Mitochondrial malate dehydrogenase and malic enzyme: Mendelian inherited electrophoretic variants in the mouse

High enzymatic activity preservation of malate dehydrogenase immobilized in a Langmuir–Blodgett film and its electrochemical biosensor application for malic acid detection

Malate dehydrogenase was immobilized on a cation octadecylamine monolayer and transferred onto an indium tin oxide coated glass substrate. The enzyme immobilized electrode was then used to electrochemically sense malic acid in the range of 2.2–50 mM.

Equine marker genes: Polymorphism for soluble erythrocyte malic enzyme

Polymorphism of equine erythrocyte malic enzyme is detactable on starch gel electrophoresis. The frequency of ME1S was 0.06 in 667 Standardbred and 0.09 in 85 Thoroughbred horses. No genetically determined electrophoretic variation in soluble malate dehydrogenase was detected.

The SMXA: a new set of recombinant inbred strain of mice consisting of 26 substrains and their genetic profile

A new set of recombinant inbred (RI) strain SMXA consisting of 26 substrains was established between SM/J and A/J. The history of the SMXA RI strains and their genetic profile covering 158 genetic marker loci are reported. From the strain distribution pattern among SMXA RI strains, the chromosomal location of salivary and tear protein genes Spe1-r, Spe1-s, Spe2, and Tpe1 were newly determined.

Identification and genetic mapping of 151 dispersed members of 16 ribosomal protein multigene families in the mouse

More than 150 individual members of 16 ribosomal protein multigene families were identified as DNA restriction fragments and genetically mapped. The ribosomal protein gene-related sequences are widely dispersed throughout the mouse genome. Map positions were determined by analysis of 144 progeny mice from both an interspecific (C57BL/6J x SPRET/Ei)F1 x SPRET/Ei and an intersubspecific (C57BL/6J x CAST/Ei)F1 x C57BL/6J backcross. In addition, 30 members of the multigene families encoding PGK1 ODC, and TPI, including five new loci for ODC and one new locus for TPI, were characterized and mapped. Interspecific backcross linkage data for 29 nonecotropic murine leukemia retroviruses endogenous to C57BL/6J mice are also reported. Transmission ratio distortions and recombination frequencies are compared between the two backcrosses.

Identification and genetic mapping of the murine gene and 20 related sequences encoding chromosomal protein HMG-17

HMG-17 is an abundant, nonhistone chromosomal protein that binds preferentially to nucleosomal core particles of mammalian chromatin. The human gene for HMG-17 has been localized to Chromosome (Chr) 1p, but the murine gene has not been previously mapped. Here we identify the murine functional gene, Hmg17, from among more than 25 related sequences (probably processed pseudogenes) and show that it is located on mouse Chr 4, in a region known to have conserved linkage relationships with human Chr 1p. We also report the map locations of 20 additional Hmg17-related sequences on mouse Chrs 1, 2, 3, 5, 7, 8, 9, 13, 15, 16, 17, 18, and X. The multiple, dispersed members of the Hmg17 multigene family can be detected efficiently with a single cDNA probe and provide useful markers for genetic mapping studies in mice.

Mapping of the Mod-1 locus on mouse chromosome 9

A new method for typing the Mod-1 locus on mouse Chromosome (Chr) 9 was developed, based on restriction fragment length polymorphism (RFLP) within a polymerase chain reaction (PCR)-amplified fragment. The new method led us to revise the strain distribution pattern (SDP) of Mod-1 in the BXD (C57BL/6J x DBA/2J) and AKXD (AKR/J x DBA/2J) recombinant inbred (RI) strains. The new SDP eliminates several previously reported examples of double recombination events between Mod-1 and the closest flanking loci in the BXD and AKXD strains. In the BXD strains, the revised SDP of Mod-1 was identical to that of the Mod-1-related D9Rtil locus. Thus, the identity of D9Rtil as a Mod-1-related locus rather than Mod-1 itself is in question. The method was also applied to an interspecific backcross panel between an inbred strain of Mus musculus molossinus (MSM/Ms) and C57BL/6J to map Mod-1 with respect to surrounding microsatellite loci, defining the proximal localization of Mod-1 with respect to D9Mit10 with a genetic distance of 0.6 +/- 0.6 cM.

