Evaluation of M307 of FUT1 gene as a genetic marker for disease resistance breeding of Sutai pigs.

Alpha (1,2) fucosyltransferase (FUT1) gene has been identified as a candidate gene for controlling the expression of the receptor for ETEC F18. The genetic variations in the position of M307 nucleotide in open reading frame of FUT1 have been proposed as a marker for selecting ETEC F18 resistant pigs. The polymorphisms of M307 in FUT1 of breeding base group for ETEC F18 resistance of Sutai pigs (Duroc × Meishan) was detected and their correlations to some immune indexes, growth and development ability, carcass traits and meat quality were also analyzed, which aimed to investigate feasibility of further breeding for diseases resistance based on M307 of FUT1 for Sutai pigs. After digested by Hin6 I, M307 of FUT1 gene could be divided into three kinds of genotypes, AA, AG, and GG. The frequencies were 0.235, 0.609, and 0.156, respectively. The results indicated that Sutai pigs with the AA genotype in M307 of FUT1 gene not only have relatively strong general disease resistance ability in piglets, but also have higher growth and development ability and stable carcass traits and meat quality. It is entirely feasible to raise the new strains of Sutai pigs resistant to Escherichia coli F18 based on genetic marker of the M307 position in FUT1gene.

The effect of mutation at M307 in FUT1 gene on susceptibility of Escherichia coli F18 and gene expression in Sutai piglets.

Escherichia coli F18 (ECF18) is a common porcine enteric pathogen. The pathogenicity of ECF18 bacteria depends on the existence of ECF18 receptor in the brush border membranes of piglet's small intestinal mucosa. Alpha (1) fucosyltransferase gene (FUT1) has been identified as the candidate gene controlling the adhesion to ECF18 receptor. The genetic variations in the position of M307 nucleotide in open reading frame of FUT1 have been proposed as a marker for selecting resistant pigs. The piglets were divided into three groups, AA, AG and GG, according to the genotypes present at M307 of FUT1. Small intestinal epithelium cells of piglets with AA, AG and GG genotypes were selected to test the adhesion capability of the wild type E.coli expressing F18ab fimbriae, the recombinant E. coli expressing F18ac fimbriae or the recombinant E. coli secreting and surface-displaying the FedF subunit of F18ab fimbriae, respectively. Here, we examined the distribution and expression of porcine FUT1 mRNA in different tissues in Sutai pigs using real-time PCR. The results showed that piglets with AA genotype show resistance, whereas piglets with GG or AG genotypes are sensitive to the pathogenic E. coli F18 in Sutai piglets. FUT1 was expressed in all the tissues that were examined, and the gene's expression was highest in the lungs. There was no significant difference in expression level among the three genotypes in the liver, lung, stomach and duodenum, where the gene expression was relatively high. The present analysis suggested that mutation at M307 in FUT1 gene determines susceptibility of small intestinal epithelium to E. coli F18 adhesion in Sutai piglet and the expression of FUT1 gene may be regulated by other factors or the mutation was likely to be in linkage disequilibrium with some cis-regulatory variants.

[Distributions of polymorphism of ADD1, MC4R, H-FABP gene, associated with IMF and BF in 3 populations in pig].

Different breeds of pigs varied in traits of meat quality, especially between local abroad varieties. Intramuscular fat content (IMF) and back fat thickness (BF) have extra difference between Chinese breeds and foreign breeds. We have known that polymorphism of H-FABP, MC4R and ADD1 gene associated relation with IMF or BF in recent research. The Meishan, Sutai and Duroc x Landrace x Yorkshair become experimental animal in this research. Result show three breeds have different IMF and BF because different distributions of polymorphism three genes. Meishan has particular genetic background, so it should be protected. The results of associated analysis show that the polymorphism of three genes was associated traits of IMF and BF, polymorphism of MC4R gene was not associated traits BF. The molecular marker can apply to pig breeding by molecular marker-assisted selection (MAS).

Relationship between the expression level of SLA-DQA and Escherichia coli F18 infection in piglets.

The expression of SLA-DQA was assayed by Real-time PCR to analyze the differential expression between ETEC F18-resistant and -sensitive post-weaning piglets, and then to compare the expression levels of SLA-DQA in 11 different tissues from 8-, 18-, 30- and 35-day-old ETEC F18-resistant piglets, which aimed at discussing the role of SLA-DQA in resistance to ETEC F18. The results showed that SLA-DQA is broadly expressed in 11 tissues with the highest expression level in lymph nodes, and a relatively higher expression level in lung, spleen, jejunum, and duodenum. In tissues of lymph node, lung, spleen, jejunum, and duodenum, the mRNA expression of SLA-DQA in resistant individuals was significantly higher than that in sensitive ones (P<0.05). In most tissues, the expression of SLA-DQA increased from 8 to 18 and 30 days (weaning day), and increased persistently to 35 days of post-weaning. Expression levels of SLA-DQA on 35 days in most tissues were significant higher than that on 8, 18 and 30 days (P<0.05). The results demonstrated that the resistance to ETEC F18 in post-weaning piglets is related to up-regulation of mRNA expression of SLA-DQA to a certain extent. The analysis suggested that SLA-DQA may be not the direct immune factor that resisted the Escherichia coli F18, but perhaps enhanced humoral immunity and cell immunity to reduce the transmembrane signal transduction of ETEC F18 bacterial LPS and then led to the resistance to ETEC F18 in piglets.