Developmental profile and tissue distribution of Drosophila alcohol dehydrogenase: an immunochemical analysis with monoclonal antibodies.

To analyze Drosophila alcohol dehydrogenase gene (Adh) expression and tissue distribution at various developmental stages, we devised several immunochemical techniques making use of monoclonal antibodies against Drosophila alcohol dehydrogenase (ADH), which had been obtained previously. We here report their application to analyze the expression of Adh in a wild-type strain of D. melanogaster. s-ELISA tests were performed to evaluate fluctuations in ADH content and specific activity during development in individual organs as well as in whole individuals. In all cases, ADH specific activity appeared to be quite constant, which implies that variations in enzyme activity reflect differences in protein content. Immunoblottings of crude homogenates revealed immunoreactive low relative molecular mass peptides in addition to the 27 KD monomeric band, showing a conserved banding pattern in different organs and developmental stages. Immunohistochemical assays on whole organs were used to analyze the general pattern of ADH distribution. Immunoperoxidase staining of cryosections proved to be of crucial relevance, as it yielded full details of the tissue localization of ADH within the ADH-positive organs. We have shown not only that ADH displays a specific distribution in some organs but also that the enzyme is restricted to certain cell types.     

Tissue-Specific Expression Phenotypes of Hawaiian Drosophila Adh Genes in Drosophila Melanogaster Transformants

Interspecific differences in the tissue-specific patterns of expression displayed by the alcohol dehydrogenase (Adh) genes within the Hawaiian picture-winged Drosophila represent a rich source of evolutionary variation in gene regulation. Study of the cis-acting elements responsible for regulatory differences between Adh genes from various species is greatly facilitated by analyzing the behavior of the different Adh genes in a homogeneous background. Accordingly, the Adh gene from Drosophila grimshawi was introduced into the germ line of Drosophila melanogaster by means of P element-mediated transformation, and transformants carrying this gene were compared to transformants carrying the Adh genes from Drosophila affinidisjuncta and Drosophila hawaiiensis. The results indicate that the D. affinidisjuncta and D. grimshawi genes have relatively higher levels of expression and broader tissue distribution of expression than the D. hawaiiensis gene in larvae. All three genes are expressed at similar overall levels in adults, with differences in tissue distribution of enzyme activity corresponding to the pattern in the donor species. However, certain systematic differences between Adh gene expression in transformants and in the Hawaiian Drosophila are noted along with tissue-specific position effects in some cases. The implications of these findings for the understanding of evolved regulatory variation are discussed.     

ADH enzyme activity and Adh gene expression in Drosophila melanogaster lines differentially selected for increased alcohol tolerance

In Drosophila melanogaster, alcohol dehydrogenase (ADH) activity is essential for ethanol tolerance, but its role may not be restricted to alcohol metabolism alone. Here we describe ADH activity and Adh expression level upon selection for increased alcohol tolerance in different life-stages of D. melanogaster lines with two distinct Adh genotypes: Adh(FF) and Adh(SS). We demonstrate a positive within genotype response for increased alcohol tolerance. Life-stage dependent selection was observed in larvae only. A slight constitutive increase in adult ADH activity for all selection regimes and genotypes was observed, that was not paralleled by Adh expression. Larval Adh expression showed a constitutive increase, that was not reflected in ADH activity. Upon exposure to environmental ethanol, sex, selection regime life stage and genotype appear to have differential effects. Increased ADH activity accompanies increased ethanol tolerance in D. melanogaster but this increase is not paralleled by expression of the Adh gene.     

Genetic determination of the developmental program for maize scutellar alcohol dehydrogenase: Involvement of a recessive,trans-acting,temporal-regulatory gene

The developmental program of alcohol dehydrogenase (ADH) activity in the scutellum of maize strain R6-67 is different from that of W64A. The level of scutellar ADH activity in R6-67 remains relatively high during the course of early sporophytic development as compared to the commonly observed pattern. In the typical inbred strain W64A, the activity of ADH declines substantially during that period. The variance values from the crosses between R6-67 and W64A reveal that the trait is under genetic control. Detailed genetic analysis suggests that a single gene is responsible for the altered developmental program of ADH activity in R6-67. This gene meets the criteria for temporal regulatory genes and is different from Adh2, the structural gene which codes the ADH-2 isozyme. We have designated this gene as Adr1 (alcohol dehydrogenase regulator, #1). Adr1 is unlinked to Adh2. There is no de novo synthesis of ADH in the scutellum during germination, and the difference in the activity level reflects the difference in the amount of enzyme protein as demonstrated by density labeling and rocket immunoelectrophoresis. Thus, it appears that Adr1 may regulate the degradation of ADH.     