A malic enzyme probe detects cross-hybridizing sequences closely linked to loci encoding other metabolic enzymes

The cytoplasmic malic enzyme (Mod-1) catalyzes the oxidative decarboxylation of malate: malate + NADP+----pyruvate + CO2 + NADPH + H+. Using a cDNA clone of Mod-1 as a probe, two new DNA markers not at the Mod-1 locus (restriction fragment length polymorphisms, RFLP) were detected by Southern blot analysis that showed extensive homology to Mod-1 sequences. Linkage of each restriction fragment length polymorphism to loci other than Mod-1 was assessed using the BXD (C57BL/6J x DBA/2J) recombinant inbred strains and confirmed by backcrosses. One polymorphic site, designated D9Rti1, was found to be closely linked to the phosphoglucomutase (Pgm-3) locus on Chromosome 9. The other hybridization site, designated D1Rti2, was closely linked to the isocitrate dehydrogenase (Idh-1) locus on Chromosome 1. The data presented imply that Mod-1 homologous sequences are tightly linked to three different metabolic enzymes.

The AXB and BXA set of recombinant inbred mouse strains

The recombinant inbred (RI) set of strains, AXB and BXA, derived from C57BL/6J and A/J, originally constructed and maintained at the University of California/San Diego, have been imported into The Jackson Laboratory and are now in the 29th to 59th generation of brother-sister matings. Genetic quality control testing with 45 proviral and 11 biochemical markers previously typed in this RI set indicated that five strains had been genetically contaminated sometime in the past, so these strains have been discarded. The correct and complete strain distribution patterns for 56 genetic markers are reported for the remaining RI strain set, which consists of 31 living strains and 8 extinct strains for which DNA is available. Two additional strains, AXB 12 and BXA 17, are living and may be added to the set pending further tests of genetic purity. The progenitors of this RI set differ in susceptibility to 27 infectious diseases as well as atherosclerosis, obesity, diabetes, cancer, cleft palate, and hydrocephalus. Thus, the AXB and BXA set of RI strains will be useful in the genetic analysis of several complex diseases.

The recombinant congenic strains--a novel genetic tool applied to the study of colon tumor development in the mouse

The development of tumors in mice is under multigenic control, but, in spite of considerable efforts, the identification of the genes involved has so far been unsuccessful, because of the insufficient resolution power of the available genetic tools. Therefore, a novel genetic tool, the RC (Recombinant Congenic) strains system, was designed. In this system, a series of RC strains is produced from two inbred strains, a "background" strain and a "donor" strain. Each RC strain contains a different small subset of genes from the donor strain and the majority of genes from the background strain. As a consequence, the individual genes of the donor strain which are involved in the genetic control of a multigenic trait, become separated into different RC strains, where they can be identified and studied individually. One of the RC strains series which we produced is made from the parental strains BALB/cHeA (background strain) and STS/A (donor strain). We describe the genetic composition of this BALB/cHeA-C-STS/A (CcS/Dem) series and show, using 45 genetic autosomal markers, that it does not deviate from the theoretical expectation. We studied the usefulness of the CcS/Dem RC strains for analysis of the genetics of colon tumor development. The two parental strains, BALB/cHeA and STS/A, are relatively resistant and highly susceptible, respectively, to the induction of colon tumors by 1,2-dimethylhydrazine (DMH). The individual RC strains differ widely in colon tumor development after DMH treatment; some are highly susceptible, while others are very resistant. This indicates that a limited number of genes with a major effect are responsible for the high susceptibility of the STS strain. Consequently, these genes can be mapped by further analysis of the susceptible RC strains. The differences between the RC strains were not limited to the number of tumors, but the RC strains differed also in size of the tumors and the relative susceptibility of the two sexes. Our data indicate that the number of tumors and the size of tumors are not controlled by the same genes. The genetics of these different aspects of colon tumorigenesis can also be studied by the RC strains. The DMH-treated mice of the parental strains and the RC strains also developed anal tumors and haemangiomas in varying numbers. The strain distribution pattern (SDP) of susceptibility for each of the three types of tumors induced by DMH is different, indicating that development of these tumors is under control of different, largely non-overlapping, sets of genes.(ABSTRACT TRUNCATED AT 400 WORDS)

