Expression level of adenosine kinase in rat tissues. Lack of phosphate effect on the enzyme activity

In this report we describe cloning and expression of rat adenosine kinase (AK) in Esccherichaia coli cells as a fusion protein with 6xHis. The recombinant protein was purified and polyclonal antibodies to AK were generated in rabbits. Immunoblot analysis of extracts obtained from various rat tissues revealed two protein bands reactive with anti-AK IgG. The apparent molecular mass of these bands was 48 and 38 kDa in rat kidney, liver, spleen, brain, and lung. In heart and muscle the proteins that react with AK antibodies have the molecular masses of 48 and 40.5 kDa. In order to assess the relative AK mRNA level in rat tissues we used the multiplex PCR technique with beta-actin mRNA as a reference. We found the highest level of AK mRNA in the liver, which decreased in the order kidney > spleen > lung > heart > brain > muscle. Measurement of AK activity in cytosolic fractions of rat tissues showed the highest activity in the liver (0.58 U/g), which decreased in the order kidney > spleen > lung > brain > heart > skeletal muscle. Kinetic studies on recombinant AK as well as on AK in the cytosolic fraction of various rat tissues showed that this enzyme is not affected by phosphate ions. The data presented indicate that in the rat tissues investigated at least two isoforms of adenosine kinase are expressed, and that the expression of the AK gene appears to have some degree of tissue specificity.     

A study of iodothyronine 5'-monodeiodinase activities in normal and pathological tissues in man and their comparison with activities in rat tissues

The present study was undertaken to investigate the peripheral iodothyronine 5'-monodeiodination in different human and rat tissues. We studied iodothyronine 5'-monodeiodinase type I (5'-DI) activity in liver, kidney, intestine, right cardiac atrium and skeletal muscle and we compared the results with those in rat tissues. Lodothyronine 5'- monodeiodinase type II (5'-DII) activity was studied in normal and ischemic human heart and in rat normal myocardium and brain. The 5'-DI activity (fmol/min x mg protein) in liver and kidney was significantly higher (p < 0.001, ANOVA) in normal rat tissue than in human. However, no significant differences were observed in 5'-DI activity between normal and tumoral human intestine or between intestinal tissue of man and rat. 5'-DI activity in normal human skeletal muscle was significantly higher than that in rat skeletal muscle (p < 0.05). The 5'-DI activity was lower in human ischemic myocardium when compared to normal myocardium either in humans (p < 0.05) or rat (p < 0.001). The Km of 5'-DI was significantly lower in rat than in human kidney and liver (p < 0.05). We conclude that 1) 5'-DI is distributed widely among extrathyroidal human and rat tissues and 5'-DII activity is detectable both in human and rat heart; 2) 5'-DI activity in liver and kidney is lower in man than in rat; 3) 5'-DI activity in the skeletal muscle is higher in man than in the rat; 4) 5'-DI activity is decreased in tumoral tissues of human liver and kidney and in ischemic myocardium, while no significant difference was found between human and rat cardiac 5'-DII activity.     

Expression level of Ubc9 protein in rat tissues

Ubc9 is a homologue of the E2 ubiquitin conjugating enzyme and participates in the covalent linking of SUMO-1 molecule to the target protein. In this report we describe a simple and efficient method for obtaining pure human recombinant Ubc9 protein. The purified Ubc9 retained its native structure and was fully active in an in vitro sumoylation assay with the promyelocytic leukaemia (PML) peptide as a substrate. In order to better understand the physiology of Ubc9 protein we examined its levels in several rat tissues. Immunoblot analyses performed on tissue extracts revealed quantitative and qualitative differences in the expression pattern of Ubc9. The Ubc9 protein was present at a high level in spleen and lung. Moderate level of Ubc9 was detected in kidney and liver. Low amount of Ubc9 was observed in brain, whereas the 18 kDa band of Ubc9 was barely visible or absent in heart and skeletal muscle. In heart and muscle extracts the Ubc9 antibodies recognized a 38 kDa protein band. This band was not visible in extracts of other rat tissues. A comparison of the relative levels of Ubc9 mRNA and protein indicated that the overall expression level of Ubc9 was the highest in spleen and lung. In spleen, lung, kidney, brain, liver and heart there was a good correlation between the 18 kDa protein and Ubc9 mRNA levels. In skeletal muscle the Ubc9 mRNA level was unproportionally high comparing to the level of the 18 kDa protein. The presented data indicate that in the rat the expression of the Ubc9 protein appears to have some degree of tissue specificity.     

