Identification of a lens-specific regulatory region (LSR) of the murine alpha B-crystallin gene.

Previous studies have shown that the -661/+44 sequence of the murine alpha B-crystallin gene contains a muscle-preferred enhancer (-426/-257) and can drive the bacterial chloramphenicol acetyltransferase (CAT) gene in the lens, skeletal muscle and heart of transgenic mice. Here we show that transgenic mice carrying a truncated -164/+44 fragment of the alpha B-crystallin gene fused to the CAT gene expressed exclusively in the lens; by contrast mice carrying a -426/+44 fragment of the alpha B gene fused to CAT expressed highly in the lens, skeletal muscle and heart, and slightly in the lung, brain, kidney, spleen and liver. DNase I protection experiments indicated that the -147/-118 sequence is protected by nuclear proteins from alpha TN4-1 lens cell line, but not by nuclear proteins from myotubes of the C2C12 cell line. Site directed mutagenesis of this sequence decreased promoter activity in transiently-transfected lens cells, consistent with this sequence being a lens-specific regulatory region (LSR). We conclude that the -426/-257 enhancer is required for expression in skeletal muscle, heart and possibly other tissues, and that the -164/+44 sequence of the alpha B-crystallin gene is sufficient for expression in the lens of transgenic mice.     

Expression of the murine alpha B-crystallin gene in lens and skeletal muscle: identification of a muscle-preferred enhancer.

The alpha B-crystallin gene is expressed at high levels in lens and at lower levels in some other tissues, notably skeletal and cardiac muscle, kidney, lung, and brain. A promoter fragment of the murine alpha B-crystallin gene extending from positions -661 to +44 and linked to the bacterial chloramphenicol acetyltransferase (CAT) gene showed preferential expression in lens and skeletal muscle in transgenic mice. Transfection experiments revealed that a region between positions -426 and -257 is absolutely required for expression in C2C12 and G8 myotubes, while sequences downstream from position -115 appear to be determinants for lens expression. In association with a heterologous promoter, a -427 to -259 fragment functions as a strong enhancer in C2C12 myotubes and less efficiently in myoblasts and lens. Gel shift and methylation interference studies demonstrated that nuclear proteins from C2C12 myoblasts and myotubes specifically bind to the enhancer.     

alpha A-crystallin is expressed in non-ocular tissues.

alpha-Crystallin, the predominant structural protein of the ocular lens, has been considered to be composed of two subunits, alpha A-crystallin and alpha B-crystallin. Of these two, alpha B-crystallin has been previously shown to be an extralenticular protein while alpha A-crystallin has been considered to be a lens-specific polypeptide. Using an antiserum directed against an N-terminal peptide of alpha-crystallin, we have detected a 20-kDa protein in various rat tissues including the brain, liver, lung, spleen, skin, and small intestine and in a number of established epithelial and fibroblast cell lines. PCR analysis of poly(A)-enriched RNA and Southern blot analysis indicated the presence of alpha A-crystallin mRNA sequences in different non-lenticular tissues. Among the non-ocular tissues examined, spleen showed the highest levels of alpha A-crystallin protein and mRNA. The identity of alpha A-crystallin sequences in the spleen was established by cloning and sequencing a polymerase chain reaction-amplified region of alpha A-crystallin mRNA. Sequences derived from spleen and eye revealed almost 100% identity at the nucleotide level. Interestingly, alpha A-crystallin and alpha B-crystallin seem to exist in an inverse quantitative relationship in the spleen and the heart, the two non-ocular tissues where they show highest concentrations, respectively. The known conserved evolution of alpha A-crystallin and the definitive demonstration of the non-ocular expression of this polypeptide suggest important non-crystallin functions for this protein.     

Regulation of the murine alpha B-crystallin/small heat shock protein gene in cardiac muscle.