Chromosomal localization of the mouse genes coding for alpha 2, alpha 3, alpha 4 and beta 2 subunits of neuronal nicotinic acetylcholine receptor

The chromosomal localization of four neuronal nicotinic acetylcholine receptor subunit genes was performed by following the mendelian segregation of their corresponding alleles in backcrosses involving the mouse species Mus spretus and the laboratory strains C57BL/6 or BALB/c. A similar analysis previously performed with muscle nicotinic acetylcholine receptor subunits revealed that the genes coding for the alpha and beta subunits are respectively located on chromosome 2 and 11, whereas the gamma and delta subunit coding genes are linked and located on mouse chromosome 1. In this study, we show that the genes coding for the neuronal nicotinic acetylcholine receptor alpha 2, alpha 3 and beta 2 subunits are dispersed on three different mouse chromosomes, viz. 14, 9 and 3 respectively. Moreover, the alpha 4 subunit gene is located on chromosome 2 but is not genetically linked to the alpha 1 subunit gene.

Population and biochemical genetics of the human mitochondrial malic enzyme

The phenotypic variation of the mitochondrial malic enzyme (MEM) was examined in 121 brains and 46 heart tissue samples from the population of north-east England. There was no difference in gene frequency distribution between sexes and the two tissues. However, a significant variation has been observed in males compared with a Scottish study. The three common phenotypes of brain were partially purified on a DEAE Sephadex column. The kinetics, heat stability and dicumarol inhibition studies show no biochemical advantage for any of the phenotypes in human brain. The extensive polymorphism of MEM suggests a possible, yet unknown, selective factor for the spread of this polymorphism. With the existing evidence of regional and racial differences, the role of random genetic drift cannot be ruled out.

Murine mucopolysaccharidosis type VII. Characterization of a mouse with beta-glucuronidase deficiency

We have characterized a new mutant mouse that has virtually no beta-glucuronidase activity. This biochemical defect causes a murine lysosomal storage disease that has many interesting similarities to human mucopolysaccharidosis type VII (MPS VII; Sly syndrome; beta-glucuronidase deficiency). Genetic analysis showed that the mutation is inherited as an autosomal recessive that maps to the beta-glucuronidase gene complex, [Gus], on the distal end of chromosome 5. Although there is a greater than 200-fold reduction in the beta-glucuronidase mRNA concentration in mutant tissues, Southern blot analysis failed to detect any abnormalities in the structural gene, Gus-sb, or in 17 kb of 5' flanking and 4 kb of 3' flanking sequences. Surprisingly, a sensitive S1 nuclease assay indicated that the relative level of kidney gusmps mRNA responded normally to androgen induction by increasing approximately 11-fold. Analysis of this mutant mouse may offer valuable information on the pathogenesis of human MPS VII and provide a useful system in which to study bone marrow transplantation and gene transfer methods of therapy.

The reduction of aromatic alpha-keto acids by cytoplasmic malate dehydrogenase and lactate dehydrogenase

