Evolution of a gene. Multiple genes for LDH isozymes provide a model of the evolution of gene structure, function and regulation

Abundance of repetitive sequence elements in the mouse testis-specific lactate dehydrogenase-C gene

We have cloned and sequenced the entire mouse ldhc gene and mapped it physically in relation to the somatic ldha gene. The 2 genes were found to be oriented in head-to-tail fashion with about a 6-kilobase (kb) distance between the 3' end of ldha and the 5' end of ldhc. The ldhc gene is composed of 43% repetitive elements compared to only 16% in the ldha gene. Despite the close physical distance of mouse ldha and ldhc, the 2 genes have a very different content of repetitive elements, and this most likely reflects different levels of selective pressure.

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.

Enzyme activities in fish spermatozoa with focus on lactate dehydrogenase isoenzymes from herring Clupea harengus

The activities of NAD- and NADP-dependent dehydrogenases and creatine kinase were compared in extracts of spermatozoa from herring (Clupea harengus), carp (Cyprinus carpio) and catfish (Clarias gariepinus). The activity of malic enzyme in herring spermatozoa was approximately 5 and 36 times higher than in carp and catfish spermatozoa. In contrast, lactate dehydrogenase activity in herring spermatozoa was very low. Herring spermatozoa possess two isoenzymes of lactate dehydrogenase: LDH-A(2)B(2) and LDH-B(4). Both herring spermatozoa isozymes were separated, partly purified and characterized by kinetic and physico-chemical properties. The pH optima and K(m) values for pyruvate reduction were 7.1, 7.25, 7.6 and 0.22, 0.07, 0.09 mM for LDH-A(4), LDH-A(2)B(2) and LDH-B(4), respectively. The isoenzymes also have different thermostabilities. High activity of malic enzyme in herring spermatozoa suggests adaptation to metabolism at high oxygen tension.

Electrophoretic Variant of a Lactate Dehydrogenase Isoenzyme and Selective Promoter Methylation of the LDHA Gene in a Human Retinoblastoma Cell Line

Background: Lactate dehydrogenase (LD), a tetrameric product of the genes LDHA and LDHB, may be increased in sera of cancer patients. A variant isoenzyme with electrophoretic mobility between LD2 and LD3 (LD2ex) has been described in patients, but its molecular nature is largely unknown.

Methods: A newly established retinoblastoma cell line, NCC-RbC-51 (R51), showed an isoenzyme pattern with only two bands, LD1 and LD2ex. We investigated the isoenzymes by Northern blot, Western blot, and methylation analysis and PCR.

Results: Northern blot analysis revealed that R51 cells expressed no wild-type/somatic LDHA mRNA, but did express a small amount of LDHA-related mRNA with a slightly higher molecular mass. Western blot analysis confirmed the anti-LDHA-reactive protein with a 3-kDa higher molecular mass. Treatment of R51 cells with the demethylating agent 5-aza-2′-deoxycytidine restored the expression of the LD2, -3, -4, and -5 isoenzymes. PCR analysis of sodium bisulfite-treated genomic DNA revealed that the CpG island in the promoter region around exon a of the LDHA gene was completely methylated. Reverse transcription-PCR analysis and direct sequencing revealed that R51 cells expressed a RNA with the sequence of the human homolog of a murine testis-specific variant that has exon 0 as the 5′ noncoding sequence. LDHB was expressed normally in R51 cells.

Conclusions: The somatic LDHA in R51 cells is transcriptionally silenced by promoter hypermethylation around exon a, leaving only LDHB to be expressed normally and a testis-specific variant transcript of LDHA containing exon 0. LD2ex possibly results from tetramerization of three wild-type LDHB molecules and one variant LDHA product.

Multilocus isozyme systems in African lungfish, Protopterus annectens: distribution, differential expression and variation in dipnoans

Distribution of ADH, ALP, FBALD, GAPDH, G3PDH, G6PDH, GPI, LDH, MDH, PGM, and SOD was identified in retina, heart, muscle, liver, kidney, gills, brain, gut, lung and ovary of the African lungfish. Data are compared with patterns previously described in dipnoans and other vertebrates. The number of loci expressed for all enzymes was found to be similar to those of diploid Actinopterygii. Differences in the number of loci expressed in Amphibia were found for ALP, sG3PDH, GPI, LDH, MDH and SOD. Differences in tissue distribution were noted in ALP due to the absence of an intestinal-specific form typical of teleostean fish, amphibians, reptiles and birds, and in GPI and MDH, due to the tissue expression, as in primitive fish. There were also differences in LDH, where a third locus (LDH-C*) was expressed in the gills of Protopterus annectens and not in the retina or liver tissues, as in teleosts. LDH-A4 was most common in all the tissues. Major differences were noted in the tissue patterns of protein expression in the three dipnoans compared. As expected, the least divergence was found between the two species belonging to the same family (Lepidosirenidae). The highest index of divergence was observed between Neoceratodus forsteri and Lepidosiren paradoxa, belonging to the families Ceratontidae and Lepidosirenidae, respectively. The divergence is revealed by changes at the enzyme and morphological levels. These results suggest that P. annectens occupies an interesting systematic position, its biochemical characteristics distinguishing it from N. forsteri, L. paradoxa, the advanced fish and amphibians.

Lactate dehydrogenase genes of caiman and Chinese soft-shelled turtle, with emphasis on the molecular phylogenetics and evolution of reptiles

L-Lactate dehydrogenase (LDH) cDNAs encoding for LDH-A(4) (muscle) and LDH-B(4) (heart) isozymes from caiman (Caiman crocodilus apaporiensis) belonging to the order Crocodilia and Chinese soft-shelled turtle (Pelodiscus sinensis) belonging to the order Chelonia were sequenced. The phylogenetic relationships of the newly determined cDNA and their deduced protein sequences, as well as the previously published sequences of vertebrate LDH isozymes, were analyzed by various phylogenetic tree construction methods. These results indicated that Chelonia is indeed more closely related to Crocodilia. The divergent times between caiman and alligator, turtle and soft-shelled turtle, and Chelonia and Crocodilia were estimated to be approximately 36, 100 and 177 million years, respectively.

