Mattiello Lucia, Begcy Kevin, da Silva Felipe Rodrigues, Jorge Renato A, Menossi Marcelo
Laboratório Nacional de Ciência e Tecnologia do Bioetanol, CTBE/CNPEM, Campinas, SP, Brazil,
Mol Biol Rep. 2014 Dec;41(12):8107-16. doi: 10.1007/s11033-014-3709-1. Epub 2014 Sep 10.
Soil acidity limits crop yields worldwide and is a common result of aluminum (Al) phytotoxicity, which is known to inhibit root growth. Here, we compared the transcriptome of leaves from maize seedlings grown under control conditions (soil without free Al) and under acidic soil containing toxic levels of Al. This study reports, for the first time, the complex transcriptional changes that occur in the leaves of maize plants grown in acidic soil with phytotoxic levels of Al. Our data indicate that 668 genes were differentially expressed in the leaves of plants grown in acidic soil, which is significantly greater than that observed in our previous work with roots. Genes encoding TCA cycle enzymes were upregulated, although no specific transporter of organic acids was differentially expressed in leaves. We also provide evidence for positive roles for auxin and brassinosteroids in Al tolerance, whereas gibberellin and jasmonate may have negative roles. Our data indicate that plant responses to acidic soil with high Al content are not restricted to the root; tolerance mechanisms are also displayed in the aerial parts of the plant, thus indicating that the entire plant responds to stress.
土壤酸度限制了全球农作物的产量,这是铝(Al)植物毒性的常见结果,已知铝会抑制根系生长。在此,我们比较了在对照条件下(不含游离铝的土壤)和含有毒性水平铝的酸性土壤中生长的玉米幼苗叶片的转录组。本研究首次报道了在含有植物毒性水平铝的酸性土壤中生长的玉米植株叶片中发生的复杂转录变化。我们的数据表明,在酸性土壤中生长的植物叶片中有668个基因差异表达,这显著高于我们之前对根系研究中观察到的数量。编码三羧酸循环酶的基因上调,尽管叶片中没有有机酸特异性转运蛋白差异表达。我们还提供了生长素和油菜素内酯在耐铝性中发挥积极作用的证据,而赤霉素和茉莉酸可能起消极作用。我们的数据表明,植物对高铝酸性土壤的反应并不局限于根部;耐受机制也表现在植物地上部分,从而表明整株植物对胁迫作出反应。
