Genetic Analysis of Liver Neuraminidase Isozymes in RATTUS NORVEGICUS: Independent Control of Neu-1 and Neu-2 Phenotypes

Two recently identified isozymes of neuraminidase in rat liver were examined for transmission patterns and linkage relationships, and for variation among inbred strains. The isozymes, designated neuraminidase-1 (NEU-1) and neuraminidase-2 (NEU-2), exhibited no electrophoretic mobility variants among the 22 inbred strains examined, but did possess striking interstrain variation in activity phenotypes on electrophoretic gels. The results of a backcross analysis involving the KGH and ACP strains revealed that NEU-1 and NEU-2 phenotypes are independently controlled, each by a single autosomal locus with additively acting alleles. The two loci are unlinked to one another, but the gene controlling NEU-1 is tightly linked to RT1, the rat major histocompatibility complex. This gene is almost certainly identical to Neu-1, a gene identified previously through its effect on "total" activity levels of liver neuraminidase as determined by fluorometric assay of tissue homogenates. NEU-2 and the gene controlling its phenotype were not detected by the fluorometric technique. We designate the genes controlling the NEU-1 and NEU-2 phenotypes as Neu-1 and Neu-2, respectively. Data from this and other studies place Neu-1 between Glo-1 and dw-3. The location of Neu-2 is unknown.     

Genetic variation in alkaline phosphatase of the house mouse (Mus musculus) with emphasis on a manganese-requiring isozyme

Genetic variation among inbred strains is described for electrophoretic migration of alkaline phosphatase from intestine, kidney, blood plasma, and three isozymes of liver. A manganese-requiring isozyme of liver and kidney unaffected by neuraminidase is described, and the locus controlling variation in this isozyme is designated Akp-1. Data from recombinant inbred strains place the locus on chromosome 1 at a distance of 3.6 +/- 2.9 cM from the M1s locus on the side distal to the centromere. Test-cross data show the following gene order and recombination percentages: Dip-1 19.0 +/- 3.8% Lp 7.4 +/- 2.2% Akp-1.     

Isoelectric focusing studies of aldehyde dehydrogenases from mouse tissues: variant phenotypes of liver, stomach and testis isozymes

Isoelectric focusing techniques (IEF) were used to examine the tissue distribution and genetic variability of aldehyde dehydrogenases (AHDs) from inbred strains of mice. Twelve zones of AHD activity were resolved which were differentially distributed between tissues. Liver extracts exhibited highest activity for most enzymes, with the exception of isozymes found in stomach (AHD-4) and testis (AHD-4 and AHD-6). Genetic variants for AHD-1 (liver mitochondrial isozyme) and AHD-4 (stomach isozyme) were examined from inbred strains and F1 hybrid animals. The results were consistent with dimeric subunit structures (designated as A2 and D2 isozymes respectively). IEF patterns for activity variants of testis-specific AHD-6 were identical, with 3-banded phenotypes being observed. pI values for the AHD forms as well as for aldehyde oxidase and xanthine oxidase isozymes, which stain in the absence of coenzyme, were reported.     

Lactate dehydrogenase isozymes in xenotropic virus producing mice

Lactate dehydrogenase (LDH; E.C. 1.1.1.27) isozymes were compared in three inbred strains of mice, and two strains of wild mice, as well as the F1 hybrids and other genetic crosses involving two of the inbred strains. The strains examined were NZB/B1NJ, 129/J and C57BL/6J, Mus musculus molossinus and M. musculus castaneus. Genetic crosses were made between the xenotropic virus-producing NZB and the non-virus producing 129/J mice. Tissue specificity of LDH in these strains was studied using homogenates of kidney, liver, spleen and thymus. Polymorphism of the enzyme was studied by agarose gel electrophoresis. Enzyme polymorphism in the tissues of NZB and 129/J has not been previously reported. The liver and spleen tissues of 129/J showed the absence of LDH-1 and LDH-2 isozymes. Thymic homogenates of NZB showed a lack of expression of LDH-1, LDH-2 and LDH-3 isozymes. The F1, F2 and the backcross progeny from genetic crosses involving NZB, and 129/J mice showed an isozyme pattern more similar to the non-virus-producing 129/J strain than the virus-producing NZB. Evidence of genetic regulation at the LDH-B subunit appears to be the reason for the differential expression of the isozymes in NZB and 129/J strains. The other inbred strain of mice, C57BL/6J, also showed a greater similarity to the 129/J strain than NZB. The two strains of wild mice were similar in their expression of LDH-isozymes between each other and to the 129/J strain, with respect to the liver and spleen tissues.     

