Supernumerary chromosomes and spermatogenesis in a human male carrier

Screening for lactate dehydrogenase (LDH) subunit deficiencies was performed on 2880 blood samples from healthy individuals in the Fukuoka Prefecture in Japan by means of electrophoresis. The frequencies of heterozygotes with either LDH-A or LDH-B deficiency were found to be 0.104% at each locus. These estimated frequencies of either LDH-A or LDH-B deficiencies were slightly lower than, but not significantly different from, those found previously in Shizuoka Prefecture. The genetic mutations in individuals heterozygous for LDH-B deficiency were analyzed by the polymerase chain reaction and DNA conformation polymorphism. Abnormal migration patterns were observed in individuals heterozygous for LDH-B deficiency. Subsequent sequence determination of the mutant alleles revealed three novel mutations: an eight-base duplication in exon 3, a four-base duplication in exon 4, and a one-base deletion in exon 7 of the LDH-B gene. These three mutations result in frameshift translation and premature termination. In addition, the mutations resulting in the duplication of eight or four nucleotides appear to cause a decrease in the levels of LDH-B mRNA.     

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.     

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.     

Lactate dehydrogenase expression at the onset of altered loading in rat soleus muscle.

Both functional overload and hindlimb disuse induce significant energy-dependent remodeling of skeletal muscle. Lactate dehydrogenase (LDH), an important enzyme involved in anaerobic glycolysis, catalyzes the interconversion of lactate and pyruvate critical for meeting rapid high-energy demands. The purpose of this study was to determine rat soleus LDH-A and -B isoform expression, mRNA abundance, and enzymatic activity at the onset of increased or decreased loading in the rat soleus muscle. The soleus muscles from male Sprague-Dawley rats were functionally overloaded for up to 3 days by a modified synergist ablation or subjected to disuse by hindlimb suspension for 3 days. LDH mRNA concentration was determined by Northern blotting, LDH protein isoenzyme composition was determined by zymogram analysis, and LDH enzymatic activity was determined spectrophotometrically. LDH-A mRNA abundance increased by 372%, and LDH-B mRNA abundance decreased by 43 and 31% after 24 h and 3 days of functional overload, respectively, compared with that in control rats. LDH protein expression demonstrated a shift by decreasing LDH-B isoforms and increasing LDH-A isoforms. LDH-B activity decreased 80% after 3 days of functional overload. Additionally, LDH-A activity increased by 234% following 3 days of hindlimb suspension. However, neither LDH-A or LDH-B mRNA abundance was affected following 3 days of hindlimb suspension. In summary, the onset of altered loading induced a differential expression of LDH-A and -B in the rat soleus muscle, favoring rapid energy production. Long-term altered loading is associated with myofiber conversion; however, the rapid changes in LDH at the onset of altered loading may be involved in other physiological processes.     

Differential activity and synthesis of lactate dehydrogenase isozymes A (muscle), B (heart), and C (testis) in mouse spermatogenic cells

Spermatogenic cells isolated from adult and prepubertal mice by unit gravity sedimentation were used to examine enzyme activities and synthesis of the lactate dehydrogenase (LDH) isozymes during spermatogenesis. The synthesis and activity of LDH-C4, the germ cell-specific isozyme, was detected earliest in isolated preleptotene and leptotene/zygotene spermatocytes prior to the mid-pachytene stage of meiosis reported previously. The LDH-C4 isozyme was prominent in pachytene spermatocytes, round spermatids, and condensing spermatids, whereas spermatozoa contained only the LDH-C4 isozyme. In addition, somatic-type LDH isozymes consisting primarily of LDH-B subunits were present in germ cells throughout spermatogenesis. This is in contrast to a previous report that the LDH-B subunit was not synthesized in germ cells. Sertoli cells were further shown to exhibit comparable amounts of five tetrameric LDH isozymes formed by combination of muscle-type LDH-A and heart-type LDH-B subunits.     

