A new member of the insulin receptor family, insulin receptor-related receptor, is expressed preferentially in the kidney.

Shier and Watt isolated human and guinea pig genomic DNA encoding a putative protein, insulin receptor-related receptor (IRR), the primary structure of which is similar to that of other members of the insulin receptor family, the insulin receptor and type-I IGF receptor (J. Biol. Chem. 264, 14605-14608 (1989)). However, the expression of the IRR gene remained unknown. In this paper, we isolated the IRR cDNA from the rat brain and examined the expression of the IRR mRNA in a variety of rat tissues, including the brain, heart, lung, liver, small intestine, kidney, thymus, spleen, muscle, adipose tissue and cartilage by polymerase chain reaction. In contrast to the wide distribution of the insulin receptor and type-I IGF receptor mRNAs, the IRR mRNA is expressed preferentially in the kidney, which indicates that IRR has unique functions as a member of the insulin receptor family.     

Triiodothyronine nuclear binding capacity in rat tissues correlates with a 6.0 kilobase (kb) and not a 2.6 kb messenger ribonucleic acid hybridization signal generated by a human c-erbA probe

Recent studies have raised the possibility of multiple structurally distinctive tissue-specific nuclear T3 receptors, all exhibiting homology with the v-erbA oncogene and represented by mRNAs of various sizes. We have assayed the level of mRNAs recognized by a 32P-labeled cRNA derived from human plancetal c-erbA-A beta cDNA by solution hybridization and by Northern transfer in different rat tissues, as well as human liver and placenta. Two related mRNAs were demonstrated in the rat tissues analyzed, one measuring 6.0 and the other 2.6 kilobases (kb). In human liver and placenta a 6.0 kb mRNA was seen, but not a 2.6 kb mRNA. Only the 6.0 kb sequence correlated with the receptor concentration determined by 125I-T3 displacement analysis.     

Cloning and sequencing of a rat CuZn superoxide dismutase cDNA. Correlation between CuZn superoxide dismutase mRNA level and enzyme activity in rat and mouse tissues

The molecular cloning and nucleotide sequence of a cDNA clone (pR SOD) for rat CuZn superoxide dismutase (CuZnSOD) is reported. Nucleotide sequence homology with human superoxide dismutase is 86% for the coding region and 71% for the 3' untranslated region. The deduced amino acid sequence is given and the homologies with the sequences reported for other species are presented. Northern blot analysis of total RNA from various rat and mouse tissues and from two mouse cell lines show that pR SOD hybridizes with one mRNA species of about 0.7 kb. The amount of CuZnSOD mRNA in each tissue, measured by densitometry of the Northern blot autoradiograms, correlates with the enzymatic activity based on protein content. These results indicate that the control of CuZnSOD activity in mammalian tissues is largely dependent on the regulation of CuZnSOD mRNA levels. In human liver, fibroblasts and FG2 hepatoma cells, two CuZnSOD mRNAs (0.7 kb and 0.9 kb) are observed. The level of CuZnSOD mRNA in FG2 is 25% that of the liver and four times more abundant than in fibroblasts.     

Expression of ceruloplasmin gene in mammalian organs from the data of hybridization analysis with complementary DNA probes

Expression of ceruloplasmin (Cp)-coding gene in rat and human liver and brain tissues was studied by Northern blot hybridization and by in situ hybridization with cloned species-specific cDNA probes. In rat brain structures, different levels of Cp mRNA were detected, the maximal one was found in cerebellum. The steady-state level of Cp mRNA in rat and human brain was several times lower than in parenchymatous liver cells. The size heterogeneity of Cp mRNA was found. Polyadenylated RNA prepared from human liver contains two equally abundant Cp mRNAs differing in their chain length (3.6 and 4.5 kb) while brain polyadenylated RNA contains a single Cp mRNA (4.5 kb).     

