How now brown chow? Investigating direct functional roles for dissolved organic matter in aquatic animal nutrition and health

现在棕色松狮怎么样了？

• 批准号: RGPIN-2018-04134
• 负责人: Glover, Chris
• 金额: $ 2.4万
• 依托单位: Athabasca University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=711873
• 关键词: How; now; brown; chow; Investigating

Dissolved organic matter (DOM) represents the product of decomposing plant and soil matter that washes into water bodies and mixes with organic material generated by aquatic organisms themselves. At high concentrations, such as in waters draining forested regions, DOM is responsible for a tea-like, brown colouration. While generally considered to be biologically inert, recent findings suggest that DOM could have direct effects on aquatic animals. The current program seeks to develop an advanced understanding of these biological roles of DOM, through research in three distinct, but overlapping, areas. One research focus is to determine whether amino acids, a simple form of DOM, contribute to the growth of early life-stages of fish. Before larval fish develop a gastrointestinal tract that allows for the absorption of nutrients, there is evidence suggesting that amino acids are taken up by the skin and support the health of larval fish, but this has yet to be experimentally shown. This hypothesis will be tested in the current proposal, and if proven to be true, will offer a way of increasing the productivity and survival of fish in aquaculture, and could result in cheaper and more effective fish feeds. This research will also contribute to an enhanced fundamental understanding of fish nutrition, by examining the development of digestive and absorptive processes in the fish gut. A second research focus asks a similar question regarding the nutritive role of DOM in aquatic invertebrates, such as insect larvae. It is known that DOM-rich waters support larger populations of insect larvae, such as those of black flies and mosquitoes, than DOM-poor waters. There is some evidence to suggest that this is because these larvae, and other freshwater invertebrates such as the water flea, can use DOM to aid growth and survival. Knowledge of DOM roles in supporting insect nutrition will offer significant insight into factors that influence seasonal variation in biting insects, important vectors of disease and irritation. It may also facilitate prediction of how insect numbers will be impacted by factors that change aquatic DOM concentration and composition (e.g. forest fires, land-use changes), which may in turn have implications for human health and disease. The final research focus seeks to understand how the differing chemical composition of different DOMs affect their capacity to directly alter the biology of aquatic animals. This work builds on growing recognition that DOM can directly cause stress in animals. However, why certain pathways are affected, and why these effects are restricted to certain DOMs, is not well understood. Given that most studies ignore the possible roles of DOM on aquatic animal health, this research will increase awareness of DOM actions on biota, and will represent the first steps towards a model that will allow prediction of these effects based on site-specific DOM composition.

溶解有机物（DOM）代表植物和土壤物质分解的产物，这些物质冲入水体并与水生生物本身产生的有机物质混合。在高浓度下，例如在森林地区的沃茨中，DOM会导致茶样的棕色。虽然通常被认为是生物惰性的，但最近的研究结果表明，DOM可能对水生动物产生直接影响。目前的计划旨在通过三个不同但重叠的领域的研究，对DOM的这些生物学作用进行深入的了解。 一个研究重点是确定氨基酸，DOM的一种简单形式，是否有助于鱼类早期生命阶段的生长。在幼鱼发育出胃肠道以吸收营养之前，有证据表明氨基酸被皮肤吸收并支持幼鱼的健康，但这还有待实验证明。这一假设将在目前的提案中得到检验，如果被证明是正确的，将提供一种提高水产养殖中鱼类生产力和存活率的方法，并可能导致更便宜和更有效的鱼类饲料。这项研究还将有助于通过检查鱼肠道中消化和吸收过程的发展，加强对鱼类营养的基本了解。 第二个研究重点是关于DOM在水生无脊椎动物（如昆虫幼虫）中的营养作用的类似问题。已知富含DOM的沃茨比缺乏DOM的沃茨支持更大的昆虫幼虫种群，例如黑蝇和蚊子的幼虫种群。有一些证据表明，这是因为这些幼虫和其他淡水无脊椎动物，如水蚤，可以使用DOM来帮助生长和生存。DOM在支持昆虫营养的作用的知识将提供重要的洞察因素，影响季节性变化的叮咬昆虫，重要的疾病和刺激的载体。它还有助于预测改变水生DOM浓度和组成的因素（如森林火灾、土地使用变化）将如何影响昆虫数量，这些因素反过来可能对人类健康和疾病产生影响。 最终的研究重点是了解不同DOM的不同化学成分如何影响其直接改变水生动物生物学的能力。这项工作建立在越来越多的认识，DOM可以直接导致动物的压力。然而，为什么某些途径受到影响，以及为什么这些影响仅限于某些DOM，还没有很好的理解。鉴于大多数研究忽略了DOM对水生动物健康的可能作用，这项研究将提高人们对DOM对生物群作用的认识，并将代表建立一个模型的第一步，该模型将允许基于特定地点的DOM组成预测这些影响。