Properties of rat and mouse beta-glucuronidase mRNA and cDNA, including evidence for sequence polymorphism and genetic regulation of mRNA levels

cDNA clones containing partial sequences for beta-glucuronidase (beta G) were constructed from rat preputial gland RNA and identified by their ability to selectively hybridize beta G mRNA. One such rat clone was used to isolate several cross-hybridizing clones from a mouse-cDNA library prepared from kidney RNA from androgen-treated animals. Together, the set of mouse clones spans about 2.0 kb of the 2.6-kb beta G mRNA. Using these cDNA clones as probes, a genomic polymorphism for DNA restriction fragment size was found that proved to be genetically linked to the beta G gene complex. A fragment of beta G cDNA was subcloned into a vector carrying an SP6 polymerase promoter to provide a template for the in vitro synthesis of single-stranded RNA complementary to beta G mRNA. This provided an extremely sensitive probe for the assay of beta G mRNA sequences. Using either nick-translated cDNA or transcribed RNA as a hybridization probe, we found that mouse beta G RNA levels are strongly induced by testosterone, and that induction by testosterone is pituitary-dependent. During the lag period preceding induction, during the induction period itself, and during deinduction following removal of testosterone, beta G mRNA levels paralleled rates of beta G synthesis previously measured by in vivo pulse-labelling experiments. Genetic variation in the extent of induction affected either the level of beta G mRNA or its efficiency of translation depending on the strain of mice tested.     

Genetic Mapping of a Possible New Alcohol Dehydrogenase Sequence to Mouse Chromosome 3 at the Adh-1/Adh-3 Complex

Southern blot analysis of mouse genomic DNA reveals two Eco RI fragments which faintly hybridize to mouse Adh-1 cDNA and are not part of the Adh-1 gene. These fragments were isolated from agarose gels, cloned, and characterized. Sequence analysis of the 2.1-kb Eco RI fragment suggests that it is likely a pseudogene since it does not contain a long open reading frame. However, the 2.0-kb Eco RI fragment contains a coding sequence with a long open reading frame which corresponds to exon 6 of the mouse Adh-1 gene. Comparison of the coding sequence with other known ADHs suggests that the sequence has diverged sufficiently from any currently known class of ADH to be a possible distinct class. Further confirmation awaits analysis of currently available genomic clones. Using these sequences as probe, restriction fragment length polymorphisms were identified for each sequence between C57Bl/6J and DBA/2J inbred mouse strains. The strain distribution pattern for these allelic differences was determined among the B × D recombinant inbred strains. This analysis revealed that the 2.1-kb Eco RI sequence is located on chromosome 3 but at a distance from the Adh-1/Adh-3 complex as previously reported. However, the new polymorphism identified in the 2.0-kb Eco RI fragment enabled this sequence to be mapped at the Adh-1/Adh-3 complex.     

Molecular cloning, nucleotide sequence, and tissue distribution of malonyl-CoA decarboxylase

Malonyl-CoA decarboxylase was purified from goose uropygial gland, reduced, carboxymethylated, and digested with trypsin. Several peptides were purified by high performance liquid chromatography and their amino acid sequences determined. Oligonucleotide probes were prepared based on their amino acid sequences. Size-selected RNA from the goose uropygial gland was used to construct cDNA libraries in lambda gt11 and pUC9 vectors. Immunological screening of the lambda gt11 cDNA library yielded one clone, lambda DC1, which contained a 2.2-kilobase pair insert; hybridization with the synthetic oligonucleotide probes confirmed its identity as malonyl decarboxylase. Screening of the pUC9 cDNA library with the insert of lambda DC1 as a probe detected one clone, pDC2, with an insert of 2.9 kilobase pairs. The nucleotide sequences of the two cDNAs revealed an open reading frame encoding a polypeptide of 462 amino acids. The deduced amino acid sequence was confirmed as malonyl-CoA decarboxylase by matching it to the amino acid sequences of three tryptic peptides derived from mature enzyme. Northern blot analysis of mRNA from goose brain, kidney, liver, lung, and gland revealed malonyl-decarboxylase mRNA of 3000 nucleotides. Since clone pDC2 contains a 2928-nucleotide insert, it represents nearly the full length of mRNA. Brain, kidney, lung, and liver contained less than 1% of the malonyl-CoA decarboxylase mRNA in the gland. Southern blot analysis of genomic DNA showed a single band in both liver and gland, suggesting that malonyl-CoA decarboxylase is a single copy gene.     