点突变对高加索乳杆菌醇脱氢酶酶活的影响

从高加索乳杆菌基因组中克隆醇脱氢酶基因,构建重组表达菌后发现不同转化子具有不同的活性,测序结果表明在部分位点发生了点突变.结合生物信息学知识通过对醇脱氢酶结构与作用机理分析,认为在酶关键位点的变变对酶的活性影响较大,而非关键位点的突变对酶活的影响虽明显降低,但其突变的数目可能对酶活的影响呈现一定的累加效应.其中活性最高的重组菌表达了一个可将苯乙酮高选择对映还原成(S)-笨乙醇的醇脱氢酶,该研究结果为酶的定向进化研究提供了理论依据.     

Structure,expression, chromosomal location and product of the gene encoding ADH1 inPetunia

A genomic clone for an alcohol dehydrogenase (Adh) gene has been isolated fromPetunia hybrida cv. V30 by screening aPetunia genomic library with a maizeAdh1 probe. A combination of RFLP and allozyme segregation data failed to demonstrate which of twoAdh loci, both of which map to chromosome 4, was the source of the cloned gene. The product of the cloned genes has been identified unequivocally by a transient expression assay inPetunia protoplasts. We have designated this genePetunia Adh1. The expression of this gene is tightly regulated in the developing anther, where its gene product is the predominant ADH isozyme. It is anaerobically inducible in roots, stems and leaves of seedlings. The induction of enzyme activity is correlated with induction ofAdh1 mRNA.     

Translation initiation in Drosophila melanogaster is reduced by mutations upstream of the AUG initiator codon.

The importance to in vivo translation of sequences immediately upstream of the Drosophila alcohol dehydrogenase (Adh) start codon was examined at two developmental stages. Mutations were introduced into the Adh gene in vitro, and the mutant gene was inserted into the genome via germ line transformation. An A-to-T substitution at the -3 position did not affect relative translation rates of the ADH protein at the second-instar larval stage but resulted in a 2.4-fold drop in translation of ADH at the adult stage. A second mutant gene, containing five mutations in the region -1 to -9, was designed to completely block translation initiation. However, transformant lines bearing these mutations still exhibit detectable ADH, albeit at substantially reduced levels. The average fold reduction at the second-instar larval stage was 5.9, while at the adult stage a 12.5-fold reduction was observed.     

Molecular analysis of a somaclonal mutant of maize alcohol dehydrogenase

Summary Plants regenerated from tissue cultures of maize were screened for variants of ADH1 and ADH2. Root extracts of 645 primary regenerant plants were tested, and one stable mutant of Adh1 was detected. The mutant gene (Adh1-Usv) produces a functional enzyme with a slower electrophoretic mobility than that of the progenitor Adh1-S allele, and is stably transmitted to progeny. The mutant was not present among four other plants derived from the same immature embryo, and therefore arose as a consequence of the culture procedure. The gene of Adh1-Usv was cloned and sequenced. A single base change in exon 6 was the only alteration found in the gene sequence. This would translate in the polypeptide sequence to a valine residue substituting for a glutamic acid residue, resulting in the loss of a negative charge and the production of a protein with slower electrophoretic mobility.Abbreviations kb kilobase pairs - ADH alcohol dehydrogenase     

Mutant alleles that are altered in quantitative,organ-specific behavior

Three new mutant alleles of maize alcohol dehydrogenase-1 (Adh 1) were recovered following allyl alcohol selection of pollen. Each is altered in quantitative, organ-specific, regulatory properties. All mutant sites act in cis to the structural gene component. One mutant arose spontaneously, one followed indirectly from irradiation with high Z accelerated particles, and one was induced by an autonomous mutator system. Each mutant is assessed in three organs by utilizing ADH allozyme ratios that were quantified at the level of ADH enzyme activity and either [³H]-Leu incorporation into newly synthesized ADH 1 subunits or direct protein determinations. One mutation simultaneously raises Adh 1 expression in one organ and lowers it in another, another affects expression in one organ only, and another is extremely underexpressed in all organs but is unstable. This unstable allele has generated derivative mutant alleles that have less or zero ADH expression. We do not yet know whether or not coding sequences are involved in these mutants. We conclude that information for organ specificity and quantitative behavior resides near or within Adh 1 coding sequences.     

Deletion of a conserved regulatory element in the Drosophila Adh gene leads to increased alcohol dehydrogenase activity but also delays development

In vivo levels of enzymatic activity may be increased through either structural or regulatory changes. Here we use Drosophila melanogaster alcohol dehydrogenase (ADH) in an experimental test for selective differences between these two mechanisms. The well-known ADH-Slow (S)/Fast (F) amino acid replacement leads to a twofold increase in activity by increasing the catalytic efficiency of the enzyme. Disruption of a highly conserved, negative regulatory element in the Adh 3' UTR also leads to a twofold increase in activity, although this is achieved by increasing in vivo Adh mRNA and protein concentrations. These two changes appear to be under different types of selection, with positive selection favoring the amino acid replacement and purifying selection maintaining the 3' UTR sequence. Using transgenic experiments we show that deletion of the conserved 3' UTR element increases adult and larval Adh expression in both the ADH-F and ADH-S genetic backgrounds. However, the 3' UTR deletion also leads to a significant increase in developmental time in both backgrounds. ADH allozyme type has no detectable effect on development. These results demonstrate a negative fitness effect associated with Adh overexpression. This provides a mechanism whereby natural selection can discriminate between alternative pathways of increasing enzymatic activity.     

