Post-transcriptional analysis of rat mitochondrial D-3-hydroxybutyrate dehydrogenase control through development and physiological stages.

The nuclear encoded mitochondrial D-3-hydroxybutyrate dehydrogenase (BDH) is synthesized in the cytosal as a larger precursor. This membrane enzyme which requires lecithin for activity plays an essential role in energy metabolism as a ketone bodies-converting enzyme. A cDNA clone of the rat liver enzyme encompassing an antigenic determinant peptide has been isolated after immunoscreening of a lambda gt11 expression library. The nucleotide sequence of this 279-base cDNA insert contains a single open reading frame of 93 amino-acids, which represents about a third of the mature enzyme. Amino-acid sequence analysis predicts a hydrophobic stretch of 29 amino-acids long which probably functions as membrane anchor domain, or as an important region for the enzyme activation by phospholipid. By using this cDNA probe the BDH gene has been investigated at the mRNA level. There is only one mRNA (2-kb size) for BDH whatever the studied tissue. The rat gene is differently expressed since its mRNA is already present in the foetus liver while the BDH polypeptide amount is low and its enzymatic activity is not detectable even in the late stage of foetal development. The mRNA content is higher in the liver than in extrahepatic tissues. Adrenalectomy and ovariectomy increase liver mRNA content and polypeptide level, as well as activity of BDH. These effects are totally or partially abolished by corticosterone and estradiol treatments respectively. In addition, a 15-day hyperlipidic diet stimulates BDH gene expression. Present results show that the gene expression of this mitochondrial enzyme is modulated through development and hormonal and metabolic conditions mentioned above.     

Gene expression of D-beta-hydroxybutyrate dehydrogenase. III. Molecular cloning of a DNAc

In order to continue the molecular studies of D-beta-hydroxybutyrate dehydrogenase (BDH) undertaken in our laboratory for several years, we have initiated a genetic approach which consists in the BDH cDNA cloning from a rat liver cDNA library. The immunoscreening method allowed to isolate a clone which exhibits a DNA insert shorter than the expected full length BDH cDNA.     

Expression of active rat DNA polymerase beta in Escherichia coli

A recombinant plasmid for expression of rat DNA polymerase beta was constructed in a plasmid/phage chimeric vector, pUC118, by an oligonucleotide-directed mutagenesis technique. The insert contained a 1005 bp coding sequence for the whole rat DNA polymerase beta. The recombinant plasmid was designed to use the regulatory sequence of Escherichia coli lac operon and the initiation ATG codon for beta-galactosidase as those for DNA polymerase beta. The recombinant clone, JMp beta 5, obtained by transfection of E. coli JM109 with the plasmid, produced high levels of DNA polymerase activity and a 40-kDa polypeptide that were not detected in JM109 cell extract. Inducing this recombinant E. coli with isopropyl beta-thiogalactopyranoside (IPTG) yielded amounts of 40-kDa polypeptide as high as 19.3% of total protein. Another recombinant clone, JMp beta 2-1, which was constructed by an oligonucleotide-directed mutagenesis to use the second ATG codon for the initiation codon, thus deleting the first 17 amino acid residues from the amino terminus, produced neither high DNA polymerase activity nor the 40-kDa polypeptide. The evidence suggests that this amino-terminal structure is important for stability of this enzyme in E. coli. The DNA polymerase was purified to homogeneity from the IPTG-induced JMp beta 5 cells by fewer steps than the procedure for purification of DNA polymerase beta from animal cells. The properties of this enzyme in activity, chromatographic behavior, size, antigenicity, and also lack of associated nuclease activity were indistinguishable from those of DNA polymerase beta purified from rat cells, indicating the identity of the overproduced DNA polymerase in the JMp beta 5 and the rat DNA polymerase beta.     

Cloning and expression in Escherichia coli of cDNA for arginase of rat liver

A cDNA expression library constructed in a plasmid pUC8 from poly(A)+ RNA of rat liver was screened immunologically, using an antibody against arginase of rat liver. A cDNA clone was isolated and identified by hybrid-selected translation. The clone contained an insert approximately 1.35 kilobase pairs in length. In the bacterial clone, we detected a specific protein of Mr = about 43,000 that is slightly larger than the purified arginase (Mr = about 40,000) and a high activity of arginase was expressed. The arginase mRNA species of about 1600 bases long was detected in the liver, but not in the small intestine, kidney, spleen and heart of the rats.     