The murine alpha B-crystallin/small heat shock protein gene is expressed at high levels in the lens and at lower levels in the heart, skeletal muscle, and numerous other tissues. Previously we have found a skeletal-muscle-preferred enhancer at positions -427 to -259 of the alpha B-crystallin gene containing at least four cis-acting regulatory elements (alpha BE-1, alpha BE-2, alpha BE-3, and MRF, which has an E box). Here we show that in transgenic mice, the alpha B-crystallin enhancer directs the chloramphenicol acetyltransferase reporter gene driven by the alpha B-crystallin promoter specifically to myocardiocytes of the heart. The alpha B-crystallin enhancer was active in conjugation with the herpes simplex virus thymidine kinase promoter/human growth hormone reporter gene in transfected rat myocardiocytes. DNase I footprinting and site-specific mutagenesis experiments showed that alpha BE-1, alpha BE-2, alpha BE-3, MRF, and a novel, heart-specific element called alpha BE-4 are required for alpha B-crystallin enhancer activity in transfected myocardiocytes. By contrast, alpha BE-4 is not utilized for enhancer activity in transfected lens or skeletal muscle cell lines. Alpha BE-4 contains an overlapping heat shock sequence and a reverse CArG box [5'-GG(A/T)6CC-3']. Electrophoretic mobility shift assays with an antibody to serum response factor and a CArG-box-competing sequence from the c-fos promoter indicated that a cardiac-specific protein with DNA-binding and antigenic similarities to serum response factor binds to alpha BE-4 via the reverse CArG box; electrophoretic mobility shift assays and antibody experiments with anti-USF antiserum and heart nuclear extract also raised the possibility that the MRF E box utilizes USF or an antigenically related protein. We conclude that the activity of the alpha B-crystallin enhancer in the heart utilizes a reverse CArG box and an E-box-dependent pathway.     

Cellular distribution of alpha B-crystallin in non-lenticular tissues

alpha B-Crystallin is a subunit of alpha-crystallin, a major protein component of the vertebrate lens. Recently, its expression in various extra-lenticular tissues has been demonstrated by both Western and Northern blotting. In this study, the cellular distribution of alpha B-crystallin in rat organs was examined in detail using immunohistochemistry. Positive reactions were observed in lens, iris, heart, skeletal muscle (type 1 and type 2A fibers), striated muscle in skin and esophagus, Henle's loop and medullary collecting duct of the kidney, Schwann cells of peripheral nerves, glia of the central nervous system, and decidual cells of the placenta. A close correlation with markers of oxidative activity suggests that alpha B-crystallin is expressed in cells that have high levels of oxidative function.     

小鼠不同组织及缺氧损伤后的大鼠心肌细胞中RIP3的表达

目的:检测小鼠组织中受体相互作用丝氨酸/苏氨酸蛋白激酶家族(RIPs)表达谱,并检测RIP3在大鼠心肌细胞缺氧损伤后的表达。方法:①采用荧光实时定量PCR分别检测RIPs家族基因在小鼠组织(心、肝、肺、肾、脑、小肠、骨骼肌、脾和主动脉)中的mRNA表达谱,并采用Western blot进一步检测RIP3在小鼠组织的蛋白表达谱。②将培养的大鼠心肌细胞分为缺氧组和对照组,缺氧组置于缺氧环境中培养48 h,采用western blot检测其中RIP3的表达变化。结果:①mRNA水平:RIP1 mRNA在脑组织中表达最高,心脏、肺、肾、骨骼肌较低;RIP2在心脏和肺表达量较其他组织高;RIP3在肠中表达较其他组织高出4倍以上,脑组织中未检测到RIP3表达;RIP4的表达以肺最高,而骨骼肌、脑和血管中表达量低。②蛋白水平:在小鼠组织中,RIP3表达以脑、骨骼肌中最高,心脏、肝、肺中表达较低。③培养的大鼠心肌细胞中,缺氧组心肌细胞的RIP3表达量显著高于对照组(P0.05)。结论:RIPs在小鼠组织中呈现差异表达,而在培养的大鼠心肌细胞缺氧损伤后RIP3表达升高。     