Expression and catalysis of sex-specific cytochrome P450 isozymes in rat liver

Research interest in the study of cytochromes P450 has recently been shifting to the characterization of "constitutively" expressed isozymes from that of the inducible forms. Several "constitutive" cytochrome P450 isozymes have been purified from rat liver including five immunochemically related proteins designated cytochromes P450f, P450g, P450h, P450i, and P450k. These hemoproteins have been identified as distinct isozymes on the basis of spectral, electrophoretic, and catalytic properties and NH2-terminal sequence analysis. Purification and immunoquantitation studies have indicated that these isozymes are expressed in a developmental as well as sex-related manner, and are relatively refractory to induction by xenobiotics. Cytochromes P450h and P450g are male-specific proteins, cytochrome P450i is a female-specific isozyme, while cytochromes P450f and P450k are present in both male and female adult rats. In addition, the expression of cytochrome P450g was shown to segregate into two phenotypes in outbred rats. Genetic studies utilizing inbred strains have indicated that the gene responsible for inheritance of high levels of cytochrome P450g is autosomal. Although considerable progress has been made in understanding the role of gonadal hormones and growth hormone in the hepatic regulation of cytochromes P450g, P450h, and P450i in particular, the physiological significance of the "constitutive" isozymes in the liver remains largely unresolved.     

Genetics and ontogeny of aldehyde dehydrogenase isozymes in the mouse: Evidence for a locus controlling the inducibility of the liver microsomal isozyme

Variation in the inducibility of the liver microsomal isozyme of aldehyde dehydrogenase (designated AHD-Cy) by phenobarbital administration was observed among inbred strains and linkage testing stocks of Mus musculus. The phenotypes were inherited in a normal Mendelian fashion with two alleles showing codominance at a proposed regulatory locus (designated Ahd-3r). Strain variation was also observed for the induction of liver AHD-Cy by 17-β-oestradiol administration to ovarectimized female mice. Moreover, this enzyme was elevated in activity by the administration of high (nonphysiological) levels of progesterone. Development studies showed that the liver and kidney AHD-Cy isozyme exhibited low activities in late-stage fetal and neonatal mice and reached adult levels by approximately 6 weeks of age.     

Isozyme variations in acetaldehyde dehydrogenase (E.C.1.2.1.3) in human tissues

Summary NAD-dependent acetaldehyde dehydrogenase (ALDH) of human tissues was investigated by electrophoresis and enzyme assay. ALDH is located mainly in the liver and kidney. The isozymes consist of at least six different components. Five different phenotypes were found in a total of 68 human liver and kidney specimens. It is likely that three isozyme sets are concerned in determining ALDH types. The distribution of various phenotypes of ALDH isozyme sets is presented.     

The immunological properties of pyruvate kinase. II. The relationship of the human erythrocyte isozyme to the human liver isozymes.

We have examined the hypothesis that the human erythrocyte isozyme of pyruvate kinase (EC 2.7.1.40) is a hybrid of the two isozymes present in liver. Rabbit antiserum against purified human erythrocyte pyruvate kinase inactivates the erythrocyte isozyme and the major liver isozyme from human tissue but does not inactivate the minor liver isozyme. The electrophoretic mobilities of the erythrocyte and major liver isozymes are altered by anti-erythrocyte enzyme antibody while the mobility of the minor liver isozyme is unaffected. Gel diffusion analysis indicates cross-reactivity between the erythrocyte and major liver isozyme but no cross-reactivity with the minor liver isozyme. The hybrid hypothesis would predict cross-reactivity including changes in activity and mobility of all isozymes and we conclude, therefore that the hypothesis is incorrect.     

