Saltmarsh Boundary Modulates Dispersal of Mangrove Propagules: Implications for Mangrove Migration with Sea-level Rise

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2015 Mar 12

PMID 25760867

Citations 4

Authors

Jennifer M Peterson

Susan S Bell

Affiliations

Soon will be listed here.

Abstract

Few studies have empirically examined the suite of mechanisms that underlie the distributional shifts displayed by organisms in response to changing climatic condition. Mangrove forests are expected to move inland as sea-level rises, encroaching on saltmarsh plants inhabiting higher elevations. Mangrove propagules are transported by tidal waters and propagule dispersal is likely modified upon encountering the mangrove-saltmarsh ecotone, the implications of which are poorly known. Here, using an experimental approach, we record landward and seaward dispersal and subsequent establishment of mangrove propagules that encounter biotic boundaries composed of two types of saltmarsh taxa: succulents and grasses. Our findings revealed that propagules emplaced within saltmarsh vegetation immediately landward of the extant mangrove fringe boundary frequently dispersed in the seaward direction. However, propagules moved seaward less frequently and over shorter distances upon encountering boundaries composed of saltmarsh grasses versus succulents. We uniquely confirmed that the small subset of propagules dispersing landward displayed proportionately higher establishment success than those transported seaward. Although impacts of ecotones on plant dispersal have rarely been investigated in situ, our experimental results indicate that the interplay between tidal transport and physical attributes of saltmarsh vegetation influence boundary permeability to propagules, thereby directing the initial phase of shifting mangrove distributions. The incorporation of tidal inundation information and detailed data on landscape features, such as the structure of saltmarsh vegetation at mangrove boundaries, should improve the accuracy of models that are being developed to forecast mangrove distributional shifts in response to sea-level rise.

Citing Articles

Assessment the Impacts of Sea-Level Changes on Mangroves of Ceará-Mirim Estuary, Northeastern Brazil, during the Holocene and Anthropocene.

Nunes S, Franca M, Cohen M, Pessenda L, Rodrigues E, Magalhaes E Plants (Basel). 2023; 12(8).

PMID: 37111944 PMC: 10141466. DOI: 10.3390/plants12081721.

Tropical cyclones and the organization of mangrove forests: a review.

Krauss K, Osland M Ann Bot. 2019; 125(2):213-234.

PMID: 31603463 PMC: 7442392. DOI: 10.1093/aob/mcz161.

Microspatial ecotone dynamics at a shifting range limit: plant-soil variation across salt marsh-mangrove interfaces.

Yando E, Osland M, Hester M Oecologia. 2018; 187(1):319-331.

PMID: 29497834 DOI: 10.1007/s00442-018-4098-2.

Contrasting Effects of Historical Sea Level Rise and Contemporary Ocean Currents on Regional Gene Flow of Rhizophora racemosa in Eastern Atlantic Mangroves.

Ngeve M, Van der Stocken T, Menemenlis D, Koedam N, Triest L PLoS One. 2016; 11(3):e0150950.

PMID: 26964094 PMC: 4786296. DOI: 10.1371/journal.pone.0150950.

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