Further studies on the alcohol dehydrogenases in barley: evidence for a third alcohol dehydrogenase locus and data on the effect of an alcohol dehydrogenase – 1 null mutation in homozygous and in heterozygous condition

Barley ADH-1 modulates susceptibility to Bgh and is involved in chitin-induced systemic resistance

The plant primary energy metabolism is profoundly reorganized under biotic stress conditions and there is increasing evidence for a role of the fermentative pathway in biotic interactions. Previously we showed via transient gene silencing or overexpression a function of barley alcohol dehydrogenase 1 (HvADH-1) in the interaction of barley with the parasitic fungus Blumeria graminis f.sp. hordei (Bgh). Here we extend our studies on stable transgenic barley events over- or under-expressing HvADH-1 to analyse ADH-1 functions at the level of whole plants. Knock-down (KD) of HvADH-1 by dsRNA interference resulted in reduced and overexpression of HvADH-1 in strongly increased HvADH-1 enzyme activity in leaves of stable transgenic barley plants. The KD of HvADH-1 coincided with a reduced susceptibility to Bgh of both excised leaves and leaves of intact plants. Overexpression (OE) of HvADH-1 results in increased susceptibility to Bgh when excised leaves but not when whole seedlings were inoculated. When first leaves of 10-day-old barley plants were treated with a chitin elicitor, we observed a reduced enzyme activity of ADH-1/-1 homodimers at 48 h after treatment in the second, systemic leaf for empty vector controls and HvADH-1 KD events, but not for the HvADH-1 OE events. Reduced ADH-1 activity in the systemic leaf of empty vector controls and HvADH-1 KD events coincided with chitin-induced resistance to Bgh. Taken together, stable HvADH-1 (KD) or systemic down-regulation of ADH-1/-1 activity by chitin treatment modulated the pathogen response of barley to the biotrophic fungal parasite Bgh and resulted in less successful infections by Bgh.

Infection of barley with the parasitic fungus Blumeria graminis f.sp. hordei results in the induction of HvADH1 and HvADH2

Besides the established functions of alcohol dehydrogenase (ADH) in the flooding response and in seed and pollen metabolism there is increasing evidence for a role of the fermentative pathway in biotic interactions. We have recently shown that barley ADH may be involved in susceptibility to the parasitic fungus Blumeria graminis f.sp. hordei (Bgh). Here, the transcriptional regulation of the barley ADH genes HvADH1 and HvADH2 after challenge of susceptible barley leaves with Bgh is addressed. Bgh infection results in an induction of HvADH1 and HvADH2, whereas HvADH3 expression was not detectable in leaves. With the use of native polyacrylamide gels the iso-enzyme composition with and without challenge by Bgh was analyzed, showing an activation of HvADH1 and HvADH2 in Bgh treated leaves.

Alcohol dehydrogenase 1 of barley modulates susceptibility to the parasitic fungus Blumeria graminis f.sp. hordei

Plant primary energy metabolism is profoundly reorganized under biotic stress conditions and there is increasing evidence for a role for the fermentative pathway in biotic interactions. However, the mechanisms regulating metabolic reprogramming are not well understood despite its critical function in the biotic stress response. Here the function of alcohol dehydrogenase (ADH) in the interaction of barley with the parasitic fungus Blumeria graminis f.sp. hordei (Bgh) is addressed. Challenge of susceptible barley leaves with Bgh resulted in transcriptional activation of HvADH1 and an induction of ADH enzyme activity starting 24 h after infection and reaching a clear-cut effect 4 d after infection. This increase in ADH enzyme activity was not observed in the resistant near-isogenic mlo5 line. Moreover, an induction of ADH enzyme activity by Bgh was enhanced in the presence of sucrose in hydroponically grown seedlings. Transient knock-down or overexpression of HvADH1 in barley epidermal cells mediated a decrease or increase in the penetration success of Bgh, respectively. Inhibition of ADH activity by pyrazole resulted in a delay in symptoms. The pyrazole effect could be overcome by adding glucose to the incubation medium, pinpointing a nutritional effect of ADH in the barley-Bgh interaction. Taken together, misexpression of pathogen-inducible HvADH1 or variation of ADH activity modulates the pathogen response of barley to the biotrophic fungal parasite Bgh. In this way, ADH knock-down/inhibition results in reduced fungal success. The possibility is discussed that ADH activity supports biotrophy by maintaining glycolytic metabolism in pathogen-stressed barley.