中国林蛙乳酸脱氢酶多基因系统及基因间连锁关系的研究

（１）用聚丙烯酰胺凝胶电泳对山西产中国林蛙４个地理群的３３３只林蛙进行了分析,结果表明：中国林蛙的ＬＤＨ由ＬＤＨ－Ａ,ＬＤＨ－Ｂ和ＬＤＨ－Ｃ３个基因决定。ＬＤＨ－Ａ是单态座位,ＬＤＨ－Ｂ和ＬＤＨ－Ｃ均为多态座位,每个多态座位均有两个等位基因。ＬＤＨ－Ｂ与ＬＤＨ－Ｃ呈紧密连锁关系。认为ＬＤＨ－Ｃ是ＬＤＨ－Ｂ的重复产物。（２）热稳定性、尿素处理稳定性及组织特异性研究表明：ＬＤＨ对温度和尿素处理稳定性顺序为Ａ４＞Ｂ’４＞Ｂ４＞Ｃ４。Ａ４在骨骼肌和肝脏等组织中活力最大,Ｂ４在心肌和卵巢中活力最强,ＬＤＨ－Ｃ主要在眼球和卵巢中表达。（３）Ｌｄｈ－ｂ和Ｌｄｈ－ｂ＇在不同地理群间呈差异分布,随着纬度的增高,Ｌｄｈ－ｂ在种群中的频率增大。     

Patterns of gene expression during teleost embryogenesis: Lactate dehydrogenase isozyme ontogeny in the medaka (Oryzias iatipes)

The ontogeny of the lactate dehydrogenase (LDH; EC 1.1.1.27) isozymes during medaka (Oryzias latipes) embryogenesis was determined after the genetic and molecular bases of this multilocus isozyme system were established. Three LDH loci are differentially expressed among the tissues of the adult medaka. The LDH-A locus was expressed almost exclusively in the white skeletal muscle, the LDH-B locus in all tissues examined, and the LDH-C locus in the eye and brain. The contribution of each of these LDH loci was quantitatively determined throughout early medaka embryogenesis by using a combination of electrophoretic, immunochemical, and spectrophotometric procedures. LDH-B₄ is present throughout embryogenesis and is the predominant LDH isozyme during this period. LDH-C subunit activity was first detected 146 hr after fertilization (26°C), 142 hr prior to hatching. LDH-A subunit activity, however, was not detected until after hatching and, then, only as heterotetramers containing LDH-B subunits. The pattern of LDH gene expression during medaka embryogenesis was compared with the patterns of LDH gene expression during early development in five other teleost species. Some common patterns of differential LDH gene expression appear to exist among the teleosts. In all species examined, isozymes encoded in at least one LDH locus, A and/or B, were present throughout development. Those isozymes present continually during embryogenesis also tend to be active in a wide variety of differentiated tissues in the adult fish. Conversely, LDH isozymes which are active in a restricted number of adult tissues are detected only later in embryogenesis. The initiation of LDH-C gene expression, however, is closely coupled with morphological and functional differentiation of those cells in which this locus is predominantly expressed in the adult.     

Localization of lactate dehydrogenase isozymes in human muscle tissues by the mixed aggregation immunocytochemical technique.

Lactate dehydrogenase (LDH) isozyme composition and localization was determined in sections of skeletal, heart and smooth muscle by the mixed aggregation immunocytochemical method using first antibody directed against purified human LDH-A4 (M4) or LDH-B4 (H4) followed by the enzymes LDH-A4 and LDH-B4, respectively. An even distribution of the two monomers in all fibres was seen with heart muscle and smooth muscle. Heart muscle had a low concentration of A-monomers and a high concentration of B-monomers, whereas the smooth muscle had equal concentrations of the two monomers. In contrast, skeletal muscle from m. quadriceps femoris was found to be composed of two muscle fibre types, one containing mainly A-, the other mainly B-monomers. On the basis of succinate dehydrogenase activity it was shown that the red (type 1) fibres contain mainly B-monomers and the white (type 2) fibres mainly A-monomers of LDH.     

The cDNA cloning and molecular evolution of reptile and pigeon lactate dehydrogenase isozymes

The cDNAs encoding lactate dehydrogenase isozymes LDH-A (muscle) and LDH-B (heart) from alligator and turtle and LDH-A, LDH-B, and LDH-C (testis) from pigeon were cloned and sequenced. The evolutionary relationships among vertebrate LDH isozymes were analyzed. Contrary to the traditional belief that the turtle lineage branched off before the divergence between the lizard/alligator and bird lineages, the turtle lineage was found to be clustered with either the alligator lineage or the alligator-bird clade, while the lizard lineage was found to have branched off before the divergence between the alligator/turtle and bird lineages. The pigeon testicular LDH-C isozyme was evidently duplicated from LDH-B (heart), so it is not orthologous to the mammalian testicular LDH-C isozymes.      

