showed that the low detection rates (1.54 %, 5/390 for TGEV vs 1.28 %, 6/390 for Rota C) of the two pathogens were present in those pig samples. Intriguingly, co-infection of pigs by PDCoV and PEDV was observed (Table 1). All PDCoV positive nursing piglets were also tested positive for PEDV, thereby indicating a 100 % co-infection rate.
Sequence comparison and phylogenetic analysis of the S gene of PDCoVs
The full-length sequences of S genes in five PDCoV-positive samples from the four different farms were amplified and designated provisionally CH/GD01/2015, CH/GD02/2015, CH/GD03/2015, CH/HN01/2015, and CH/GX01/2015, respectively. Sequencing results showed that they were composed of 3480 nucleotides (nt). Compared to all published American and individual Asian strains (including HKU15-44, CHN-AH-2004, KNU14-04, PDCoV/Swine/Thailand/S5015L/2015 and PDCoV/Swine/Thailand/S5011/2015), a 3-nt deletion in the S gene was identified in the five current PDCoV strains, six other Chinese viral strains and one Thai viral strain reported previously (Additional file 1: Table S1) [5, 17, 18]. Sequence alignment results revealed that CH/GD01/2015, CH/GD02/2015, CH/GD03/2015, CH/HN01/2015 and CH/GX01/2015 had >99.9 % homology in the S gene nucleotide sequence, indicating these five viral strains evolved from the same ancestor (Table 2). Further analysis showed that the five viruses reported in this study had the highest nucleotide identity (98.9 to 99.5 %) with a Jiangxi strain (PDCoV/CHJXNI2/2015) isolated from Jiangxi province bordering with the northern region of Guangdong province, and possessed the lowest nucleotide similarity (95.4 to 95.9 %) with PDCoV/Swine/Thailand/S5011/2015 and PDCoV/Swine/Thailand/S5015L/2015, isolated from Thailand (Table 2). From the above data, phylogenetic analysis of the S gene showed that the current PDCoVs circulating in southern China were most closely related to other Chinese PDCoV isolates than to those isolated previously from USA, South Korea and Thailand (Fig. 1). In addition, in the S gene, any possible recombinant events were not detected among those PDCoV strains.
Sequence comparison and phylogenetic analysis of the N gene of PDCoVs
Similarly, N gene sequences of all five PDCoV-positive samples were identified as 1029 nt in size. Sequence alignment results suggested that there was no deletion or insertion in N gene regions (Additional file 1: Table S1). Consistent with the data of S gene, multiple sequence alignment results of N gene showed that CH/GD01/2015, CH/GD02/2015, CH/GD03/2015, CH/HN01/2015 and CH/GX01/2015 had the highest nucleotide homology (99.1 to 99.7 %) with PDCoV/CHJXNI2/2015, and the lowest nucleotide homology (96.9 to 97.1 %) with PDCoV/Swine/Thailand/S5011/2015 and PDCoV/Swine/Thailand/ S5015L/2015 (Table 2). In addition, in the phylogenetic tree based on N gene, PDCoVs were divided into three main branches (Chinese branch, American branch and Thai branch). The five viral isolates reported from this work were clustered together within the Chinese branch (Fig. 2). Moreover, there were no any possible recombinant events occurring at the N gene of those PDCoV strains.
Epidemiology of PDCoVs
PDCoV was first identified by Deltacoronavirus specific-PCR in rectal swabs of pigs (10.1 %, 17/169) with unknown healthy status in Hong Kong. Then, PDCoV emerged in United States, China, South Korea and Thailand [5, 17, 18]. In most of studies, excluding PEDV, TGEV and porcine rotavirus, PDCoV, as an important enteric pathogen, was detected in clinical samples from pigs with diarrhea [9–12, 23]. In addition, it was confirmed experimentally that less than two-week old piglets were susceptible to PDCoV, which caused mild to moderate diarrhea as well as macroscopic and microscopic lesions in small intestines of conventional piglets (5-day-old), and severe diarrhea, vomiting, fecal shedding of virus, and severe atrophic enteritis in gnotobiotic pigs (11- to 14-day-old) [2, 3]. The data further confirmed that PDCoV were enteropathogenic in pigs. Meanwhile, PEDV or rotavirus showed higher detection rates in PDCoV-positive samples compared with other TGEV and rotavirus [8, 13–15, 24]. As shown above, co-infection of PDCoV and PEDV occurred in nursing piglets (Table 1), indicating that the diarrhea-related pathogens were quite complex clinically and not easy to control in the field. Moreover, in the two recent studies, PDCoV was shown to have higher infectivity in sows with diarrhea (81.0 %, 34/42) than nonclinical counterparts (23.5 %, 4/17) [8, 15], which might imply that sows often carry PDCoV. And further, it could result in the transmission of PDCoV from sows to the foetus and even newborn piglets, although the pathogenesis mechanism of PDCoV remains unclear.
To further understand the origin of PDCoV, some retrospective studies were made using PCR and enzyme-linked immunosorbent assay (ELISA) [24–26]. In Dong et al. study, 2 of 6 samples collected from Anhui Province of China in 2004 were positive for PDCoV, up to now, it was the most ancient time for the detection of PDCoV in China. Meanwhile, PDCoV could date back to August 2013 in United States, where only 3 PDCoV-samples were detected using PCR in archived samples. As for serology of PDCoV, anti-PDCoV IgG antibodies could date back to 2010 using an indirect anti-PDCoV IgG ELISA based on the putative S1 portion of the spike protein. The above studies indicated that PDCoV could have circulated in China at least since 2004 and in United States since 2010. Maybe, due to limted samples in the present study, we did not detect PDCoV in pig samples collected from Guangdong province between 2012 and 2014. Although Asian leopard cat coronavirus (GenBank accession no. EF584908) was close to PDCoV in the phylogenetic trees (Figs. 1 and 2), in the future, more epidemiological surveys should be warranted to uncover the origin of PDCoV.