Connexin43: a protein from rat heart homologous to a gap junction protein from liver

Northern blot analysis of rat heart mRNA probed with a cDNA coding for the principal polypeptide of rat liver gap junctions demonstrated a 3.0- kb band. This band was observed only after hybridization and washing using low stringency conditions; high stringency conditions abolished the hybridization. A rat heart cDNA library was screened with the same cDNA probe under the permissive hybridization conditions, and a single positive clone identified and purified. The clone contained a 220-bp insert, which showed 55% homology to the original cDNA probe near the 5' end. The 220-bp cDNA was used to rescreen a heart cDNA library under high stringency conditions, and three additional cDNAs that together spanned 2,768 bp were isolated. This composite cDNA contained a single 1,146-bp open reading frame coding for a predicted polypeptide of 382 amino acids with a molecular mass of 43,036 D. Northern analysis of various rat tissues using this heart cDNA as probe showed hybridization to 3.0-kb bands in RNA isolated from heart, ovary, uterus, kidney, and lens epithelium. Comparisons of the predicted amino acid sequences for the two gap junction proteins isolated from heart and liver showed two regions of high homology (58 and 42%), and other regions of little or no homology. A model is presented which indicates that the conserved sequences correspond to transmembrane and extracellular regions of the junctional molecules, while the nonconserved sequences correspond to cytoplasmic regions. Since it has been shown previously that the original cDNA isolated from liver recognizes mRNAs in stomach, kidney, and brain, and it is shown here that the cDNA isolated from heart recognizes mRNAs in ovary, uterus, lens epithelium, and kidney, a nomenclature is proposed which avoids categorization by organ of origin. In this nomenclature, the homologous proteins in gap junctions would be called connexins, each distinguished by its predicted molecular mass in kilodaltons. The gap junction protein isolated from liver would then be called connexin32; from heart, connexin43.     

Three cDNA clones encoding mouse transplantation antigens: Homology to immunoglobulin genes

We constructed cDNA libraries from poly(A)⁺ RNA isolated from cell lines of two different inbred strains of mice, and screened the libraries with a cDNA clone encoding a human transplantation antigen. Three cDNA clones were identified, sequenced and found to encode amino acid sequences highly homologous to portions of a known mouse transplantation antigen. Comparison of the cDNA sequences of mouse transplantation antigens with the constant region domains of the mouse immunoglobulin μ gene reveals a striking homology, which suggests that the two genes share a common ancestor. Antibody genes undergo DNA rearrangements during B cell differentiation that are correlated with their expression. In contrast, DNA blots with these cDNA probes suggest that the genes for the transplantation antigens are not rearranged in the genomes of liver or embryo cells, which express these antigens, as compared with sperm cells, which do not express these antigens. In Bam HI-digested liver DNAs from different inbred strains of mice, 10–15 bands of hybridization were found. Accordingly, the genes encoding the transplantation antigens appear to constitute a multigene family with similar gene numbers in different mice.     

A frameshift mutation destabilizes androgen receptor messenger RNA in the Tfm mouse.

A composite mouse androgen receptor DNA sequence was obtained by amplifying genomic DNA or cDNA using the polymerase chain reaction. The open reading frame was 2,697 basepairs, encoding a polypeptide of 899 amino acids (98,204 mol wt). Amino acid sequence comparisons indicated that the mouse androgen receptor (AR) is 97% homologous with rat AR and 83% with human AR. The amino acid sequences of the three receptors are identical within the DNA- and steroid-binding domains. Northern blot analysis revealed the predominant mouse AR mRNA to be 10 kilobases (kb). A 1.7-kb mRNA species was detected in mouse kidney using a cDNA probe containing only 5' untranslated AR sequence. Lack of hybridization with AR-coding sequence probes suggested that the 1.7-kb mRNA was not a truncated form of AR mRNA. Sequencing of genomic DNA isolated from testicular feminized (Tfm) mice revealed a single base deletion in the N-terminal domain, resulting in a frameshift mutation. Cycloheximide treatment caused a dramatic increase in AR mRNA in kidneys of Tfm mice, but not wild-type mice, suggesting that the Tfm mutation results in an unstable AR mRNA.     

Molecular cloning and nucleotide sequence of a human renin cDNA fragment.