Alpha B-crystallin is expressed in kidney epithelial cell lines and not in fibroblasts

We have recently shown the presence of alpha B-crystallin in non-ocular tissues of diverse embryological origins such as the heart, brain, spinal cord, kidney, retina, etc. Using an alpha B-crystallin-specific antiserum and immunofluorescence, immunoblotting, immunoprecipitation and peptide mapping with Staphylococcus aureus protease, we demonstrate differential expression of alpha B-crystallin in epithelial and fibroblast cell lines. alpha B-Crystallin was detectable only in epithelial cell lines such as MDBK, MDCK, LLCPK1 and JTC-12, and was not observed in two kidney fibroblast cell lines, one skin fibroblast cell line, and one corneal fibroblast cell line. Differential expression of the alpha B-crystallin gene was also confirmed by Northern blot analysis of the RNAs isolated from these cell lines. These data suggest a cell-type-specific role for alpha B.     

Structure,tissue expression pattern,and function of the amino acid transporter rat PAT2

The second member of the PAT (proton-coupled amino acid transporter) family of H(+)-coupled, pH-dependent, Na(+)-independent amino acid transporters was isolated from a rat lung cDNA library. The cDNA for rat PAT2 is 2396bp in length, including 70bp of 5'UTR and a poly(A) tail. The transporter gene, consisting of 10 exons, is located on rat chromosome 10q22. The cDNA codes for a protein of 481 amino acids with 72% identity (over 449 amino acids) with rat PAT1. Tissue expression studies demonstrate that mRNA abundance is generally low with highest levels being detected in lung and spleen, with lower levels in the brain, heart, kidney, and skeletal muscle. Functional expression in either mammalian cells or Xenopus laevis oocytes demonstrates that rat PAT2 mediates pH-dependent, Na(+)-independent uptake of glycine, proline, and alpha(methyl)aminoisobutyric acid (MeAIB). In conclusion PAT2 has a limited tissue distribution, higher affinity (Michaelis-Menten constant for glycine uptake between 0.49 and 0.69mM), and distinct substrate specificity compared to PAT1.     

Tissue-specific expression of four types of rat calmodulin-dependent protein kinase II mRNAs

cDNA clones for a fifth polypeptide of rat brain calmodulin-dependent protein kinase II were isolated and sequenced. The cDNA sequence encoded a polypeptide, designated delta, consisting of 533 amino acid residues with a molecular weight of 60,080. Comparison of amino acid sequences of this and alpha, beta, beta', and gamma polypeptides of calmodulin-dependent protein kinase II reveals marked homology among them. The mRNAs for delta were expressed in rat brain tissues with different regional specificities. The distribution of alpha, beta/beta', gamma, and delta mRNAs in cerebrum, skeletal muscle, diaphragm, heart, small intestine, uterus, aorta, liver, kidney, lung, and testis were examined by RNA blot hybridization analysis with probes specific for the respective mRNAs. A 3.9-kilobase (kb) RNA species hybridizable with a probe for gamma was found in all the tissues examined, and 4.0-4.2-kb RNA species hybridizable with a probe for delta were found in all the tissues examined except for liver, while a 4.8-kb RNA species hybridizable with a probe for alpha and a 4.2-kb RNA species hybridizable with a probe for beta were present in brain but not in the other tissues. With the alpha probe, however, a 4.1- and 2.6-kb RNA species were both detected in skeletal muscle and diaphragm. With the beta probe, a 4.3-kb RNA in skeletal muscle and diaphragm, 2.9-kb RNA in small intestine, and 4.0-kb RNA in testis were detected. With the delta probe, a 3.5-kb RNA in heart and 1.8-kb RNA in testis were detected. Thus, gamma and delta mRNAs were expressed in various tissues, while alpha and beta/beta' mRNAs were primarily, if not exclusively, expressed in brain.     

