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.     

Molecular analysis of genetic differences among inbred mouse strains controlling tissue expression pattern of alcohol dehydrogenase 4

The ADH gene family in vertebrates is composed of at least seven distinct classes based upon sequence comparisons and enzyme properties. The Adh4 gene product may play an important role in differentiation and development because of its capacity to metabolize retinol to retinoic acid. Allelic gene differences exist among inbred mouse strains which control structure and tissue-specific regulation of Adh4. C57BL/6 mice are unique and have no detectable ADH4 enzyme activity in epididymis and low levels in seminal vesicle, ovary and uterus compared to other strains. C57BL/6 mice express Adh4 in stomach at levels similar to other strains. The goal of this research was to investigate this genetic variation at the molecular level. Northern analysis revealed that the content of ADH4 mRNA in tissues correlate with the enzyme expression pattern. Interestingly, C57BL/6 mice express an ADH4 mRNA in stomach which is smaller than expressed in C3H and other mice. An analysis of the 5'- and 3'-ends of the mRNA using RACE analysis determined that the ADH4 mRNA in C57BL/6 mice is truncated in the 3'-untranslated region. Sequence analysis of RACE products showed that the truncation is due to a single nucleotide mutation which produces an early polyadenylation signal. Additional RACE and Northern analysis revealed that at least five different polyadenylation sites are used in the Adh4 gene. Using 3'-end polymorphisms found between C57BL/6 and C3H strains and RT-PCR, it was shown that the lack of expression in epididymis in C57BL/6 mice is cis-acting in F(1) hybrid animals. The DNA sequence of the proximal promoter (-600/+42 nt) was determined in several mouse strains differing in tissue-specific expression patterns and did not reveal any nucleotide substitutions correlating with expression pattern suggesting further upstream or downstream sequences may be involved.     

Regulatory elements involved in Drosophila Adh gene expression are conserved in divergent species and separate elements mediate expression in different tissues.

Alcohol dehydrogenase (ADH) is expressed in a complex temporal and spatial pattern from tandem promoters (proximal and distal) in Drosophila melanogaster, and from two closely linked genes (Adh-1 and Adh-2) in D. mulleri. The expression patterns of Adh-1 and the proximal promoter, and Adh-2 and the distal promoter are similar, but not identical. We show that the mulleri Adh genes are appropriately expressed when introduced into the melanogaster genome, indicating that the cis- and trans-acting elements which regulate the corresponding promoters are functionally equivalent in the two species. By analyzing the expression of in vitro generated mutants of the mulleri Adh locus, we define at least three regulatory regions of the mulleri Adh genes and show that different control elements mediate the expression of Adh in different tissues.     

Correct developmental expression of a cloned alcohol dehydrogenase gene transduced into the Drosophila germ line

We have used P-element-mediated transformation to introduce a cloned Drosophila alcohol dehydrogenase (Adh) gene into the germ line of ADH null flies. Six independent transformants expressing ADH were identified by their acquired resistance to ethanol. Each transformant carries a single copy of the cloned Adh gene in a different chromosomal location. Four of the six transformant lines exhibit normal Adh expression by the following criteria: quantitative levels of ADH enzyme activity in larvae and adults; qualitative tissue specificity; the size of stable Adh mRNA; and the characteristic developmental switch in utilization of two different Adh promoters. The remaining two transformants express ADH enzyme activity with the correct tissue specificity, but at a lower level than wild type. These results demonstrate that an 11.8 kb chromosomal fragment containing the Adh gene includes the cis-acting sequences necessary for its correct developmental expression, and that a variety of chromosomal sites permit proper Adh gene function.     

Selective recruitment of <Emphasis Type="Italic">Adh</Emphasis> genes for distinct enzymatic functions in <Emphasis Type="Italic">Petunia hybrida</Emphasis>

Alcohol dehydrogenase (ADH) activity in plants is generally associated with glycolytic fermentation, which facilitates cell survival during episodes of low-oxygen stress in water-logged roots as well as chronically hypoxic regions surrounding the vascular core. Work with tobacco and potato has implicated ADH activity in additional metabolic roles, including aerobic fermentation, acetaldehyde detoxification and carbon reutilization. Here a combination of approaches has been used to examine tissue-specific patterns of Adh gene expression in order to provide insight into the potential roles of alcohol dehydrogenases, using Petunia hybrida, a solanaceous species with well-characterized genetics. A reporter-gene study, relying on the promoters of Adh1 and Adh2 to drive expression of the gene for a green fluorescent protein derivative, mgfp5, revealed unexpectedly complex patterns of GFP fluorescence in floral tissues, particularly the stigma, style and nectary. Results of GC-MS analysis suggest the association of ADH with production of aromatic compounds in the nectary. Overall the results demonstrate selective recruitment of Adh gene family members in tissues and organs associated with diverse ADH functions.     