We have studied human renin messenger RNA by hybridization with the mouse submaxillary gland (SMG) renin cDNA probe. The human kidney messenger RNA is about 1.6 kilobase (kb) long, similarly to the mouse SMG renin mRNA. A kidney renin cDNA clone of 1.1 kb length was obtained. A comparison of nucleotide sequences of mouse and human cDNA clones reveals conservation of residues involved in catalytic mechanisms and a potential glycosylation site. The human renin molecular probe allowed us to study renin expression in human chorionic tissue. The chorionic and kidney renin messenger RNAs are similar in length. The Southern blot analysis reveals the presence of a single renin gene in human DNA.     

cDNA of a Novel mRNA Expressed Predominantly in Mouse Kidney

We examined embryonic carcinoma (EC) cells for a potential prototype molecule of C3, the third component of complement. PCR primers, corresponding to the base sequence derived from the C3 cDNA of several species, were used for PCR amplification of the EC cell cDNA. All the PCR products obtained had the same sequence and showed no sequence homology to C3. Subsequently, cDNA clones were isolated from a mouse liver cDNA library using the PCR product as a probe. Unexpectedly, neither the base sequence of the cDNA clones nor the amino acid sequence deduced from the cDNA showed homology to C3, although partial homology was observed to a number of sequences from EST databases. We designated this new clone NCU-G1. Northern hybridization experiments revealed that NCU-G1 is expressed constitutively not only in the mouse fetus but also in various mouse tissues, and is most abundant in the kidney cortex.     

Reciprocal regulation of sex-dependent expression of testosterone 15 alpha-hydroxylase (P-450(15 alpha)) in liver and kidney of male mice by androgen. Evidence for a single gene

Testosterone 15 alpha-hydroxylase activities and its mRNA levels are higher in kidneys than in livers from male 129/J mice. Castration of 129/J male mice resulted in repression of P-450(15 alpha) in kidney, but increased it in liver. Two types of cDNA (p15 alpha-29 (Type I) and -15 (Type II)) encoding P-450(15 alpha) were previously cloned from 129/J female livers (Burkhart, B.A., Harada, N., and Negishi, M. (1985) J. Biol. Chem. 260, 15357-15361). With the use of p15 alpha-29 as a probe, Type I and II P-450(15 alpha) cDNAs were isolated from libraries of 129/J kidney poly(A)+ RNA. The nucleotide sequences of the cDNAs showed that Type I and II cDNAs from liver and kidney were identical and shared 98.3% similarity. The deduced amino acid sequence from a full-length Type I cDNA indicated that Type I P-450(15 alpha) consists of 494 amino acids with a molecular weight of 56,594. Nine amino acid substitutions were found in the Type II clone in 432 amino acids overlapping Type I. Type I cDNA clones accounted for approximately 90% P-450(15 alpha) clones isolated from a male kidney library, whereas approximately 90% of cDNA clones in a female kidney library were Type II. Liver cDNA libraries from males and females contained similar ratios of Type I and II. Effects of castration on Type I and II mRNAs were determined by Southern hybridization of a 32P-labeled ClaI-ClaI fragment from p15 alpha-29 to cDNAs synthesized from kidney and liver poly(A)+ RNAs prepared from sham-operated, castrated 129/J mice. The double-stranded cDNAs were digested with ClaI and PstI prior to gel electrophoresis to create the diagnostic restriction fragments specific for Type I or II. Castration resulted in decreased levels of Type I mRNA in male kidney. In male liver, only Type I mRNA rose significantly in response to castration. Testosterone administration returned the Type I mRNA to normal levels in castrated mice. It therefore appears that the high levels of P-450(15 alpha) in male kidney were due to androgen-dependent induction of Type I mRNA. Both Types I and II were repressed in male liver, which results in decreased levels of P-450(15 alpha). Androgen was responsible for the repression and expression of Type I in liver and kidney, but not Type II.     