The morphological basis of hallucal orientation in extant birds

The perching foot of living birds is commonly characterized by a reversed or opposable digit I (hallux). Primitively, the hallux of nonavian theropod dinosaurs was unreversed and lay parallel to digits II-IV. Among basal birds, a unique digital innovation evolved in which the hallux opposes digits II-IV. This digital configuration is critical for grasping and perching. I studied skeletons of modern birds with a range of hallucal designs, from unreversed (anteromedially directed) to fully reversed (posteriorly directed). Two primary correlates of hallucal orientation were revealed. First, the fossa into which metatarsal I articulates is oriented slightly more posteriorly on the tarsometatarsus, rotating the digit as a unit. Second, metatarsal I exhibits a distinctive torsion of its distal shaft relative to its proximal articulation with the tarsometatarsus, reorienting the distal condyles and phalanges of digit I. Herein, I present a method that facilitates the re-evaluation of hallucal orientation in fossil avians based on morphology alone. This method also avoids potential misinterpretations of hallucal orientation in fossil birds that could result from preserved appearance alone.

Tachyzoite-specific isoform of Toxoplasma gondii lactate dehydrogenase is the target antigen of a murine CD4(+) T-cell clone

In two-dimensionally separated Toxoplasma gondii lysate, mouse Th1 clone 3Tx15 detects two proteins of apparent molecular weight 40000 and pI of 5.8 and 5.9. Microsequencing of peptide fragments from tryptic digestion of one of these proteins yielded partial sequences of T. gondii lactate dehydrogenase (LDH)1. As shown by Western blot, toxoplasmic LDH co-migrates in two-dimensional gel electrophoresis with both T-cell antigenic proteins. With synthetic peptides spanning the complete primary structure of T. gondii LDH1, the T-cell epitope was mapped to a nine amino acid partial sequence which exhibits a motif for binding to I-E(k), the class II restriction element of antigen recognition by clone 3Tx15. From the two known isoforms of T. gondii LDH, clone 3Tx15 specifically recognises tachyzoite LDH1, but not bradyzoite LDH2, as shown with the corresponding epitope peptides and recombinant proteins. Antigen-presenting cells infected with live bradyzoites stimulate 3Tx15 T cells, while killed bradyzoites provide no antigenic stimulus. This finding implies that a transformation into the tachyzoite stage occurs in cells challenged with bradyzoites. Although LDH1 represents one major constituent of the tachyzoite proteome, the protein does not seem to be immunogenic in T. gondii infection of mice. This is evident from the lack of serum anti-LDH immunoreactivity and the failure of adoptively transferred 3Tx15 T cells to protect against lethal challenge. In conclusion, a T-cell-stimulatory Toxoplasma antigen is identified by means of a novel, high-resolution T-cell blot technique, the clones antigenic fine specificity allowing detection of parasite-stage conversion.

Lactate dehydrogenase production and release in a newly established human myeloma cell line

Aggressive multiple myeloma with high serum lactate dehydrogenase (LDH) often has unusual clinical features and is considered to be a distinct clinical entity of multiple myeloma. A myeloma cell line, designated Maska-98, was established from the bone marrow of a patient with aggressive myeloma with extremely high serum LDH that was resistant to conventional chemotherapy. Maska-98 cells had morphological features of immature plasma cells, and immunophenotypic analysis showed that the cells expressed the plasma cell-associated surface antigens including CD38, 49d, and 56, but no T- or B-cell antigens, such as CD2, 3, 4, 8, 19, and 20. Maska-98 cells contained cytoplasmic immunoglobulin (IgG lambda). By utilizing this cell line we demonstrated that the myeloma cells produce and release a large amount of LDH, since (i) abundant LDH was found in the culture supernatant of Maska-98, (ii) immunocytochemical analysis showed that cytoplasm of the cells was strongly stained with anti-LDH monoclonal antibody, and (iii) Maska-98 cells expressed a greater amount of LDH mRNA than the T-cell line TALL-1, as shown by reverse transcription-polymerase chain reaction. As far as we know, there is no report of a myeloma cell line producing excess LDH. Therefore, Maska-98 would provide a novel source for further studies of the pathogenesis of aggressive multiple myeloma with high serum LDH.

Differential expression of lactate dehydrogenase isozymes (LDH) in human placenta with high expression of LDH-A(4) isozyme in the endothelial cells of pre-eclampsia villi

To evaluate the role of LDH isozymes in the human placenta during the third trimester, placentae were obtained from patients with normal pregnancy and pre-eclampsia. LDH-A(4)isozyme was immunolocalized primarily in the fetal endothelial cells while LDH-B(4)isozyme was predominantly present in syncytiotrophoblasts. This distinct cellular expression pattern of LDH isozymes was confirmed in HUVE and JEG cells. In addition to demonstrating the presence of five LDH isozymes in the placenta, zymograms showed that there was predominant activity of LDH-A(4)isozyme in HUVE cells and high activity of LDH-B(4)in JEG cells. Quantitative studies of LDH by agarose gel electrophoresis and Northern analysis in patients concluded that LDH-A(4)isozyme was increased in pre-eclampsia. The LDH-A(4)isozyme activity increased (P< 0.01) approx 1.6-fold in pre-eclampsia but there was no difference in the LDH-B(4)isozyme activity between placentae from normal compared to pre-eclampsia pregnancy. The level of LDH-A mRNA was increased (P< 0.05) approx twofold in pre-eclampsia. We conclude that the LDH-A gene in the endothelial cells of the placenta within the fetal microvasculature is increased in pre-eclampsia, probably as a result of hypoxia. LDH-A(4)isozyme activity and gene expression in placental endothelial cells, therefore, is a marker for the endothelial pathology seen in pre-eclampsia.

