Gene expression of DAM5 and DAM6 is suppressed by chilling temperatures and inversely correlated with bud break rate

Tao

Ooka

et al. 2011

This study investigated the regulation of the seasonal expression of PpDAM5 and PpDAM6, two of the six peach (Prunus persica) dormancy-associated MADS-box genes, in relation to the endodormancy and development of lateral vegetative and flower buds of low-and high-chill peach cultivars. PpDAM5 and PpDAM6 were originally found as homologs of Arabidopsis SVP/AGL24 at the EVERGROWING (EVG) locus of peach and have been recently shown to be involved in lateral bud endodormancy. Seasonal expression analyses in this study indicated that PpDAM5 and PpDAM6 transcript levels in lateral vegetative buds of both low-and high-chill cultivars in the field negatively correlated with bud burst percentages determined under forcing conditions. Negative correlation was also found between their transcript levels and the flower organ enlargement rate. These results suggest that distinct seasonal expression patterns of PpDAM5 and PpDAM6 are correlated with a distinct chilling requirement for bud break and flowering of low-and high-chill cultivars. Characterization of the genomic structure of PpDAM5 and PpDAM6 revealed the presence of large insertions in the first introns of both PpDAM5 and PpDAM6 in low-chill peach. Alteration of the genomic structure is discussed with respect to the low-chill character.

Section: Discussionsupporting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Comparative Analyses of Dormancy-associated MADS-box Genes, PpDAM5 and PpDAM6, in Low- and High-chill Peaches (Prunus persica L.)

Tao

Ooka

et al. 2011

“…In peach, six DAM genes showed distinct seasonal expression changes in the shoot apex. Peach DAM1, DAM2, and DAM4 were most closely associated with terminal bud formation (Li et al, 2009), whereas peach DAM5 and DAM6 expression was negatively correlated with the time required for terminal bud break in peach (Jimenéz et al, 2010). Negative correlation of peach PpDAM5 and PpDAM6 expression with the time required for bud break was also reported for lateral vegetative (Yamane et al, 2011a) and flower (Yamane et al, 2011b, c) buds.…”

Section: ) Identification Of Dormancy-associated Madsbox Genes In Prmentioning

confidence: 76%

“…Secondly, in the early flowering Japanese apricot cultivar 'Taoxingmei', digital expression of DAMs in flower buds was maintained at high levels in ecodormancy (Jan.) in comparison to that observed in endodormancy (Dec.), and decreased during February (Zhong et al, 2013). This is not consistent with the dormancyassociated expression patterns of PmDAMs in vegetative buds (Sasaki et al, 2011) and peach DAMs in flower buds (Jimenéz et al, 2010;Yamane et al, 2011b, c). Recently, chromatin modifications in the peach DAM6 gene were investigated to characterize the repression mechanism of DAM6 expression during dormancy release (Leida et al, 2012).…”

Section: ) Expression Analysis Of Dam Genesmentioning

confidence: 92%

Regulation of Bud Dormancy and Bud Break in Japanese Apricot (Prunus mume Siebold ^|^amp; Zucc.) and Peach [Prunus persica (L.) Batsch]: A Summary of Recent Studies

2014

Bud dormancy allows most deciduous fruit tree species to avoid injury in unsuitable environments, synchronize their annual growth, and adapt to a temperate zone climate. Because bud dormancy affects next season's fruit production and vegetative growth, it is considered one of the most important physiological factors that control fruit production. Recent global climate changes require us to better understand the genetic factors regulating bud dormancy, especially those that induce dormancy release and subsequent bud break. In this review, environmental factors that affect the seasonal dormancy depth of Japanese apricot (P. mume Siebold & Zucc.) and peach [P. persica (L.) Batsch] are first outlined. Next, recent progress of genetic, biochemical, and molecular biological studies of Prunus dormancy regulation is described. Recent advances in functional genomics have promoted the discovery of gene function and gene networks associated with bud dormancy regulation. A group of candidate genes for bud dormancy regulation, the DORMANCY-ASSOCIATED MADS-box (DAM) genes in Prunus, are focused. Recently reported expressional analysis suggests a significant role for DAMs in dormancy release and bud break of Japanese apricot and peach vegetative buds. Transformation studies of PmDAM6 have demonstrated that it has an inhibitory effect on the apical growth of poplar (Populus spp.). As bud dormancy is a quantitative polygenic trait, not only DAMs, but also other genes and gene networks appear to regulate bud dormancy. Ongoing and future studies will undoubtedly facilitate the unveiling of the molecular aspects of bud dormancy regulation in temperate fruit tree species of Prunus.

“…Other DAMs, DAM4 and DAM5, were also up-regulated during endodormancy, although statistically significant differences were observed in leaf buds but not in flower buds. This is unlikely to reflect organspecific expression patterns, but probably reflects the lower sensitivity of EST analyses compared with realtime PCR, because it has been reported that DAM5 is up-regulated in flower buds during endodormancy in peach (Jimenéz et al, 2010;Yamane et al, 2011b, c) and Japanese apricot (Ooka et al, 2010). Most of the unigenes that were up-regulated at the endodormant stage, including two commonly up-regulated unique sequences in leaf and flower buds, showed no homology to genes or proteins in the public databases; therefore, we cannot predict their functions, although it is likely that they are involved in endodormancy regulation.…”

Section: Digital Expression Analysis Based On Est Assemblymentioning

confidence: 99%

454-Pyrosequencing of the Transcriptome in Leaf and Flower Buds of Japanese Apricot (Prunus mume Sieb. et Zucc.) at Different Dormant Stages

Habu

Igarashi

et al. 2012

Bud dormancy in temperate woody perennials is a complex process consisting of three different stages; paradormancy, endodormancy, and ecodormancy. Endodormant buds differ from the other types of dormant buds in that they cannot resume growth under favorable conditions. Because endodormant buds require a certain amount of chilling accumulation for the transition to ecodormancy, genes showing chilling-mediated differential expression patterns are candidates for internal factors controlling endodormancy. To search for genes controlling the endodormancy of Japanese apricot (Prunus mume Sieb. et Zucc.), we performed 454-pyrosequencing to examine gene expression patterns of the dormant leaf and flower buds of Japanese apricot at three different stages of dormancy. We also used buds from branches that had been collected at the endodormant stage and treated with cold or non-cold temperatures. From 485,376 reads generated, we obtained 28,382 contigs and 85,247 singletons, of which 47,401 (41.7%) were annotated by BLAST searches against the non-redundant NCBI protein/ nucleotide database. Among them, only 2,530 sequences showed high sequence similarity to Prunus genes in the database, while the remaining 44,871 sequences showed similarity to known genes of other genera and were novel in Prunus. Functional classification by the gene ontology (GO) term indicated that the genes obtained in this study function in a relatively wide range of biological processes. We searched for up-regulated genes in endodormant leaf and flower buds and found that 74 and 82 genes, respectively, were up-regulated at the endodormant stage as compared with the paradormant stage. About one-third of them, 21 and 25 genes in the leaf and flower buds, respectively, were down-regulated at the ecodormant stage as compared with the endodormant stage. P. mume DORMANCY-ASSOCIATED MADS (PmDAM) genes were among those that were up-regulated preferentially in endodormant buds. From the EST data obtained, we constructed a "Japanese apricot dormant bud EST database" (JADB) for future studies on dormancy in Prunus.