High and complementary expression patterns of alcohol and aldehyde dehydrogenases in the gastrointestinal tract: implications for Parkinson's disease

Parkinson's disease (PD) is a heterogeneous movement disorder characterized by progressive degeneration of dopamine neurons in substantia nigra. We have previously presented genetic evidence for the possible involvement of alcohol and aldehyde dehydrogenases (ADH; ALDH) by identifying genetic variants in ADH1C and ADH4 that associate with PD. The absence of the corresponding mRNA species in the brain led us to the hypothesis that one cause of PD could be defects in the defense systems against toxic aldehydes in the gastrointestinal tract. We investigated cellular expression of Adh1, Adh3, Adh4 and Aldh1 mRNA along the rodent GI tract. Using oligonucleotide in situ hybridization probes, we were able to resolve the specific distribution patterns of closely related members of the ADH family. In both mice and rats, Adh4 is transcribed in the epithelium of tongue, esophagus and stomach, whereas Adh1 was active from stomach to rectum in mice, and in duodenum, colon and rectum in rats. Adh1 and Adh4 mRNAs were present in the mouse gastric mucosa in nonoverlapping patterns, with Adh1 in the gastric glands and Adh4 in the gastric pits. Aldh1 was found in epithelial cells from tongue to jejunum in rats and from esophagus to colon in mice. Adh3 hybridization revealed low mRNA levels in all tissues investigated. The distribution and known physiological functions of the investigated ADHs and Aldh1 are compatible with a role in a defense system, protecting against alcohols, aldehydes and formaldehydes as well as being involved in retinoid metabolism.     

Molecular differences in Adh1-F and Adh1-S alleles in the sugar beet Beta vulgaris L

We compared nucleotide sequences of exon 4 and part of exon 5 of alleles F and S of the Adh1 locus controlling alcohol dehydrogenase in sugar beet. The Adh1-F and Adh1-S sequences of the examined fragment were shown to differ by two nucleotides. Adenine (A) and cytosine (C) of Adh1-F were substituted by respectively thymine (T) and adenine (A) in Adh1-S. Consequently, glutamine and asparagine from the F subunit of ADH1 are replaced by valine and lysine, respectively. Because of differences in the amino acid content, the F subunit is by two elementary charges more negatively charged electrically than the S subunit, which correlates with differences in their electrophoretic mobility. Comparison of the examined Adh1 fragment of sugar beet with its counterparts in other plants showed that the sites bearing substitutions in the former species are classed as variable.     

Redundant cis-acting elements control expression of the Drosophila affinidisjuncta Adh gene in the larval fat body.

The alcohol dehydrogenase (Adh) gene in the Hawaiian species of fruit fly, Drosophila affinidisjuncta, like the Adh genes from all Drosophila species analyzed, is expressed at high levels in the larval fat body via a larval-specific promoter. To identify the cis-acting elements involved in this highly conserved aspect of Adh gene expression, deleted D. affinidisjuncta genes were introduced into D. melanogaster by somatic transformation. Unlike previously described methods, this transformation system allows analysis of Adh gene expression specifically in the larval fat body. The arrangement of sequences influencing expression of the proximal promoter of this gene in the larval fat body differs markedly from that described for the Adh gene from the distant relative, D. melanogaster. Multiple redundant elements dispersed 5' and 3' to the gene, only some of which map to regions carrying evolutionarily conserved sequences, affect expression in the fat body. D. affinidisjuncta employs a novel mode of Adh gene regulation in which the proximal promoter is influenced by sequences having roles in expression of the distal promoter. This gene is also unique in that far upstream sequences can compensate for loss of sequences within 200 bp of the proximal RNA start site. Furthermore, expression is influenced in an unusual, context-dependent manner by a naturally-occurring 3' duplication of the proximal promoter--a feature found only in Hawaiian species.     

Species-specific differences in tissue-specific expression of alcohol dehydrogenase are under the control of complexcis-acting loci: Evidence fromDrosophila hybrids

Differences in the expression of alcohol dehydrogenase in the hindgut and testis of adult Drosophila virilis, D. texana, D. novamexicana and D. borealis flies were observed. These heritable differences do not arise due to chromosomal rearrangements, since the polytene chromosome banding patterns did not reveal any such gross chromosomal rearrangements near the Adh locus in any of the tested species. Analysis of the interspecific hybrids revealed that these differences are controlled by complex cis-acting genetic loci. Further, the cis-acting locus controlling the expression of ADH in testis was found to be separable by crossing-over.     

Introduction of single-stranded ADH genes into Drosophila results in tissue-specific expression

We injected single-stranded circular DNA containing a Drosophila Adh gene into ADH-negative embryos of Drosophila melanogaster and performed ADH histochemical staining on third instar larvae of the injected generation. Introduction of either the coding or non-coding strand resulted in correct tissue-specific expression of the Adh gene in larvae. Southern blotting revealed that the bulk of the injected DNA became double-stranded shortly after injection and was not integrated into the genome.