Trade-offs and synergies in the structural and functional characteristics of leaves photosynthesizing in aquatic environments

Maberly, Stephen Christopher; Gontero, Brigitte. 2018 Trade-offs and synergies in the structural and functional characteristics of leaves photosynthesizing in aquatic environments. In: Adams, William W.; Terashima, Ichiro, (eds.) The leaf: a platform for performing photosynthesis. Cham, Switzerland, Springer, 307-343. (Advances in Photosynthesis and Respiration, 44).

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Official URL: https://doi.org/10.1007/978-3-319-93594-2_11

Abstract/Summary

Aquatic plants, comprising different divisions of embryophytes, derive from terrestrial ancestors. They have evolved to live in water, both fresh and salty, an environment that presents unique challenges and opportunities for photosynthesis and growth. These include, compared to air, a low water stress, a greater density, and attenuation of light, and a more variable supply of inorganic carbon, both in concentration and chemical species, but overall a lower carbon availability, and the opportunity to take up nutrients from the water. The leaves of many aquatic plants are linear, dissected, whorled, or cylindrical with a large volume of air spaces. They tend to have a high specific leaf area, thin cuticles, and usually lack functional stomata. Exploiting the availability of chemicals in their environment, freshwater macrophytes may incorporate silica in their cell wall, while seagrasses contain sulphated polysaccharides, similar to those of marine macroalgae; both groups have low lignin content. This altered cell wall composition produces plants that are more flexible and therefore more resistant to hydraulic forces (mechanical stress arising from water movement). Aquatic plants may have enhanced light harvesting complexes conferring shade adaptation, but also have mechanisms to cope with high light. Aquatic plants have evolved numerous strategies to overcome potential carbon-limitation in water. These include growing in micro-environments where CO2 is high, producing leaves and roots that exploit CO2 from the air or sediment and operating concentrating mechanisms that increase CO2 (CCM) around the primary carboxylating enzyme, ribulose-1,5-bisphosphate carboxylase-oxygenase. These comprise C4 metabolism, crassulacean acid metabolism, and the ability to exploit the often high concentrations of HCO3−, and ~50% of freshwater macrophytes and ~85% of seagrasses have one or more CCM. Many of these adaptations involve trade-offs between conflictin constraints and opportunities while others represent ‘synergies’ that help to maximize the productivity of this important group of plants.

Item Type:	Publication - Book Section
Digital Object Identifier (DOI):	https://doi.org/10.1007/978-3-319-93594-2_11
UKCEH and CEH Sections/Science Areas:	Water Resources (Science Area 2017-)
ISBN:	9783319935928
NORA Subject Terms:	Ecology and Environment Botany
Date made live:	08 Nov 2018 14:58 +0 (UTC)
URI:	https://nora.nerc.ac.uk/id/eprint/521442

Item Type:

Publication - Book Section

Digital Object Identifier (DOI):

https://doi.org/10.1007/978-3-319-93594-2_11

UKCEH and CEH Sections/Science Areas:

Water Resources (Science Area 2017-)

ISBN:

9783319935928

NORA Subject Terms:

Ecology and Environment
Botany

Date made live:

08 Nov 2018 14:58 +0 (UTC)