Intestinal leucine aminopeptidase and alkaline phosphatase: Genetic regulation and development in mice

Intestinal and serum leucine aminopeptidase (LAP) and alkaline phosphatase (AKP) were characterized by electrophoresis for eight inbred strains of laboratory mice. Intestinal LAP and AKP of adult mice were expressed concordantly within strains, as banded or diffuse, and concordantly for rate of migration within strains that had diffuse isozymes. All strains, except DD/S, had a single band of serum LAP and a single, diffuse zone of serum AKP. DD/S had a double band of serum LAP as well as isozymes of intestinal LAP and AKP unlike those of other strains. All strains displayed similar, neuraminidase-sensitive isozymes of intestinal LAP and of AKP prior to weaning, but after weaning there was marked sensitivity to neuraminidase only in DD/S. In interstrain crosses, banded/diffuse, migration rate, and neuraminidase sensitivity were inherited as independent autosomal traits, with indications of variable penetrance and genetic interaction. Support was provided by NIH Grant RR08117.     

Further studies on the genetic control of chicken plasma alkaline phosphatase isozyme.

The effects of neuraminidase treatment on the electrophoretic pattern of alkaline phosphatase (AP) isozymes and AP activity were investigated in chicken plasma. AP comprised three isozymes. The zymogram of an individual chicken plasma had two bands, either the faster (F) or the slower (S) moving band by isozyme types and the B band irrespective of isozyme types. Mobility of the S band and AP activity in chicken plasma were not affected by neuraminidase treatment. The treatment has a reduced migration rate of the F band equal to that of the S band and the B band of both types closer to the origin. The genetic control of these bands is discussed.     

Further studies on the genetic control of chicken plasma alkaline phosphatase isozyme

The effects of neuraminidase treatment on the electrophoretic pattern of alkaline phosphatase (AP) isozymes and AP activity were investigated in chicken plasma. AP comprised three isozymes. The zymogram of an individual chicken plasma had two bands, either the faster (F) or the slower (S) moving band by isozyme types and the B band irrespective of isozyme types. Mobility of the S band and AP activity in chicken plasma were not affected by neuraminidase treatment. The treatment has a reduced migration rate of the F band equal to that of the S band and the B band of both types closer to the origin. The genetic control of these bands is discussed.     

Separation and quantification of serum alkaline phosphatase isozymes in the rat by affinity electrophoresis

The purpose of this study was to examine the possibility of separation and quantification of serum alkaline phosphatase (ALP) isozymes in rats by wheatgerm lectin affinity electrophoresis. Cellulose acetate electrophoresis of the liver and bone ALPs without lectin results in overlapping bands, but in the presence of lectin, the mobility of the band of bone enzyme was retarded and well separated from the liver enzyme band. With this affinity electrophoretic method, we determined the serum ALP isozymes in fed and fasting rats grouped by age. As a result, the absolute activity of bone isozyme showed a downward trend with age in the fed and fasting rats. The serum ALP activity was steadily higher in fed rats than in fasting rats, and the increase was due to intestinal ALP isozyme. There was low activity bordering complete absence in liver isozyme under both nutritional conditions. The affinity electrophoretic method provided a rapid, reproducible, and relatively simple technique for further clinical characterization of ALP isozyme in the rat serum.     

Rat liver phosphofructokinase isozymes

The labile phosphofructokinase activity of rat liver was found to be stabilized and efficiently extracted in 50 mm Tris-HCl, pH 8.0, 50 mm NaF, 10 mm dithiothreitol, and 1.0 mm ATP. By the method of DEAE-cellulose chromatography liver phosphofructokinase activity could be resolved into two isozymes. The major isozyme which was 85% of the total isolated activity was purified to homogeneity. This 15,000-fold purified isozyme had a specific activity of about 90 IU/mg protein with 25–30% recovery of the total activity. Sodium dodecyl sulfate-polyacrylamide disc gel electrophoresis of the sodium dodecyl sulfate-treated isozyme indicated a subunit molecular weight of 65,000. Antiserum to the major isozyme was obtained from rabbits, and immunotitration of the two isozymes indicated that they were immunologically different. Kinetic properties of the two isozymes indicated that the major isozyme was more susceptible to ATP and citrate inhibition as well as relief of ATP and citrate inhibition by fructose-6-P, AMP, and ammonia. With the use of DEAE-cellulose chromatography and antiserum titration of 100,000g supernatant fluids, it was shown that the two hepatic isozymes were always found together in adult, embryonic, and neoplastic liver and in kidney.     