Expression of R-3-hydroxybutyrate dehydrogenase, a ketone body converting enzyme in heart and liver mitochondria of ruminant and non-ruminant mammals.

1. The properties of rat liver and bovine heart R-3-hydroxybutyrate dehydrogenase (BDH) have been extensively studied in the past 20 years, but little is known concerning the biogenesis and the regulation of this dehydrogenase over different species. 2. In addition, controversial results were often reported concerning the activity, the level and the subcellular location of this enzyme in ruminants. 3. BDH activity found in liver and kidney mitochondria from ruminants (cow and sheep) is low, while it is much higher in rat. 4. However, the enzyme activity is detected in microsomes and in cytosol of liver and of kidney cells from ruminants. These activities are not correlated to ketonaemia level. 5. Although low BDH activity is detected in liver mitochondria from ruminants; the bovine liver BDH gene seems to be translated since BDH can be immunodetected by using an antiserum raised against bovine heart BDH. 6. Beside this, the good cross-reactivity between heart BDH and liver BDH suggests their high level of homology in ruminants.     

Phosphatidylcholine activation of human heart (R)-3-hydroxybutyrate dehydrogenase mutants lacking active center sulfhydryls: site-directed mutagenesis of a new recombinant fusion protein

(R)-3-Hydroxybutyrate dehydrogenase (BDH) is a lipid-requiring mitochondrial enzyme with a specific requirement of phosphatidylcholine (PC) for function. A plasmid has been constructed to express human heart (HH) BDH in Escherichia coli as a hexahistidine-tagged fusion protein (HH-Histag-BDH). A rapid two-step affinity purification yields active HH-Histag-BDH (and six mutants) with high specific activity ( approximately 130 micromol of NAD(+) reduced.min(-1).mg(-1)). HH-Histag-BDH has no activity in the absence of phospholipid and exhibits a specific requirement of PC for function. The HH-Histag-BDH-PC complex (and HH-BDH derived therefrom by enterokinase cleavage) has apparent Michaelis constants (K(m) values) for NAD(+), NADH, (R)-3-hydroxybutyrate (HOB), and acetoacetate (AcAc) similar to those for bovine heart or rat liver BDH. A computed structural model of HH-BDH predicts the two active center sulfhydryls to be C69 (near the adenosine moiety of NAD) and C242. With both sulfhydryls derivatized, BDH has minimal activity, but site-directed mutagenesis of C69 and/or C242 now shows that neither of these cysteines is required for PC activation or catalysis (the double mutant, C69A/C242A, is highly active with essentially normal kinetic parameters). Six cysteine mutants each have an increased K(m)(NADH) (2-6-fold) but an unchanged K(m)(NAD)+. The C242S and C69A/C242S enzymes (but not the analogous C242A mutants nor the C69A or C69S mutants) exhibit approximately 10-fold increases in K(m)(HOB) and K(m)(AcAc), reflecting an altered substrate binding site. Thus, although C242 (in the C-terminal lipid binding domain of BDH) is close to the active site, it appears to be in a hydrophobic environment and only indirectly defines the substrate binding site at the catalytic center of BDH.     

Expression of a cDNA encoding a rat liver glutathione S-transferase Ya subunit in Escherichia coli

A full length cDNA clone, pGTB38 (C. B. Pickett et al. (1984) J. Biol. Chem. 259, 5182-5188), complementary to a rat liver glutathione S-transferase Ya mRNA has been expressed in Escherichia coli. The cDNA insert was isolated from pGTB38 using MaeI endonuclease digestion and was inserted into the expression vector pKK2.7 under the control of the tac promoter. Upon transformation of the expression vector into E. coli, two protein bands with molecular weights lower than the full-length Ya subunit were detected by Western blot analysis in the cell lysate of E. coli. These lower-molecular-weight proteins most likely result from incorrect initiation of translation at internal AUG codons instead of the first AUG codon of the mRNA. In order to eliminate the problem of incorrect initiation, the glutathione S-transferase Ya cDNA was isolated from the expression vector and digested with Bal31 to remove extra nucleotides from the 5' noncoding region. The protein expressed by this expression plasmid, pKK-GTB34, comigrated with the Ya subunit on sodium dodecyl sulfate polyacrylamide gels and was recognized by antibodies against the YaYc heterodimer. The expressed Ya homodimer was purified by S-hexylglutathione affinity and ion-exchange chromatographies. Approximately 50 mg pure protein was obtained from 9 liters of E. coli culture. The expressed Ya homodimer displayed glutathione-conjugating, peroxidase, and isomerase activities, which are identical to those of the native enzyme purified from rat liver cytosol. Protein sequencing indicates that the expressed protein has a serine as the NH2 terminus whereas the NH2 terminus of the glutathione S-transferase Ya homodimer purified from rat liver cytosol is apparently blocked.     