Regulation of lactate production by FSH, iL1beta, and TNFalpha in rat Sertoli cells

One of the "nurse cell" functions of Sertoli cells is to provide lactate for the energy production in spermatocytes and spermatids. The present study shows that, as in porcine Sertoli cells, interleukin (IL)1beta and follicle-stimulating hormone (FSH) increase lactate production in rat Sertoli cells (basal, 9.1 +/- 1.0; FSH (100 ng/ml), 16.6 +/- 2.0; IL1beta (50 ng/ml), 13.3 +/- 1.6 microg/microg DNA). Increments in glucose uptake (basal, 1083 +/- 70; FSH, 2686 +/- 128; IL1beta, 1899 +/- 74 dpm/microg DNA), lactic dehydrogenase (LDH) activity (basal, 36.6 +/- 4.1; FSH, 52.2 +/- 4.9; IL1beta, 55.3 +/- 5.1 mUI/microg DNA), LDH A mRNA levels, and redistribution of LDH isozymes are involved in these stimulatory effects. Differences in the period required by IL1beta to increase glucose uptake, as compared with the porcine model, have been observed. In addition, tumor necrosis factor alpha (TNFalpha), one of the major stimulators for lactate production in porcine Sertoli cells, does not control the secretion of this glucose metabolite in rat Sertoli cells. Lactate production may be regulated differently among mammals.

RT-PCR amplification of a Rhizopus oryzae lactate dehydrogenase gene fragment

No amino acid or DNA sequence information in sequence databases was found for a fungal lactate dehydrogenase (LDH) isozyme. Highly conserved regions in the lactate dehydrogenase enzymes of all taxonomies are found to be betaalphabeta nucleotide binding and substrate binding sites, also catalysis/active site. The conserved regions were selected as PCR primer target regions. The degenerate primers were designed according to the codon usage, determined by analyzing a number of different genes of Rhizopus species. A fragment of the gene (ldh), coding for approximately 72% of the lactate dehydrogenase enzyme from Rhizopus oryzae, was amplified using degenerate primers by Reverse Transcriptase-Polymerase Chain Reaction (RT-PCR). The size of the amplified fragment containing betaalphabeta nucleotide binding site, substrate binding site and catalysis/active site is found to be about 700 bp. The reported degenerate PCR primers and the amplification conditions may lead to the cloning of the lactate dehydrogenase gene of R. oryzae, which is an important organism due to its utilization in lactic acid and enzyme productions in industrial scales.

Lactate dehydrogenase from the northern krill Meganyctiphanes norvegica: comparison with LDH from the Antarctic krill Euphausia superba

Electrophoretic polymorphism of lactate dehydrogenase (LDH, EC 1.1.1.27) from abdominal muscle is reported in the northern krill Meganyctiphanes norvegica. In the population, from the Gullmarsfjord (west coast of Sweden), LDH was encoded for by two different Ldh-A* and -B* loci. The isoenzymes were named according to their electrophoretic mobilities. Ldh-A* locus was polymorphic. The allelic frequencies were a=0.99, a'=0.002, a"=0.004, a"'=0.004. The level of LDH polymorphism is low. Most individuals possess the same amount of two LDH homopolymers (LDH-A*(4) and LDH-B*(4)). The Meganyctiphanes norvegica LDH-A*(4) and LDH-B*(4) isoenzymes and the predominant LDH-A*(4) isoenzyme from Euphausia superba were purified to specific activities of 294, 306 and 464 micromol NADH min(-1) mg(-1), respectively. In both species the LDH isoenzymes were separated by chromatofocusing. All three isoenzymes are L-specific tetramers with molecular weight of approximately 160 kDa. Northern krill LDH-A*(4) has higher affinity for pyruvate and lactate and is more thermostable than LDH-B*(4). Both isoenzymes are inhibited significantly by high concentration of pyruvate but not lactate. Antarctic krill isoenzyme exhibits high substrate affinities, high NAD inhibition, high inhibition at 10 mM pyruvate, lack of lactate inhibition, and high heat stability and resembles northern krill LDH-A*(4) isoenzyme.

Isozyme distribution of ten enzymes and their loci in South American lungfish, Lepidosiren paradoxa (Osteichthyes, Dipnoi)

Scarce bibliographical data exists on the enzymes in Lepidosiren paradoxa and analysis of several enzymes was considered worthy of investigation. Distribution of ADH, ALP, FBALD, GAPDH, G3PDH, G6PDH, GPI, LDH, MDH, and PGM was identified in ten tissues (retina, heart, muscle, liver, kidney, lung, gut, gills, brain, and ovary) of the South American lungfish and compared with patterns previously described in other vertebrates. Compared with earlier results differences in the number of loci expressed were observed for ADH, G3PDH, GPI, and MDH. The number of loci expressed and/or in tissue specificity of several enzymes (ADH, FBALD, GAPDH, G3PDH, G6PDH and PGM) were found to be similar to those of other vertebrates. Differences were detected in ALP due to the absence of an intestinal-specific form typical of fish, amphibians, reptiles and birds; further differences were observed in GPI and MDH due to their tissue expression. The differences in LDH involve the LDH-A4 isozyme which was most common in tissues. Overall, comparison with other vertebrates reveals that in L. paradoxa the tissue-restricted expressions of some enzymes are similar, while others have retained an ancestral pattern and exhibit a more widespread tissue expression of genes.

