Regulation of rat liver maturation in vitro by glucocorticoids.

The biochemistry of liver maturation was studied by using the RLA209-15 fetal rat hepatocyte line that is temperature sensitive for maintenance of the differentiated fetal liver phenotype. At 33 degrees C these cells were dedifferentiated; but at 40 degrees C they were phenotypically differentiated and, like normal fetal hepatocytes, synthesized moderate levels of albumin and transferrin, high levels of authentic (69,000 and 73,000 molecular weight) rat fetal alpha-fetoprotein (AFP), and low levels of a 65,000-molecular-weight variant AFP. Our results indicated that administration of glucocorticoid hormones to RLA209-15 cells at 40 degrees C induced a series of events associated with normal hepatocyte maturation; synthesis of fetal AFP was inhibited, whereas the synthesis of variant AFP, albumin, transferrin, tyrosine aminotransferase, and alpha 1-acid glycoprotein was induced. The variant AFP was produced by RLA209-15 cells at both temperatures and was encoded by an mRNA of 1.7 kilobases (kb). The fetal AFP was encoded by an mRNA of 2.2 kb. Normal adult rat liver contained three AFP mRNAs of 2.2 (minor), 1.7, and 1.5 kb. The 1.7-kb adult liver AFP mRNA comigrated with the RNA found in RLA209-15 cells, and both directed the synthesis of a 50,000-molecular-weight precursor polypeptide of the variant AFP. Administration of glucocorticoids to RLA209-15 cells grown at 33 degrees C stimulated synthesis of both the fetal and variant AFPs, but the levels of the 2.2-kb AFP mRNA were preferentially increased. RLA209-15 cells contained two glucocorticoid receptor mRNAs of 6.8 and 4.5 kb. The glucocorticoid-mediated maturation described above was blocked by the antiglucocorticoid RU486.     

Expression of the thyroid hormone receptor gene, erbAalpha, in B lymphocytes: alternative mRNA processing is independent of differentiation but correlates with antisense RNA levels.

The erbAalpha gene encodes two alpha-thyroid hormone receptor isoforms, TRalpha1 and TRalpha2, which arise from alternatively processed mRNAs, erbAalpha1 (alpha1) and erb alpha2 (alpha2). The splicing and alternative polyadenylation patterns of these mRNAs resemble that of mRNAs encoding different forms of immunoglobulin heavy chains, which are regulated at the level of alternative processing during B cell differentiation. This study examines the levels of erbAalpha mRNA in eight B cell lines representing four stages of differentiation in order to determine whether regulation of the alternatively processed alpha1 and alpha2 mRNAs parallels the processing of immunoglobulin heavy chain mRNAs. Results show that the pattern of alpha1 and alpha2 mRNA expression is clearly different from that observed for immunoglobulin heavy chain mRNAs. B cell lines display characteristic ratios of alpha1/alpha2 mRNA at distinct stages of differentiation. Furthermore, expression of an overlapping gene, Rev-ErbAalpha (RevErb), was found to correlate strongly with an increase in the ratio of alpha1/alpha2 mRNA. These results suggest that alternative processing of erbAalpha mRNAs is regulated by a mechanism which is distinct from that regulating immunoglobulin mRNA. The correlation between RevErb and erbAalpha mRNA is consistent with negative regulation of alpha2 via antisense interactions with the complementary RevErb mRNA.     

Fetal and variant alpha-fetoproteins are encoded by mRNAs that differ in sequence at the 5' end

