Estrogen-induced expression of mouse lactate dehydrogenase-A gene

The synthesis of lactate dehydrogenase-A isoenzyme was shown to increase significantly in the uterus of immature mice treated by diethylstilbestrol. The expression of the mouse LDH-A promoter and cat fusion gene in Chinese hamster ovary cells was also induced by 17 beta-estradiol and diethylstilbestrol.     

Estimation of the gene frequency of lactate dehydrogenase subunit deficiencies

To detect the frequency of lactate dehydrogenase (LDH) subunit deficiency, screening for LDH subunit deficiency was performed on 3,776 blood samples from healthy individuals in Shizuoka Prefecture by means of electrophoresis. The frequency of heterozygote with LDH-A subunit deficiency was found to be 0.185%, and with LDH-B subunit deficiency, 0.159%. The frequencies of both subunit deficiencies were not significantly different. Gene frequencies of LDH subunit deficiencies were calculated by the simple counting procedure, and the results are as follows: gene frequency of LDH-A subunit deficiency was 11.9 X 10(-4), and that of LDH-B subunit deficiency, 7.9 X 10(-4). In addition, the second case in the world of a homozygous individual with LDH-A subunit deficiency was detected by this screening. This case with regard to the characteristics of LDH-A subunit deficiency are summarized herein.     

Expression of the mouse lactate dehydrogenase-A promoter fused with the bacterial gpt gene in Chinese hamster ovary cells

The promoter region of the cloned mouse lactate dehydrogenase-A gene was fused with the gpt gene of Escherichia coli, and this fusion gene was shown to express in Chinese hamster ovary cells. This result demonstrates that the cloned LDH-A promoter is indeed functional.     

Expression of the cDNA encoding for mouse sperm-specific lactate dehydrogenase C in Chinese-hamster ovary cells.

The cloned cDNA encoding for mouse sperm-specific lactate dehydrogenase C (LDH-C) was inserted immediately downstream to the MMTV 5' LTR promoter, and it was shown to synthesize mouse LDH-C polypeptide in Chinese-hamster ovary cells. The mouse LDH-C subunit and the endogenous Chinese-hamster LDH-A subunit formed in vivo a heterotetrameric LDH-A3C1 isoenzyme, and this novel isoenzyme exhibited enzymic activity utilizing lactate as substrate.     

Nucleotide sequences of the cDNA and an intronless pseudogene for human lactate dehydrogenase-A isozyme

Eight cDNA clones for lactate dehydrogenase-A isozyme (LDH-A) were isolated from a human fibroblast cDNA library, characterized, and no sequence heterogeneity was found. Four cDNA clones appear to contain nearly full-length cDNA inserts and the complete nucleotide sequence of 1710 base pairs consists of the protein-coding sequence (999 base pairs), the 5' (97 base pairs) and 3' (565 base pairs) untranslated regions and poly(dA) tail (49 base pairs). The predicted amino acid sequence of the human LDH-A polypeptide shows 92% homology (27 differences out of 331 amino acids compared) with that of the pig LDH-A subunit determined by direct protein sequencing [Kiltz et al. (1977) Hoppe-Seyler's Z. Physiol. Chem. 358, 123-127]. Human genomic clones containing an LDH-A pseudogene were isolated and the nucleotide sequence of 1635 base pairs from an intronless pseudogene was determined. The presence of two termination codons, two deletions of three nucleotides each and the replacement of three arginine residues at the active site (nos 98, 105 and 168) by other amino acids renders its coding region incapable of producing a functional LDH-A protein. A comparison between human LDH-A cDNA and the pseudogene sequences reveals 12.9% differences (114 transitions, 65 transversions and 36 deletions/insertions). Further, only four out of the 25 dCpdG dinucleotides present in the cDNA sequence remain unchanged, although the sequences possess 87.1% homology.     