Identification of two novel GTP-binding protein alpha-subunits that lack apparent ADP-ribosylation sites for pertussis toxin

Molecular cloning of cDNAs encoding alpha-subunits of guanine nucleotide-binding regulatory proteins (G-proteins) has revealed the existence of nine species of alpha-subunits. We have identified two additional G-protein alpha-subunits, which we refer to as GL1 alpha and GL2 alpha, by isolating bovine liver cDNA clones that cross-hybridized at reduced stringency with bovine Gi1 alpha-subunit cDNA. The deduced amino acid sequences of GL1 alpha and GL2 alpha share 83% identity with each other and show 45-55% identity with those of other known G-protein alpha-subunits. Both GL1 alpha and GL2 alpha lack a consensus site for ADP-ribosylation by pertussis toxin. Messenger RNA corresponding to GL2 alpha was detected in all tissues examined, but GL1 alpha mRNA was detected only in liver, lung, and kidney. Antiserum prepared against a synthetic pentadecapeptide corresponding to the deduced carboxyl terminus of GL2 alpha specifically reacted with a 40-kDa protein in mouse liver, brain, lung, heart, kidney, and spleen. The amount of the 40-kDa protein was highest in brain and lung. We suggest that GL1 alpha and GL2 alpha are new members of a subfamily of pertussis toxin-insensitive G-proteins.     

Oxidative Myocytes of Heart and Skeletal Muscle Express Abundant Sarcomeric Mitochondrial Creatine Kinase

Sarcomeric mitochondrial creatine kinase catalyzes the reversible transfer of a high energy phosphate between ATP and creatine. To study cellular distribution of the kinase, we performed immunocytochemical studies using a peptide antiserum specific for the kinase protein. Our results demonstrated that the sarcomeric mitochondrial creatine kinase gene is abundantly expressed in heart and skeletal muscle, with no protein detected in other tissues examined, including brain, lung, liver, spleen, kidney, bladder, testis, stomach, intestine, and colon. RNA blot study showed that there is no detectable expression of the kinase mRNA in the thymus gland. In heart and skeletal muscle, the kinase protein is expressed in atrial and ventricular cardiomyocytes and a subpopulation of skeletal myofibres. In skeletal muscle, fast myosin heavy chain co-localization studies demonstrated that the sarcomeric mitochondrial creatine kinase is highly expressed in type 1, slow-oxidative and type 2A, fast-oxidative-glycolytic myofibres. We conclude that the kinase gene is abundantly expressed in oxidative myocytes of heart and skeletal muscle and may contribute to oxidative capacity of these cells.     

Alpha B-crystallin is expressed in non-lenticular tissues and accumulates in Alexander's disease brain

Rosenthal fibers (RFs) are abnormal inclusions within astrocytes, characteristic of Alexander's disease. We have previously isolated a 22 kd protein component of RFs from Alexander's disease brain. By Western blotting, we detected its equivalent in several rat organs, with the highest level in heart, and in a human astrocytoma cell line (U-373MG). A cDNA library established from U-373MG was screened with an anti-RF protein antibody. A partial cDNA clone encoding the lens protein alpha B-crystallin was isolated. The anti-RF protein antibodies react with lens alpha B-crystallin. Furthermore, the distribution of alpha B-crystallin mRNA in rat organs is consistent with the Western blots. Therefore, alpha B-crystallin is not lens-specific and it can accumulate in large amounts in astrocytes in pathological conditions.     