This study demonstrates that cytoplasmic malate dehydrogenase (MDH-s) catalyzes the reduction of aromatic alpha-keto acids in the presence of NADH, that the enzyme which has been described in the literature as aromatic alpha-keto acid reductase (KAR; EC 1.1.1.96) is identical to MDH-s, and that the reduction of aromatic alpha-keto acids is due predominantly to a previously unrecognized secondary activity of MDH-s and the remainder is due to the previously recognized activity of lactate dehydrogenase (LDH) toward aromatic keto-acids. MDH-s and KAR have the same molecular weight, subunit structure, and tissue distribution. Starch gel electrophoresis followed by histochemical staining using either p-hydroxy-phenylpyruvic acid (HPPA) or malate as the substrate shows that KAR activity comigrates with MDH-s in all species studied except some marine species. Inhibition with malate, the end product of the MDH reaction, substantially reduces or totally eliminates KAR activity. Genetically determined electrophoretic variants of MDH-s seen in the fresh water bony fish of the genus Xiphophorus and the amphibian Rana pipiens exhibited identical variation for KAR, and the two traits cosegregated in the offspring from one R. pipiens heterozygote studied. Both enzymes comigrate with no electrophoretic variation among several inbred strains of mice. Antisera raised against purified chicken MDH-s totally inhibited both MDH-s and KAR activity in chicken liver homogenates. There is no evidence to suggest that any protein besides MDH-s and LDH catalyzes this reaction with the possible exception of the situation in Xiphophorus, in which a third independent zone of HPPA reduction is observed. In most species the activity formerly described as KAR appears to be due to a previously unsuspected activity of MDH-s toward aromatic monocarboxylic alpha-keto acids. In all species examined the KAR activity is associated only with MDH-s; in tissue homogenates the mitochondrial form of MDH (MDH-m) is not detected after electrophoresis using HPPA as a substrate.

Biochemical genetic variants in mice selectively bred for sensitivity or resistance to ethanol-induced sedation

The distribution of biochemical genetic variants was examined among eight inbred strains of mice, which served as contributors to a heterogeneous stock of mice (HS), and in short-sleep (SS) and long-sleep (LS) mice, selectively bred from the HS stock for differential ethanol sensitivity. Fifteen loci for enzymes of alcohol and aldehyde metabolism, as well as 12 other biochemical loci, were investigated. Thirteen of these loci exhibited allelic variation between strains, of which six were separately fixed in the SS and LS mice. Comparisons of genetic similarity coefficients, based upon the distributions of allelic variants for the loci examined, with behavioural sensitivities (sleep-time) to an acute dose of ethanol for the inbred and selected strains of mice, indicated no correlations between these data. This suggests that this collective group of loci are not useful indicators of the genes selectively bred in the SS and LS strains, which are responsible for the differential sensitivities to acute doses of ethanol.

Aldehyde reductase isozymes in the mouse: evidence for two new loci and localization of Ahr-3 on chromosome 7

Evidence is presented for two new forms of mouse liver and kidney aldehyde reductase activity (designated AHR-3 and AHR-4) resolved using cellulose acetate electrophoresis zymogram techniques and stained by glyceraldehyde and NADPH as substrate and coenzyme, respectively. Activity variants were observed for those isozymes among inbred strains of mice and used in a genetic analyses to support a proposal for two new genetic loci (Ahr-3 and Ah-4) which control the activity phenotype for these isozymes. Segregation analysis indicated that these loci are separately localized on the mouse genome, with Ahr-3 positioned on the distal end of chromosome 7. Liver AHR-2 (or hexonate dehydrogenase) exhibited no detectable phenotypic variation among the 44 inbred strains of mice examined. The AHR-3 and AHR-4 isozymes were readily distinguished from AHR-1 [or aldehyde reductase A2, described previously by Duley and Holmes (Biochem. Genet. 20:1067, 1982)], hexonate dehydrogenase (AHR-2), and alcohol dehydrogenase A2 in terms of their differential substrate, coenzyme, and inhibitor specificities.

Linkage and polymorphism of a gene controlling lactate dehydrogenase in the rat

The amount of lactate dehydrogenase subunit A in rat serum is under the control of the lactate dehydrogenase regulatory gene Ldr-1, and it is determined by two alleles, Ldr-1a (high) and Ldr-1b (low). Sex and LDH-A level segregate independently, so the Ldr-1 gene is autosomal. The genes for albino, red eye, hemoglobin, and Ldr-1 are linked (linkage group I), and their order is Ldr-1-Hbb-r-c. Our data put Ldr-1 45 cM from Hbb, and Hbb is 7 cM from c. Data in the literature separate r and c by 0.3 cM.

Biochemical markers of three strains derived from Japanese wild mouse (Mus musculus molossinus)

Twenty-eight biochemical markers were examined in three strains (Mol-A, Mol-N and Mol-T) derived from the the Japanese wild mouse, Mus musculus molossinus, as well as five laboratory strains, Mus musculus musculus. The Mol strains showed specific alleles at as many as 12 loci. These findings emphasize that the Mol strains have significance in future genetic and developmental studies.

