Overexpression of the transcription factor HvSNAC1 improves drought tolerance in barley (Hordeum vulgare L.)
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Date
2014-02-23
Date Issued
ISI Journal
Impact factor: 2.465 (Year: 2014)
Citation
Ayed Al-Abdallat, Jamal Yousef Ayad, Andrew McCown, Jamal Abu Elenein, Zakaria Ibrahim Al-Ajlouni, Wendy Harwood. (23/2/2014). Overexpression of the transcription factor HvSNAC1 improves drought tolerance in barley (Hordeum vulgare L. ). Molecular Breeding, 33 (2), pp. 401-414.
Abstract
NAC proteins constitute a family of plantspecific
transcription factors that are involved in many
plant cellular processes including responses to abiotic
stress. In this study, a cDNA clone encoding the
HvSNAC1 transcription factor was isolated from
drought-stressed barley using a bioinformatics approach
based on amino acid sequence data of the stress-related
SNAC1 protein from rice. Phylogenetic analysis of the
deduced amino acid sequence of HvSNAC1 showed
that this protein belongs to the stress clade of NAC
proteins that include SNAC1 and TaNAC2. Expression analysis indicated that the HvSNAC1 gene is strongly
induced by different abiotic stresses including drought.
Overexpression of HvSNAC1 in barley under the control
of a constitutive promoter produced plants that grew
normally under well-watered conditions when compared
with wild-type plants. Transgenic barley plants
overexpressing HvSNAC1 showed higher drought tolerance
at different growth stages when compared with
wild-type plants. In addition, the constitutive overexpression
of HvSNAC1 resulted in improved water status,
photosynthetic activity and reducedwater loss ratewhen
compared with wild-type plants under drought conditions.
Furthermore, the transgenic plants also showed
significantly improved productivity, as reflected by the
increase in biological yield over the wild-type plants
under severe field drought conditions. In conclusion, the
HvSNAC1 gene could be a useful tool for improving
barley productivity under field drought conditions
without impairment in growth under normal field
conditions.