The temperature-sensitive RLA209-15 fetal rat hepatocyte line grown at the nonpermissive temperature (40 degrees C, normal phenotype) produces authentic rat alpha-fetoproteins (AFPs) of 69K and 73K (fetal AFPs) which are encoded by a 2.2-kb mRNA. These cells also produce low levels of a 1.7-kb AFP mRNA and a 65K variant AFP when grown at the permissive temperature (33 degrees C, transformed phenotype). Hybrid-selected translation demonstrates that the 1.7-kb AFP mRNA encodes the 65K variant AFP. Northern blot hybridization and S1 nuclease analyses indicate that the 1.7-kb mRNA lacks sequences present in the first seven 5' exons of the 2.2-kb AFP mRNA. However, the 1.7- and 2.2-kb AFP mRNAs share common sequences extending from the beginning of the eighth exon (corresponding to nucleotide 873 of the fetal AFP mRNA) to the 3' end. Primer extension analysis suggests that the 1.7-kb RNA contains additional sequences 5' to the common regions shared by both AFP mRNAs. We have previously shown that adult rat liver produces a 1.7-kb AFP mRNA; we now report the isolation of a cDNA (ARFP5) encoding this variant AFP mRNA from an adult rat liver cDNA library. Restriction endonuclease mapping and sequence analysis of ARFP5 confirm that the 1.7- and 2.2-kb AFP mRNAs share similar sequences at the 3' region (approximately 1.1 kb). However, ARFP5 contains an additional 90 bp variant AFP mRNA-specific 5' sequence which is located in the seventh intron of the rat AFP gene.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of three beta-tubulin mRNAs during rat brain development.

The nucleotide sequence of a complete rat brain beta-tubulin T beta 15 has been determined from three overlapping cDNA clones. The overall length of the T beta 15 sequence is 1589 bp and shows between 84.5% and 88.6% homology within the coding region as compared with chick and human beta-tubulin sequences. On the other hand, the 3'-non-coding region is highly divergent. Comparison of the derived amino acid sequences from different species demonstrates that the amino acid changes are not randomly distributed, but rather there are several conserved and two highly variable regions common to beta-tubulin polypeptides from various sources. The T beta 15 sequence encodes a dominant neuronal 1.8-kb beta-tubulin mRNA species. Two other minor beta-tubulin mRNA species of 2.6 and 2.9 kb are present in rat brain. By using two synthetic oligonucleotide probes complementary to the carboxyl-terminal divergent region and to the amino-terminal conserved region, we have shown that the three mRNAs are distinct species, which are developmentally regulated. The level of the 1.8-kb mRNA species increases till the age of 12 days thereafter its level decreases. The 2.9-kb mRNA is an early neuronal mRNA species, while the 2.6-kb mRNA is a late neuronal species which is detected at 30 days of rat brain development. The data illustrate that there is a differential expression of the beta-tubulin multigene family during rat brain development which may suggest different functions for the various beta-tubulin isotopes.     

Differential expression of two neural cell-specific beta-tubulin mRNAs during rat brain development.

We recently demonstrated that beta-tubulin mRNA expression is regulated during rat brain development. This is manifested by a dramatic decrease in both 1.8- and 2.9-kilobase (kb) mRNAs when extensive neurite elongation is occurring. Coincident with these decreases is the increased production of a 2.5-kb mRNA. (J.F. Bond and S.R. Farmer, Mol. Cell. Biol. 3:1333-1342, 1983). In the present study, we have isolated and characterized three different cDNAs corresponding to beta-tubulin mRNAs (R beta T.1, R beta T.2, and R beta T.3). Hybridization of 3' untranslated region subclones of R beta T.1 and R beta T.2 cDNAs to RNA from a variety of rat tissues and cells revealed that these two cDNAs are neural cell specific. R beta T.1 corresponds to an abundant 1.8-kb mRNA expressed only at early stages of rat brain development. R beta T.2 corresponds to the 2.5-kb mRNA expressed at later stages. These data strongly suggest that there is differential expression of the beta-tubulin multigene family during rat brain development.     

Sequence complementarity between the 5'-terminal regions of mRNAs for rat mitochondrial cytochrome P-450c27/25 and a growth hormone-inducible serine protease inhibitor. A possible gene overlap.