Developmental regulation of D-beta-hydroxybutyrate dehydrogenase in rat liver and brain

The activities of ketone-metabolizing enzymes in rat brain increase 3- to 5-fold during the suckling period before decreasing to the adult level after weaning. We have observed that a similar developmental pattern also exists for D-beta-hydroxybutyrate dehydrogenase (BDH) in rat liver. Utilizing antibodies prepared against the purified protein we determined that the changes in BDH activities in both brain and liver are due to changes in the amount of BDH in the mitochondria. In vitro translations of isolated RNA followed by immunoprecipitation revealed that the increase in BDH activity and content was correlated with an increase in the level of functional BDH-mRNA in both liver and brain.     

Molecular cloning of an alcohol (butanol) dehydrogenase gene cluster from Clostridium acetobutylicum ATCC 824.

In Clostridium acetobutylicum, conversion of butyraldehyde to butanol is enzymatically achieved by butanol dehydrogenase (BDH). A C. acetobutylicum gene that encodes this protein was identified by using an oligonucleotide designed on the basis of the N-terminal amino acid sequence of purified C. acetobutylicum NADH-dependent BDH. Enzyme assays of cell extracts of Escherichia coli harboring the clostridial gene demonstrated 15-fold-higher NADH-dependent BDH activity than untransformed E. coli, as well as an additional NADPH-dependent BDH activity. Kinetic, sequence, and isoelectric focusing analyses suggest that the cloned clostridial DNA contains two or more distinct C. acetobutylicum enzymes with BDH activity.     

Cloning and expression of the Bacteroides fragilis TAL2480 neuraminidase gene, nanH, in Escherichia coli.

We have cloned the Bacteroides fragilis TAL2480 neuraminidase (NANase) structural gene, nanH, in Escherichia coli. This was accomplished by using the cloning shuttle vector pJST61 and a partial Sau3A library of TAL2480 chromosomal inserts created in E. coli. The library was mobilized into the NANase-deficient B. fragilis TM4000 derivative TC2. NANase-producing colonies were enriched by taking advantage of the inability of TC2, but not the wild-type of NANase+ revertant, to grow in vitro in fluid aspirated from the rat granuloma pouch. Plasmids pJST61-TCN1 and pJST61-TCN3, containing inserts of 9.1 and 4.5 kilobases (kb), respectively, were found in the TC2 derivatives that grew in the rat pouch medium. In B. fragilis, NANase production from the two plasmids was inducible by free N-acetylneuraminic acid or sialic acid-containing substrates, just as in the parental TAL2480 strain. However, when these plasmids were transferred back to E. coli, NANase activity was barely detectable. A 3.5-kb portion of the insert in pJST61-TCN3 was subcloned in pJST61 to give plasmid pJST61-SC3C; NANase was produced from this plasmid both in E. coli and in B. fragilis. In E. coli, NANase expression was under the control of the vector promoter lambda pR and was therefore completely abolished by the presence of a lambda prophage. In B. fragilis, NANase production was inducible by free N-acetylneuraminic acid or sialic acid-containing substrates. By using deletion analysis and Tn1000 mutagenesis, the NANase structural gene and control region that functions in B. fragilis were localized to a 1.5- to 2.0-kb region of the insert. A partial nucleotide sequence of the NANase-deficient Tn1000 insertion mutants allowed us to identify the nanH gene and deduce the amino acid sequence of a portion of the NANase protein. We identified five regions showing great similarity to the Asp boxes, -Ser-X-Asp-X-Gly-X-Thr-Trp-, of other bacterial and viral NANase proteins.     