Lactate dehydrogenase-B cDNA from the teleost Fundulus heteroclitus: evolutionary implications

A cDNA that encodes the heart-type lactate dehydrogenase (LDH-B) from the teleost fish Fundulus heteroclitus was cloned and sequenced. The protein encoded by the cDNA was analyzed in relation to 13 LDH proteins from a variety of taxa. One of the deductions from this analysis is that LDH-B proteins have residues in the active site that are unique and that may be important in determining the biochemistry of the heart-type isozyme. Phylogenetic analysis of the LDH sequences indicates that the branch lengths are greater in lower vertebrates, suggesting that the amino acid replacement rates vary depending on the evolutionary constraints within each taxon. Furthermore, the analysis suggests that LDH-C arose prior to the divergence of the LDH-A and LDH-B isozymes and thus that it is probably ancestral to these isozymes.     

Functional and adaptive significance of differentially expressed lactate dehydrogenase isoenzymes in tissues of four obligatory air-breathing Channa species

This study investigates the differential expression of lactate dehydrogenase (LDH) isoenzymes in the genus Channa using PAGE. With the help of obligate air-breathing, all of the selected species can sustain water deprivation to varying degrees. In subunit composition and higher electrophoretic mobility of LDH-A₄, the profiles of channid species were similar to other teleosts documented in the literature. However, inter- and intra-species differences, with particular reference to aerobic/anaerobic metabolic options, existed. Whereas glycolysis in Channa punctata appears to depend largely on aerobic LDH-B and partly on anaerobic LDH-A, metabolism in C. gachua, C. striata and C. marulius depends exclusively on the activity of anaerobic LDH-A. Expression of the third locus Ldh-C was recorded in the eyes of C. marulius, in addition to C. gachua. Heat inactivation experiments reveal species differences between LDH isoenzymes and a general order of the relative stabilities: LDH-C > DH-B > LDH-A. Metabolic and evolutionary implications of the findings have also been discussed.     

Inhibition kinetics of lactate dehydrogenase isoenzymes by gossypol acetic acid

The effect of gossypol acetic acid, a potent male sterilent was studied on LDH from goat liver (LDH-A4), heart (LDH-B4) and testis (LDH-C4) in vitro. All the preparations of LDH were inhibited by gossypol when the reaction was carried out in pyruvate-lactate (direct) or lactate to pyruvate (reverse) directions. The IC50 of gossypol for the pyruvate oxidation by LDH isozymes varied between 16 and 42 microM in presence of 0.27 mM pyruvate and 0.15 mM NADH at 25 degrees C and pH 7.4 whereas for the lactate oxidation, IC50 was 125 microM in a system containing 3.3 mM lactic acid and 1.8 mM NAD at 25 degrees C and pH 9.0. Reciprocal plots due to Lineweaver-Burk showed that these isozymes are inhibited in a non-competitive manner with respect to pyruvate and lactate, and in a competitive fashion when NAD and NADH were varied as substrates. Ki values of LDH-A4, -B4 and -C4 isozymes in presence of gossypol were 20, 34 and 29 microM against pyruvate; 33, 43 and 45 microM against NADH; 85, 85 and 125 microM against lactate and 94, 108 and 83 microM against NAD respectively.     

Molecular evidence for a clade of turtles.

Although turtles have been generally grouped with the most primitive reptile species, the origin and phylogenetic relationships of turtles have remained unresolved to date. To confirm the phylogenetic position of turtles in amniotes, we have cloned and determined the cDNA sequences encoding for skink lactate dehydrogenase (LDH)-A and LDH-B, snake LDH-A, and African clawed frog LDH-A; four alpha-enolase cDNA sequences from turtle, alligator, skink, and snake were also cloned and determined. All of these eight cDNA sequences, as well as the previously published LDH-A, LDH-B, and alpha-enolase of mammals, birds, reptiles, and African clawed frog, were analyzed by the phylogenetic tree reconstruction methods of neighbor-joining, maximum parsimony, and maximum likelihood. In the phylogenetic analyses, the turtle was found to be closely related to the alligator. Also, we found that the turtle had diverged after the divergence of squamates and birds. This departs from previous hypotheses of turtle evolution and further suggests that turtles are the latest of divergent reptiles, having been derived from an ancestor of crocodilian lineage within the last 200 million years.     

