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一种简单的内陆养殖系统有助于深入了解海鞘胚胎后发育生理学。

A simple inland culture system provides insights into ascidian post-embryonic developmental physiology.

作者信息

Mathiesen Birthe Thuesen, Ohta Mayu, Magalhaes Boris Pinto De, Castelletti Chiara, Perria Vincenzo, Schuster Keaton, Christiaen Lionel, Ohta Naoyuki

机构信息

Michael Sars Centre, University of Bergen , Bergen, Norway.

Center for Developmental Genetics, Department of Biology, New York University , New York, NY, USA.

出版信息

Open Biol. 2025 Jan;15(1):240340. doi: 10.1098/rsob.240340. Epub 2025 Jan 15.

DOI:10.1098/rsob.240340
PMID:39809318
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11732436/
Abstract

Maintenance and breeding of experimental organisms are fundamental to life sciences, but both initial and running costs, and hands-on zootechnical demands can be challenging for many laboratories. Here, we first aimed to further develop a simple protocol for reliable inland culture of tunicate model species of the genus. We cultured both and in controlled experimental conditions, with a focus on dietary variables, and quantified growth and maturation parameters. From statistical analysis of these standardized datasets, we gained insights into the post-embryonic developmental physiology of and inferred an improved diet and culturing conditions for sexual maturation. We showed that body length is a critical determinant of both somatic and sexual maturation, which suggests the existence of systemic control mechanisms of resource allocation towards somatic growth or maturation and supports applying size selection as a predictor of reproductive fitness in our inland culture to keep the healthiest animals at low density in the system. In the end, we successfully established a new protocol, including size selection, to promote both sperm and egg production. Our protocol using small tanks will empower researchers to initiate inland cultures with low costs and reduced space constraints.

摘要

实验生物的饲养和繁殖是生命科学的基础,但初始成本和运营成本,以及实际操作中的畜牧技术要求对许多实验室来说都具有挑战性。在此,我们首先旨在进一步开发一种简单的方案,用于可靠地在内陆培养该属的被囊动物模型物种。我们在可控的实验条件下培养了[具体物种1]和[具体物种2],重点关注饮食变量,并对生长和成熟参数进行了量化。通过对这些标准化数据集的统计分析,我们深入了解了[具体物种1]和[具体物种2]的胚胎后发育生理学,并推断出促进性成熟的改良饮食和培养条件。我们表明,体长是体细胞成熟和性成熟的关键决定因素,这表明存在着资源分配的系统控制机制,用于体细胞生长或成熟,并支持在我们的内陆养殖中应用大小选择作为生殖适应性的预测指标,以便在系统中以低密度饲养最健康的动物。最后,我们成功建立了一种新的方案,包括大小选择,以促进精子和卵子的产生。我们使用小水箱的方案将使研究人员能够以低成本和减少空间限制启动内陆[具体物种]培养。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4419/11732436/91489ba4757f/rsob.240340.f006.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4419/11732436/592184385cbc/rsob.240340.fg001.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4419/11732436/198b067d9a72/rsob.240340.f001.jpg
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