Recently we reported that a P-450c27/25 cDNA probe hybridizes to two RNA species of about 1.9 and 2.3-2.4 kilobase pairs (kb) in some rat tissues. To understand the molecular relationship between the two mRNAs, we have isolated and characterized a cDNA for the larger, previously uncharacterized 2.3-kb mRNA species. The 2.3-kb cDNA is identical to the previously reported 1.9-kb P-450c27/25 cDNA excepting a 400-nucleotide-long 5' extension. The terminal 291 nucleotides of this extension exhibit 100% complementarity with the 5'-translated region of the mRNA belonging to a family of growth hormone-inducible serine protease inhibitors (SPI). Northern blot analysis, using strand-specific probes, and S1 nuclease protection revealed the presence of the 2.3-kb mRNA exhibiting the sequence characteristics of the larger cDNA. These results were further confirmed by polymerase chain reaction amplification of reverse transcribed RNA. Expression of the 2.3-kb cDNA in COS cells resulted in the correct mitochondrial targeting of a 52-kDa protein exhibiting the properties of P-450c27/25. Furthermore, both the 1.9- and 2.3-kb mRNAs appear to direct the synthesis of a similarly sized 55-kDa precursor protein in a reticulocyte lysate system. Restriction mapping, polymerase chain reaction amplification and partial sequencing of a 25-kb genomic DNA clone suggest the proximal location of the SPI and the P-450c27/25 protein coding regions in the rat genome on either side of a common overlap region. The results also show that the P-450c27/25 mRNAs are regulated by growth hormone in parallel to the SPI mRNAs. These results collectively suggest that a growth hormone-inducible SPI family mRNA and the P-450c27/25 mRNA are encoded by two closely linked, possibly overlapping genes.     

Regulation of two c-erbA messenger ribonucleic acids in rat GH3 cells by thyroid hormone

There is recent evidence suggesting that c-erbA is the thyroid hormone nuclear receptor, and that there may be multiple c-erbA genes. We investigated the effect of T3 on two c-erbA mRNAs present in GH3 cells. A partial cDNA was isolated from rat GH3 cells which is nearly identical (99.6% nucleotide identity) to rat c-erbA alpha, except for a unique 3'-region corresponding to the carboxyl terminal region of the predicted protein sequence. This cDNA (c-erbA alpha-2), like rat c-erbA alpha, hybridizes to a 2.6 kilobase (kb) mRNA which is distinct from a 6.2 kb species that hybridizes to c-erbA beta. Since nuclear T3-binding is down-regulated by T3, we hypothesized that one or both c-erbA mRNAs might be regulated by T3. GH3 cells were treated with 10 nM T3 for up to 24 h, a manipulation known to decrease nuclear T3 binding by approximately 2-fold in GH cells. Both the 6.2 kb and 2.6 kb mRNA species decreased to nearly 50% of control values at 24 h. These data indicate that these two c-erbA mRNAs are regulated by T3 and suggest that the T3 effect on T3 binding-activity in GH cells may be mediated, in part, by down-regulation of c-erbA mRNA levels.     

Alternative splicing model for the synthesis and secretion of the 20 kilodalton form of rat growth hormone

The characterization of a 20 kilodalton (20 kD) variant of rat growth hormone is reported. The 20 kD variant from rat pituitary gland extracts was identified on Western immunoblots of polyacrylamide gels. It was also shown that pituitary tissue maintained in culture secretes the 20 kD form. A rat growth hormone cDNA fragment was used as a probe in S1 nuclease mapping experiments of rat pituitary poly (A) mRNA to detect the presence of two growth hormone mRNAs in the rat pituitary gland. The protected mRNAs correspond to the predicted sizes that would encode the 22 kD and 20 kD forms of growth hormone. The site of variation between the mRNAs maps to a potential alternative 3' splice site in the 5' end of exon 3 of the coding sequence. The results support the hypothesis that the 20 kD variant in rat is the product of an mRNA alternatively spliced in exon 3, as is the case for the human growth hormone.     

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.     

Isolation and functional expression of pituitary peptidylglycine alpha-amidating enzyme mRNA. A variant lacking the transmembrane domain

We demonstrate that, in rat pituitary, peptidylglycine alpha-amidating enzyme was encoded by at least 5 distinct mRNAs. Southern blot and ribonuclease protection analyses revealed that the mRNAs arose through alternative splicing. A variant lacking the transmembrane domain-coding sequence was a major mRNA species for the enzyme in the pituitary. When the cDNAs were expressed in COS-7 cells, the variant was the most efficient in producing a secretory form (37 kDA) of the enzyme.     