Co-ordinate expression of cytochrome c oxidase subunit III and VIc mRNAs in rat tissues.

Cytochrome c oxidase (EC 1.9.3.1) is an enzyme which is composed of subunits derived from both the mitochondrial and the nuclear genomes. To determine whether or not the expression of these two genomes is co-ordinated at the mRNA level, we have examined the steady-state levels of mRNAs coding for cytochrome c oxidase subunit III (mitochondrially encoded) and subunit VIc (nuclear-encoded) in rat tissues. This was compared with the tissue concentration of the holoenzyme, which was estimated by measuring cytochrome c oxidase enzyme activity. The tissues (heart, brain, liver, kidney, soleus muscle and superficial white vastus muscle) possessed a 13-fold range of enzyme activity, which was highest in heart and lowest in the superficial vastus muscle. Specific subunit mRNA levels were quantified by using slot-blot hybridization of cDNA probes to total tissue RNA. The highest values for subunit III and Vlc mRNA tissue contents were found in kidney, followed by liver and heart (40-60% of that of kidney). The white vastus muscle contained the lowest subunit mRNA level (15% of that of kidney). Although some variability was apparent within each tissue, a parallel pattern of mRNA expression of the nuclear- and mitochondrially encoded subunits was observed. Differences between muscle (heart, vastus and soleus) and non-muscle tissues were noted in the relationship between mRNA and protein levels of expression. Thus, although this suggests that tissue-specific regulatory processes operate, the steady-state expression of subunit III and subunit Vlc mRNAs appears to be co-ordinately regulated.     

一氧化氮合成酶（NOS）基因表达的半定量检测及其运用

本工作参照Ｍａｒｔｉｎ（１９９３）定量ＲＴ－ＰＣＲ方法,建立了一种灵敏,简捷,特异的定量ＮＯＳ ｍＲＮＡ测定方法;证明了ＮＯＳ ｍＲＮＡ不仅存在于脑组织,亦广泛分布于心,肾,肺和肝组织中,其中以脑组织含量最高,肾,心次之。除内皮细胞以外,平滑肌细胞中ＮＯＳ ｍＲＮＡ水平下降,提示ＮＯＳ基因表达受抑,可能与高血压的病因密切相关。     

Effects of hyperthyroidism induced by L-thyroxin administration on lipid peroxidation in various rat tissues

Thyroid dysfunctions are associated with many pathological signs in the body. One of these is lipid peroxidation that develops due to over- or under-secretion of thyroid hormones. The present study was conducted to determine lipid peroxidation that develops in different tissues including the brain, liver and heart of rats in experimental hyperthyroidism induced by L-thyroxin. The study was carried out on 30 male Sprague-Dawley rats. They were divided into three groups as control, sham hyperthyroidism and hyperthyroidism. Malondialdehyde (MDA) and glutathione (GSH) levels in rat tissues were determined at the end of a 3-weeks period of L-thyroxin administration. It was observed that MDA levels in the hyperthyroidism group were significantly higher in the cerebral cortex, liver and ventriculer tissue of heart (p < 0.001) than in the control and in sham hyperthyroidism groups. GSH levels were higher in the hyperthyroidism group than in control and sham hyperthyroidism groups in all tissues (p < 0.001). Results demonstrate that hyperthyroidism induced by L-thyroxin activates both oxidant and antioxidant systems in cerebral, hepatic and cardiac tissues. However, the increase in antioxidant activity cannot adequately prevent oxidative damage.     