Cloning of rat alpha-fetoprotein 3'-terminal complementary deoxyribonucleic acid sequences and preparation of radioactively labeled hybridization probes from cloned deoxyribonucleic acid inserts

Double-stranded complementary deoxyribonucleic acid (cDNA) was synthesized from rat yolk sac alpha-fetoprotein (AFP) mRNA, inserted into the PstI site of plasmid pBR322 by an oligo(deoxyguanylic acid).oligo(deoxycytidylic acid) joining technique, and cloned in Escherichia coli chi 1776. A plasmid containing an inserted AFP double-stranded cDNA with a contiguous poly(adenylic acid) [poly(A)] segment was identified and subsequently employed in a new method for preparing AFP-specific hybridization probe. Following an initial digestion of the AFP plasmid with HindIII to create an open, recessed 3' end, lambda exonuclease III was employed to remove the DNA strand opposite the coding strand of the cDNA insert. Oligo(thymidylic acid) was then annealed to the poly(A) segment and employed as primer for E. coli DNA polymerase I to synthesize a 32P-labeled cDNA copy of the AFP coding strand. The single-stranded cDNA product was easily isolated by sedimentation through isokinetic alkaline sucrose gradients. Hybridization with this AFP-specific cDNA probe showed that the yolk sac contained a 6-fold greater concentration of AFP mRNA than that of the fetal liver. AFP mRNA was also found in the normal adult liver, but at a much lower level than in the fetal liver. The concentrations of AFP mRNA in Morris hepatomas 7777 and 8994, however, were significantly elevated to a 2- to 3-fold higher concentration that in the fetal liver.     

Interplay of SOS induction,recombinant gene expression,and multimerization of plasmid vectors in Escherichia coli

Using pBR322- and pUC-derived plasmid vectors, a homologous (Escherichia coli native esterase) and three heterologous proteins (human interleukin-2, human interleukin-6, and Zymomonas levansucrase) were synthesized in E. coli IC2015(recA::lacZ) and GY4786 (sfiA::lacZ) strains. Via time-course measurement of beta-galactosidase activity in each recombinant culture, the SOS induction was estimated in detail and the results were systematically compared. In recombinant E. coli, the SOS response did not happen either with the recombinant insert-negative plasmid backbone alone or the expression vectors containing the homologous gene. Irrespective of gene expression level and toxic activity of synthesized foreign proteins, the SOS response was induced only when the heterologous genes were expressed using a particular plasmid vector, indicating strong dependence on the recombinant gene clone and the selection of a plasmid vector system. It is suggested that in recombinant E. coli the SOS response (i.e., activation of recA expression and initial sfiA expression) may be related neither to metabolic burden nor toxic cellular event(s) by synthesized heterologous protein, but may be provoked by foreign gene-specific interaction between a foreign gene and a plasmid vector. Unlike in E. coli XL1-blue(recA(-)) strains used, all expression vectors encoding each of the three heterologous proteins were multimerized in E. coli IC2015 strains in the course of cultivation, whereas the expression vectors containing the homologous gene never formed the plasmid multimers. The extent of multimerization was also dependent on a foreign gene insert in the expression vector. As a dominant effect of the SOS induction, recombinant plasmid vectors used for heterologous protein expression appear to significantly form various multimers in the recA(+) E. coli host.     

Fermentation studies of the secretion of Serratia marcescens nuclease by Escherichia coli

The secretion of a Serratia marcescens nuclease was followed by fermentation with Escherichia coli. A plasmid, p403-SD2, carrying a 1.3-kilobase-pair insert with a 0.4-kilobase-pair region upstream of the nuclease gene caused a growth-phase-regulated expression of nuclease in E. coli in the same way as that seen in S. marcescens. Deletion of the regulatory gene generating plasmid p403-Rsa1 resulted in a constitutive expression of the nuclease. Anaerobiosis stimulated the expression from p403-SD2 in stationary growth phase by a factor of 10 compared with expression stimulated by cultivation in aerobic conditions; no such effect was found for plasmid p403-Rsa1. Different nutritional factors caused the expression level and the amount of extracellular nuclease to vary more when nuclease was expressed from plasmid p403-SD2 than when it was expressed from plasmid p403-Rsa1. A correlation between the regulatory gene and the extracellular secretion of nuclease is proposed.     

