The transporter PHO84/NtPT1 is a target of aluminum to affect phosphorus absorption in Saccharomyces cerevisiae and Nicotiana tabacum L.

IF 2.9 3区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY Metallomics Pub Date : 2023-12-09 DOI:10.1093/mtomcs/mfad069
Zhiwei Huang, Shixuan Zhang, Ranran Chen, Qian Zhu, Ping Shi, Yuhu Shen
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Abstract

The molecular mechanism of aluminum toxicity in biological systems is not completely understood. Saccharomyces cerevisiae is one of the most used model organisms in the study of environmental metal toxicity. Using an unbiased metallomic approach in yeast, we found that aluminum treatment caused phosphorus deprivation, and the lack of phosphorus increased as the pH of the environment decreased compared to the control strain. By screening the phosphate signaling and response pathway (PHO pathway) in yeast with the synthetic lethality of a new phosphorus-restricted aluminum-sensitive gene, we observed that pho84Δ mutation conferred severe growth defect to aluminum under low-phosphorus conditions, and the addition of phosphate alleviated this sensitivity. Subsequently, the data showed that PHO84 determined the intracellular aluminum-induced phosphorus deficiency, and the expression of PHO84 was positively correlated with aluminum stress, which was mediated by phosphorus through the coordinated regulation of PHO4/PHO2. Moreover, aluminum reduced phosphorus absorption and inhibited tobacco plant growth in acidic media. In addition, the high-affinity phosphate transporter NtPT1 in tobacco exhibited similar effects to PHO84, and overexpression of NtPT1 conferred aluminum resistance in yeast cells. Taken together, positive feedback regulation of the PHO pathway centered on the high-affinity phosphate transporters is a highly conservative mechanism in response to aluminum toxicity. The results may provide a basis for aluminum-resistant microorganisms or plant engineering and acidic soil treatment.

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转运体PHO84/NtPT1是铝影响酿酒酵母和烟草对磷吸收的靶标。
生物系统中铝毒性的分子机制尚不完全清楚。酿酒酵母是环境金属毒性研究中应用最广泛的模式生物之一。在酵母中使用无偏金属组学方法,我们发现铝处理导致了磷的剥夺,并且与对照菌株相比,随着环境pH的降低,缺磷量增加。通过合成致死性限磷铝敏感基因对酵母的PHO通路进行筛选,我们发现pho84Δ突变在低磷条件下会使铝产生严重的生长缺陷,而添加磷酸盐可以减轻这种敏感性。随后,数据显示PHO84决定了细胞内铝诱导的缺磷,并且PHO84的表达与铝胁迫呈正相关,而铝胁迫是磷通过PHO4/PHO2的协同调控介导的。在酸性培养基中,铝降低了烟草对磷的吸收,抑制了烟草的生长。此外,烟草中的高亲和磷酸盐转运体NtPT1表现出与PHO84相似的作用,并且NtPT1的过表达使酵母细胞对铝具有抗性。综上所述,以高亲和力磷酸盐转运体为中心的PHO通路的正反馈调节是铝毒性反应的高度保守机制。研究结果可为耐铝微生物或植物工程及酸性土壤处理提供依据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Metallomics
Metallomics 生物-生化与分子生物学
CiteScore
7.00
自引率
5.90%
发文量
87
审稿时长
1 months
期刊介绍: Global approaches to metals in the biosciences
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