Genetic reprogramming of lactate dehydrogenase, citrate synthase, and phosphofructokinase mRNA in bovine nuclear transfer embryos produced using bovine fibroblast cell nuclei

Adult animal cloning has progressed to allow the production of offspring cloned from adult cells, however many cloned calves die prenatally or shortly after birth. This study examined the expression of three important metabolic enzymes, lactate dehydrogenase (LDH), citrate synthase, and phosphofructokinase (PFK), to determine if their detection in nuclear transfer (NT) embryos mimics that determined for in vitro produced embryos. A day 40 nuclear transfer produced fetus derived from an adult cell line was collected and fetal fibroblast cultures were established and maintained. Reconstructed NT embryos were then produced from this cell line, and RT-PCR was used to evaluate mRNA reprogramming. All three mRNAs encoding these enzymes were detected in the regenerated fetal fibroblast cell line. Detection patterns were first determined for IVF produced embryos (1-cell, 2-cell, 6-8 cell, morula, and blastocyst stages) to compare with their detection in NT embryos. PFK has three subunits: PFK-L, PFK-M, and PFK-P. PFK-L and PFK-P were not detected in bovine oocytes. PFK subunits were not detected in 6-8 cell embryos but were detected in blastocysts. Results from NT embryo RT-PCR demonstrated that PFK was not detected in 8-cell NT embryos but was detected in NT blastocysts indicating that proper nuclear reprogramming had occurred. Citrate synthase was detected in oocytes and throughout development to the blastocyst stage in both bovine IVF and NT embryos. LDH-A and LDH-B were detected in bovine oocytes and in all stages of IVF and NT embryos examined up to the blastocyst stage. A third subunit, LDH-C was not detected at the blastocyst stage in IVF or NT embryos but was detected in all earlier stages and in mature oocytes. In addition, LDH-C mRNA was detected in gonad isolated from the NT and an in vivo produced control fetus. These results indicate that the three metabolic enzymes maintain normal expression patterns and therefore must be properly reprogrammed following nuclear transfer.

Expression of lactate dehydrogenases A and B during chicken spermatogenesis: characterization of testis specific transcripts

The substrates required for glycolysis change markedly at successive stages of spermatogenesis suggesting a considerable plasticity in the expression of glycolytic enzymes. Lactate dehydrogenase (LDH) isoenzymes, LDH-A and LDH-B, are expressed in premeiotic, meiotic cells, and early spermatids, both in avian and mammalian spermatogenesis. Highly polyadenylated forms, particularly of LDH-A, were detected in chicken testis. While mammals and columbid birds express the testis specific LDH-C gene in meiotic and postmeiotic cells, several LDH-B testis specific transcripts were detected in the corresponding cells during chicken spermatogenesis. These testis specific transcripts and the mRNA of mammalian LDH-C show several properties in common, such as temporal correlation of expression, mRNA stability, and repression of premature translation. These observations suggest that the testis specific transcripts could perform during chicken spermatogenesis the functions of the LDH-C mRNA in mammalian testis.

IMP-L3, A 20-hydroxyecdysone-responsive gene encodes Drosophila lactate dehydrogenase: structural characterization and developmental studies

IMP-L3, a gene isolated as a potential mediator of imaginal disc morphogenesis in Drosophila melanogaster, encodes lactate dehydrogenase (LDH). The predicted amino acid sequence of IMP-L3 is 58-61% identical to those of human LDHs. In cultured imaginal discs, IMP-L3 transcript levels and LDH enzyme activity increase in response to the steroid hormone, 20-hydroxyecdysone. In embryos, IMP-L3 transcript and LDH activity appear in developing somatic muscles by late stage 13, well before the onset of muscular contraction. High levels of transcript and LDH activity persist throughout embryogenesis and throughout larval development. The gene has been localized by in situ hybridization and deficiency mapping to 65A7-65B2 on the third chromosome. LDH activity is reduced to approximately 50% of wild type in animals heterozygous for a deficiency that removes the 65A-B region. Embryos deficient for the 65A-b region lack LDH activity. We conclude that IMP-L3 is the only gene that encodes LDH in Drosophila.

Differential messenger RNA distribution of lactate dehydrogenase LDH-1 and LDH-5 isoforms in the rat brain

The role of lactate in brain energy metabolism has recently received renewed attention. Although blood-borne monocarboxylates such as lactate poorly cross the blood-brain barrier in the adult brain, lactate produced within the brain parenchyma may be a suitable substrate for brain cells. Lactate dehydrogenase is crucial for both the production and utilization of lactate. In this article, we report the regional distribution of the messenger RNAs for lactate dehydrogenase isoforms 1 and 5 in the adult rat brain using in situ hybridization histochemistry with specific [alpha-(35)S]dATP 3' end-labeled oligoprobes. The autoradiographs revealed that the lactate dehydrogenase-1 messenger RNA is highly expressed in a variety of brain structures, including the main olfactory bulb, the piriform cortex, several thalamic and hypothalamic nuclei, the pontine nuclei, the ventral cochlear nucleus, the trigeminal nerve and the solitary tractus nucleus. In addition, the granular and Purkinje cell layers of the cerebellum showed a strong labeling. The neocortex (e.g., cingular, retrosplenial and frontoparietal cortices) often exhibits a marked laminar pattern of distribution of lactate dehydrogenase-1 messenger RNA (layers II/III, IV and VI being most strongly labeled). In contrast, expression of the lactate dehydrogenase-5 messenger RNA generally seemed more diffusely distributed across the different brain regions. Expression was particularly strong in the hippocampal formation (especially in Ammon's horn and dentate gyrus) and in the cerebral cortex, where no laminar pattern of distribution was observed. Overall, these data are consistent with the emerging idea that lactate is an important energy substrate produced and consumed by brain cells.

cDNA cloning of pig testicular lactate dehydrogenase-C, thermal stability of the expressed enzyme, and polymorphism among strains

Pig testicular lactate dehydrogenase-C (LDHC) cDNA was cloned and sequenced. The deduced sequence of 332 amino acids from pig LDHC shows 73% and 67% identity with that of pig LDHA (muscle) and LDHB (heart) respectively, whereas pig LDHA and LDHB isozymes shows 74% sequence identity. Pig and mouse LDHC cDNAs were subcloned into bacterial expression vector, and the expressed pig LDHC isozyme was shown to be as thermally stable as mouse LDHC isozyme. Pig genomic DNAs from Chinese Meishan, English Yorkshire, Danish Landrace and American Duroc were shown to exhibit polymorphic sites for restriction enzymes EcoRI, BamHI and PstI.