Physiological and biochemical changes in plants under waterlogging

Waterlogging usually results from overuse and/or poor management of irrigation water and is a serious constraint with damaging effects. The rapidly depleting oxygen from submerged root zone is sensed and plant adjusts expressing anaerobic proteins. Plant cells shift their metabolism towards low energy yielding anaerobic fermentation pathways in the absence of oxygen. Structural modifications are also induced as aerenchyma formation and adventitious rootings, etc. Studies at molecular and biochemical levels to facilitate early perception and subsequent responses have also been worked out to produce resistant transgenic plants. This review explores the sequential changes of plant responses at different levels regarding their defense strategies and efforts made to enhance them, tailoring crucial regulators so that they can withstand waterlogging stress.

Oxygen deficiency in barley (Hordeum vulgare) grain during malting

The steep water is generally aerated in industrial barley malting. However, it is questionable whether oxygen actually reaches the embryo, which remains entrapped under the husk, testa, and pericarp until chitting occurs. The aim of our study was to investigate whether barley embryos experience oxygen deficiency during steeping, and whether various steeping conditions affect the oxygen deficiency. Alcohol dehydrogenase Adh2 was induced in all steeping conditions studied. Therefore, oxygen deficiency occurred regardless of the steeping conditions. However, steeping conditions affected the rate of recovery from oxygen deficiency, germination rate, and onset of alpha-amylase production. When barley was subjected to oxygen deficiency by applying N(2) gas during steeping, the timing of the treatment determined its effects. The importance of aeration increased as the process proceeded. Oxygen deprivation at the beginning of the process had little effect on malt quality. Therefore, the timing of aeration is important in the optimization of germination during the steeping stage of malting.

The influence of linkage and inbreeding on patterns of nucleotide sequence diversity at duplicate alcohol dehydrogenase loci in wild barley (Hordeum vulgare ssp. spontaneum)

Patterns of nucleotide sequence diversity are analyzed for three duplicate alcohol dehydrogenase loci (adh1-adh3) within a species-wide sample of 25 accessions of wild barley (Hordeum vulgare ssp. spontaneum). The adh1 and adh2 loci are tightly linked (recombination fraction <0.01) while the adh3 locus is inherited independently. Wild barley is predominantly self-fertilizing (approximately 98%), and as a consequence, effective recombination is restricted by the extreme reduction in heterozygosity. Large reductions in effective recombination, in turn, widen the conditions for linkage to influence nucleotide sequence diversity through the action of selective sweeps or background selection. These considerations would appear to predict (1) homogeneity in patterns of nucleotide sequence diversity, especially between closely linked loci, and (2) extensive linkage disequilibrium relative to random-mating species. In contrast to these expectations, the wild barley data reveal heterogeneity in patterns of nucleotide sequence diversity and levels of linkage disequilibrium that are indistinguishable from those observed at adh1 in maize, an outbreeding grass species.

Heterogeneous geographic patterns of nucleotide sequence diversity between two alcohol dehydrogenase genes in wild barley (Hordeum vulgare subspecies spontaneum)

Patterns of nucleotide sequence diversity in the predominantly self-fertilizing species Hordeum vulgare subspecies spontaneum (wild barley) are compared between the putative alcohol dehydrogenase 3 locus (denoted "adh3") and alcohol dehydrogenase 1 (adh1), two related but unlinked loci. The data consist of a sequence sample of 1,873 bp of "adh3" drawn from 25 accessions that span the species range. There were 104 polymorphic sites in the sequenced region of "adh3." The data reveal a strong geographic pattern of diversity at "adh3" despite geographic uniformity at adh1. Moreover, levels of nucleotide sequence diversity differ by nearly an order of magnitude between the two loci. Genealogical analysis resolved two distinct clusters of "adh3" alleles (dimorphic sequence types) that coalesce roughly 3 million years ago. One type consists of accessions from the Middle East, and the other consists of accessions predominantly from the Near East. The two "adh3" sequence types are characterized by a high level of differentiation between clusters ( approximately 2.2%), which induces an overall excess of intermediate frequency variants in the pooled sample. Finally, there is evidence of intralocus recombination in the "adh3" data, despite the high level of self-fertilization characteristic of wild barley.