Expression of Tropomyosin Genes During the Development of the Rat Cerebellum

The expression of the tropomyosin genes in the rat nervous system was examined during the postnatal development of the cerebellum, using human-specific alpha-, beta-, gamma-, and delta-tropomyosin cDNA probes and rat-specific alpha-, beta-, and delta-tropomyosin oligonucleotide probes. The beta- and gamma-genes do not seem to be expressed in the rat brain. The delta-tropomyosin gene produces two mRNAs: a major one of 2.4 kb, which is highly concentrated during the first postnatal week and then decreases fourfold in level until the age of 35 days, and a minor one of 2 kb, with the same developmental profile as the 2.4-kb mRNA. A 3-kb mRNA is expressed by the alpha-tropomyosin gene and is characteristic of the mature rat. The expression of the tropomyosin genes during the development of the rat cerebellum does not seem to be regulated through alternative splicing but rather implies the differential expression of two different isogenes. The multiple isoforms of tropomyosin produced during neuronal differentiation may be intimately involved in the regulation of the organization and function of actin microfilaments.     

Expression of three forms of thyroid hormone receptor in human tissues

At least two thyroid hormone receptor (hTR) genes are present in humans, but the significance of this multiplicity is unknown. These receptors could have differences in tissue distribution or possess different functions. We studied the distribution and abundance of three hTR mRNAs (hTR beta, hTR alpha 1, and hTR alpha 2) by Northern blot analysis. Three mRNAs were expressed in all tissues examined. hTR beta was strongly expressed in brain and prostate predominantly as a 10.0-kilobase (kb) mRNA. This mRNA was also expressed in thyroid and was much less abundant in liver, kidney, placenta, tonsil, and spleen. hTR alpha 1 is represented by two mRNAs with sizes of 6.0 and 3.2 kb. The 6.0-kb mRNA was constantly less abundant than the 3.2-kb mRNA. hTR alpha 2 was detected as a single mRNA with a size of 3.2 kb, using a probe unique for this mRNA. Both hTR alpha 1 and hTR alpha 2 were strongly expressed in brain, prostate, and thyroid and much less in other tissues. The relative amounts of the three hTR mRNAs were roughly parallel in each tissue. It is of interest that none of these hTRs was abundant in liver, which is the major thyroid hormone-responsive organ. Another hTR may be present in liver.     

Variation in insulin receptor messenger ribonucleic acid expression in human and rodent tissues

The expression of insulin receptor mRNA was studied in human and rodent tissues by Northern analysis. Human EBV-transformed lymphocytes contained four receptor mRNA species of sufficient length to encode the entire proreceptor: 9.5, 7.9, 7.1, and 5.7 kb. In human fibroblasts, the same four species were observed; however, the 7.9 and 5.7 kb mRNAs were markedly decreased. In mouse liver, rat hepatoma cells, and normal rat brain, kidney, liver, and muscle only two mRNA species (7.4 and 9.6 kb) were detected. Each of these human and rodent mRNAs hybridized equally well with cDNA sequences encoding the binding and kinase domains of the insulin receptor. Several smaller polyadenylated mRNAs (approximately 1.8 to 3.3 kb) were also identified in human cell lines that appeared to separately encode either alpha- or beta-subunit sequences of the receptor. In rats, liver had the highest content of insulin receptor mRNA, followed by kidney, brain, and muscle. The relative amount of the two mRNA species also varied among the rat tissues. The ratio of the 9.6-7.4 kb species was 2.7 in brain but only 1.0 to 1.6 in the other tissues (P less than 0.025). Dexamethasone treatment increased the content of the two insulin receptor mRNAs in rat liver by 2-fold. The half-life of both mRNA species was 70 min in rat hepatoma cells. These findings indicate that insulin receptor gene expression is complex and regulated with differential expression of insulin receptor mRNA and/or alterations in mRNA processing among various tissues.