L. C. Muñoz, M. Rivera, J. Muñoz, F. Sarsu, I. Rao
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引用次数: 1
摘要
热胁迫是影响菜豆籽粒产量的主要因素。小豆(Phaseolus acutifolius A. Gray)比普通豆更能适应热胁迫。对10个单株大豆材料、4个普通大豆基因型和4个种间系进行了温室条件下的耐热性评价,并与环境温度下生长的植物进行了比较。高温处理白天29±5°C,夜间>24°C(最高27°C),环境温度(AT)处理白天25±5°C,夜间19±2°C。在茎、根形态生理特征和产量组成方面进行了基因型差异评价。基因型和基因型与温度的交互作用对所有茎和根的形态生理特征均有显著影响。高温对叶片光合效率、叶绿素含量和气孔导度有显著影响。这种影响是积极的还是消极的,取决于基因型。四组份总叶绿素含量降低,而普通豆基因型和种间系受影响较小。高温胁迫下,叶片气孔导度降低,但叶片光合效率提高。普通豆基因型增加气孔导度,降低叶片光合效率。与环境条件相比,高温降低了总根长、比根长和荚果生物量,但对所测基因型的花粉活力无显著影响。叶片性种质资源对高温的优越适应性归因于其调节气孔开放和光合效率的能力,以及在生理成熟期间将光合产物从老叶重新动员到豆荚的优越能力
Heat stress-induced changes in shoot and root characteristics of genotypes of tepary bean (Phaseolus acutifolius A. Gray), common bean (Phaseolus vulgaris L.) and their interspecific lines
Heat stress is a major limitation to grain yield in common bean (Phaseolus vulgaris L.). Tepary bean (Phaseolus acutifolius A. Gray) is better adapted to heat stress than common bean. Ten tepary bean accessions, four common bean genotypes and four interspecific lines involving P. vulgaris and P. acutufolius, P. coccineus and P. dumosus were evaluated for tolerance to heat stress conditions induced under greenhouse conditions and these were compared to plants grown under ambient temperatures. The high temperature treatment was 29 ±5 °C during the day and was >24 °C (up to 27 °C) during the night, while the ambient temperature (AT) treatment was 25 ±5 °C during the day and 19± 2 °C at night. The genotypic differences were evaluated for morpho-physiological characteristics of shoot and root and also yield components. The Genotype and Genotype × Temperature interactions were significant for all shoot and root morpho-physiological characteristics evaluated. Higher temperature (HT) significantly affected leaf photosynthetic efficiency, total chlorophyll content, and stomatal conductance. The effect was positive or negative, depending on the genotypes. Tepary accessions showed reduced total chlorophyll content, while common bean genotypes and the interspecific lines were less affected. Tepary accessions also showed reduced stomatal conductance, but increased leaf photosynthetic efficiency under HT. Common bean genotypes increased stomatal conductance and decreased leaf photosynthetic efficiency. High temperature decreased total root length, specific root length and pod biomass compared to ambient conditions, but there was no marked effect on pollen viability of the tested genotypes. The superior adaptation of tepary germplasm accessions to high temperature is attributed to their ability to regulate stomatal opening and photosynthetic efficiency, together with a superior ability to remobilize photosynthates from older leaves to pods during physiological maturity
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