Molecular analysis of the alcohol dehydrogenase gene family of barley

One partial and two complete genomic clones of the three loci specifying alcohol dehydrogenase (ADH) in barley were isolated by screening libraries with a maize Adh1 cDNA probe. Each gene is characterised by an intron arrangement similar to that of both maize Adh1 and Adh2, although two genes show an exon fusion. A comparison with the maize coding sequences unambiguously assorts the barley loci into an Adh1-like gene and two Adh2-like genes, indicating that an ancient gene duplication underlies the widespread occurrence of two Adh loci in higher plants. In the barley lineage there has been a further duplication-transposition of a progenitor "Adh2" locus to give rise to the extant three-gene system, with gene copies of different ancestry being closely linked. An Adh1 null-allele, Adh1-M9, has been cloned; the available sequence includes an intron with a missing acceptor splice signal. Two independent clones of one of the barley Adh2-like genes have an 18 bp in-frame deletion towards the 3' end of the coding sequence. The barley Adh2-like genes are extensively diverged in their 5' sequences apart from a conserved 15 bp motif in the mRNA leader region and sequences at the start of transcription. A sequence related to the hexanucleotide core of a regulatory element found in maize Adh1 and in other anaerobically induced plant genes is present in the 5' region of barley Adh2.

Catalytic properties of alcohol dehydrogenase isozymes specified by duplicate genes in the diploid plant Stephanomeria exigua

The alcohol dehydrogenase (ADH) isozymes induced in flooded roots of the diploid plant Stephanomeria exigua are specified by tightly linked genes comprising a complex locus, Adh1. Individuals homozygous for a complex with two active genes which specify electrophoretically different subunits have three ADH-1 isozymes, two intragenic homodimers and an intergenic heterodimer. Individual isozymes were partially purified from plants homozygous for several different Adh1 complexes and apparent Km values for acetaldehyde, ethanol, NAD, and NADH and responses to temperature, pH, and two different alcohols were determined. The two homodimeric enzymes specified by a particular Adh1 complex generally differed in one or more of the properties studied, and in three of four cases, intergenic heterodimers differed significantly from intermediacy, often having lower Km values than either homodimer. None of the isozymes studied could be considered greatly divergent or defective. Constraints on evolution of duplicate genes which form intergenic heterodimers are considered.

Distorted segregation and linkage of alcohol dehydrogenase genes in Camellia japonica L. (Theaceae)

Alcohol dehydrogenase isozymes in Camellia japonica are encoded by two genes, Adh-1 and Adh-2. Both loci are expressed in seeds, and their products randomly associate into intragenic and intergenic dimers. Electrophoresis of leaf extracts reveals only the products of Adh-2. Formal genetic analysis indicated that the two Adh loci are tightly linked (combined estimate of r = 0.004). Most segregations fit expected Mendelian ratios, but in some families distorted segregation was observed at Adh-1, Adh-2, or both loci. The deficient progeny class varied across families, and in two apparent back-crosses three rather than two phenotypic classes were recovered. The mechanism underlying these distortions is not known, but evidence is presented that suggests that the phenomenon is genic or segmental in nature. Plausible hypotheses include linkage of the Adh structural genes with a gametophytic self-incompatibility locus, translocation heterozygosity involving the segment bearing Adh-1 and Adh-2, or a combination of these two mechanisms.

Three alcohol dehydrogenase genes in wild and cultivated barley: characterization of the products of variant alleles

Barley (Hordeum vulgare) and its wild progenitor (H. spontaneum) have three loci for alcohol dehydrogenase (EC 1.1.1.1; ADH). The Adh1 locus is constitutively expressed in seed tissues, whereas expression of the loci Adh2 and Adh3 requires anaerobic induction. The Adh3 gene is well expressed in aleurone and embryo tissues kept under N2 for 2-3 days. Using N2-treated embryos, a diverse collection of H. spontaneum was screened in starch gels for electrophoretic variants at the Adh3 locus. Four variants were found: two were conventional mobility variants (Adh3 S, Adh3 V); one was a null variant (Adh3 n); and the fourth (Adh3 I) variant lacked active homodimers and showed reduced heterodimer activity. The 35S-labeled monomers induced under N2 in the lines homozygous for Adh1, Adh2, or Adh3 variants were immunoprecipitated with antiserum raised against maize ADH. Fluorography after separation by SDS-PAGE and by urea-isoelectric focusing indicated that the Adh3 n allele was CRM- and that the Adh3 I gene product was smaller than normal. The Adh1 and Adh3 variants showed independent segregation.