Abstract
Aldehyde dehydrogenases (ALDHs) constitute a superfamily of NAD(P)+-dependent enzymes that catalyze the irreversible oxidation of a wide range of reactive aldehydes to their corresponding nontoxic carboxylic acids. ALDHs have been studied in many organisms from bacteria to mammals; however, no systematic analyses incorporating genome organization, gene structure, expression profiles, and cis-acting elements have been conducted in the model tree species Populus trichocarpa thus far. In this study, a comprehensive analysis of the Populus ALDH gene superfamily was performed. A total of 26 Populus ALDH genes were found to be distributed across 12 chromosomes. Genomic organization analysis indicated that purifying selection may have played a pivotal role in the retention and maintenance of PtALDH gene families. The exon-intron organizations of PtALDHs were highly conserved within the same family, suggesting that the members of the same family also may have conserved functionalities. Microarray data and qRT-PCR analysis indicated that most PtALDHs had distinct tissue-specific expression patterns. The specificity of cis-acting elements in the promoter regions of the PtALDHs and the divergence of expression patterns between nine paralogous PtALDH gene pairs suggested that gene duplications may have freed the duplicate genes from the functional constraints. The expression levels of some ALDHs were up- or down-regulated by various abiotic stresses, implying that the products of these genes may be involved in the adaptation of Populus to abiotic stresses. Overall, the data obtained from our investigation contribute to a better understanding of the complexity of the Populus ALDH gene superfamily and provide insights into the function and evolution of ALDH gene families in vascular plants.
Highlights
Endogenous aldehydes are intermediates or byproducts in a range of fundamental biochemical pathways that are generated during the metabolism of carbohydrates, vitamins, steroids, amino acids, and lipids [1, 2]
The Populus Aldehyde dehydrogenases (ALDHs) superfamily is larger than the Arabidopsis ALDH superfamily, the number of ALDHs in the P. trichocarpa genome was found to be consistent with 1.4~1.6 putative Populus homologs for each Arabidopsis gene according to previous comparative genomics studies [23]
Seven of the 10 ALDH families in Populus were represented by more than one gene (ALDH3, six genes; ALDH2, four genes; ALDH6, four genes; ALDH11, three genes; ALDH7, ALDH10, and ALDH18, two genes), whereas the remaining three families (ALDH5, ALDH12, and ALDH22) each were encoded by a single-copy gene
Summary
Endogenous aldehydes are intermediates or byproducts in a range of fundamental biochemical pathways that are generated during the metabolism of carbohydrates, vitamins, steroids, amino acids, and lipids [1, 2]. When produced in excessive amounts, these aldehydes can have detrimental effects on cellular metabolism because of their chemical reactivity [3,4,5]. Cellular levels of aldehydes need to be regulated to maintain normal developmental processes. ALDH protein sequences that share less than 40% identity would form a new family. Previous classifications of the ALDH gene superfamily in eukaryotes have identified 24 protein families based on sequence identity [7,8,9,10]. Among the 24 ALDH families, 14 (ALDH2, ALDH3, ALDH5, ALDH6, ALDH7, ALDH10, ALDH11, ALDH12, ALDH18, ALDH19, ALDH21, ALDH22, ALDH23 and ALDH24) contain members from plant species and seven (ALDH11, ALDH12, ALDH19, ALDH21, ALDH22, ALDH23 and ALDH24) are unique to plants [10]
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