A new biological strategy for high productivity of recombinant proteins in animal cells by the use of hypoxia-response enhancer

Oxygen supply is one of the major problems in the production of useful proteins by cultured animal cells and therefore it is of importance to devise a system by which a high productivity of human therapeutic recombinant proteins can be maintained or enhanced under low oxygen concentrations. A number of hypoxia-inducible genes have been found in animal cells and the induction in most cases is due to hypoxic activation of the gene transcription. A consensus sequence (HRE = hypoxia-response enhancer) responsible for the hypoxic activation exists in these genes and the binding of a protein, which is widely distributed in animal cells, to this sequence responding to hypoxia activates the promoter activity. The promoter of lactate dehydrogenase A gene is active in Chinese hamster ovary (CHO) cells and the vicinal HRE stimulates the promoter activity efficiently in hypoxia. We have prepared a number of permanent CHO cell lines producing recombinant human erythropoietin (Epo) under control of this promoter/HRE. Epo production was highly hypoxia-inducible when the wild-type of HRE was used but uninducible when the mutant HRE was used. There was little difference in the in vitro and in vivo activities, and glycosylation between Epo produced by the cells cultured in 21% and 2% oxygen. Furthermore, forced expression of hypoxia-inducible factor-1alpha (HIF-1alpha) enhanced Epo production in all oxygen concentrations. These results indicate that a biological strategy based on the hypoxic induction of gene transcription provides a novel system which guarantees a high productivity even uner low oxygen concentrations.

Tumor necrosis factor-alpha stimulates lactate dehydrogenase A expression in porcine cultured sertoli cells: mechanisms of action

In the present study, we investigated the regulatory action of tumor necrosis factor-alpha (TNFalpha) on lactate dehydrogenase A (LDH A), a key enzyme involved in lactate production. To this end, use was made of a primary culture system of porcine testicular Sertoli cells. TNFalpha stimulated LDH A messenger RNA (mRNA) expression in a dose (ED50 = 2.5 ng/ml; 0.1 nM TNFalpha)-dependent manner. This stimulatory effect was time dependent, with an effect detected after 6 h of TNFalpha treatment and maximal after 48 h of exposition (5-fold; P<0.001). The direct effect of TNFalpha on LDH A mRNA could not be accounted for by an increase in mRNA stability (half-life = 9 h), but was probably due to an increase in LDH A gene transcription. Inhibitors of protein synthesis (cycloheximide), gene transcription (actinomycin D and dichlorobenzimidazole riboside), tyrosine kinase (genistein), and protein kinase C (bisindolylmaleimide) abrogated completely (actinomycin D, dichlorobenzimidazole riboside, cycloheximide, and genistein) or partially (bisindolylmaleimide) TNFalpha-induced LDH A mRNA expression. These observations suggest that the stimulatory effect of TNFalpha on LDH A mRNA expression requires protein synthesis and may involve a protein tyrosine kinase and protein kinase C. In addition, we report that LDH A mRNA levels were increased in Sertoli cells treated with FSH. However, although the cytokine enhances LDH A mRNA levels through increased gene transcription, the hormone exerts its stimulatory action through an increase in LDH A mRNA stability. The regulatory actions of the cytokine and the hormone on LDH A mRNA levels and therefore on lactate production may operate in the context of the metabolic cooperation between Sertoli and postmeiotic germ cells in the seminiferous tubules.

Energy metabolism in critically ill patients: lactate is a major oxidizable substrate

The potential role of an energy defect in acute diseases is still in the centre of the pathophysiological understanding of such states and therefore of our attempts to limit or to reverse the possible deleterious consequences of such defect. In fact several recent experimental works have shown that instead of being a negative consequence, the lactate production and the related metabolic acidosis due to the stimulation of anaerobic ATP-production pathway is rather a protective adapted response.

The fourth barrier

At the entrance of a new era, clinical xenotransplantation is a valued and auspicious option in tackling the problem of donor shortage. Because of ethical and anatomical issues, domestic farm animals are considered the most favourable species for organ donation, but transplantation of their organs leads to a complex process of rejection. Mechanistically, three immunological barriers, namely hyperacute rejection, delayed xenograft rejection and a subsequent cellular rejection, are distinguished. A fifth (microbiological) barrier is also being recognised. This review focuses on problems regarding the fourth barrier, i.e. physiology, in possible clinical settings and their corresponding animal models. Besides anatomical differences and posture, biochemical differences may have a severe impact on recipient survival. Differences in blood components and electrolyte and other biochemical concentrations are easily detected throughout the species considered for xenotransplantation. Enzymes and hormones have complex routes of action, activation and inhibition, and their molecular differences can impede function. As infusion or medicine may correct certain imbalances in electrolytes and proteins, problems with complex interactions might be difficult to retrieve and solve. Experimentally, survival of discordant xenografts show promising results, but the first physiological problems have already been detected. So, based upon the few experimental data available and the comparison of veterinary physiology, one might expect differences between the organs grafted, regarding the possible occurrence of physiological problems. Moreover, precautions must be taken to extrapolate long-term survival, because of species specificity.