At the territory of China, Southern China mainly includes Guangdong province, Hainan province and the Guangxi autonomous region. Although molecular detection of PDCoV was performed in these regions [23, 24], little information was available on PDCoV prevalence. In a study by Chen et al., an overall positive-PDCoV rate of 23.4 % (15/64) was obtained in all samples collected from Guangdong, Shanxi and Hubei provinces. However, more detailed data of PDCoV was not available in Guangdong province. Meanwhile, in the study from Dong et al., only four archived samples from the Guangxi autonomous region were examined, but all negative for PDCoV. In this study, we demonstrated that PDCoV circulated and was co-infected by PEDV on those swine farms in Guangdong province, Hainan province and the Guangxi autonomous region, which further contributed to the epidemiology of PDCoV in these regions despite the relatively low prevalence.
Genetic diversity of PDCoVs
The first two reported full-length PDCoV genome sequences (HKU15-44 and HKU15-155) were 25, 437 nt and 25, 432 nt in length, respectively, and they had 99.1 % nucleotide similarity with each other. Moreover, further sequence alignment showed a 3-nt (TAA) insertion in the S gene and a 3-nt (TTA) insertion in the 3’ untranslated region (UTR) of HKU15-44 [1, 5]. During the past 3 years, PDCoV-associated swine enteric disease was paid great attention in the major pig producing countries, especilly United States and China. Up to May 2016, more than 30 complete PDCoV genome sequences were published in the GenBank database. All were generated in China and United States except for one sequence from South Korea and three sequences from Thailand [8–19]. The Korean strain, KNU14-04, had 25, 422 nt in length, with similar genome features (a 3-nt insertion in the S gene with 3, 483 nt and a 3-nt insertion in the 3’ UTR, respectively) to all American strains and the Chinese strain (HKU15-44). Comparing complete genomes of the remaining Chinese strains to the American, Thai and Korean counterparts, CHN-HB-2014, CHN-JS-2014, PDCoV/CHJXNI2/2015, CH/Sichuan/S27/2012, CH/SXD1/2015 and P23_15_TT_1115 only had the 3-nt (AAT) deletion in the S gene (3, 480 nt) [14, 23, 24], while CHN-AH-2004 only had the 3-nt (TAA) deletion in the 3’ UTR [5, 24]. In the present study, 3-nt insertion was not found in UTR for our five obtained PDCoV (data not shown). Moreover, two additional unique features including a 6-nt (TTTGAA) deletion in the nonstructural protein (nsp) 2 region and a 9-nt (GCCGGTTGG) deletion in the nsp 3 region were also found in CH/Sichuan/S27/2012. However, for Thai viral isolates, they owned one additional unique nucleotide (C) insertion in the 3’ UTR [17, 18]. The biological significance of these naturally occurring deletions or insertions in PDCoV biology and pathogenesis warrants further investigations.
In this study, five S and five N gene sequences, respectively, were obtained to evaluate wherever genetic diversity of PDCoVs existed in southern China. Our results showed that these five S and five N gene sequences were more closely related to Chinese strains, and all clustered together in the phylogenetic tree (Table 2, Figs. 1 and 2). However, CH/GD01/2015 and CH/GD02/2015, reported in this study, originated from the same pig farm in Guangdong province, but had 48 nt and 12 nt differences in the S and N genes, respectively. The observed 48 nucleotide changes in the S gene made these viruses differ by 25 amino acid residues (Additional file 2: Table S2). For the N gene, the 12 nucleotide changes among these viruses resulted in 3 amino acid substitutions (Additional file 2: Table S2). Among them, 18 of 25 amino acid differences occurred at the first two-third parts of S gene. Interestingly, in spite of amino acid mutation, both S and N protein retained almost consistent amino acid properties (especially pH value) (Additional file 2: Table S2). Future study will address important roles of these polymorphisms in viral replication and pathogenesis. In addition, they were divided into two distinct small branches (Figs. 1 and 2). These findings suggested that PDCoVs in southern China have diverged from a common ancestor. Despite the emerging genetic diversity, overall, PDCoV prevalence is still largely restricted by the territory as demonstrated in Figs. 1 and 2.
For the two enteric coronaviruses (PEDV and TGEV) in pigs, the recombination events were often detected. However, most of them were from intra-recombination [27–30]. Recently, only one emerging recombinant/chimeric virus (named swine enteric coronavirus, SeCoV) was discovered in swine feces and resulted from inter-recombination of PEDV and TGEV, which had a TGEV backbone and a PEDV spike gene [31, 32]. In this study, there were no any possible recombinant events occurring in PDCoV strains. Maybe, the number and length of our obtained PDCoV sequences were limited. In the following study, the recombination event of PDCoV warrants further attentions.
This study reported the prevalence of PDCoV on swine farms in southern China. Phylogenetic analysis of currently circulating PDCoV strains in this region and other previously reported strains supported the theory of geographical clustering of PDCoV infection landscape. The origin of various PDCoVs in different countries and regions should be further studied.
ELISA, enzyme-linked immunosorbent assay; MEGA, molecular evolutionary genetics analysis; N, nucleocapsid; PBS, phosphate buffered saline; PDCoV, porcine deltacoronavirus; PEDV, porcine epidemic diarrhea virus; PHEV, porcine hemagglutinating encephalomyelitis virus; PRCV, porcine respiratory coronavirus; RDP, recombination detection program; Rota C, porcine rotavirus group C; RT-PCR, reverse transcription polymerase chain reaction; S, Spike; SeCoV, swine enteric coronavirus; TGEV, transmissible gastroenteritis virus; UTR, untranslated region