Intron 1 mediated regulation of bovine prion protein gene expression: Role of donor splicing sites, sequences with potential enhancer and suppressor activities

Prion protein plays a key role in the pathogenesis of transmissible spongiform encephalopathies. Because changes in expression of the prion protein gene (PRNP) alter the incubation time and severity of prion diseases. Our previous work revealed a strong association between the promoter (spanning base pairs (bp) −88 to −30) and intron 1 (spanning bp +114 to +892) that leads to optimum expression of the bovine PRNP. Here, we employed two mutation analysis strategies (deletion and insertion) and two reporter assay systems (luciferase and GFP expression) to define the regulatory domains within intron 1 and further elucidate its role in regulating the promoter activity of the bovine prion protein gene. We identified DNA sequences with potential suppressor and enhancer activities within the 5′ end of intron 1. Moreover stability analyses for PRNP mRNAs demonstrated that splicing sites and mechanism are critical for bovine PRNP expression.     

Polymorphism of the prion protein gene (<Emphasis Type="Italic">PRNP</Emphasis>) in Polish cattle affected by classical bovine spongiform encephalopathy

Recent attempts to discover genetic factors affecting cattle resistance/susceptibility to bovine spongiform encephalopathy (BSE) have led to the identification of two insertion/deletion (indel) polymorphisms, located within the promoter and intron 1 of the prion protein gene PRNP, showing a significant association with the occurrence of classical form of the disease. Because the effect of the polymorphisms was studied only in few populations, in this study we investigated whether previously described association of PRNP indel polymorphisms with BSE susceptibility in cattle is also present in Polish cattle population. We found a significant relation between the investigated PRNP indel polymorphisms (23 and 12 bp indels), and susceptibility of Polish Holstein-Friesian cattle to classical BSE (P < 0.05). The deletion variants of both polymorphisms were related to increased susceptibility, whereas insertion variants were protective against BSE.     

Cloning and polymorphism analysis of prion protein gene in domestic bactrian camel in China

Up to now, little is known about the prion protein gene (PRNP) of domestic bactrian camels, and no polymorphisms of the bactrian camel PRNP have been analyzed or reported. In this study, we cloned and analyzed the PRNP sequences of 89 domestic bactrian camels. The results showed that the amino acid sequence of bactrian camel PrP starts with the consensus sequence MVKSH, with almost identical amino acid sequence to the PrP of dromedary camels. A four octapeptide PHGGGWGQ repeat region follows a nonapeptide (PQGGGGWGQ) in the N-terminal of deduced amino acid sequence from residues 54 to 95. Polymorphisms of PRNP in both species of camels were observed in codons 16(A → V), 17(M → T), 120(N → S), 176(R → K), 215(I → V), 234(S → Y), 237(Y → S), and 239(Q → G) by comparing with other ruminants. The PrP gene nucleotide sequence alignments of bactrian camels (HQ204566.1 and HQ204567.1) showed high identity with dromedary camel (99.2%, 99.1%), sheep (91.9%, 91.8%) and cattle (91.8%, 91.6%). This study provides valuable data for future research on susceptibility or resistance of camels to prion diseases.     

Indels within promoter and intron 1 of bovine prion protein gene modulate the gene expression levels in the medulla oblongata of two Japanese cattle breeds

Genetic differences which exist in the prion protein gene (PRNP) have been reported to influence susceptibility of humans, sheep and goats to prion diseases. In cattle, however, none of the known coding polymorphisms has a direct effect on bovine spongiform encephalopathy (BSE). It has been reported that 23‐bp insertion/deletion (indel) polymorphisms within the promoter region have a tentative association to BSE susceptibility in German cattle, and a lower number of 24‐bp repeat units in the open reading frame (ORF) was reported to reduce BSE susceptibility in transgenic mice. In this study, because of the hypothesis that bovine PRNP promoter polymorphisms cause changes in PRNP expression, we genotyped PRNP polymorphisms in the promoter and intron 1 using 218 genomic DNA samples from two Japanese cattle breeds. We also analysed the expression levels of prion in 40 animals by quantification of real‐time PCR using mRNAs extracted from the medulla oblongata to study the relationship between PRNP genotypes and PRNP expression. We found a significant correlation between promoter indel polymorphisms and PRNP‐mRNA expression (P_0.0413) and therefore hypothesize that differences in polymorphisms could be one of the causes of differences in PRNP expression levels. We also report a novel difference in PRNP expression (P < 0.0001) between Japanese Black and Japanese Brown cattle breeds. There was no significant difference based on age and sex of the animals.     