Somatomedin-C/insulin-like growth factor-I and insulin-like growth factor-II mRNAs in rat fetal and adult tissues

Somatomedin-C or insulin-like growth factor I (Sm-C/IGF-I) and insulin-like growth factor II (IGF-II) have been implicated in the regulation of fetal growth and development. In the present study 32P-labeled complementary DNA probes encoding human and mouse Sm-C/IGF-I and human IGF-II were used in Northern blot hybridizations to analyse rat Sm-C/IGF-I and IGF-II mRNAs in poly(A+) RNAs from intestine, liver, lung, and brain of adult rats and fetal rats between day 14 and 17 of gestation. In fetal rats, all four tissues contained a major mRNA of 1.7 kilobases (kb) that hybridized with the human Sm-C/IGF-I cDNA and mRNAs of 7.5, 4.7, 1.7, and 1.2 kb that hybridized with the mouse Sm-C/IGF-I cDNA. Adult rat intestine, liver, and lung also contained these mRNAs but Sm-C/IGF-I mRNAs were not detected in adult rat brain. These findings provide direct support for prior observations that multiple tissues in the fetus synthesize immunoreactive Sm-C/IGF-I and imply a role for Sm-C/IGF-I in fetal development as well as postnatally. The abundance of a 7.5-kb Sm-C/IGF-I mRNA in poly(A+) RNAs from adult rat liver was 10-50-fold higher than in other adult rat tissues which provides further evidence that in the adult rat the liver is a major site of Sm-C/IGF-I synthesis and source of circulating Sm-C/IGF-I. Multiple IGF-II mRNAs of estimated sizes 4.7, 3.9, 2.2, 1.75, and 1.2 kb were observed in fetal rat intestine, liver, lung, and brain. The 4.7- and 3.9-kb mRNAs were the major hybridizing IGF-II mRNAs in all fetal tissues. Higher abundance of IGF-II mRNAs in rat fetal tissues compared with adult tissues supports prior hypotheses, based on serum IGF-II concentrations, that IGF-II is predominantly a fetal somatomedin. IGF-II mRNAs are present, however, in some poly(A+) RNAs from adult rat tissues. The brain was the only tissue in the adult rat where the 4.7- and 3.9-kb IGF-II mRNAs were consistently detected. Some samples of adult rat intestine contained the 4.7- and 3.9-kb IGF-II mRNAs and some samples of adult liver and lung contained the 4.7-kb mRNA. These findings suggest that a role for IGF-II in the adult rat, particularly in the central nervous system, cannot be excluded.     

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.     

Gene expression for a novel protein RGPR-p117 in various species: the stimulation by intracellular signaling factors

The presence and expression for the gene encoding a novel regucalcin gene promoter region-related protein (RGPR-p117) in various species was investigated by using Southern "zoo blot" and Northern hybridization analyses. A "zoo blot" analysis demonstrated that RGPR-p117 gene was widely conserved in various species including human, rat, mouse, dog, cow, pig, rabbit, chicken, fish, C. elegans and yeast. The gene was not found in Xenopus. Northern blot analysis showed that RGPR-p117 mRNA was expressed in the liver of human, rat, mouse, and rabbit as a single mRNA of approximately 4.5 kb, respectively. However, homologous mRNA was not found in the liver of Xenopus. The expression of RGPR-p117 mRNA in liver was clearly enhanced 5 h after a single intraperitoneal administration of CaCl(2) (5 mg Ca(2+)/100 g body weight) to rats. The RGPR-p117 mRNA is also expressed in the cloned H4-II-E rat hepatoma cells, although this expression was weak as compared with that of liver tissues. Moreover, the RGPR-p117 mRNA expression in H4-II-E cells was stimulated in the presence of dibutyryl cAMP, PMA, insulin, 17beta-estradiol, or serum in culture medium. The present study demonstrates that the RGPR-p117 gene is conserved in various species, and that its expression is stimulated by intracellular signaling factors.     