Lamprey fructose-1,6-bisphosphate aldolase: characterization of the muscle-type and non-muscle-type isozymes

To study evolutionary aspects of fructose-1,6-bisphosphate (Fru-1,6-P2) aldolase during deuterostomian evolution, we have purified and characterized aldolases from the muscle and liver of lamprey (Entosphenus japonicus). Aldolase from the skeletal muscle and liver was identified to be the muscle-type isozyme and the non-muscle-type isozyme that was encoded by cDNAs M8 and L3, respectively, as described previously (Zhang, R., Yatsuki, H., Kusakabe, T., Iwabe, Miyata, T., Imai, T., Yoshida, M., and Hori, K., J. Biochem. 117, 545-553, 1995). The muscle-type isozyme has properties similar to vertebrate aldolase A, while the non-muscle-type isozyme shows a similarity to bacterial class I aldolase and vertebrate aldolase C but not to aldolase B, the liver-type aldolase, in terms of kinetic parameters: the Kcat values toward Fru-1,6-P2 and Fru-1-P, the Fru-1,6-P2/Fru-1-P activity ratio, and the Km values toward these substrates. The two enzymes have tetrameric forms with a molecular mass of approximately 160,000 and have similar pH optimum. The muscle-type and non-muscle-type isozymes from the tissues show different electrophoretic mobility; the muscle-type isozyme moves much faster than the non-muscle-type isozyme toward anodic side. The recombinant muscle-type and non-muscle-type aldolases gave similar characteristics as those from the tissues. The results presented in this paper, together with the data presented in the previous paper, strongly suggest that in lamprey it is possible to have two types of aldolase isozymes rather than one or three isozymes.

Toxoplasma gondii expresses two distinct lactate dehydrogenase homologous genes during its life cycle in intermediate hosts

Two Toxoplasma gondii genes were characterized that are differentially expressed during the parasite's life cycle. The genes named LDH1 and LDH2, respectively, encode polypeptides similar to the enzyme lactate dehydrogenase (LDH; L-lactate:NAD+ oxidoreductase, EC 1.1.1.27) from a variety of organisms. They show 64.0% nucleotide identity in the coding region and both have an intron at the same relative position. The deduced amino acid sequences of LDH1 and LDH2 share 71.1% identity. LDH1 and LDH2 are most similar to an LDH of Plasmodium falciparum (46.5% and 48.5% amino acid identities, respectively). The mRNA of LDH2 was only detected in the bradyzoite stage, while the mRNA of LDH1 was detected in both the bradyzoite and tachyzoite stages. However, by isoelectric focusing and immunoblot analysis, only one LDH isoform was found to be expressed in each stage. Furthermore, the expression of a reporter gene carrying chloramphenicol acetyltransferase (CAT) coding sequence and the putative LDH2 promoter sequence was significantly up-regulated by growing parasites in tissue culture in media with alkaline pH (pH 8.2, a condition known to induce the expression of bradyzoite-specific antigens), while the expression of a CAT reporter construct carrying the putative LDH1 promoter sequence was down-regulated by similar treatment. These results indicate that LDH expression is developmentally regulated in T. gondii and suggest a possible correlation between stage conversion and alteration in carbohydrate or energy metabolism in this parasite.

Selective distribution of lactate dehydrogenase isoenzymes in neurons and astrocytes of human brain

In vertebrates, the interconversion of lactate and pyruvate is catalyzed by the enzyme lactate dehydrogenase. Two distinct subunits combine to form the five tetrameric isoenzymes of lactate dehydrogenase. The LDH-5 subunit (muscle type) has higher maximal velocity (Vmax) and is present in glycolytic tissues, favoring the formation of lactate from pyruvate. The LDH-1 subunit (heart type) is inhibited by pyruvate and therefore preferentially drives the reaction toward the production of pyruvate. There is mounting evidence indicating that during activation the brain resorts to the transient glycolytic processing of glucose. Indeed, transient lactate formation during physiological stimulation has been shown by 1H-magnetic resonance spectroscopy. However, since whole-brain arteriovenous studies under basal conditions indicate a virtually complete oxidation of glucose, the vast proportion of the lactate transiently formed during activation is likely to be oxidized. These in vivo data suggest that lactate may be formed in certain cells and oxidized in others. We therefore set out to determine whether the two isoforms of lactate dehydrogenase are localized to selective cell types in the human brain. We report here the production and characterization of two rat antisera, specific for the LDH-5 and LDH-1 subunits of lactate dehydrogenase, respectively. Immunohistochemical, immunodot, and western-blot analyses show that these antisera specifically recognize their homologous antigens. Immunohistochemistry on 10 control cases demonstrated a differential cellular distribution between both subunits in the hippocampus and occipital cortex: neurons are exclusively stained with the anti-LDH1 subunit while astrocytes are stained by both antibodies. These observations support the notion of a regulated lactate flux between astrocytes and neurons.

Methods for the separation of lactate dehydrogenases and clinical significance of the enzyme

Lactate dehydrogenase (LDH), an ubiquitous enzyme among vertebrates, invertebrates, plants and microbes was discovered in the early period of enzymology. The enzyme has been dissolved in several distinguishable molecular forms. In mammals, three types of subunits encoded by the genes Ldh-A, Ldh-B and Ldh-C give rise to a selected number of tetrameric isoenzymes. LDH-A4, LDH-B4 and the mixed hybrid forms of the A- and B-subunits are present in many tissues but with certain distribution patterns. LDH-C4 is confined in mammals to testes and sperm. Numerous techniques have been employed to purify, characterize and separate the different forms of the enzyme. This report deals with the main protocols and procedures of purification of LDH and its isoenzymes including chromatographic and electrophoretic methods, partitioning in aqueous two-phase systems and precipitation approaches. In particular, affinity separation techniques based on natural and pseudo-biospecific ligands are described in detail. In addition, basic physico-chemical and kinetic properties of the enzyme from different sources are summarized in a second part, the clinical significance of the determination of LDH in diverse body fluids in respect to the total activity and the isoenzyme distribution in different organs is discussed.