Apolipoprotein gene expression in the rabbit: abundance, size, and distribution of apolipoprotein mRNA species in different tissues

We have used human apolipoprotein cDNAs as hybridization probes to study the relative abundance and distribution of apolipoprotein mRNAs in rabbit tissues by RNA blotting analysis. The tissues surveyed included liver, intestine, lung, pancreas, spleen, stomach, skeletal muscle, testis, heart, kidney, adrenal, aorta, and brain. We found that liver is the sole or major site of synthesis of apoA-II, apoA-IV, apoB, apoC-I, apoC-II, apoC-III, and apoE, and the intestine is a major site of synthesis of apoA-I, apoA-IV, and apoB. Minor sites of apolipoprotein mRNA synthesis were as follows: apoA-I, liver and skeletal muscle; apoA-IV, spleen and lung; apoB, kidney; apoC-II and apoC-III, intestine. ApoE mRNA was detected in all tissues surveyed with the exception of skeletal muscle. Sites with moderate apoE mRNA (10% of the liver value) were lung, brain, spleen, stomach, and testis. All rabbit mRNAs had forms with sizes comparable to their human counterparts. In addition, hybridization of hepatic and intestinal RNA with human apoA-IV and apoB probes produced a second hybridization band of approximately 2.4 and 8 kb, respectively. Similarly, hybridization of rabbit intestinal RNA with human apoC-II produced a hybridization band of 1.8 kb. The 8 kb apoB mRNA form may correspond to the apoB-48 mRNA, whereas the apoA-IV- and apoC-II-related mRNA species have not been described previously. This study provides a comprehensive survey of the sites of apolipoprotein gene expression and shows numerous differences in both the abundance and the tissue distribution of several apolipoprotein mRNAs between rabbit and human tissues. These findings and the observation of potentially new apolipoprotein mRNA species are important for our understanding of the cis and trans acting factors that confer tissue specificity as well as factors that regulate the expression of apolipoprotein genes in different mammalian species.     

Chicken lens delta-crystallin gene expression and methylation in several non-lens tissues.

RNA sequences coding for the most abundant chicken lens proteins, delta-crystallin, were detected at very low levels in day old post hatch chick lung, heart, kidney and liver, and in 6 day embryo headless bodies. The pattern of cytosine methylation within the CCGG sequences of the delta-crystallin genes was also examined and shown to vary in several non-lens tissues, from several stages of development. Embryonic neural retina, which expresses a higher level of delta-crystallin RNA than the above tissues, is no less methylated in the sites studied than the tissues which have no association with the eye, and is actually more heavily methylated than the kidney. Thus no obvious correlation was found between undermethylation and gene expression.     

Differential regulation of Na,K-ATPase alpha 1, alpha 2, and beta subunit mRNA and protein levels by thyroid hormone

The purpose of this study was to determine the effect of thyroid status on the Na,K-ATPase alpha isoforms and beta in rat heart, skeletal muscle, kidney, and brain at the levels of mRNA, protein abundance, and enzymatic activity. Northern and dot-blot analysis of RNA (euthyroid, hypothyroid, and triiodothyronine-injected hypothyroids = hyperthyroids) and immunoblot analysis of protein (euthyroid and hypothyroid) revealed isoform-specific regulation of Na,K-ATPase by thyroid status in kidney, heart, and skeletal muscle and no regulation of sodium pump subunit levels in the brain. In general, in the transition from euthyroid to hypothyroid alpha 1 mRNA and protein levels are unchanged in kidney and skeletal muscle and slightly decreased in heart, while alpha 2 mRNA and protein are decreased significantly in heart and skeletal muscle. In hypothyroid heart and skeletal muscle, the decrease in alpha 2 protein levels was much greater than the decrease in alpha 2 mRNA levels relative to euthyroid indicating translational or post-translational regulation of alpha 2 protein abundance by triiodothyronine status in these tissues. The regulation of beta subunit by thyroid status is tissue-dependent. In hypothyroid kidney beta mRNA levels do not change, but immunodetectable beta protein levels decrease relative to euthyroid, and the decrease parallels the decrease in Na,K-ATPase activity. In hypothyroid heart and skeletal muscle beta mRNA levels decrease; beta protein decreases in heart and was not detected in the skeletal muscle. These findings demonstrate that the euthyroid levels of expression of alpha 1 in heart, alpha 2 in heart and skeletal muscle, and beta in kidney, heart, and skeletal muscle are dependent on the presence of thyroid hormone.