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海洋腹足纲动物的分子见解:转录组学和蛋白质组学方法揭示具有潜在治疗潜力的多肽

Molecular Insights into the Marine Gastropod : Transcriptomic and Proteopeptidomic Approaches Reveal Polypeptides with Putative Therapeutic Potential.

作者信息

Barros Gabriel Marques de, Gama Letícia Fontes, Mello Felipe Ricardo de, Corrêa Claudia Neves, Fiametti Louise Oliveira, Montenegro Horácio, Ottoni Cristiane Angélica, Castro Leandro Mantovani de

机构信息

Department of Biological and Environmental Sciences, Bioscience Institute, São Paulo State University (UNESP), Sao Vicente 11330-900, SP, Brazil.

Biodiversity of Coastal Environments Postgraduate Program, Department of Biological and Environmental Sciences, Bioscience Institute, São Paulo State University (UNESP), Sao Vicente 11330-900, SP, Brazil.

出版信息

Int J Mol Sci. 2025 Apr 16;26(8):3751. doi: 10.3390/ijms26083751.

DOI:10.3390/ijms26083751
PMID:40332358
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12027567/
Abstract

The marine environment is a rich source of new biotechnologies and products. Bottom trawling for shrimp species such as and leads to the unintentional capture of non-target species, known as bycatch, which includes a variety of marine life that are often discarded without economic value. A common bycatch species on the southeast coast of Brazil is (), a carnivorous gastropod that feeds mainly on bivalves. Despite its abundance, this species is still little studied, especially for biotechnological applications. Other gastropods such as Conus are known for their diverse and potent toxins, which offer great potential for pharmacological discoveries. In this study, an omics approach, including transcriptomics and proteopeptidomics, was applied to explore at the molecular level. The transcriptome of the muscle foot/mantle led to the annotation of 19,097 genes via Gene Ontology, identifying 20 toxin-like transcripts identified considering the Gastropod class. The proteome fraction confirmed 2179 transcripts, including sequences with toxin activity, such as conotoxin precursors, Conodipine-P3, and BPTI/Kunitz domain-containing proteins. In addition, 9663 peptides of 1484 precursor proteins were detected in the peptide fraction, including 2 sequences representing neurotoxins. The identification of these sequences could lead to the discovery of new molecules with therapeutic potential.

摘要

海洋环境是新生物技术和产品的丰富来源。对诸如[虾的品种1]和[虾的品种2]等虾类进行底拖网捕捞会导致意外捕获非目标物种,即副渔获物,其中包括各种通常被丢弃且无经济价值的海洋生物。在巴西东南海岸,一种常见的副渔获物是[物种名称]([物种学名]),一种主要以双壳类为食的肉食性腹足纲动物。尽管其数量众多,但该物种仍鲜少被研究,尤其是在生物技术应用方面。其他腹足纲动物,如芋螺属,以其多样且强效的毒素而闻名,这些毒素在药理学发现方面具有巨大潜力。在本研究中,采用了包括转录组学和蛋白质肽组学在内的组学方法,在分子水平上对[物种名称]进行探索。通过基因本体论对肌肉足/外套膜的转录组进行注释,共注释了19097个基因,根据腹足纲类别鉴定出20个类似毒素的转录本。蛋白质组部分确认了2179个转录本,包括具有毒素活性的序列,如芋螺毒素前体Conodipine - P3以及含BPTI/Kunitz结构域蛋白。此外, 在肽段部分检测到1484个前体蛋白的9663个肽段,其中包括2个代表神经毒素的序列。这些序列的鉴定可能会促成具有治疗潜力的新分子的发现。

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