The prion protein-encoding gene (prnp) strongly influences the susceptibility of small ruminants to transmissible spongiform encephalopathies (TSEs). Hence, selective breeding programs have been implemented to increase sheep resistance to scrapie. For goats, epidemiological and experimental studies have provided some association between certain polymorphisms of the cellular prion protein (PrP C ) and resistance to TSEs. Among them, the Q/K polymorphism at PrP C codon 222 (Q/K 222 ) yielded the most promising results. In this work, we investigated the individual effects of the K 222 -PrP C variant on the resistance/susceptibility of goats to TSEs. For that purpose, we generated two transgenic mouse lines, expressing either the Q 222 (wild type) or K 222 variant of goat PrP C . Both mouse lines were challenged intracerebrally with a panel of TSE isolates. Transgenic mice expressing the wildtype (Q 222 ) allele were fully susceptible to infection with all tested isolates, whereas transgenic mice expressing similar levels of the K 222 allele were resistant to all goat scrapie and cattle BSE isolates but not to goat BSE isolates. Finally, heterozygous K/Q 222 mice displayed a reduced susceptibility to the tested panel of scrapie isolates. These results demonstrate a highly protective effect of the K 222 variant against a broad panel of different prion isolates and further reinforce the argument supporting the use of this variant in breeding programs to control TSEs in goat herds. IMPORTANCEThe objective of this study was to determine the role of the K 222 variant of the prion protein (PrP) in the susceptibility/resistance of goats to transmissible spongiform encephalopathies (TSEs). Results showed that transgenic mice expressing the goat K 222 -PrP polymorphic variant are resistant to scrapie and bovine spongiform encephalopathy (BSE) agents. This protective effect was also observed in heterozygous Q/K 222 animals. Therefore, the single amino acid exchange from Q to K at codon 222 of the cellular prion protein provides resistance against TSEs. All the results presented here support the view that the K 222 polymorphic variant is a good candidate for selective breeding programs to control and eradicate scrapie in goat herds.
It has been reported that suboptimal in vitro culture (IVC) of mouse embryos can affect the postnatal expression of epigenetically sensitive alleles, resulting in altered postnatal growth, organ dimensions, health, and behavior in the offspring. Although these detrimental impacts on the offspring are well described, the relative contribution of the IVC-produced fathers is unclear. In this work, we have analyzed if suboptimal IVC (achieved by altering the culture medium by the addition of FCS) can affect male fertility and if organ size and glucose clearance, two of the adverse effects produced by suboptimal IVC conditions, were transmitted to the next two generations. IVC-produced males had lower sperm concentrations (5.8 × 10(6) spermatozoa in IVC vs. 14.5 × 10(6) spermatozoa in control), and these sperm exhibited decreased overall motility (49.6% vs. 72.8% in control) and progressive motility (22.6% vs. 32.2% in control). Fertility tests demonstrated that the percentage of pregnancies was reduced for IVC males (35% for IVC-produced males vs. 86% for in vivo controls). These features were related to a modified gene expression pattern in adult male testes, showing an altered gene expression in genes involved in DNA repair and apoptosis that was confirmed by TUNEL assay. Regarding the IVC related adverse phenotype transmitted to offspring, male glucose intolerance was shown only in F1 and F2 male but not female offspring. The same occurred with male abnormalities in the organ size of the liver, which were transmitted to F1 and F2 males but not to F1 females; moreover, analysis of the F0, F1, and F2 males revealed greater coefficients of variance in body weight and glucose intolerance than the control group. Finally, we analyzed, through gene silencing, the effect of IVC on the mRNA expression at the blastocyst stage for 11 known gene expression modifiers of epigenetic reprogramming. Suboptimal IVC reduced the expression of Kap1, Sox2, Hdac1, Dnmt1, and Dnmt3a, suggesting a molecular epigenetic role for gene expression modifiers in the origin and transmission of these abnormal phenotypes.
Cellular prion protein (PRNP) is a glycoprotein involved in the pathogenesis of transmissible spongiform encephalopathies (TSEs). Although the physiological function of PRNP is largely unknown, its key role in prion infection has been extensively documented. This study examines the functionality of PRNP during the course of embryoid body (EB) differentiation in mouse Prnp-null (KO) and WT embryonic stem cell (ESC) lines. The first feature observed was a new population of EBs that only appeared in the KO line after 5 days of differentiation. These EBs were characterized by their expression of several primordial germ cell (PGC) markers until Day 13. In a comparative mRNA expression analysis of genes playing an important developmental role during ESC differentiation to EBs, Prnp was found to participate in the transcription of a key pluripotency marker such as Nanog. A clear switching off of this gene on Day 5 was observed in the KO line as opposed to the WT line, in which maximum Prnp and Nanog mRNA levels appeared at this time. Using a specific antibody against PRNP to block PRNP pathways, reduced Nanog expression was confirmed in the WT line. In addition, antibody-mediated inhibition of ITGB5 (integrin αvβ5) in the KO line rescued the low expression of Nanog on Day 5, suggesting the regulation of Nanog transcription by Prnp via this Itgb5. mRNA expression analysis of the PRNP-related proteins PRND (Doppel) and SPRN (Shadoo), whose PRNP function is known to be redundant, revealed their incapacity to compensate for the absence of PRNP during early ESC differentiation. Our findings provide strong evidence for a relationship between Prnp and several key pluripotency genes and attribute Prnp a crucial role in regulating self-renewal/differentiation status of ESC, confirming the participation of PRNP during early embryogenesis.
It is well known that transit through the epididymis involves an increase in the compaction of sperm chromatin, which acquires fully condensed status at the caput epididymidis. The purpose of this study was to compare the terminal deoxyribonucleotidyl transferase-mediated dUTP nick end-labelling (TUNEL) assay, the comet assay, the sperm chromatin structure assay (SCSA) and the sperm chromatin dispersion (SCD) test by analysing spermatozoa from the caput and cauda epididymidis in order to demonstrate the ability of each technique to discriminate between different degrees of sperm maturity related to chromatin compaction and DNA fragmentation. Our results suggest that some populations of DNA-fragmented spermatozoa associated with immature sperm can only be identified using the comet assay and the SCSA but not with the SCD test or the TUNEL assay.
The cell wall integrity pathway (CWI) plays an important role in the biogenesis of the cell wall in Candida albicans and other fungi. In the present work, the C. albicans MKK2 gene that encodes the putative MAPKK of this pathway was deleted in different backgrounds and the phenotypes of the resultant mutants were characterised. We show here that Mkk2 mediates the phosphorylation of the Mkc1 MAPK in response to cell wall assembly interfering agents such as zymolyase or tunicamycin and also to oxidative stress. Remarkably, mkk2 and mkc1 mutants display related but distinguishable- cell wall associated phenotypes and differ in the pattern of MAPK phosphorylation under different stress conditions. mkk2 and mkc1 mutants display an altered expression of GSC1, CEK1 and CRH11 genes at different temperatures. Combined deletion of MKK2 with HST7 supports a cooperative role for the Cek1-mediated and CWI pathways in regulating cell wall architecture under vegetative growth. However, and in contrast to Mkc1, Mkk2 does not seem to play a role in the virulence of C. albicans in the mouse systemic model or the Galleria mellonella model of infection.
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