The tissue-specific expression and developmental regulation of two nuclear genes encoding rat mitochondrial proteins. Medium chain acyl-CoA dehydrogenase and mitochondrial malate dehydrogenase

To study the regulation of nuclear genes which encode mitochondrial enzymes involved in oxidative metabolism, absolute levels of mRNA encoding rat medium chain acyl-CoA dehydrogenase (MCAD) and rat mitochondrial malate dehydrogenase (mMDH) were determined in developing and adult male rat tissues. MCAD mRNA is expressed in a variety of adult male tissues with highest steady state levels in heart, adrenal, and skeletal muscle and lowest levels in brain, lung, and testes. In comparison, steady state levels of mMDH mRNA in adult male rat tissues were similar to those of MCAD mRNA in heart, small intestine, adrenal, and skeletal muscle but markedly different in brain, stomach, and testes. Thus, the steady-state levels of MCAD and mMDH mRNA are highest in adult tissues with high energy requirements. Dot blot analysis of RNA prepared from late fetal, suckling, and weaning rat heart, liver, and brain demonstrated the presence of MCAD and mMDH mRNA during the fetal period in all three tissues. Both MCAD and mMDH mRNA levels increased 2-2.5-fold at birth followed by a decline during the first postnatal week in heart and liver. The patterns of accumulation of these mRNAs in heart and liver during the weaning and early adult periods were also similar, although the absolute levels were significantly different. Brain MCAD mRNA levels were consistently low (less than 0.1 pg/micrograms total cellular RNA) throughout the developmental stages. However, brain mMDH mRNA levels exhibited a marked increase during the weaning period, reaching a peak concentration which is higher than the level of mMDH mRNA in heart and liver at any point during development. These results indicate that the level of expression of the nuclear genes encoding MCAD and mMDH is tissue-specific and developmentally regulated. The patterns of MCAD and mMDH mRNA accumulation parallel the changes in energy metabolism which occur during development and among adult tissues.     

自发性高血压大鼠多组织炎症状态

高血压是一种慢性血管性疾病,易累及肾、肝、心、脑等组织,引起脑卒中和心、肾损害等并发症.本研究对高血压时肾、肝、心、脑等组织的炎症状态进行了观察.实验采用自发性高血压大鼠(spontaneously hypertensive rat,SHR)和正常血压的Wistar-Kyoto(WKY)大鼠,用RT-PCR和Western blot法观察肾、肝、心、脑等组织炎症相关因子IL-1p、TNFα、ICAM-1、iNOS、C/EBPδ和PPARγ的基因表达;紫外分光光度法观察蛋白质羰基化水平和FRAP法检测组织总抗氧化能力.结果显示(1)SHR组织炎症相关因子表达较对照WKY增强,除IL-1βmRNA在肝和脑的增加不明显外,其余均有显著性差异(P＜0.05);(2)SHR和WKY大鼠肾、心、脑蛋白质羰基化水平(nmol/mg蛋白)分别为8.93±1.08和2.27±0.43、2.23±0.23和0.17±0.02、13.42±1.10和5.72±1.01,SHR明显增加(P＜0.05);而肝脏蛋白质羰基化水平无明显变化;(3)SHR肾、肝、心、脑总抗氧化能力水平显著低于WKY大鼠(P＜0.05).以上结果表明,SHR多个组织(肾、肝、心和脑)均存在炎症因子被诱导和氧化应激反应等明显的炎症状态,提示炎症可能在高血压及其并发症的病理改变中起重要作用.     

Developmental regulation of insulin-like growth factor II mRNA in different rat tissues

