Grow with the flow: Is phenotypic plasticity across hydrodynamic gradients common in seaweeds?

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Liam J. M. Coleman, Patrick T. Martone
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Abstract

Seaweeds are widely assumed to be phenotypically plastic across hydrodynamic gradients, yet while many marine macroalgae exhibit intraspecific phenotypic variation that correlates with flow, researchers often fail to test whether such variation is due to plasticity or another mechanism, such as local adaptation. In this minireview, we considered mechanisms for sensing flow in seaweeds that could facilitate adaptive phenotypic plasticity across hydrodynamic gradients. We then reviewed the literature from 1900 to 2024 to see how often phenotypic variation and plasticity across hydrodynamic gradients had been observed and demonstrated in different groups of seaweeds. In the last 124 years, phenotypic variation and plasticity in response to flow have been well documented in brown algae but scarcely documented in red and green algae. This could suggest that brown algae are better able to sense and respond to flow than red and green algae, perhaps due to the intercalary meristem of many brown algae, including most kelps. However, this skewed distribution could also be the result of publication bias, as most studies involving flow have been conducted on brown algae. Only 30% of 141 papers specifically investigated if observations of phenotypic variation along hydrodynamic gradients were due to plasticity. To date, phenotypic plasticity in response to flow has been demonstrated in 20 brown algal species, five red algal species, and two green algal species. Thus, the assumption that phenotypic plasticity to flow is common across seaweeds is not particularly well supported by the literature. Mechanisms underlying plasticity to flow are poorly understood and remain a critical avenue for future research.

Abstract Image

随波逐流:跨越水动力梯度的表型可塑性在海藻中常见吗?
人们普遍认为海藻具有跨越水动力梯度的表型可塑性,然而,虽然许多海洋大型藻类表现出与水流相关的种内表型变异,但研究人员往往无法检验这种变异是由于可塑性还是其他机制(如局部适应)造成的。在本小视图中,我们探讨了海藻感知水流的机制,这种机制可促进海藻跨越水动力梯度的适应性表型可塑性。然后,我们回顾了从 1900 年到 2024 年的文献,以了解在不同类别的海藻中观察和证明跨越水动力梯度的表型变异和可塑性的频率。在过去的 124 年中,褐藻的表型变异和对水流的可塑性得到了很好的记录,但红藻和绿藻的表型变异和可塑性却鲜有记录。这可能表明,与红藻和绿藻相比,褐藻对水流的感知和反应能力更强,这可能是由于许多褐藻(包括大多数海带)都有闰分生组织。不过,这种偏斜分布也可能是发表偏差造成的,因为大多数涉及水流的研究都是针对褐藻进行的。在141篇论文中,只有30%的论文专门研究了沿水力梯度观察到的表型变化是否是由于可塑性造成的。迄今为止,已有 20 个褐藻物种、5 个红藻物种和 2 个绿藻物种证实了表型对水流的可塑性。因此,认为表型对水流的可塑性在所有海藻中都很普遍的假设并没有得到文献的充分支持。人们对流动可塑性的机制了解甚少,这仍是未来研究的一个重要方向。
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
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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