Palmitate increases Nur77 expression by modulating ZBP89 and Sp1 binding to the Nur77 proximal promoter in pancreatic β-cells

Nur77 is a stress sensor in pancreatic β-cells, which negatively regulates glucose-stimulated insulin secretion. We recently showed that a lipotoxic shock caused by exposure of β-cells to the saturated fatty acid palmitate strongly increases Nur77 expression. Here, using dual luciferase reporter assays and Nur77 promoter deletion constructs, we identified a regulatory cassette between −1534 and −1512 bp upstream from the translational start site mediating Nur77 promoter activation in response to palmitate exposure. Chromatin immunoprecipitation, transient transfection and siRNA-mediated knockdown assays revealed that palmitate induced Nur77 promoter activation involves Sp1 recruitment and ZBP89 release from the gene promoter.     

Deletion/insertion polymorphism of the prion protein gene (<Emphasis Type="Italic">PRNP</Emphasis>) in Polish Holstein-Friesian cattle

The aim of the present study was to identify the deletion/insertion polymorphism of the bovine prion protein gene (PRNP) within the promoter sequence (23 bp), intron 1 (12 bp) and 3’ untranslated region (14 bp). DNA was isolated from blood of 234 randomly tested Polish Holstein-Friesian cows and from semen of 47 sires used for artificial insemination (AI) in 2004. No statistically significant differences were found in the frequency of genotypes and alleles between cows and breeding bulls in the 3 analysed polymorphic sites within thePRNP gene. Only 3 haplotypes were identified in sires and 4 haplotypes in cows.     

Deletion / insertion polymorphisms of the prion protein gene (<Emphasis Type="BoldItalic">PRNP</Emphasis>) in gayal (<Emphasis Type="BoldItalic">Bos frontalis</Emphasis>)

Resistance to fatal disease bovine spongiform encephalopathy (BSE), due to misfolded prion protein in cattle, is associated with a 23-bp indel polymorphism in the putative promoter and a 12-bp indel in intron 1 of the PRNP gene. Gayal (Bos frontalis) is an important semiwild bovid species and of great conservation concern, but till today these indel polymorphisms have not been evaluated in gayals. Therefore, we collected 225 samples of gayals and evaluated the genetic indel polymorphism in the two regions of this PRNP gene. The results revealed high allelic frequencies of insertions at these indel sites: 0.909 and 0.667 for, respectively, the 23 bp and 12 bp indels, both also with significant genotype frequencies (\(\chi ^{2}\): 9.81; 23 bp and \(\chi ^{2}\): 43.56; 12 bp). At the same time, the haplotype data showed indel polymorphisms with extremely low deletion (0.01) in both regions of the PRNP gene. We compared these data with those reported for healthy and BSE-affected cattle (Bos taurus) breeds from two European countries, Germany and Switzerland, and significant difference (\(P\,{<}\,0.001\)) was observed between BSE-affected as well as the healthy cattle. Further, our data were also extensively compared with previous reports on BSE and highly significant (\(P\,{<}\,0.001\)) outcomes were observed. This result suggested negligible genetic susceptibility to BSE in gayals. To the best of our knowledge, this study is the first comprehensive deciphering information about the PRNP indel polymorphisms of 23 bp and 12 bp in gayals, a semiwild species of China.     

Correlation between grass carp (Ctenopharyngodon idella) resistance to grass carp reovirus and the genetic insert-deletion polymorphisms in promoter and intron of RIG-I gene

RIG-I (retinoic acid-inducible gene I) is an essential cytosolic pathogen recognition receptor that binds to a variety of viral RNA or DNA to induce type I interferons. In the present study, insert–deletion polymorphisms in promoter and introns of CiRIG-I (Ctenopharyngodon idella RIG-I) were explored, their associations with resistance/susceptibility to grass carp reovirus (GCRV) were analyzed. To this end, genomic sequence of CiRIG-I gene was obtained, and twenty pairs of primers were prepared for the detection of insert–deletion polymorphisms. Five insert–deletion mutations were found, a 2-bp mutation and an 8-bp mutation existed in the promoter and other three sizes in 74 bp, 146 bp and 53 bp were sited in the intron 8. After a challenge experiment, only the genotype and allele of − 740 insert–deletion mutation in the promoter and allele of 6804 insert–deletion mutation were significantly associated with resistance/susceptibility to GCRV among the five mutations (P < 0.05). To further identify this correlation, another independent challenge test was carried out. The result revealed that the cumulative mortality in ins/ins genotype individuals (43.75%) at − 740 insert–deletion mutation was significantly lower than that in ins/del (72.09%) and del/del (74.19%) genotypes (P < 0.05). Linkage disequilibrium and haplotype analysis showed 6610 insert–deletion mutation and 6804 insert–deletion mutation were linkage disequilibrium. The haplotype ins–ins (6610ins–6804ins) was significantly susceptible to GCRV, and ins–del (6610ins–6804del) was significantly resistant to GCRV (P < 0.05). Those could be potential gene markers for the future molecular selection of strains that are resistant to GCRV.