Insulin-like growth factor II (IGF-II) is present at high levels in fetal and early neonatal rat plasma, and decreases profoundly following birth. In the present study, the levels of IGF-II RNA in different rat tissues at different ages were determined by hybridization to a rat IGF-II cDNA probe. IGF-II RNA was present in 11 of 13 fetal or neonatal tissues examined: at higher levels in muscle, skin, lung, liver, intestine, and thymus; at lower levels in brain stem, heart, cerebral cortex, kidney, and hypothalamus; and undetectable in spleen and pancreas (although the latter RNA was partially degraded). In each tissue, Northern blot hybridization revealed the presence of six IGF-II RNAs: 6, 4, 3.8, 2.2, 1.7, and 1.2 kilobase pairs, consistent with results previously observed in the BRL-3A rat liver cell line and attributed to alternative RNA processing. Although differences in the relative abundance of these RNAs were observed in different tissues, the same size species occurred in all tissues with the 4-kilobase pair RNA the most abundant species. RNAs from the different tissues were examined at six developmental ages (days 16 and 21 of gestation; days 2, 11, 22, and 75 after birth) by hybridization to slot blots and Northern blots. In lung, thymus, kidney, and brain stem, IGF-II RNA was expressed at higher levels in the fetus than after birth, whereas in muscle, skin, liver, heart, and intestine, the high fetal levels of IGF-II RNA continued through day 11 or day 22 after birth. IGF-II RNA persisted into adulthood in cerebral cortex and hypothalamus. Although the significance of these tissue-specific differences in the developmental regulation of the expression of IGF-II RNA remains to be established, they exhibit intriguing temporal correlations with major maturational events in some tissues such as lung and muscle.     

Tissue specific hormonal regulation of the rat angiotensinogen gene expression

Angiotensinogen is the precursor of the most potent pressor substance, angiotensin. Angiotensinogen levels are increased in some forms of human hypertension. Its levels are modulated by various factors including glucocorticoids, estrogens, and prostaglandins. We have recently reported the isolation of a human angiotensinogen cDNA clone and provided evidence for the presence of its mRNA in rat liver, brain, and heart. In this communication we report the effect of dexamethasone and estradiol on angiotensinogen mRNA levels in rat liver, brain, and heart. Our results indicate that angiotensinogen levels are increased to different extents in these three tissues as a result of glucocorticoid or estrogen administration.     

Renin expression in the kidney and brain is reciprocally controlled by captopril

The tissue distribution of rat renin mRNA was examined. Sensitive RNase protection analyses demonstrated that renin mRNA are produced by the extra-renal tissues such as adrenal, brain, liver, lung, pituitary and testis. In response to sodium depletion and captopril treatment, the expression of mRNAs encoding rat renin were in a tissue-specific manner. The level of kidney renin mRNA remarkably increased in sodium-depleted rats treated with captopril, whereas that of brain renin mRNA definitely decreased. No significant change in the level of liver renin mRNA was observed after the same treatment. These results suggest that the expression of cerebral renin is regulated by physiological stimuli independent of its extra-cerebral expression.     

Demonstration of transthyretin mRNA in the brain and other extrahepatic tissues in the rat

Studies were conducted to ascertain if transthyretin mRNA was present in extrahepatic tissues of the rat. A trnasthyretin cDNA clone was isolated from a lambda gt11 human liver cDNA library by antibody screening and its identity was confirmed by nucleotide sequence analysis. This transthyretin cDNA clone was used to survey poly(A+) RNA isolated from 12 different rat tissues for transthyretin mRNA by Northern blot analysis. The liver contained the highest level of transthyretin mRNA and this level was not altered by the vitamin A status of the rat. A significant amount of transthyretin mRNA was found in the brain (30% of the level of the liver) which was localized in specific regions of the brain. In addition, detectable levels of transthyretin mRNA (1% to 2% of that of the liver) were observed in the stomach, heart, skeletal muscle, and spleen. Translation of brain poly(A+) RNA in rabbit reticulocyte lysates and immunoprecipitation of the translation products with anti-transthyretin antiserum resulted in a protein band of the same size as liver pre-transthyretin. Liver pre-transthyretin was processed by the cotranslational addition of dog pancreas microsomal membranes to a protein that migrated coincidentally with monomeric serum transthyretin. These data suggest that transthyretin in the brain and the cerebrospinal fluid results from de novo synthesis and that transthyretin may play a significant physiological function, as yet unknown, within the nervous system.     

