Immunochemical demonstration of a novel beta-subunit isoform of X, K-ATPase in human skeletal muscle

Recently we have identified mRNA encoding a hitherto unknown mammalian X,K-ATPase beta-subunit expressed predominantly in muscle tissue (Pestov, N. B. et al. (1999) FEBS Lett. 456, 243-248). Here we demonstrate the existence of the predicted protein, designated as beta(m) (beta(muscle)), in human adult skeletal muscle membranes using immunoblotting with beta(m)-specific antibodies generated against recombinant polypeptide formed by extramembrane beta(m) domains. The electrophoretic mobility of beta(m) was shown to be abnormally low due to the presence of Glu-rich sequences. In contrast to mature forms of other known X,K-ATPase beta-subunits, carbohydrate moiety of beta(m) is sensitive to endoglycosidase H and appears to be composed of short high-mannose or hybrid N-glycans. This finding argues in favor of an intracellular location of beta(m) in human skeletal muscle.     

Identification of a novel gene of the X,K-ATPase beta-subunit family that is predominantly expressed in skeletal and heart muscles.

We have identified the fifth member of the mammalian X,K-ATPase beta-subunit gene family. The human and rat genes are largely expressed in skeletal muscle and at a lower level in heart. The deduced human and rat proteins designated as beta(muscle) (beta(m)) consist of 357 and 356 amino acid residues, respectively, and exhibit 89% identity. The sequence homology of beta(m) proteins with known Na,K- and H,K-ATPase beta-subunits are 30.5-39.4%. Unlike other beta-subunits, putative beta(m) proteins have large N-terminal cytoplasmic domains containing long Glu-rich sequences. The data obtained indicate the existence of hitherto unknown X,K-ATPase (most probably Na,K-ATPase) isozymes in muscle cells.     

Betam,a structural member of the X,K-ATPase beta subunit family,resides in the ER and does not associate with any known X,K-ATPase alpha subunit

betam, a muscle-specific protein, is structurally closely related to the X,K-ATPase beta subunits, but its intrinsic function is not known. In this study, we have expressed betam in Xenopus oocytes and have investigated its biosynthesis and processing as well as its putative role as a chaperone of X,K-ATPase alpha subunits, as a regulator of sarcoplasmic reticulum Ca(2+)-ATPase (SERCA), or as a Ca(2+)-sensing protein. Our results show that betam is stably expressed in the endoplasmic reticulum (ER) in its core glycosylated, partially trimmed form. Both full-length betam, initiated at Met(1), and short betam species, initiated at Met(89), are detected in in vitro translations as well as in Xenopus oocytes. betam cannot associate with and stabilize Na,K-ATPase (NK), or gastric and nongastric H,K-ATPase (HK) alpha isoforms. betam neither assembles stably with SERCA nor is its trypsin sensitivity or electrophoretic mobility influenced by Ca(2+). A mutant, in which the distinctive Glu-rich regions in the betam N-terminus are deleted, remains stably expressed in the ER and can associate with, but not stabilize X,K-ATPase alpha subunits. On the other hand, a chimera in which the ectodomain of betam is replaced with that of beta1 NK associates efficiently with alpha NK isoforms and produces functional Na,K-pumps at the plasma membrane. In conclusion, our results indicate that betam exhibits a cellular location and functional role clearly distinct from the typical X,K-ATPase beta subunits.     

cDNA cloning of the beta-subunit of the rat gastric H,K-ATPase

A cDNA encoding the beta-subunit of the rat gastric H,K-ATPase has been identified using oligonucleotide probes based on the amino acid sequences of two peptides from the pig H,K-ATPase beta-subunit (Hall, K., Perez, G., Anderson, D., Gutierrez, C., Munson, K., Hersey, S. J., Kaplan, J. H., and Sachs, G. (1990) Biochemistry 29, 701-706). The nucleotide sequence of the 1.3-kilobase cDNA has been determined and the primary structure of the protein deduced. The protein consists of 294 amino acids and has an Mr of 33,625. The amino acid sequence of the H,K-ATPase beta-subunit is similar to those of the beta 1 (29% identity) and beta 2 (37% identity) subunits of the Na,K-ATPase. Based on the hydropathy profile it seems to have the same transmembrane organization as the Na,K-ATPase beta-subunit, with a single membrane-spanning domain near the amino terminus. Seven potential N-linked glycosylation sites are located in the putative extracellular regions of the protein. Northern blot analyses of poly(A)+ RNAs from 13 tissues demonstrate that the H,K-ATPase beta-subunit mRNA is expressed at high level in stomach and is not expressed in any of the other tissues.     