Strong evolutionary conservation of broadly expressed protein isoforms in the troponin I gene family and other vertebrate gene families

It is well established that different protein classes undergo molecular evolution at different rates, presumably reflecting differing functional constraints. However, it is also the case that different isoforms of the "same" protein, encoded by a multigene family, may evolve at different rates. Here I report a relationship within gene families between isoform evolutionary rate and gene expression profile: Broadly expressed isoforms show stronger sequence conservation than do narrowly expressed isoforms. This observation emerged initially from cDNA cloning and sequencing studies, described here, of a vertebrate gene family encoding three differentially expressed isoforms of the muscle protein troponin I. However, the expression breadth/sequence conservation relationship applies to vertebrate gene families in general. In a broad and arbitrary survey sampling of sequence data on well-characterized vertebrate gene families, I found that in 14/15 families the most strongly conserved isoform was the most broadly expressed isoform, or one of several similarly broadly expressed isoforms. Broadly expressed isoforms are presumably subjected to greater negative selection pressure because they must function in a more diverse biochemical environment than do narrowly expressed isoforms. The expression breadth/evolutionary rate relationship has several interesting implications regarding the overall process of gene family evolution by duplication/divergence from ancestral genes.

L-lactate dehydrogenase A4- and A3B isoforms are bona fide peroxisomal enzymes in rat liver. Evidence for involvement in intraperoxisomal NADH reoxidation

The subcellular localization of l-lactate dehydrogenase (LDH) in rat hepatocytes has been studied by analytical subcellular fractionation combined with the immunodetection of LDH in isolated subcellular fractions and liver sections by immunoblotting and immunoelectron microscopy. The results clearly demonstrate the presence of LDH in the matrix of peroxisomes in addition to the cytosol. Both cytosolic and peroxisomal LDH subunits have the same molecular mass (35.0 kDa) and show comparable cross-reactivity with an anti-cytosolic LDH antibody. As revealed by activity staining or immunoblotting after isoelectric focussing, both intracellular compartments contain the same liver-specific LDH-isoforms (LDH-A4 > LDH-A3B) with the peroxisomes comprising relatively more LDH-A3B than the cytosol. Selective KCl extraction as well as resistance to proteinase K and immunoelectron microscopy revealed that at least 80% of the LDH activity measured in highly purified peroxisomal fractions is due to LDH as a bona fide peroxisomal matrix enzyme. In combination with the data of cell fractionation, this implies that at least 0.5% of the total LDH activity in hepatocytes is present in peroxisomes. Since no other enzymes of the glycolytic pathway (such as phosphoglucomutase, phosphoglucoisomerase, and glyceraldehyde-3-phosphate dehydrogenase) were found in highly purified peroxisomal fractions, it does not seem that LDH in peroxisomes participates in glycolysis. Instead, the marked elevation of LDH in peroxisomes of rats treated with the hypolipidemic drug bezafibrate, concomitantly to the induction of the peroxisomal beta-oxidation enzymes, strongly suggests that intraperoxisomal LDH may be involved in the reoxidation of NADH generated by the beta-oxidation pathway. The interaction of LDH and the peroxisomal palmitoyl-CoA beta-oxidation system could be verified in a modified beta-oxidation assay by adding increasing amounts of pyruvate to the standard assay mixture and recording the change of NADH production rates. A dose-dependent decrease of NADH produced was simulated with the lowest NADH value found at maximal LDH activity. The addition of oxamic acid, a specific inhibitor of LDH, to the system or inhibition of LDH by high pyruvate levels (up to 20 mm) restored the NADH values to control levels. A direct effect of pyruvate on palmitoyl-CoA oxidase and enoyl-CoA hydratase was excluded by measuring those enzymes individually in separate assays. An LDH-based shuttle across the peroxisomal membrane should provide an efficient system to regulate intraperoxisomal NAD+/NADH levels and maintain the flux of fatty acids through the peroxisomal beta-oxidation spiral.

Hypoxic regulation of lactate dehydrogenase A. Interaction between hypoxia-inducible factor 1 and cAMP response elements

The oxygen-regulated control system responsible for the induction of erythropoietin (Epo) by hypoxia is present in most (if not all) cells and operates on other genes, including those involved in energy metabolism. To understand the organization of cis-acting sequences that are responsible for oxygen-regulated gene expression, we have studied the 5' flanking region of the mouse gene encoding the hypoxically inducible enzyme lactate dehydrogenase A (LDH). Deletional and mutational analysis of the function of mouse LDH-reporter fusion gene constructs in transient transfection assays defined three domains, between -41 and -84 base pairs upstream of the transcription initiation site, which were crucial for oxygen-regulated expression. The most important of these, although not capable of driving hypoxic induction in isolation, had the consensus of a hypoxia-inducible factor 1 (HIF-1) site, and cross-competed for the binding of HIF-1 with functionally active Epo and phosphoglycerate kinase-1 sequences. The second domain was positioned close to the HIF-1 site, in an analogous position to one of the critical regions in the Epo 3' hypoxic enhancer. The third domain had the motif of a cAMP response element (CRE). Activation of cAMP by forskolin had no effect on the level of LDH mRNA in normoxia, but produced a magnified response to hypoxia that was dependent upon the integrity of the CRE, indicating an interaction between inducible factors binding the HIF-1 and CRE sites.