Biochemical properties and level of expression of alcohol dehydrogenases in the allotetraploid plant Tragopogon miscellus and its diploid progenitors

This study demonstrates that homoeologous genes in two diploid plant species that specify different amounts of an enzyme maintain the same relative level of expression in an allotetraploid derivative. The three predominant alcohol dehydrogenase (ADH) isozymes (DD, DP, PP) in seeds of the recently evolved allotetraploid plant Tragopogon miscellus (Compositae) are dimers specified by Adh3-D and Adh3-P genes derived from its diploid progenitors T. dubius and T. pratensis. Seeds of T. pratensis contain twice as much ADH activity as those of T. dubius, while T. miscellus is intermediate. The three isozymes were similar in a number of catalytic properties; the densitometric ratio of the isozymes purified from T. miscellus was 1 DD:4DP:4PP for both ADH activity and protein; and dissociation-reassociation of the DP enzyme gave a 1:2:1 ratio of the three isozymes. Therefore, the enzymes were similar in specific activity, but twice as many P as D subunits were present in active enzymes in T. miscellus, precisely the difference in activity between the parents. In T. miscellus, the specific activity of ADH and its activity per mg tissue are intermediate to those of the diploids, because relative expression of the Adh gene in each genome is not influenced by the presence of the other genome.     

Molecular analysis of alcohol dehydrogenase electromorphs in wild type and transformed Drosophila melanogaster

The protein expressed by the alcohol dehydrogenase locus (Adh) in D. melanogaster comprises a small group of electromorphs. We are able to study the expression of these electromorphs by electrophoretic separation and subsequent probing of blots of the separated polypeptides with antiserum for alcohol dehydrogenase (ADH). In the present study we have utilized this technique to study and compare the ADH electromorphs in wild type D. melanogaster with D. melanogaster transformants which carry an Adh gene from D. grimshawi, D. hawaiiensis or D. affinidisjuncta and produced functional ADH (10, 19). We have determined that polypeptides are produced by the donor loci in the transformed flies and further show that although the molecular weight of the expressed polypeptides is similar to D. melanogaster electromorphs, the isoelectric points are not similar. Thus this methodology offers the potential to study naturally occurring ADH electromorphs and null alleles independent of enzymatic activity assays.     

Alcohol dehydrogenase activities and ethanol tolerance in Anastrepha (Diptera, Tephritidae) fruit-fly species and their hybrids

The ADH (alcohol dehydrogenase) system is one of the earliest known models of molecular evolution, and is still the most studied in Drosophila. Herein, we studied this model in the genus Anastrepha (Diptera, Tephritidae). Due to the remarkable advantages it presents, it is possible to cross species with different Adh genotypes and with different phenotype traits related to ethanol tolerance. The two species studied here each have a different number of Adh gene copies, whereby crosses generate polymorphisms in gene number and in composition of the genetic background. We measured certain traits related to ethanol metabolism and tolerance. ADH specific enzyme activity presented gene by environment interactions, and the larval protein content showed an additive pattern of inheritance, whilst ADH enzyme activity per larva presented a complex behavior that may be explained by epistatic effects. Regression models suggest that there are heritable factors acting on ethanol tolerance, which may be related to enzymatic activity of the ADHs and to larval mass, although a pronounced environmental effect on ethanol tolerance was also observed. By using these data, we speculated on the mechanisms of ethanol tolerance and its inheritance as well as of associated traits.     

The ADH gene-enzyme system and the fitness of Drosophila melanogaster mutants]

Physico-chemical properties of ADH and some fitness parameters were examined in two mutant (cn and vg) and two wild-type (C-S and D) strains of Drosophila melanogaster. It was shown that, under the experimental conditions, longevity, fecundity and heat resistance did not depend on the activity and the electrophoretic mobility of enzymes. The Adh gene-enzyme system of the mutants was analyzed in relation to the saturation of their genotypes with genes of wild-type flies having different allelic control of the enzyme. ADH activity was shown to be positively correlated with the frequency of F allele of the structural gene (r = 0.84), whereas thermostability of the enzyme was not associated with electrophoretic mobility. Low thermostability of ADH in vg mutants, which was correlated with low heat resistance (r = 0.94), is assumed to be controlled by the thermostable allele Adh Fs.