The Genetic Diversity of the Macrophyte Ceratophyllum demersum in Backwaters Reflects Differences in the Hydrological Connectivity and Water Flow Rate of Habitats

The Genetic Diversity of the Macrophyte Ceratophyllum demersum in Backwaters Reflects Differences in the Hydrological Connectivity and Water Flow Rate of Habitats

Macrophytes often live in fluvial backwaters that have a variety of hydrological connections to a main river. Since the ability of these plants to adapt to changing environments may depend on the genetic diversity of the populations, it is important to know whether it can be influenced by habitat ch...

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Bibliographic Details
Published in:Plants (Basel) Vol. 13; no. 16; p. 2220
Main Authors: Engloner, Attila I, Németh, Kitti, Bereczki, Judit
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 10-08-2024
MDPI
Subjects:
Aquatic plants
Backwaters
Biodiversity
Ceratophyllum demersum
Changing environments
Climate change
Connectivity
DNA polymerase
Environmental changes
Flow rates
gene flow
Gene polymorphism
Genetic diversity
Genetic variability
Habitat fragmentation
Habitats
hydrochory
Hydrology
Investigations
Macrophytes
microsatellite polymorphism
Microsatellites
Monte Carlo simulation
Plant diversity
Polymorphism
Population
Population genetics
Populations
Rivers
Statistical analysis
submerged macrophyte
Water
Water flow
gene flow
microsatellite polymorphism
submerged macrophyte
hydrochory
habitat fragmentation
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Summary:Macrophytes often live in fluvial backwaters that have a variety of hydrological connections to a main river. Since the ability of these plants to adapt to changing environments may depend on the genetic diversity of the populations, it is important to know whether it can be influenced by habitat characteristics. We examined the microsatellite polymorphism of the submerged macrophyte from various backwaters and showed that the genetic diversity of this plant clearly reflects habitat hydrological differences. The greatest genetic variability was found in a canal system where constant water flow maintained a direct connection between the habitats and the river. In contrast, an isolated backwater on the protected side of the river had the lowest plant genetic diversity. Oxbows permanently connected to the branch system with static or flowing water, and former river branches temporarily connected to the main bed contained populations with moderately high or low genetic variability. The results demonstrate that habitat fragmentation can be a result not only of the loss of direct water contact, but also of the lack of flowing water. Adverse hydrological changes can reduce the genetic diversity of populations and thus the ability of this macrophyte to adapt to changing environments.
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ISSN:2223-7747
2223-7747
DOI:10.3390/plants13162220