Molecular characterization of genetic mutation in human lactate dehydrogenase-A (M) deficiency

Human lactate dehydrogenase-A mutant gene was isolated from the genomic DNA library of a patient deficient in LDH-A (Muscle) subunit. The nucleotide sequences of seven protein-coding exons were determined and a deletion of 20 base-pairs in exon 6 was found. This mutation results in a frame-shift translation and premature termination. The predicted incomplete LDH-A (M) subunit containing only 259 instead of 331 amino acids appears to be degraded rapidly, since no protein was detected immunologically (Maekawa et al., Am J Hum Genet 39:232-238, 1986). In addition, three synonymous (silent) substitutions, A to C, T to C, and G to A, were observed at codons 115, 160 and 172, respectively, in this LDH-A mutant gene.     

Isolation and characterization of a cDNA and a pseudogene for mouse lactate dehydrogenase-A isozyme

A mouse lactate dehydrogenase-A cDNA was isolated and it was shown to contain the 393bp of the protein-coding sequence and 488bp of the 3' untranslated region. The amino acid sequence deduced from its open reading frame provided independent evidence for the sequence of residues 201-331 of mouse LDH-A subunit (muscle). This cDNA clone was used as a probe to isolate a mouse genomic clone containing a truncated, processed LDH-A pseudogene. This pseudogene showed 81.6% homology at 713 positions compared with the LDH-A cDNA sequence. The divergence of this pseudogene was estimated to have occurred 39 million years ago.     

Characterization of beta-D-N-acetylhexosaminidase isoenzymes in man-Chinese hamster somatic cell hybrids.

A series of man-Chinese hamster hybrids were investigated with the use of an anti-Chinese hamster hexosaminidase serum, a specific anti-human hex A serum and an anti-human hex B serum. The expression of human hex A was found to be dependent on the presence of hex B. A heteropolymeric molecule is formed independently of hex B, which consists of Chinese hamster and specific hex A moieties. It has an electrophoretic mobility nearly identical to hex A. A relationship between the absence and presence of the heteropolymeric molecule, mannosephosphate isomerase (MPI), and pyruvate kinase (PK-3), assigned to chromosome 15, was established. With respect to the two locus subunit model, the gene coding for the alpha subunit, specific for hex A, has been localized on chromosome 15.     

Assignment of the structural genes for the alpha subunit of hexosaminidase A, mannosephosphate isomerase, and pyruvate kinase to the region q22-qter of human chromosome 15.

Concordant segregation of the expression of the alpha subunit of human hexosaminidase A, human mannosephosphate isomerase, and pyruvate kinase was observed in somatic cell hybrids between either thymidine kinase-deficient mouse cells or thymidine kinase-deficient Chinese hamster cells and human white blood cells carrying a translocation of the distal half (q 22-qter) of the long arm of chromosome 15 to chromosome 17. A positive correlation was established between the expression of these human phenotypes and the presence of the distal half of the long arm of human chromosome 15.     

A Mutation Affecting the Lactate Dehydrogenase Locus Ldh-1 in the Mouse. II. Mechanism of the Ldh-a Deficiency Associated with Hemolytic Anemia

A procarbazine hydrochloride-induced mutation at the Ldh-1 structural locus encoding the A subunit of lactate dehydrogenase (LDH) was used to study the molecular and metabolic basis of severe hemolytic anemia due to LDH-A deficiency in the mouse. The mutant allele designated Ldh-1(a-m1Neu) codes for an enzyme that as homotetramer differs from the wild-type enzyme by a marked instability, acidic shift of the pH profile, increased K(m) for pyruvate and altered inhibition by high concentrations of this substrate. Except for the latter, all these altered properties of the mutant protein contribute to the diminished LDH activity in heterozygous and homozygous mutant individuals. Impaired energy metabolism of erythrocytes indicated by a relatively low ATP concentration is suggested to result in cell death at the end of the reticulocyte stage leading to the expression of hemolytic anemia with extreme reticulocytosis and hyperbilirubinemia. Despite the severe anemia, affected homozygous mutants exhibit approximately normal body weight and do not show noticeable impairment of viability or fertility. To date no such condition is observed in man. This discrepancy is likely due to the fact that in human erythrocytes both LDH-A and LDH-B subunits are expressed such that homozygotes for a LDH-A or LDH-B deficiency would not result in a comparably extreme LDH activity deficiency.     