Analysis of the tissue-specific expression, developmental regulation, and linkage relationships of a rodent gene encoding heart fatty acid binding protein

The rat contains at least three homologous cytosolic proteins that bind long chain fatty acids, termed liver (L-), intestinal (I-), and heart (H-) fatty acid binding protein (FABP). I-FABP mRNA is confined to the gastrointestinal tract while L-FABP mRNA is abundantly represented in hepatocytes as well as enterocytes. We have isolated a rat heart FABP cDNA clone and determined the pattern of H-FABP mRNA accumulation in a wide variety of tissues harvested from late fetal, suckling, weaning, and adult rats. RNA blot hybridizations and primer extension analysis disclosed that the distribution of H-FABP mRNA in adult rat tissues is different from that of I- or L-FABP mRNA. H-FABP mRNA is most abundant in adult heart. This mRNA was also present in an adult slow twitch (type I) skeletal muscle (soleus, 63% of the concentration in heart), testes (28%), a fast twitch skeletal muscle (psoas, 17%), brain (10%), kidney (5%), and adrenal gland (5%). H-FABP mRNA was not detected in adult small intestine, colon, spleen, lung, or liver RNA. Distinct patterns of developmental change in H-FABP mRNA accumulation were documented in heart, placenta, brain, kidney, and testes. Myocardial H-FABP mRNA levels rise rapidly during the 48 h prior to and after birth, reaching peak levels by the early weaning period. The postnatal increase in myocardial H-FABP mRNA concentration and its relative distribution in adult fast and slow twitch skeletal muscle are consistent with its previously proposed function in facilitating mitochondrial beta-oxidation of fatty acids. However, the presence of H-FABP mRNA in brain, a tissue which does not normally significantly oxidize fatty acids in late postnatal life, suggests that H-FABP may play a wider role in fatty acid metabolism than previously realized. Mouse-hamster somatic cell hybrids were utilized to map H-FABP. Using stringencies which did not produce cross-hybridization between L-, I-, and H-FABP DNA sequences, we found at least three loci in the mouse genome, each located on different chromosomes, which reacted with our cloned H-FABP cDNA. None of these H-FABP-related loci were linked to the gene which specifies a highly homologous adipocyte-specific protein termed aP2 or to genes encoding two other members of this protein family, cellular retinol binding protein and cellular retinol binding protein II.(ABSTRACT TRUNCATED AT 400 WORDS)     

Distribution and regulation of rat insulin-like growth factor I messenger ribonucleic acids encoding alternative carboxyterminal E-peptides: evidence for differential processing and regulation in liver

Alternative splicing of insulin-like growth factor I (IGF-I)/somatomedin C mRNAs generates two IGF-I mRNAs coding for IGF-I peptides with different sequences in the E domain of the IGF-I prohormone. These two mRNAs encode alternative E peptides due to the presence (IGF-Ib) or absence (IGF-Ia) of a 52-base insert in the region coding for the E domain. We have used a solution hybridization/RNase protection assay to determine the tissue distribution and regulation by GH of the expression of these alternative IGF-I mRNAs. IGF-Ib mRNAs are present in low abundance (representing approximately 2.5% of the total IGF-I mRNA) in heart, lung, muscle, testes, stomach, kidney, and brain, but represent approximately 13% of the IGF-I mRNA in liver. GH treatment of hypophysectomized rats increased steady-state IGF-I mRNA levels in liver, kidney, lung, and heart. In kidney, lung, and heart, IGF-Ia and IGF-Ib mRNA levels were coordinately regulated by GH, but, in liver, the fold increase in IGF-Ib mRNA levels was approximately three times greater than the fold increase in IGF-Ia mRNA levels. These data suggest that the processing of IGF-I mRNA in liver is different than in nonhepatic tissues. These results also further elucidate the organization of the rat IGF-I gene as well as the generation of multiple IGF-I mRNAs by alternative splicing.     