Nucleotide sequence of the Acinetobacter calcoaceticus trpGDC gene cluster

A plasmid library of Acinetobacter calcoaceticus HindIII fragments was constructed, and clones that complemented an Escherichia coli pabA mutant were selected. Plasmids containing a 3.9-kb fragment of A. calcoaceticus DNA that also complemented E. coli trpD and trpC-(trpF+) mutants were obtained. We infer that complementation of E. coli pabA mutants was the result of the expression of the amphibolic anthranilate- synthase/p-aminobenzoate-synthase glutamine-amidotransferase gene and that the plasmid insert carried the entire trpGDC gene cluster. In E. coli minicells, the plasmid insert directed the synthesis of polypeptides of 44,000, 33,000, and 20,000 daltons, molecular masses that are consistent with the reported molecular masses of phosphoribosylanthranilate transferase, indoleglycerol-phosphate synthase, and anthranilate-synthase component II, respectively. A 3,105- bp nucleotide sequence was determined. Comparison of the A. calcoaceticus trpGDC sequences with other known trp gene sequences has allowed insight into (1) the evolution of the amphibolic trpG gene, (2) varied strategies for coordinate expression of trp genes, and (3) mechanisms of gene fusions in the trp operon.      

Fermentation studies of the secretion of Serratia marcescens nuclease by Escherichia coli.

The secretion of a Serratia marcescens nuclease was followed by fermentation with Escherichia coli. A plasmid, p403-SD2, carrying a 1.3-kilobase-pair insert with a 0.4-kilobase-pair region upstream of the nuclease gene caused a growth-phase-regulated expression of nuclease in E. coli in the same way as that seen in S. marcescens. Deletion of the regulatory gene generating plasmid p403-Rsa1 resulted in a constitutive expression of the nuclease. Anaerobiosis stimulated the expression from p403-SD2 in stationary growth phase by a factor of 10 compared with expression stimulated by cultivation in aerobic conditions; no such effect was found for plasmid p403-Rsa1. Different nutritional factors caused the expression level and the amount of extracellular nuclease to vary more when nuclease was expressed from plasmid p403-SD2 than when it was expressed from plasmid p403-Rsa1. A correlation between the regulatory gene and the extracellular secretion of nuclease is proposed.     

Primary structure of rat liver D-beta-hydroxybutyrate dehydrogenase from cDNA and protein analyses: a short-chain alcohol dehydrogenase.

The amino acid sequence of D-beta-hydroxybutyrate dehydrogenase (BDH), a phosphatidyl-choline-dependent enzyme, has been determined for the enzyme from rat liver by a combination of nucleotide sequencing of cDNA clones and amino acid sequencing of the purified protein. This represents the first report of the primary structure of this enzyme. The largest clone contained 1435 base pairs and encoded the entire amino acid sequence of mature BDH and the leader peptide of precursor BDH. Hybridization of poly(A+) rat liver mRNA revealed two bands with estimated sizes of 3.2 and 1.7 kb. A computer-based comparison of the amino acid sequence of BDH with other reported sequences reveals a homology with the superfamily of short-chain alcohol dehydrogenases, which are distinct from the classical zinc-dependent alcohol dehydrogenases. This protein family, initially discerned from Drosophila alcohol dehydrogenase and bacterial ribitol dehydrogenase, is now known to include at least 20 enzymes catalyzing oxidations of distinct substrates.     

Isolation of genes required for hydrogenase synthesis in Escherichia coli

A mutant strain of Escherichia coli, strain AK23, is devoid of hydrogenase activity when grown anaerobically on glucose and cannot grow on H2 plus fumarate. From E. coli chromosomal DNA library, a plasmid, pAK23, was isolated which restored hydrogenase activity in this strain. Two smaller plasmids, pAK23C and pAK23S, containing different parts of the insert DNA fragment of plasmid pAK23, were isolated. The former plasmid restored activity in strain AK23 while the latter did not. The smallest active DNA fragment in plasmid pAK23C was 0.9 kb. This gene is designated hydE. Plasmids pAK23 and pAK23S restored activity in another hydrogenase-negative strain, SE-3-1 (hydB), while plasmid pAK23C did not, suggesting that plasmid pAK23 contains two genes required for hydrogenase expression. Strain AK23 was also devoid of formate hydrogenlyase and formate dehydrogenase activities and these activities were restored by some of the plasmids. Hydrogenase and formate-related activities in strain AK23 were restored by growth of cells in a high concentration of nickel. Plasmid pAK23C led to synthesis of a polypeptide of subunit molecular mass 36 kDa and plasmid pAK23S led to synthesis of polypeptides of subunit molecular masses 30 and 41 kDa.