Isolation of a lactic dehydrogenase-A-deficient CHO-K1 mutant by nylon cloth replica plating.

A mutant Chinese hamster ovary cell deficient in lactate dehydrogenase A activity has been isolated using a nonselective technique. The method uses histochemical staining to examine colonies directly for enzyme activity and nylon cloth replica plating to recover particular clones. The mutant cell has an apparent Km (pyruvate to lactate) that is nearly tenfold higher than the parental cell, while its Vmax has been reduced more than 80-fold. In mutant cell extracts with added porcine LDH-B enzyme, molecular dissociation and recombination of subunits produces two new active LDH tetramers (A1B3, A2B2). The electrophoretic mobility of at least one of the tetramers (A1B3) was different from those formed in the parental extracts. The evidence suggests the variant cell contains a mutation in the structural gene for LDH-A.     

Genomic organization of human lactate dehydrogenase-A gene.

A human genomic clone containing the lactate dehydrogenase-A (LDH-A) gene of approx. 12 kilobases in length was isolated and characterized. The protein-coding sequence is interrupted by six introns, and the positions of these introns are at the random coil regions or near the ends of secondary structures located on the surface of the LDH-A molecule. An additional intron is present at 24 nucleotides 5' to the translation initiation codon ATG, while the 3' untranslated sequence of 565 nucleotides is not interrupted. The genomic blot analysis of human placenta DNA indicates the presence of multiple LDH-A gene-related sequences.     

Relative mRNA expression of the lactate dehydrogenase A and B subunits as determined by simultaneous amplification and single strand conformation polymorphism. Relation with subunit enzyme activity

To explore if it is correlated in human tumor cells that the expression of LDH homologous gene and LDH isoenzymes, we used RT-PCR-SSCP technique to measure the relative expression of genes with homologous sequences. The combination of PCR using common primers designed in the highly conserved regions and single-strand conformation polymorphism analysis of the products is used for quantitative determination of the proportions of LDH-A mRNA in human cancer cell lines. The proportion is compared with that of the activities of isoenzymes. The results indicated that the enzyme activity of LDH-A was consistent with mRNA levels in the human tumor cell. The present procedure using a single pair of primers for two fragments can overcome disadvantages in quantitative analysis using multiplex PCR. Template concentrations and PCR cycles did not affect the proportions of LDH-A and LDH-B in the product.     

A brain L-type calcium channel alpha 1 subunit gene (CCHL1A2) maps to mouse chromosome 14 and human chromosome 3.

A rat brain cDNA probe was used to localize a gene encoding the alpha 1 subunit of neuronal dihydropyridine-sensitive L-type calcium channels in the mouse and human genomes. Hybridization of the probe to Southern blots made with DNAs from a Chinese hamster x mouse somatic cell hybrid panel indicated that this gene maps to mouse chromosome 14 (Chr 14). Southern blot analysis of an intersubspecies cross demonstrated that the calcium channel alpha 1 subunit gene, termed Cchl1a2, can be positioned 7.5 cM proximal to Np-1. Similarly, segregation among human X rodent somatic cell hybrids indicated that CCHL1A2 maps to human chromosome 3. These assignments are consistent with a region of linkage homology between human chromosome 3p and a proximal region of mouse Chr 14.     

