The microbiology of isoprene cycling in aquatic ecosystems

IF 1.6 4区环境科学与生态学 Q3 ECOLOGY

Aquatic Microbial Ecology Pub Date : 2021-01-01 DOI:10.3354/AME01972

R. Dawson, AT Crombie, P. Pichon, M. Steinke, TJ McGenity, J. Murrell

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引用次数: 9

Abstract

Isoprene (2-methyl-1,3-butadiene) is emitted in vast quantities (>500 Tg C yr-1). Most isoprene is emitted by trees, but there is still incomplete understanding of the diversity of isoprene sources. The reactivity of isoprene in the atmosphere has potential implications for both global warming and global cooling, with human health implications also arising from isoprene-induced ozone formation in urban areas. Isoprene emissions from terrestrial environments have been studied for many years, but our understanding of aquatic isoprene emissions is less complete. Several abundant phytoplankton taxa produced isoprene in the laboratory, and the relationship between chlorophyll a and isoprene production has been used to estimate emissions from marine environments. The aims of this review are to highlight the role of aquatic environments in the biological cycling of isoprene and to stimulate further study of isoprene metabolism in marine and freshwater environments. From a microbial ecology perspective, the isoprene metabolic gene cluster, first identified in Rhodococcus sp. AD45 (isoGHIJABCDEF) and subsequently found in every genome-sequenced isoprene-degrader, provides the ideal basis for molecular studies on the distribution and diversity of isoprene-degrading communities. Further investigations of isoprene-emitting microbes, such as the influence of environmental factors and geographical location, must also be considered when attempting to constrain estimates of the flux of isoprene in aquatic ecosystems. We also report isoprene emission by the scleractinian coral Acropora horrida and the degradation of isoprene by the same coral holobiont, which highlights the importance of better understanding the cycling of isoprene in marine environments.

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水生生态系统中异戊二烯循环的微生物学研究

异戊二烯(2-甲基-1,3-丁二烯)大量排放(>500 Tg C -1)。大多数异戊二烯是由树木排放的，但对异戊二烯来源的多样性仍有不完全的了解。异戊二烯在大气中的反应性对全球变暖和全球变冷都有潜在影响，城市地区异戊二烯引起的臭氧形成也会对人类健康产生影响。陆地环境的异戊二烯排放已经研究了多年，但我们对水生异戊二烯排放的了解尚不完整。几个丰富的浮游植物类群在实验室中产生异戊二烯，叶绿素a和异戊二烯产生之间的关系已被用来估计海洋环境的排放量。本文综述的目的是强调水生环境在异戊二烯生物循环中的作用，并促进海洋和淡水环境中异戊二烯代谢的进一步研究。从微生物生态学的角度来看，异戊二烯代谢基因簇首先在Rhodococcus sp. AD45 (isoGHIJABCDEF)中被发现，随后在所有异戊二烯降解生物基因组中都被发现，为研究异戊二烯降解群落的分布和多样性提供了理想的分子基础。在试图限制对水生生态系统中异戊二烯通量的估计时，还必须考虑对异戊二烯排放微生物的进一步调查，例如环境因素和地理位置的影响。我们还报道了核状珊瑚Acropora horda的异戊二烯排放和相同珊瑚全息生物对异戊二烯的降解，这突出了更好地了解海洋环境中异戊二烯循环的重要性。

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

Aquatic Microbial Ecology 环境科学-海洋与淡水生物学

CiteScore

3.30

自引率

0.00%

发文量

审稿时长

3.0 months

期刊介绍： AME is international and interdisciplinary. It presents rigorously refereed and carefully selected Research Articles, Reviews and Notes, as well as Comments/Reply Comments (for details see AME 27:209), Opinion Pieces (previously called ''As I See It'') and AME Specials. For details consult the Guidelines for Authors. Papers may be concerned with: Tolerances and responses of microorganisms to variations in abiotic and biotic components of their environment; microbial life under extreme environmental conditions (climate, temperature, pressure, osmolarity, redox, etc.). Role of aquatic microorganisms in the production, transformation and decomposition of organic matter; flow patterns of energy and matter as these pass through microorganisms; population dynamics; trophic interrelationships; modelling, both theoretical and via computer simulation, of individual microorganisms and microbial populations; biodiversity. Absorption and transformation of inorganic material; synthesis and transformation of organic material (autotrophic and heterotrophic); non-genetic and genetic adaptation; behaviour; molecular microbial ecology; symbioses.