Murine liver arylsulfatase B processing influenced by region on chromosome 17

SM/J liver arylsulfatase B has a more rapid electrophoretic mobility and occurs as a series of more acidic isozymes following electrofocusing in narrow pH gradients than the liver enzyme from C57BL/6J mice. The SM/J and C57BL/6J electrofocusing patterns were both converted to a single isozyme with similar isoelectric points by pretreatment with neuraminidase, suggesting that the SM/J and C57BL/6J isozymes differed with respect to their sialic acid content. Arylsulfatase B electrofocusing and thermostability phenotypes segregated independently among progeny of SM/J×C57BL/6J crosses, suggesting that the electrofocusing phenotypes were not determined by different alleles at As-1, the putative structural locus for arylsulfatase B. Comparison of the joint segregation of hepatic acid phosphatase electrophoretic patterns and liver arylsulfatase B electrofocusing profiles revealed that the electrofocusing profiles may be determined by a region on chromosome 17 near or identical to Apl. Kidney, brain, and spleen arylsulfatase B electrofocusing patterns did not appear to differ between SM/J and C57BL/6J mice.This research was supported in part by Biomedical Sciences Research Support Grant RR-07030, by NIGMS Grant 1-RO1GM27707-01, and by Grant 1–570 from the National Foundation/March of Dimes.     

Coexpression of distinct eye- and liver-specific LDH isozymes in cichlid fish

In a recent electrophoretic survey of lactate dehydrogenase (LDH) in neotropical cichlid fishes (Perciformes, Cichlidae) we have discovered several species in which a cathodal liver-specific isozyme is expressed along with the highly-anodal eye-specific isozyme (LDH-C4) typically encountered in perciform fishes. We believe this fourth, liver-specific LDH isozyme to be real and not artifactual since homogenization of fresh liver from one of these species, the Basketmouth cichlid (Acaronia nassa), in either of two nondenaturing detergents or in the presence of the protease inhibitor phenylmethylsulfonylfluoride affects neither the presence nor mobility of this cathodal band. Moreover, it continues to be expressed in the captively bred F1 of these same wild fish. The discovery of several fish species, like the Basketmouth, in which biochemically distinct eye- and liver-specific LDH isozymes are coexpressed, is discussed in light of the currently accepted hypothesis that these two isozymes are encoded by a single locus (LDH-C) which has undergone divergent tissue expression in several other major teleost groups. Preliminary characterization of the liver-specific isozyme relative to the eye-specific LDH-C4 in the Basketmouth cichlid with respect to thermolability and NADH-induced binding to oxamate-sepharose columns suggests that the eye- and liver-specific LDH isozymes are biochemically quite distinct in this fish and that they are probably encoded by two distinct loci.     

同工酶差异位点分析在蔬菜杂交种纯度检测中的应用

用１０种同工酶和蛋白质和分析体系,分析了７种重要蔬菜的７１个杂交种与其亲本之间的差异位点以及这些差异位点用于杂交种纯度检测的可能性和存在的问题。试验表明,作物的不同种类,杂交种与亲本之间的亲缘关系以及作物种类的遗传多态性,都会影响同工酶差异位点产生的多寡,从而影响到这一技术是否能用于此种作物的纯度检测,分析了不同同工酶在不同蔬菜中的多态性以及在蔬菜种子纯度检测中的表现。     

Genetics and ontogeny of aldehyde dehydrogenase isozymes in the mouse: Localization of Ahd-1 encoding the mitochondrial isozyme on chromosome 4

Electrophoretic variants for the mitochondrial isozyme of aldehyde dehydrogenase (AHD) have been observed in inbred strains and in Harwell linkage testing stocks of Mus musculus. F₁ (LVC×C57BL/Go) mice showed a codominant allele three-banded phenotype, which suggests a dimeric subunit structure (designated AHD-A₂). The anodal-migrating supernatant isozyme of AHD was electrophoretically invariant among the 23 inbred strains and stocks examined. The genetic locus encoding AHD-A₂ (suggested name Ahd-1) is localized on chromosome 4 and was mapped close to je (jerker) and Gpd-1 (encoding the liver and kidney isozyme of glucose-6-phosphate dehydrogenase). Ontogenetic analyses demonstrated that both AHD isozymes exhibited low activity in late fetal and early neonatal liver and kidney extracts, and reached adult levels within 3 weeks of birth.     