Localization of mRNAs encoding the alpha-subunits of signal-transducing G-proteins within rat brain and among peripheral tissues

The sequence of the mRNAs which encode the alpha-subunits of the signal-transducing G-proteins Gs, Go and two forms of Gi (termed Gi1 and Gi2) have recently been reported. Based on rat sequences we prepared oligodeoxynucleotide probes for measurement of these mRNAs in rat brain and peripheral tissues. The relative abundance of these mRNA species in brain was Gs greater than Go approximately Gi2 greater than Gi1. The Gs and Gi2 mRNAs had somewhat lower levels in heart, kidney and liver than in brain, and Go and Gi1 mRNAs were not detected in the peripheral tissues. Using in situ hybridization we localized each of these mRNAs within slices of the rat brain. The patterns of distribution of Gs and Gi2 mRNA were very similar, but very different from that of Go and Gi1 mRNA. These data illustrate that receptor-effector coupling G-proteins are regionally specialized in their expression. This regional specialization may reflect a selective coupling of individual G-proteins with the various neurotransmitter receptors and effector pathways.     

Regional Distribution of the GABAA/Benzodiazepine Receptor (α Subunit) mRNA in Rat Brain

A human cDNA clone containing the 5' coding region of the GABAA/benzodiazepine receptor alpha subunit was used to quantify and visualize receptor mRNA in various regions of the rat brain. Using a [32P]CTP-labelled antisense RNA probe (860 bases) prepared from the alpha subunit cDNA, multiple mRNA species were detected in Northern blots using total and poly A rat brain RNA. In all brain regions, mRNAs of 4.4 and 4.8 kb were observed, and an additional mRNA of 3.0 kb was detected in the cerebellum and hippocampus. The level of GABAA/benzodiazepine receptor mRNA was highest in the cerebellum followed by the thalamus = frontal cortex = hippocampus = parietal cortex = hypothalamus much greater than pons = striatum = medulla. In situ hybridization revealed high levels of alpha subunit mRNA in cerebellar gray matter, olfactory bulb, thalamus, hippocampus/dentate gyrus, and the arcuate nucleus of the hypothalamus. These data suggest the presence of multiple GABAA/benzodiazepine receptor alpha subunit mRNAs in rat brain and demonstrate the feasibility of studying the expression of genes encoding the GABAA/benzodiazepine receptor after pharmacological and/or environmental manipulation.     

Insulin receptor gene expression during development: developmental regulation of insulin receptor mRNA abundance in embryonic rat liver and yolk sac, developmental regulation of insulin receptor gene splicing, and comparison to abundance of insulin-like growth factor 1 receptor mRNA.

Insulin gene expression has been demonstrated in nonpancreatic tissues early in development, suggesting that this hormone might have actions significant for the differentiating embryo. Because such actions imply ligand-receptor binding, we quantified mRNAs encoding the two known forms of insulin receptor in rat liver and yolk sac, two endodermally derived tissues shown to express insulin genes, between gestation days (E) 13 and E21 (mid-organogenesis to parturition). Because of its presumed importance for fetal growth, we estimated the abundance of mRNA encoding insulin-like growth factor 1 (IGF 1) receptor in the same samples for comparison. The abundance of insulin receptor mRNA exceeded that for IGF 1 receptor mRNA in liver and yolk sac at all times studied. This difference was greater in liver, where insulin receptor mRNAs were three to more than 50 times more abundant than IGF 1 receptor mRNA on gestation days E13-E16, times which antedate the development of significant hepatic metabolic actions of insulin. The marked abundance of mRNAs encoding insulin receptors is consistent with the hypothesis that insulin has significant actions in specific tissues during the organogenic period.     

Developmental regulation of calmodulin gene expression in rat brain and skeletal muscle.