Cloning and regulation of messenger RNA for mouse apolipoprotein E

A cDNA clone for mouse apolipoprotein E has been identified from a mouse liver cDNA library by a combination of differential colony hybridization and hybrid selection-translation. The identity of the clone was unambiguously established by partial sequencing and comparison with human apolipoprotein E nucleotide and amino acid sequences. In conjunction with an in vitro translation assay for apolipoprotein E, the clone has been used to examine the relative levels of apolipoprotein E mRNA in various tissues of the mouse and the regulation of apolipoprotein E synthesis in response to a diet rich in saturated fat and cholesterol. In the tissues examined, the clone was found to hybridize to a polyadenylated RNA species of approximately 1400 nucleotides. Of the tissues involved in lipoprotein synthesis, liver is very rich (about 1% of total) in apolipoprotein E mRNA while intestine contains only trace amounts. Appreciable levels of active apolipoprotein E mRNA (up to 10% of that in liver) are also detected in peripheral tissues not associated with lipoprotein synthesis, including lung, kidney, spleen, and heart. Thus, extrahepatic apolipoprotein E synthesis may contribute significantly to the levels present in plasma, and a possible function in "reverse cholesterol transport" is considered. When mice were placed on a high lipid diet there was no discernible change in the level of apolipoprotein E mRNA in liver or intestine, although the level of the circulating protein increased about 3-fold. We conclude that in mice the effect of diet on apolipoprotein E levels in blood does not result from induction of mRNA in these tissues.     

Human ornithine decarboxylase sequences map to chromosome regions 2pter----p23 and 7cen----qter but are not coamplified with the NMYC oncogene

Using a mouse cDNA probe for ornithine decarboxylase (ODC), we have identified and isolated an ODC cDNA clone from a lambda gt11 recombinant library prepared from human liver cell mRNA. The 2.0-kb insert of this clone hybridizes with several mouse genomic ODC DNA restriction fragments under conditions of low stringency, but reacts with only few human DNA fragments and a polyA+ RNA species of 2.2 kb under both nonstringent and stringent hybridization conditions. This suggests that, unlike the mouse genome, there are only few ODC genes in the human genome. The human ODC DNA fragments segregate with chromosome regions 2pter----p23 and 7cen----qter in mouse X human somatic cell hybrid clones containing normal, translocated, and deleted human chromosomes. Sequences of the short arm of chromosome 2 containing the NMYC oncogene at 2p23----p24 are often involved in DNA amplification in neuroblastomas and small-cell lung cancers. However, in at least three cases--one neuroblastoma cell line, one neuroblastoma tumor, and one lung carcinoma--the ODC sequences are not coamplified with the NMYC oncogene.     

A glutaminase (gis) gene maps to mouse chromosome 1, rat chromosome 9, and human chromosome 2

A rat cDNA clone encoding a portion of phosphate-activated glutaminase was used to identify DNA restriction fragment length polymorphisms (RFLPs) in sets of somatic cell hybrids and between wild-derived and inbred strains of mice. Segregation of rat and mouse chromosomes among somatic cell hybrids indicated assignment to rat chromosome 9 and mouse chromosome 1. Analysis of chromosome 1 alleles for several genes in an interspecific cross between Mus spretus and C3H/HeJ-gld/gld mice indicates that glutaminase can be positioned within 5.5 +/- 2.0 cM proximal to Ctla-4. Similarly, human-hamster somatic cell hybrids were examined for RFLPs, and four human EcoRI restriction fragments were found to hybridize with the rat glutaminase probe. Two of these restriction fragments cosegregated and mapped to human chromosome 2 in a region that is syntenic with mouse chromosome 1 and rat chromosome 9.     

Molecular cloning of the cDNA coding for regucalcin and its mRNA expression in mouse liver: The expression is stimulated by calcium administration

The molecular cloning of the cDNA coding for a Ca2+-binding proteinregucalcin and its mRNA expression in mouse liver were investigated. ThecDNA clone encoding a regucalcin was isolated from a mouse liver cDNAlibrary and sequenced. Analysis of the sequence of the cloned cDNA showedthat the cDNA encoded the complete amino acid sequence of the mouseregucalcin molecule; the cDNA had an open reading frame of 897 bp. Mouseregucalcin was composed of 299 amino acid residues, and its molecular weightwas estimated to be 33,406 Da. The amino acid sequence of mouse regucalcinhad 94% homology, as compared with that of rat regucalcin. Northernblot analysis with the mouse liver cDNA probe revealed that mouse regucalcinmRNA was mainly present in the liver but only slightly in the kidney with asize of 1.8 kb. Hepatic regucalcin mRNA level of male mouse was higher thanthat of female mouse. A single intraperitoneal administration of calciumchloride (5, 15, and 30 mg Ca2+/100 g body weight) to mice induced aremarkable increase in regucalcin mRNA in the liver; the increase inregucalcin mRNA levels at 30 min after calcium administration wasdose-dependent. The present results demonstrate that regucalcin mRNA in miceis uniquely expressed in the liver, and that its expression is stimulated bycalcium administration.     

