Rhizophora zonation, salinity, and nutrients in the western atlantic

Rhizophora is the dominant genus of mangrove forests on the Atlantic coast of northern South America. What determines the zonation frequently observed in sympatric populations of the two neotropical species, R. mangle and R. racemosa, and their hybrids, R. × harrisonii, is an open question. The most...

Full description

Saved in:
Bibliographic Details
Published in:Biotropica 2021-03, Vol.53 (2), p.384-396
Main Authors: Cerón‐Souza, Ivania, Barreto, María Beatriz, Barreto‐Pittol, Eduardo, Silva, Angie, Feliner, Gonzalo N., Medina, Ernesto
Format: Article
Language:English
Subjects:
Aluminum
Animal behavior
Brackishwater environment
Bulk density
Calcium
Chemical composition
Estuaries
Hybrids
Intertidal environment
Intertidal zone
Iron
Leaves
Magnesium
Manganese
Mangrove soils
Mangrove swamps
Mangroves
Microsatellites
Nutrients
Organic matter
Paria Gulf
Plant cover
Questions
Rhizophora
Rhizophora mangle
Salinity
Salinity effects
Salinity tolerance
Soil
stable isotopes
Sympatric populations
Sympatry
Taxonomy
Trees
Zonation
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Rhizophora is the dominant genus of mangrove forests on the Atlantic coast of northern South America. What determines the zonation frequently observed in sympatric populations of the two neotropical species, R. mangle and R. racemosa, and their hybrids, R. × harrisonii, is an open question. The most widely held hypothesis is that differences in salinity tolerance among the taxonomic groups explain the observed zonation. To address this question, we analyzed the elemental composition of soils and canopy leaves from 60 Rhizophora spp. trees distributed in different intertidal zones of an estuarine site of the Paria Gulf, Venezuela. The low intertidal zone showed lower salinity, organic matter, C, N, S, and Na, and higher bulk density, Al, Fe, and Mn concentrations compared with the higher intertidal zones. Using morphological characters and microsatellite molecular markers, we identified 39 pure R. mangle, 19 hybrids, and only two pure R. racemosa. We found that both intertidal position and taxonomic groups explained most of the differences in leaf variables measured across trees. The ratio Mg/Ca, however, was higher in R. mangle than in R. racemosa and hybrids regardless of intertidal position. Moreover, at some specific intertidal position, R. mangle differed from R. racemosa and hybrids in the values of C, N, K, Mg, Fe, Mn, C/N, K/Ca, S/Ca, and δ13C. We conclude that despite the scarcity of R. racemosa and the absence of a clear species zonation, our results suggest that R. mangle copes with salinity differently than R. racemosa and R. × harrisonii. Rhizophora is the dominant genus of mangrove forests on the Atlantic coast of northern South America. What determines the zonation frequently observed in sympatric populations of the two neotropical species, R. mangle and R. racemosa, and their hybrids, R. × harrisonii, is an open question. The most widely held hypothesis is that differences in salinity tolerance among the taxonomic groups explain the observed zonation. To address this question, we analyzed the elemental composition of soils and canopy leaves from 60 Rhizophora spp. trees distributed in different intertidal zones of an estuarine site of the Paria Gulf, Venezuela. Using morphological characters and microsatellite molecular markers, we identified 39 pure R. mangle, 19 hybrids, and only two pure R. racemosa. We found that both intertidal position and taxonomic groups explained most of the differences in leaf variables measured across trees. The r
ISSN:0006-3606
1744-7429
DOI:10.1111/btp.12924