Characterization of the glycolysis in lactate dehydrogenase-A deficiency

Recurrent rhabdomyolysis due to decreased glycolysis occurred during strenuous exercise by patients with lactate dehydrogenase-A subunit (LDH-A; muscle) deficiency. We report the glycolytic features of 4 patients from 2 families in whom the severity of the disease differed. There was no difference in the gene abnormality. The enzyme activity of LDH in the muscle was less than 5% that of the control value. Glycolysis in the muscle showed that the respective sums of the pyruvate and lactate levels in the patients with mild and severe symptoms were reduced to approximately 65% and 35% that of the control value. Comparable amounts of glycerol 3-phosphate were produced. Glycerol 3-phosphate dehydrogenase activity in the muscles of patients with mild symptoms was three times the control value. These findings suggest that the disease severity in our patients may be related to the degree of NADH reoxidation by glycerol 3-phosphate dehydrogenase substituting for LDH.

Expression profile of Ldh-a in the developing rat (Rattus norvegicus) testis suggests regulation at the translational level

Expression of Ldh-a and Ldh-c mRNAs was examined in the rat testis. The mRNA levels of both Ldh-a and Ldh-c increase during testicular maturation. In the adult testis, Ldh-a mRNA is expressed maximally in primary spermatocytes. Comparison of the Ldh-a mRNA expression profile with its translation product suggests that this gene is translationally down-regulated during spermatogenesis.

Molecular analysis of four lactate dehydrogenase-A mutants in the mouse

Four electrophoretic and/or enzyme-activity variants of murine LDH-A subunit (Ldhla-m1Neu, Ldhla-m5Neu, Ldhla-m6Neu, Ldhla-m9Neu), induced by procarbazine hydrochloride or ethylnitrosourea (ENU), were analyzed at the DNA level. The exons of the Ldhl gene from homozygous mutants were amplified by PCR and sequenced. Three mutations resulted from nucleotide substitutions in exon 5: the transitions A-->G at codons 216 (Ldhla-m5Neu) and 225 (Ldhla-m6Neu), and the transversion G-->C (Ldhla-m1Neu) at codon 222. The mutations resulted in the replacements of Glu by Gly (Ldhla-m5Neu), Gln by Arg (Ldhla-m6Neu) and Asp by His (Ldhla-m1Neu). The fourth base substitution, the transition T-->C (Ldhla-m9Neu), has been found at the GT donor splice site following the first exon; this mutation affected the efficiency of transcription. All ENU-induced mutations were A/T-->G/C transitions. The mutation events could be correlated with the biochemical and physiological alterations observed in affected mice.

Molecular genetic studies of muscle lactate dehydrogenase deficiency in white patients

We identified two new mutations in 2 white patients with muscle lactate dehydrogenase deficiency. Both patients had exercise intolerance, cramps, and recurrent myoglobinuria. One patient was homozygous for a 2-bp deletion in exon 5, resulting in a frameshift with premature termination of translation. The second patient was homozygous for a G-->A substitution at the 3' end of exon 2, leading to exon skipping and splicing of exon 1 to exon 3; the aberrantly spliced messenger RNA contains a frameshift, resulting in premature termination of translation. The present report provides evidence of molecular genetic heterogeneity in white patients with muscle lactate dehydrogenase deficiency.

Evolutionary relationships of lactate dehydrogenases (LDHs) from mammals, birds, an amphibian, fish, barley, and bacteria: LDH cDNA sequences from Xenopus, pig, and rat

The nucleotide sequences of the cDNAs encoding LDH (EC 1.1.1.27) subunits LDH-A (muscle), LDH-B (liver), and LDH-C (oocyte) from Xenopus laevis, LDH-A (muscle) and LDH-B (heart) from pig, and LDH-B (heart) and LDH-C (testis) from rat were determined. These seven newly deduced amino acid sequences and 22 other published LDH sequences, and three unpublished fish LDH-A sequences kindly provided by G. N. Somero and D. A. Powers, were used to construct the most parsimonious phylogenetic tree of these 32 LDH subunits from mammals, birds, an amphibian, fish, barley, and bacteria. There have been at least six LDH gene duplications among the vertebrates. The Xenopus LDH-A, LDH-B, and LDH-C subunits are most closely related to each other and then are more closely related to vertebrate LDH-B than LDH-A. Three fish LDH-As, as well as a single LDH of lamprey, also seem to be more related to vertebrate LDH-B than to land vertebrate LDH-A. The mammalian LDH-C (testis) subunit appears to have diverged very early, prior to the divergence of vertebrate LDH-A and LDH-B subunits, as reported previously.

Oxygen-regulated control elements in the phosphoglycerate kinase 1 and lactate dehydrogenase A genes: similarities with the erythropoietin 3' enhancer

Production of the glycoprotein hormone erythropoietin (Epo) in response to hypoxic stimuli is almost entirely restricted to particular cells within liver and kidney, yet the transcriptional enhancer lying 3' to the Epo gene shows activity inducible by hypoxia after transfection into a wide variety of cultured cells. The implication of this finding is that many cells which do not produce Epo contain a similar, if not identical, oxygen-regulated control system, suggesting that the same system is involved in the regulation of other genes. We report that the human phosphoglycerate kinase 1 and mouse lactate dehydrogenase A genes are induced by hypoxia with characteristics which resemble induction of the Epo gene. In each case expression is induced by cobalt, but not by cyanide, and hypoxic induction is blocked by the protein-synthesis inhibitor cycloheximide. We show that the relevant cis-acting control sequences are located in the 5' flanking regions of the two genes, and we define an 18-bp element in the 5' flanking sequence of the phosphoglycerate kinase 1 gene which is both necessary and sufficient for the hypoxic response, and which has sequence and protein-binding similarities to the hypoxia-inducible factor 1 binding site within the Epo 3' enhancer.

Expression of lactic dehydrogenase isoenzymes in rabbit muscle during development

1. Rabbit cDNA probes for H and M lactic dehydrogenase subunits were used to monitor mRNA levels in different muscle types during growth. 2. At the same time, lactic dehydrogenase activity and relative quantities of H and M protein subunits were measured. 3. The main results are that mRNA abundance depends on muscle type and age, and mRNA abundance is not correlated with enzymatic activity.