A null mutation at the mouse Phosphoglucomutase-1 locus and a new locus Pgm-3

A null mutation at the phosphoglucomutase locus (Pgm-1) was discovered by electrophoretic analysis of the inbred mouse strain C57BL/6J. The null allele (Pgm-1n) was shown to segregate as a Mendelian unit alternative to the Pgm-1a and Pgm-1b alleles. Mice expressing the Pgm-1n allele, either in the heterozygous or homozygous state, are viable, healthy, and fertile. The occurrence of the Pgm-1n mutant revealed a previously unreported genetic locus (Pgm-3) that controls the expression of a third phosphoglucomutase. Two electrophoretically expressed alleles of Pgm-3 (inherited without dominance) are found in the inbred mouse strains C57BL/6J and DBA/2J. Linkage observed between the Pgm-3 locus, the dilute locus (d) and the cytoplasmic malic enzyme locus (Mod-1) has allowed assignment of the Pgm-3 locus to chromosome 9. A striking tissue specific expression of Pgm-1 and Pgm-3 was observed. Products of the Pgm-3 locus were detected in kidney, testes, brain, and heart. In contrast, Pgm-1 controlled isozymes were present in kidney, spleen, ovaries, and erythrocytes.

Linkage of Pgm-3 in the house mouse and homologies of three phosphoglucomutase loci in mouse and man

The discovery of a third phosphoglucomutase locus (Pgm-3) in the house mouse is reported. Three alleles are recognized on the basis of differences in electrophoretic mobility and enzymatic activity. Pgm-3A (fast mobility and high activity) is present in inbred strain C57BL/10J and 24 other strains; Pgm-3b (slow mobility and high activity) is present in LP/Pas and six other strains; and Pgm-3c (no detectable activity in any tissue tested) is present in strain DBA/2J and 14 other strains. Seventy-four recombinant inbred strains derived from progenitors that differed at Pgm-3 were used to study genic linkage. Pgm-3 is on chromosome 9 and is linked to Sep-1, d, Mod-1, and Ltw-3. Gene order and recombination frequencies are estimated as d 3.8 +/- 1.8%. Pgm-3 2.3 +/- 1.2% Mod-1. Substrate specificities and cofactor requirements show that mouse Pgm-1 is homologous with human Pgm-2, mouse Pgm-2 with human Pgm-1, and mouse Pgm-3 with human Pgm-3.

Mouse mitochondrial superoxide dismutase locus is on chromosome 17

The hamster X mouse hybridoma cell line GCL28 carries only one copy of mouse chromosome 17 but expresses H-2 antigens controlled by the major histocompatibility complex of the mouse. The cell line and clones derived from it were subjected to treatment with H-2 specific antisera and complement and a series of H-2 antigen-negative clones was produced. Typing of the clones for the mouse enzyme glyoxalase 1, which is encoded by an H-2-linked gene, revealed that the loss of H-2 antigen expression was accompanied by the loss of chromosomes 17 in these clones. This suggestion was verified by karyotype analysis of selected clones. Typing of the clones and subclones for the mouse mitochondrial superoxide dismutase (SOD-2) indicated complete concordance between loss of chromosome 17 and loss of SOD-2 activity. This finding suggests that the locus controlling the expression of SOD-2 is located on chromosome 17. Since a similar locus in the human is linked to HLA, the human major histocompatibility complex, extensive homology must exist between the mouse and human MHC-bearing chromosomes.

Analysis of malate dehydrogenase isozymes from anuran amphibian ovary by isoelectric focusing

The isozymes patterns of ovarian malate dehydrogenase (MDH) from various anuran amphibian series were analyzed by isoelectric focusing (IEF). Extensive variability was observed in both the soluble (sMDH) and mitochondrial (mMDH) patterns with as few as two and as many nine bands being visualized in different species. The mean pIs for sMDH ranged from 4.5 to 8.3 and those for mMDH fell between 5.1 and 8.2. The sMDHs are considerably more heat labile in Rana species living in northern latitudes compared to those from southern states. Inhibition with p-chlormercuribenzoate (PCMB) revealed the importance of sulfhydryl groups for the activity of sMDHs, while the functional requirement for these groups in mMDHs appears to be of lesser importance. Observations from these studies lend support to the accumulating evidence that Rana pipiens from such southern locations as New Mexico may have undergone speciation.