The expression, activity and localisation of the secretory pathway Ca2+ -ATPase (SPCA1) in different mammalian tissues

The distribution of the secretory pathway Ca2+ -ATPase (SPCA1) was investigated at both the mRNA and protein level in a variety of tissues. The mRNA and the protein for SPCA1 were relatively abundant in rat brain, testis and testicular derived cells (myoid cells, germ cells, primary Sertoli cells and TM4 cells; a mouse Sertoli cell line) and epididymal fat pads. Lower levels were found in aorta (rat and porcine), heart, liver, lung and kidney. SPCA activities from a number of tissues were measured and shown to be particularly high in brain, aorta, heart, fat pads and testis. As the proportion of SPCA activity compared to total Ca2+ ATPase activity in brain, aorta, fat pads and testis were relatively high, this suggests that SPCA1 plays a major role in Ca2+ storage within these tissues. The subcellular localisation of SPCA1 was shown to be predominantly around the Golgi in both human aortic smooth muscle cells and TM4 cells.     

Tissue-specific expression of a novel GTP-binding protein (smg p25A) mRNA and its increase by nerve growth factor and cyclic AMP in rat pheochromocytoma PC-12 cells

We have purified a novel GTP-binding protein, designated as the smg-25A protein (smg p25A), from bovine brain membranes and determined its primary structure. In the present studies, the smg-25A mRNA levels in various tissues have been studied. The 1.6-kilobase smg-25A mRNA is detected in rat brain by Northern blot analysis. This mRNA is not detected in other rat tissues including thymus, lung, heart, liver, small intestine, kidney, and skeletal muscle. The 1.6-kilobase smg-25A mRNA is also detected in bovine adrenal medulla but not in the cortex. Moreover, this mRNA is detected in rat pheochromocytoma PC-12 cells and its level increases after differentiation of the cells into sympathetic neuron-like cells in response to nerve growth factor or dibutyryl cyclic AMP. This mRNA level does not increase in response to 12-O-tetradecanoylphorbol-13-acetate incapable of inducing differentiation. These results suggest that the smg-25A gene is specifically expressed in nerve tissues and that smg p25A plays a role in some neuronal functions.     

Cytosolic enzymes from rat tissues that activate the cooked meat mutagen metabolite N-Hydroxyamino-1-methyl-6- phenylimidazo[4,5-b]pyridine (N-OH-PhIP)

Heterocyclic amines are formed during the cooking of foods rich in protein and can be metabolically converted into cytotoxic and mutagenic compounds. These "cooked-food mutagens" constitute a potential health hazard because DNA damage arising from dietary exposure to heterocyclic amines can modify cell genomes and thereby affect future organ function. To determine enzymes responsible for heterocyclic amine processing in mammalian tissues, we performed studies to measure genotoxic activation of the N-hydroxy form of 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP) --a common dietary mutagen. O-Acetyltransferase, sulfotransferase, kinase, and amino-acyl synthetase activities were assayed using substrate-specific reactions and cytosolic enzymes from newborn and adult rat heart, liver, spleen, kidney, brain, lung, and skeletal muscle. The resultant enzyme-specific DNA adduct formation was quantified via (32)P-postlabeling techniques. In biochemical assays with rat tissue cytosolic proteins, O-acetyltransferases were the enzymes most responsible for N-hydroxy-PhIP (N-OH-PhIP) activation. Compared to O-acetyltransferase activation, there was significantly less kinase activity and even lesser amounts of sulfotransferase activity. Proyl-tRNA synthetase activation of N-OH-PhIP was not detected. Comparing newborn rat tissues, the highest level of O-acetyltransferase mutagen activation was observed for neonatal heart tissue with activities ranked in the order of heart > kidney > lung > liver > skeletal muscle > brain > spleen. Enzymes from cultured neonatal myocytes displayed high O-acetyltransferase activities, similar to that observed for whole newborn heart. This tissue specificity suggests that neonatal cardiac myocytes might be at greater risk for damage from dietary heterocyclic amine mutagens than some other cell types. However, cytosolic enzymes from adult rat tissues exhibited a different O-acetyltransferase activation profile, such that liver > muscle > spleen > kidney > lung > brain > heart. These results demonstrated that enzymes involved in catalyzing PhIP-DNA adduct formation varied substantially in activity between tissues and in some tissues, changed significantly during development and aging. The results further suggest that O-acetyltransferases are the primary activators of N-OH-PhIP in rat tissues.