Shubham Kothari, V. K. Sharma, Ashutosh Singh, Sumeet Kumar Singh, Sarita Kumari
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引用次数: 0
Abstract
Calcium (Ca) and cadmium (Cd) are transition metals coexisting in the ecosystem. Ca is indispensable for the growth and development of plants as well as animals, while Cd is regarded as a toxic heavy metal for the living system. The transportation of Cd in the biological systems often used the pathways of Ca because of chemical similarities. High concentrations of cadmium replace Ca, Mn, and Zn from their respective metalloprotein sites and strongly associated with them. Replaced minerals from their metalloprotein sites are often released as an oxidative ion that is detrimental to it. The common transportation mechanism of Ca and Cd is implicit in the role of common and similar transporters for transporting them in plants. Thus, our study was done to identify the transporters for Ca and Cd and characterize them for similarity in terms of cotransportation system. A profile-based search program identified 44 transporters genes for Ca transportation and 70 genes for cadmium transportation. They were categorized into different groups based on the presence of signature motifs and domains. Identified transporters were characterized for genomic distribution, gene structure, annotation, conserved signature motifs, and domain. Further, cis motif analysis, heat map, gene ontology, and protein–protein interaction were conducted for Ca and Cd transporter genes. In silico expression showed Os05g0319800-1304 and Os0319800-6065 transporter genes were overexpressed for Ca and Os07g00232800-40298 and Os07g00384500-25924 transporter genes overexpressed for Cd transporter. These genes could be used as a candidate genes for enhancing the Ca concentration with reduced Cd content in rice using biotechnological approaches. Twenty-seven genes were found as the common transporters for Ca and Cd. Both active and passive transporter mechanisms act as cotransporters for Ca and Cd. The common signature motifs and domains can be targeted for the characterization of cotransporters of different minerals.
钙(Ca)和镉(Cd)是共存于生态系统中的过渡金属。钙是植物和动物生长发育不可或缺的元素,而镉则被认为是对生物系统有毒的重金属。由于化学性质相似,镉在生物系统中的迁移通常使用钙的迁移途径。高浓度的镉会取代钙、锰和锌各自的金属蛋白位点,并与它们紧密联系在一起。被取代的矿物质从它们的金属蛋白位点释放出来时,往往是一种对其有害的氧化离子。钙和镉的共同运输机制隐含在植物中共同和相似的运输体对它们的运输作用中。因此,我们的研究旨在确定钙和镉的转运体,并从共转运系统的角度分析它们的相似性。通过基于轮廓的搜索程序确定了 44 个钙运输转运体基因和 70 个镉运输转运体基因。根据这些基因是否存在特征性图案和结构域,将它们分为不同的组。对鉴定出的转运体进行了基因组分布、基因结构、注释、保守的特征基调和结构域分析。此外,还对钙和镉转运体基因进行了顺式图案分析、热图、基因本体论和蛋白质-蛋白质相互作用分析。硅表达显示,Os05g0319800-1304和Os0319800-6065转运体基因过表达钙转运体,Os07g00232800-40298和Os07g00384500-25924转运体基因过表达镉转运体。这些基因可作为候选基因,利用生物技术方法提高水稻中 Ca 的浓度,降低 Cd 的含量。研究发现,27 个基因是钙和镉的共同转运体。主动和被动转运机制都是钙和镉的共转运体。这些共同的标志性基团和结构域可用于鉴定不同矿物质的共转运体。
期刊介绍:
This journal publishes original papers presenting new scientific results on breeding, genetics, physiology, pathology and production of primarily wheat, rye, barley, oats and maize.
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