Identification and biochemical analysis of mouse mutants deficient in cytoplasmic malic enzyme

During the biochemical screening of mutant enzymes in mice, individuals with an apparent nonfunctional allele at the locus (Mod-l) responsible for cytoplasmic malic enzyme were identified by starch gel electrophoresis and by enzyme activity measurements. A series of matings and genetic analyses were made, and mice homozygous for the nonfunctional or null allele (Mod-ln) were produced. The mutation appeared to occur spontaneously in the C57BL/6J strain. By double-immunodiffusion and enzyme immunoinactivation assays, the null mutants were shown to express no proteins that cross-react with the antiserum to cytoplasmic malic enzyme (CRM-negative). In liver homogenates of homozygous null mutants, lack of protein components that form complexes with IgG from the cytoplasmic malic enzyme specific antiserum was further demonstrated by passage of the original serum through a mutant liver homogenate--Sepharose column, where the postadsorbed serum retained its titer and specificity. The residual malic enzyme activity (< 10% of the normal) observed in various tissue homogenates of the homozygous null mutants was attributed to that of mitochondrial isozyme of malic enzyme. Assays of enzymes from tissues of different genotypes revealed no significant differences in activities of six other enzymes in the related metabolic pathways. However, in liver from mutant mice, a lower NADPH/NADP+ ratio was consistently observed in comparison to that from control mice. Both the mutant and the control mice of the same age were found to have comparable body weight and lipid content.

A cis-active regulatory gene in the mouse: direct demonstration of cis-active control of the rate of enzyme subunit synthesis

Mouse mitochondrial malic enzyme [L-malate:NADP+ oxidoreductase (oxaloacetate-decarboxylating), EC 1.1.1.40] is a tetrameric protein. Two alleles of the structural gene (Mod-2) are known which code for electrophoretically distinct enzyme subunits: Mod-2a and Mod-2b. A regulatory gene (Mdr-1), closely linked to Mod-2 on chromosome 7, determines the rate of mitochondrial malic enzyme synthesis in brain. Two alleles of Mdr-1 are known: Mdr-1a (high activity) and Mdr-1b (low activitiy). By pulse-labeling with [35S]methionine, immune precipitation, and isoelectric focusing under dissociating conditions, we have measured the relative rates of synthesis of the two types of enzyme subunit in animals of genotypes Mdr-1a Mod-2a/Mdr-1a Mod-2b and Mdr-1S Mod-2a/Mdr-1b Mod-2b. The results show that in the former animals both types of subunit are made at an identical rate, whereas in the latter animals the Mod-2a gene product is synthesized at a rate 2.2 times that of the Mod-2b-coded subunit. Thus we have unambiguously demonstrated that Mdr-1 is cis-active in its control of the expression of the Mod-2 structural gene.

Enzyme polymorphism in a population of Calomys musculinus (Rodentia, Cricetidae)

NAD-linked lactate malate, glycerophosphate, alcohol and nonspecific dehydrogenases, aspartate aminotransferases, and soluble esterases from extracts of tissues of individuals from a wild population of Calomys musculinus (Rodentia, Cricetidae) have been analyzed by means of starch gel electrophoresis and specific staining. Allelic frequencies and heterozygosity have been determined. Mendelian inheritance of some of the variants detected was confirmed by breeding experiments. Ten out of fifteen (66.6%) of the genetic loci investigated presented polymorphism. Mean heterozygosity per locus was very high (H = 0.2014, SE 0.046).

A serum protein polymorphism determinant on chromosome 9 of Mus musculus

Genetic polymorphism for a previously undescribed serum protein has been found among inbred strains of Mus musculus. The new serum protein locus, gene symbol Sep-1, has been located on Chromosome 9, gene order Lap-1--Sep-1--Mpi-1--d--Mod-1, by utilizing information obtained from 52 recombinant inbred strains together with standard genetic backcrosses. The strain distribution pattern for this locus, supernatant malic enzyme, and transferrin also on Chromosome 9, are given for 67 inbred strains. Because the genotype of SEP-1 can be determined for individual mice without killing them, Sep-1 is a very useful gene in linkage studies and experimental biology.