Primary structure of bovine lactate dehydrogenase-A isozyme and its synthesis in Escherichia coli

Eleven cDNA clones encoding lactate dehydrogenase(LDH)-A isozyme were isolated from a bovine lymphocyte cDNA library, and the nucleotide sequences of three of the clones (pLDH5, pLDH9 and pLDH12) were determined. With the exception of variation in the 5' portion, two cDNA clones (pLDH9 and pLDH12) appeared to contain the full-length cDNA of 1786 bp, consisting of the protein-coding sequence (996 bp), the 5'- and the 3'-untranslated regions and the poly(dA) tail. The predicted amino acid (aa) sequence of bovine LDH-A (332 aa) showed 96.7% homology with that of pig LDH-A. The protein-coding cDNA region (1650 bp) was inserted into an Escherichia coli expression vector ptac11 and expressed. The protein synthesized in E. coli showed enzyme activity of LDH and was identified by cellogel electrophoresis as LDH-5 isozyme whose subunit M chain is the product of the LDH-A gene.     

Molecular evolution of mammalian lactate dehydrogenase-A genes and pseudogenes: association of a mouse processed pseudogene with a B1 repetitive sequence

A mouse genomic clone containing a lactate dehydrogenase-A (LDH-A) processed pseudogene and a B1 repetitive element was isolated, and a nucleotide sequence of approximately 3 kb was determined. The pseudogene and B1 element are flanked by perfect 13-bp repeats, and the B1 sequence starts at 14 nucleotides 3' to the presumptive polyadenylation signal of the pseudogene. The nucleotide sequences of the LDH-A genes and processed pseudogenes from mouse, rat, and human were compared, and a phylogenetic tree was constructed. The rate and pattern of nucleotide substitutions in the LDH-A pseudogenes are similar to previously reported results (Li et al. 1984). The average rate of nucleotide substitutions in the LDH-A pseudogenes is 4.3 X 10(- 9)/site/year. The substitutions of C----T and G----A are most frequent, and A----G substitutions are relatively high. The rate of synonymous substitutions in the LDH-A genes is 5.3 X 10(-9), which is not significantly higher than the average rate of 4.7 X 10(-9) for 35 mammalian genes. The rate of nonsynonymous substitutions in the LDH-A genes is 0.20 X 10(-9), which is considerably lower than the average rate of 0.88 X 10(-9) for 35 mammalian genes. Thus, the mammalian LDH-A gene appears to be highly conserved in evolution.      

Tyrosine phosphorylation of lactate dehydrogenase A is important for NADH/NAD(+) redox homeostasis in cancer cells

The Warburg effect describes an increase in aerobic glycolysis and enhanced lactate production in cancer cells. Lactate dehydrogenase A (LDH-A) regulates the last step of glycolysis that generates lactate and permits the regeneration of NAD(+). LDH-A gene expression is believed to be upregulated by both HIF and Myc in cancer cells to achieve increased lactate production. However, how oncogenic signals activate LDH-A to regulate cancer cell metabolism remains unclear. We found that the oncogenic receptor tyrosine kinase FGFR1 directly phosphorylates LDH-A. Phosphorylation at Y10 and Y83 enhances LDH-A activity by enhancing the formation of active, tetrameric LDH-A and the binding of LDH-A substrate NADH, respectively. Moreover, Y10 phosphorylation of LDH-A is common in diverse human cancer cells, which correlates with activation of multiple oncogenic tyrosine kinases. Interestingly, cancer cells with stable knockdown of endogenous LDH-A and rescue expression of a catalytic hypomorph LDH-A mutant, Y10F, demonstrate increased respiration through mitochondrial complex I to sustain glycolysis by providing NAD(+). However, such a compensatory increase in mitochondrial respiration in Y10F cells is insufficient to fully sustain glycolysis. Y10 rescue cells show decreased cell proliferation and ATP levels under hypoxia and reduced tumor growth in xenograft nude mice. Our findings suggest that tyrosine phosphorylation enhances LDH-A enzyme activity to promote the Warburg effect and tumor growth by regulating the NADH/NAD(+) redox homeostasis, representing an acute molecular mechanism underlying the enhanced lactate production in cancer cells.