Three different calmodulin genes that encode the identical protein have been identified in the rat (Nojima, 1989); however, calmodulin gene expression at the various stages of tissue differentiation and maturation has not been previously determined. We have quantitated the content of mRNAs encoding calmodulin in the developing brain and skeletal muscle using RNA blot analysis with three specific cDNA probes. Our results show that five species of calmodulin mRNAs: 4.0 and 1.7 kb for CaM I, 1.4 kb for CaM II, and 2.3 and 0.8 kb for CaM III are detectable at all ages in the brain as well as in skeletal muscle but exhibit a tissue-specific developmental pattern of expression. The comparison of the temporal pattern of calmodulin gene expression with both mitotic activity, as demonstrated by cyclin A mRNA levels, and differentiation and maturation of specific brain or muscle regions is consistent with calmodulin involvement in development.     

Tissue-specific regulation of rat estrogen receptor mRNAs

The estrogen receptor (ER) is present in a wide variety of mammalian tissues and is required for physiological estrogen responses, including estrogen-induced tissue-specific changes in gene expression. We studied the estrogen regulation of the mRNAs encoding the ER in rat uterus, liver, and pituitary. Ovariectomized (21-28 day post surgery) female CD-1 rats were injected daily with 17 beta-estradiol (E2, 10 micrograms/100 g BW) for 0, 1, or 4 h, 1, 3, or 7 days and compared with intact controls. Steady-state levels of ER mRNA were quantified using a human ER cDNA probe. Only one hybridizing species of approximately 6.2 kilobase (kb) was detected in uterine and liver RNA, similar to that observed in MCF7 human breast cancer cells. However, the ER mRNA regulation by E2 differed in direction depending on the tissue examined. In uterus, ER mRNA increased 3- to 6-fold after ovariectomy, and returned to intact levels within 24 h of E2 replacement. In contrast, liver ER mRNA declined 1.5- to 3-fold after ovariectomy and returned to intact levels after 1-3 days of E2. In pituitary tissue two hybridizing forms of ER mRNA were observed, with one species migrating at 6.2 kb, equivalent to the form in other tissues, and a second smaller species at approximately 5.5 kb. The lower molecular weight species varied somewhat in abundance from animal to animal, averaging about 20% of the intensity of the 6.2 kb band. The ER mRNA forms were regulated positively with E2.(ABSTRACT TRUNCATED AT 250 WORDS)     

Epidermal growth factor receptor mRNA in livers from newborn, adult and partially hepatectomized rats

Epidermal growth factor (EGF) receptor mRNA expression in livers of newborn, adult control and partially hepatectomized rats 1 and 3 days post-operation was examined by Northern blot analysis. A human EGF receptor cDNA (P 64-1, Ullrich et al., 1984) was hybridized to RNA species of 10, 6 and 3 kb. These mRNAs were profoundly decreased in livers from newborn rats and relatively decreased in regenerating rat livers. beta-Actin mRNA in these tissues showed a tendency to increase over that of the adult controls.     

Mouse glutamine synthetase is encoded by a single gene that can be expressed in a localized fashion

Two mouse glutamine synthetase (GSase) cDNAs were cloned that correspond to the 2.8 kb and 1.4 kb mRNA species found in many mouse tissues (1 kb = 10(3) base-pairs). There is a sequence homology of about 90% to other mammalian GSase cDNAs in the coding region. A 2.1 kb mRNA can be discerned in fat tissue, the most abundant source of GSase mRNA. Three genomic clones G4, G21 and G2 contain GSase sequences. By several criteria G21 and G2 are pseudogenes, while G4 is a functional gene composed of seven exons and six introns. Primer extension, RNase protection and Northern analysis provide evidence that all tissues use the same major RNA start site and the different-sized mRNAs are due to the usage of two different poly(A) sites, neither of which has the consensus AAUAAA sequence. When tested by transfection into Hep G2 human hepatoma cells the G4 promoter can produce correctly initiated mRNA with only 350 base-pairs of 5' regulatory sequences. A major interest in GSase expression is its restriction to pericentral hepatocytes in adult liver. In this paper we show by in situ hybridization that GSase mRNA is only found in glial cells in the adult brain and in proximal tubular epithelium of the kidney. Coupled with the earlier demonstration of expression of GSase only in pericentral hepatocytes, it is clear that this gene is regulated by position-specific signals in many cell types.