Enzyme changes associated with mitoichondrial malic enzyme deficiency in mice

A genetically determined absence of mitochondrial malic enzyme (EC 1.1.1.40) in c3H/c6H mice is accompanied by a four-fold increase in liver glucose-6-phosphate dehydrogenase and a two-fold increase for 6-phosphogluconate dehydrogenase activity. Smaller increases in the activity of serine dehydratase and glutamic oxaloacetic transaminase are observed while the level of glutamic pyruvate transaminase activity is reduced in the liver of deficient mice. Unexpectedly, the level of activity of total malic enzyme in the livers of mitochondrial malic enzyme-deficient mice is increased approximately 50% compared to littermate controls. No similar increase in soluble malic enzyme activity is observed in heart of kidney tissue of mutant mice and the levels of total malic enzyme in these tissues are in accord with expected levels of activity in mitochondrial malic enzyme-deficient mice. The divergence in levels of enzyme activity between mutant and wild-type mice begins at 19--21 days of age. Immunoinactivation experiments with monospecific antisera to the soluble malic enzyme and glucose-6-phosphate dehydrogenase demonstrate that the activity increases represent increases in the amount of enzyme protein. The alterations are not consistent with a single hormonal response.

Genetic and cytogenetic studies of the malate dehydrogenases of Drosophila melanogaster

Genetic and cytogenetic locations of the structural genes for the NAD-dependent malate dehydrogenases have been studied. The mitochondrial form (mMDH) is coded for by a gene (mMdh) found at 62.6 on the third chromosome and included in Df(3R)R14, which includes 90C2-91A3 in the salivary gland chromosomes. Based on its inclusion within several J (Jammed; 2-41.0) deficiencies, the structural gene (cMdh) for the cytoplasmic form (cMDH) was determined to lie in region 31B-E, confirming the earlier finding of Grell. Flies lacking any cMDH activity (cMdhn-gamma 10069/Df(2L)J-der-27) were both viable and fertile.

Genetic variation, inheritance, and quaternary structure of malic enzyme in brook trout (Salvelinus fontinalis)

Electrophoretic variation is described for malic enzyme (ME) for the first time in brook trout (Salvelinus fontinalis). Since the quaternary structure of ME was not clear from examination of banding patterns in brook trout alone, ME phenotypes in rainbow trout (Salmo gairdneri)X brook trout hybrids as wel as in esocid species demonstrated that ME is tetrameric. A model of two duplicated loci is proposed to account for the observed variation. One locus (ME-2) is fixed and one locus (ME-1) is variable with three electrophoretically distinct alleles; the protein products of ME-1 are reduced in activity relative to the protein products of ME-2. Joint segregation was examined between ME-1, ME-2, and nine other biochemical loci in a splake--lake trout (Salvelinus namaycush) X brook trout hybrid--backcross. All pairwise examinations showed random assortment except ME-2 with an isocitrate dehydrogenase locus (IDH-3), which showed complete linkage in the splake backcross. This may be due to a chromosomal aberration.

Mitochondrial malic enzyme in mosaic skeletal muscle of mouse chimeras

The question was investigated whether mitochondria in the mammalian skeletal muscle fiber syncytium incorporate gene products encoded by one or many nuclei. Mouse chimeras were produced from strains which differ in their electrophoretic variants of the nuclear-coded mitochondrial protein, malic enzyme (MOD-2, E.C. 1.1.1.40, L-malate NADP+ oxidoreductase decarboxylating). The MOD-2 phenotypes of skeletal muscles of these chimeras were characterized in a starch gel electrophoretic system. The results indicate that individual mitochondria can contain products encoded by multiple nuclei and therefore that, for skeletal muscle mitochondria, the cell is not subdivided into nuclear territories. Possible mechanisms of gene product distribution in skeletal muscle fibers are discussed.