Accumulation of beta (m), a structural member of X,K-ATPase beta-subunit family, in nuclear envelopes of perinatal myocytes

Recently discovered muscle-specific beta(m) protein is structurally closely related to the X,K-ATPase beta-subunits. However, it has a number of unique properties such as predominant localization in intracellular stores and lack of association with known X,K-ATPase alpha-subunits on heterologous coexpression. In this study, the primary structure of mouse beta(m) was determined and developmental regulation of the gene (ATP1B4) was analyzed. The expression is first detected at day 14 of gestation, is sharply increased at day 16, and reaches its maximum at day 18. After birth, the expression quickly decreases and is hardly detectable in adult mice. A more detailed subcellular localization study was undertaken, and its results indicate that beta(m) not only is located in sarcoplasmic reticulum but is concentrated in nuclear envelopes of both prenatal and postnatal skeletal muscles. Immunohistochemical studies show that beta(m) is specific to myocytes and, at the subcellular level, many nuclear envelopes are intensively labeled in both fetal and newborn skeletal muscles. Accordingly, beta(m) is detected by immunoblotting in purified nuclei and nuclear membranes from neonatal skeletal muscles. On transfection of human rhabdomyosarcoma cell line RD, green fluorescent protein-tagged beta(m) resides intracellularly with significant enrichment in nuclear envelopes, whereas beta(m) with transmembrane domain deleted localizes in both cytoplasm and nucleoplasm. Nuclear beta(m) apparently is not in association with Na,K-ATPase because we never detected its alpha-subunit in myonuclear membranes. These results indicate that beta(m) has a specialized function in mammalian perinatal myocytes, different from functions of other X,K-ATPase beta-subunits. The unique temporospatial distribution of beta(m) protein expression suggests its important role in development of growing skeletal muscle.     

cDNA cloning of the beta-subunit of the human gastric H,K-ATPase.

A full-length cDNA clone encoding the human gastric H,K-ATPase (EC 3.6.1.36)beta-subunit was isolated from a human gastric mucosal lambda gt10 library using oligonucleotide probes which were based on the cDNA sequence from rat and rabbit H,K-ATPase beta-subunits. The insert was 1407 bp in length and encoded a polypeptide of 291 amino acids with a MW = 33,367 Da. It exhibited 84.2%, 85.6% and 81.3% identity to the H,K-ATPase beta-subunits of rabbit, pig and rat, respectively.     

Changes in the activity of various enzymes of carbohydrate metabolism in the liver and skeletal muscles of pigs during ontogenesis

Hexokinase, glucokinase, phosphofructokinase, glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase activity was studied in the liver and musculus quadriceps femoris of 110-day foetuses 1, 2, 3, 30 and 60-day piglets and in adult pigs. The activity of all enzymes in the tissues of newborn piglets is considerably higher than in the tissues of foetuses. The activity of hexokinase in both tissues of piglets increases in the first days after birth and lowers by the one month age. The phosphofructokinase activity in the skeletal muscles and the glucokinase one in the pig liver increase during the postnatal development. The activity of glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase in both tissues of pigs increases after birth and then decreases. Glucose metabolism in the pig liver at all stages of odontogenesis proceeds more intensively by the pentose phosphate pathway, and in the skeletal muscles--by glycolytic one.     

Oxidative Stress (Glutathionylation) and Na,K-ATPase Activity in Rat Skeletal Muscle

Background

Changes in ion distribution across skeletal muscle membranes during muscle activity affect excitability and may impair force development. These changes are counteracted by the Na,K-ATPase. Regulation of the Na,K-ATPase is therefore important for skeletal muscle function. The present study investigated the presence of oxidative stress (glutathionylation) on the Na,K-ATPase in rat skeletal muscle membranes.

Results

Immunoprecipitation with an anti-glutathione antibody and subsequent immunodetection of Na,K-ATPase protein subunits demonstrated 9.0±1.3% and 4.1±1.0% glutathionylation of the α isoforms in oxidative and glycolytic skeletal muscle, respectively. In oxidative muscle, 20.0±6.1% of the β1 units were glutathionylated, whereas 14.8±2.8% of the β2-subunits appear to be glutathionylated in glycolytic muscle. Treatment with the reducing agent dithiothreitol (DTT, 1 mM) increased the in vitro maximal Na,K-ATPase activity by 19% (P<0.05) in membranes from glycolytic muscle. Oxidized glutathione (GSSG, 0–10 mM) increased the in vitro glutathionylation level detected with antibodies, and decreased the in vitro maximal Na,K-ATPase activity in a dose-dependent manner, and with a larger effect in oxidative compared to glycolytic skeletal muscle.

Conclusion

This study demonstrates the existence of basal glutathionylation of both the α and the β units of rat skeletal muscle Na,K-ATPase. In addition, the study suggests a negative correlation between glutathionylation levels and maximal Na,K-ATPase activity.

Perspective

Glutathionylation likely contributes to the complex regulation of Na,K-ATPase function in skeletal muscle. Especially, glutathionylation induced by oxidative stress may have a role in Na,K-ATPase regulation during prolonged muscle activity.     