The complete sequence of a full length cDNA for human liver glyceraldehyde-3-phosphate dehydrogenase: evidence for multiple mRNA species.

A recombinant M13 clone (O42) containing a 65 b.p. cDNA fragment from human fetal liver mRNA coding for glyceraldehyde-3-phosphate dehydrogenase has been identified and it has been used to isolate from a full-length human adult liver cDNA library a recombinant clone, pG1, which has been subcloned in M13 phage and completely sequenced with the chain terminator method. Besides the coding region of 1008 b.p., the cDNA sequence includes 60 nucleotides at the 5'-end and 204 nucleotides at the 3'-end up to the polyA tail. Hybridization of pG1 to human liver total RNA shows only one band about the size of pG1 cDNA. A much stronger hybridization signal was observed using RNA derived from human hepatocarcinoma and kidney carcinoma cell lines. Sequence homology between clone 042 and the homologous region of clone pG1 is 86%. On the other hand, homology among the translated sequences and the known human muscle protein sequence ranges between 77 and 90%; these data demonstrate the existence of more than one gene coding for G3PD. Southern blot of human DNA, digested with several restriction enzymes, also indicate that several homologous sequences are present in the human genome.     

Primary structure of rat hepatocyte growth factor and induction of its mRNA during liver regeneration following hepatic injury

Overlapping cDNA clones for rat hepatocyte growth factor (rHGF) were isolated by cross-hybridization with the cloned cDNA for human hepatocyte growth factor (hHGF) and the nucleotide sequence of the cDNA was determined. The entire primary structure of rHGF was deduced from the sequence. Comparison of the amino acid sequences between rat and human HGFs revealed that the two sequences are highly conserved throughout the protein structures, suggesting that rat and human HGFs may be functionally similar. Responses of the rHGF mRNA during liver regeneration in rats were examined by Northern blot hybridization analysis with the aid of the cDNA probe for rHGF. The mRNA levels increased in the liver and spleen but not in the kidney after administration of carbon tetrachloride. At the maximum level of induction, the rHGF mRNA increased in the liver about 4.5-fold over its normal level. The mRNA levels also increased in the liver and spleen after administration of D-galactosamine. On the other hand, no obvious increase of the mRNA was observed in the liver and spleen after partial hepatectomy. These observations suggest that HGF may function as a regulator of liver regeneration following hepatic injury caused by hepatotoxins.     

Molecular cloning and nucleotide sequence of cDNA encoding the rat kidney S-adenosylmethionine synthetase.

We previously reported the isolation of a cDNA encoding the liver-specific isozyme of rat S-adenosylmethionine synthetase from a lambda gt11 rat liver cDNA library. Using this cDNA as a probe, we have isolated and sequenced cDNA clones for the rat kidney S-adenosylmethionine synthetase (extrahepatic isoenzyme) from a lambda gt11 rat kidney cDNA library. The complete coding sequence of this enzyme mRNA was obtained from two overlapping cDNA clones. The amino acid sequence deduced from the cDNAs indicates that this enzyme contains 395 amino acids and has a molecular mass of 43,715 Da. The predicted amino acid sequence of this protein shares 85% similarity with that of rat liver S-adenosylmethionine synthetase. This result suggests that kidney and liver isoenzymes may have originated from a common ancestral gene. In addition, comparison of known S-adenosylmethionine synthetase sequences among different species also shows that these proteins have a high degree of similarity. The distribution of kidney- and liver-type S-adenosylmethionine synthetase mRNAs in kidney, liver, brain, and testis were examined by RNA blot hybridization analysis with probes specific for the respective mRNAs. A 3.4-kilobase (kb) mRNA species hybridizable with a probe for kidney S-adenosylmethionine synthetase was found in all tissues examined except for liver, while a 3.4-kb mRNA species hybridizable with a probe for liver S-adenosylmethionine synthetase was only present in the liver. The 3.4-kb kidney-type isozyme mRNA showed the same molecular size as the liver-type isozyme mRNA. Thus, kidney- and liver-type S-adenosylmethionine synthetase isozyme mRNAs were expressed in various tissues with different tissue specificities.