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.     

Ontogenetic changes and developmental adjustments in lactate dehydrogenase isozymes of an obligate air-breathing fish Channa punctatus during deprivation of air access

In air-breathing snakehead Channa punctatus, Ldh-B is expressed at all ontogenetic and developmental stages, while Ldh-A is expressed temporally in pre-hatchlings 12-13 days ahead of bimodal respiration marked by air-breathing. Remarkable differences are observed in the LDH isozyme expression among various ontogenetic and developmental stages upon denying air access. When denied air access, water-breathing larvae show two distinct characteristics: (i) they survive longer than transitory air-breathers due to independence from air-breathing and (ii) there is more transient induction of Ldh-B than Ldh-A. Transition to bimodal breathing, which occurred post-hatching in 15-day old larvae, is coincidental with inducibility of Ldh-A and concomitant down-regulation of Ldh-B. Heart tissue from air-breathing adults denied air access shows a preferential expression of LDH-A subunit and slight down-regulation of LDH-B. Heterotetramers of A and B subunits participate in adjusting LDH levels among those stages which either precede air-breathing switchover, or are subsequent to this transition. The contribution of heterotetramers depends on the stage-specific levels of LDH homotetramers A(4) or B(4). Scaling of muscle mass during growth, tolerance to extended deprivation of air access and induction of Ldh-A are correlated. Response to restoring air contact indicated that advanced air-breathing stages of C. punctatus possess an inherent capacity to sense surface air. In kinetic properties, LDH isozymes of C. punctatus are teleost-like but species specificity is displayed in oxidative potential by cardiac muscle and in L-lactate reduction by skeletal muscle.     

Evolutionary implications of lactate dehydrogenases (LDHs) of hagfishes compared to lampreys: LDH cDNA sequences from Eptatretus burgeri, Paramyxine atami and Eptatretus okinoseanus

Heart muscles of hagfishes Paramyxine atami and Eptatretus okinoseanus express the B4 isozyme of lactate dehydrogenase [L-LDH: NAD oxidoreductase, EC 1.1.1.27] (LDH-B4) whereas their skeletal muscles express LDH-A4. To examine the relationship of hagfish LDHs to lamprey and other vertebrate LDHs, we determined the cDNA sequences of LDH-A from three hagfishes and compared them with previously published sequences. A phylogenic tree shows that hagfishes diverged just after lampreys. The deduced amino acid sequences showed ten regions common to all vertebrate LDHs examined, i.e., the active site, the pocket recognizing the substrate-coenzyme complex, part of a loop at the surface, and the substrate binding site. The cyclostomate-specific regions (S1, S2) were located in the neighborhood of the active site loop. Three regions, IGS1, IGS2 and IGS3, seem to have altered their structures during the differentiation of LDH isozymes, and the regions remain in LDH-B of vertebrates hitherto examined. IGS2 and IGS3, which are in the neighborhood of the active site, may regulate catalytic activity. There were differences in six amino acid residues (6, 10, 20, 156, 269, and 341) in LDHs of hagfishes. These differences might reflect the tolerance to high pressure and low temperature of LDHs from hagfishes at different habitat depths.     

Immunochemical studies on lactate dehydrogenase A subunit deficiencies.

In lactate dehydrogenase (LDH) A subunit deficiency, is there not only a lack of activity but also a lack of subunit production? We demonstrated three remarkable points to answer this question: There are no proteins that immunologically react with anti-A subunits. There are no heterotetramers that react with anti-B subunits. B subunits seem to be genetically produced at normal level, and all of them form only one isoenzyme, LDH-B4. From these points, we concluded that there is a complete lack of A subunit production or production of incomplete A subunits that can neither react with anti-A subunits nor form heterotetramers.     

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.