Content of thiamin phosphate esters in mammalian tissues--an extremely high concentration of thiamin triphosphate in pig skeletal muscle

In relation to a high activity of thiamin diphosphate (TDP) kinase (Koyama, S. et al. (1985) Biochem. Int. 11, 371-380) in the skeletal muscle of pigs and guinea pigs, the content of thiamin phosphate esters in tissues of these animals has been determined by the method of high-performance liquid chromatography. An extremely high concentration of thiamin triphosphate (TTP), 69.2% of the total thiamin (26.1 nmol/g wet weight), was detected in adult pig skeletal muscles. One extreme case contained TTP as 88.7% of the total thiamin (19.6 nmol/g wet weight). TTP in pig skeletal muscle was found solely in cytosol fraction. This is the first report showing an unusually high level of TTP in mammals and may give a clue as to the physiological functions of TTP.     

Molecular cloning, tissue distribution and ontogenetic expression of Xiang pig Chemerin and its involvement in regulating energy metabolism through Akt and ERK1/2 signaling pathways

Chemerin, as a new member of adipokines family, is highly expressed in adipose tissue in rodent and its expression increases with obesity. Moreover, chemerin has been reported to have significant relationship with metabolic syndrome and insulin sensitivity. Here, the gene encoding chemerin from Xiang pig was cloned. The open reading frame of this cDNA encodes 163 deduced amino acid residues. The putative protein has a N-terminal signaling peptide and a nuclear localization signal profile which are highly conserved among the vertebrate orthologs. Both chemerin and chemerinR are highly expressed in lung, kidney and small intestine in adult Xiang pig. Besides these tissues, chemerin is abundant in liver and backfat, and chemerinR is abundant in spleen and skeletal muscle. We also investigated the age-dependent expression of chemerin in suckling Xiang piglets in various tissues, which showed an interaction between age and segments in abundance of chemerin and chemerinR from day 1 to day 21. For chemerinR, it was abundant in skeletal muscle of both adult and fetal Xiang pig. Further, we treated differentiated C2C12 cells with chemerin. The result showed that chemerin regulated energy metabolism partly through Akt and ERK1/2 signaling pathway. Taken together, our findings provide basic molecular information for the deeper investigation on the function of chemerin.     

Molecular Cloning, Mapping, and Expression Analysis of the EIF4A2 Gene in Pig

A full-length cDNA clone encoding the eukaryotic translation initiation factor 4A, isoform 2 (EIF4A2), was cloned from the fetal skeletal cDNA library from the pig (Sus scrofa). EIF4A2 is a highly conserved gene for one of the protein-synthesis initiation factors involved in the binding of mRNA to the ribosome. Based on this cDNA sequence, the deduced protein of 407 amino acids contains the characteristic motifs shared by the DEAD-box supergene family. The genomic nucleotide sequence of this gene was determined and a single nucleotide polymorphism located in the 5′ untranslated region was genotyped. The porcine EIF4A2 was expressed in all tissues examined but in variable amounts. The EIF4A2 expression level in muscle was upregulated through embryonic and neonatal development until adult, suggesting that porcine EIF4A2 was possibly involved in translation regulation of other muscle-related genes in muscle formation and development. In addition, we mapped porcine EIF4A2 to q4.1 of SSC13, in agreement with comparative mapping data.     

OLFML3 expression is decreased during prenatal muscle development and regulated by microRNA-155 in pigs

The Olfactomedin-like 3 (OLFML3) gene has matrix-related function involved in embryonic development. MicroRNA-155 (miR-155), 21- to 23-nucleotides (nt) noncoding RNA, regulated myogenesis by target mRNA. Our LongSAGE analysis suggested that OLFML3 gene was differently expressed during muscle development in pig. In this study, we cloned the porcine OLFML3 gene and detected its tissues distribution in adult Tongcheng pigs and dynamical expression in developmental skeletal muscle (12 prenatal and 10 postnatal stages) from Landrace (lean-type) and Tongcheng (obese-type) pigs. Subsequently, we analyzed the interaction between OLFML3 and miR-155. The OLFML3 was abundantly expressed in liver and pancreas, moderately in lung, small intestine and placenta, and weakly in other tissues and postnatal muscle. There were different dynamical expression patterns between Landrace and Tongcheng pigs during prenatal skeletal muscle development. The OLFML3 was down-regulated (33-50 days post coitus, dpc), subsequently up-regulated (50-70 dpc), and then down-regulated (70-100 dpc) in Landrace pigs, while in Tongcheng pigs, it was down-regulated (33-50 dpc), subsequently up-regulated (50-55 dpc) and then down-regulated (55-100 dpc). There was higher expression in Tongcheng than Landrace in prenatal muscle from 33 to 60 dpc, and opposite situation from 65 to 100 dpc. Dual luciferase assay and real time PCR documented that OLFML3 expression was regulated by miR-155 at mRNA level. Our research indicated that OLFML3 gene may affect prenatal skeletal muscle development and was regulated by miR-155. These finding will help understanding biological function and expression regulation of OLFML3 gene in mammal animals.