Purification and properties of neuraminidase isozymes in Arthrobacter ureafaciens mutant

An Arthrobacter ureafaciens mutant (M1057) capable of producing neuraminidase constitutively was isolated by NTG mutagenesis from A. ureafaciens KMS 3663. Four molecular species (L, M1, M2, and S) of neuraminidase isozymes were homogeneously purified from the mutant and parent strains by means of DEAE-cellulose, affinity chromatography, ammonium sulfate precipitation, chromatofocusing, and Ultrogel AcA44 gel filtration. The molecular weights of L, M1, M2, and S isozymes were shown to be approximately 88,000, 66,000, 66,000, and 52,000, respectively. The optimal pHs and Km values of these isozymes for N-acetylneuraminosyl-alpha,(2-6)-lactose were 4.5-5.5 and 0.6-0.8 mM. Neuraminidase L, M1, M2, and S were able to hydrolyze oligosaccharides, glycoproteins and gangliosides containing alpha,(2-3)-, alpha,(2-6)-, and alpha,(2-8)-linked N-acetylneuraminic acid. Among these isozymes isolated, isozyme S was most active on colominic acid.     

Distribution of AMP-deaminase isozymes in rat tissues

1. The distribution of AMP deaminase isozymes in rat tissues was analyzed by electrophoresis on cellulose acetate membrane, by chromatography on phosphocellulose column, and by the application of immunological technique employing specific antisera against three parental AMP deaminases (isozymes A, B and C). Skeletal muscle extracts and diaphragm extracts contain a single identical isozyme, isozyme A. The major isozyme species of liver, kidney and testes are also identical and they are isozyme B. Heart extracts contains isozyme C exclusively. Extracts of brain, lung and spleen contain five isozymes, presumably a complete set of five B-C hybrids. 2. Developmental patterns of AMP deaminase isozyme were studied. In early postnatal life, extracts of heart, liver, kidney and lung contain five isozymes similar to those observed in adult brain. During postnatal development, a shift to isozyme C occurs in heart, whereas a shift to isozyme B occurs in liver and kidney. Five isozymes in lung remain throughout development. In brain a shift of B to five isozymes is observed during development. Isozyme A is the predominant form in muscle throughout postnatal development. 3. AMP deaminase in the regenerating liver was analyzed, but the data indicated that there was no change of isozyme distribution during hepatic regeneration.     

Identification of inducible calmodulin-dependent nitric oxide synthase in the liver of rats.

A calmodulin-dependent nitric oxide synthase was significantly induced in the liver of rats treated intravenously with heat-killed Propionibacterium acnes and 5 days later with Escherichia coli lipopolysaccharide. The apparent calmodulin-dependent and -independent isozymes were separated by Mono Q column chromatography after their partial purification by 2',5'-ADP-agarose affinity chromatography. Both enzymes had a molecular weight of 125,000 as determined by SDS-polyacrylamide gel electrophoresis and required NADPH, tetrahydrobiopterin, and dithiothreitol as cofactors. Their activities were completely inhibited by the specific nitric oxide synthase inhibitors NG-monomethyl-L-arginine and N omega-nitro-L-arginine at 80 and 800 microM, respectively. The peptide maps of these two isozymes with lysylendopeptidase and their reverse-phase column chromatographic profiles were indistinguishable. In the presence of bovine calmodulin, the purified calmodulin-dependent isozyme behaved as a calmodulin-independent isozyme on Mono Q column chromatography. The purified calmodulin-independent isozyme was converted to a calmodulin-dependent isozyme by EDTA and EGTA. Calmodulin blot analysis using 125I-calmodulin showed that the two isozymes bound calmodulin equally efficiently.