A large intragenic deletion in the CLCN1 gene causes Hereditary Myotonia in pigs

Mutations in the CLCN1 gene are the primary cause of non-dystrophic Hereditary Myotonia in several animal species. However, there are no reports of Hereditary Myotonia in pigs to date. Therefore, the objective of the present study was to characterize the clinical and molecular findings of Hereditary Myotonia in an inbred pedigree. The clinical, electromyographic, histopathological, and molecular findings were evaluated. Clinically affected pigs presented non-dystrophic recessive Hereditary Myotonia. Nucleotide sequence analysis of the entire coding region of the CLCN1 gene revealed the absence of the exons 15 and 16 in myotonic animals. Analysis of the genomic region flanking the deletion unveiled a large intragenic deletion of 4,165 nucleotides. Interestingly, non-related, non-myotonic pigs expressed transcriptional levels of an alternate transcript (i.e., X2) that was identical to the deleted X1 transcript of myotonic pigs. All myotonic pigs and their progenitors were homozygous recessive and heterozygous, respectively, for the 4,165-nucleotide deletion. This is the first study reporting Hereditary Myotonia in pigs and characterizing its clinical and molecular findings. Moreover, to the best of our knowledge, Hereditary Myotonia has never been associated with a genomic deletion in the CLCN1 gene in any other species.

A regulated NH2-terminal Sgk1 variant with enhanced function is expressed in the collecting duct

Sgk1 is a relatively unstable kinase that regulates epithelial Na+ transport in the distal nephron of the kidney. We identified a 5′ variant alternate transcript of human Sgk1 (Sgk1_v3) that is expressed in the connecting tubule and collecting duct, is regulated by aldosterone and insulin, and is predicted to encode an NH2-terminal variant Sgk1 isoform, Sgk1_i3. Sgk1_i3 contains a polybasic motif, KKR, in its NH2 terminus that regulates ubiquitination and stability of the expressed protein in HEK293 cells. In Fisher rat thyroid, and mpkCCDc14 cells, Sgk1_i3 had a significantly greater effect on Na+ transport compared with Sgk1 and its stimulatory effect was dependent on the kinase domain. Sgk1_i3 increased the abundance of cleaved epithelial Na+ channel (ENaC) subunits at the cell surface, which was inhibited by coexpression of Nedd4–2. Together, the data demonstrate that a renally expressed Sgk1 isoform, Sgk1_i3, shows improved stability, is regulated by insulin and aldosterone, and stimulates ENaC activity when heterologously expressed in collecting duct cells.

An evolutionarily conserved N-terminal Sgk1 variant with enhanced stability and improved function

Sgk1 is an aldosterone-induced kinase that regulates epithelial sodium channel (ENaC)-mediated Na+ transport in the collecting duct and connecting tubule of the kidney. The NH2 terminus of Sgk1 contains instability motifs that direct the ubiquitination of Sgk1 resulting in a rapidly degraded protein. By bioinformatic analysis, we identified a 5′ variant alternate transcript of human Sgk1 (Sgk1_v2) that is widely expressed, is conserved from rodent to humans, and is predicted to encode an Sgk1 isoform, Sgk1_i2, with a different NH2 terminus. When expressed in HEK293 cells, Sgk1_i2 was more abundant than Sgk1 because of an increased protein half-life and this correlated with reduced ubiquitination of Sgk1_i2 and enhanced surface expression of ENaC. Immunocytochemical studies demonstrated that in contrast to Sgk1, Sgk1_i2 is preferentially targeted to the plasma membrane. When coexpressed with ENaC subunits in FRT epithelia, Sgk1_i2 had a significantly greater effect on amiloride-sensitive Na+ transport compared with Sgk1. Together, the data demonstrate that a conserved NH2-terminal variant of Sgk1 shows improved stability, enhanced membrane association, and greater stimulation of epithelial Na+ transport in a heterologous expression system.

Disruption of imprinting in cloned mouse fetuses from embryonic stem cells

Cloned mice typically display abnormal development, such as overgrowth of fetuses and placentae. Quantitative expression analysis of eight imprinted genes (H19, Igf2, Igf2r, Air, Peg1/Mest, Peg3, Nuronatin (Nnat) and Ndn) and an alternate transcript of Igf2 (P0) in embryonic stem cloned fetuses and placentae at days 9.5, 12.5 and 17.5 after mating was carried out by real time PCR to investigate whether epigenetic modification of imprinted genes is responsible for overgrowth of the fetus and placental hypertrophy. In addition, the methylation pattern through the bisulphite sequencing method in differentially methylated regions of H19 and Igf2r was examined in day 9.5 fetuses and placentae. The results showed clearly that the expression of H19 gene decreased in cloned fetuses at days 12.5 and 17.5 after mating and in placentae at day 17.5 after mating, and Igf2 was also repressed in fetuses at days 9.5 and 12.5 after mating and in placentae at day 17.5 after mating. In contrast, the transcription of P0, which is a placental-specific transcript variant of Igf2, increased at more than four times the control in cloned placenta at day 12.5 after mating. Day 9.5 fetuses that have developed normally revealed only hypermethylated alleles in the H19 differently methylated region (DMR), and both hyper- and hypomethylated alleles in the Igf2r DMR2. These results show that inappropriate reprogramming in some imprinted genes affects the development of cloned embryos, and that aberrant P0 Igf2 transcription in particular may cause the overgrowth of cloned fetuses and placentae.