Phylogenetic relationships in Selaginellaceae based on RBCL sequences

A phylogenetic framework is developed for the clubmoss family Selaginellaceae based on maximum parsimony analyses of molecular data. The chloroplast gene rbcL was sequenced for 62 species, which represent nearly 10% of living species diversity in the family. Taxa were chosen to reflect morphological...

Full description

Saved in:
Bibliographic Details
Published inAmerican journal of botany Vol. 89; no. 3; pp. 506 - 517
Main Authors Korall, Petra, Kenrick, Paul
Format Journal Article
LanguageEnglish
Published United States Botanical Soc America 01.03.2002
Botanical Society of America
Botanical Society of America, Inc
Subjects
Biological taxonomies
Botany
Classification
Genetics
lycopod
Mosses
Parsimony
Phylogenetics
Phylogeny
Plant morphology
Plants
Polymerase chain reaction
rbcL
Resurrection
resurrection plant
rubisco
Selaginellaceae
Species diversity
Systematics
Taxa
xerophyte
Online AccessGet full text

Cover

More Information
Summary:A phylogenetic framework is developed for the clubmoss family Selaginellaceae based on maximum parsimony analyses of molecular data. The chloroplast gene rbcL was sequenced for 62 species, which represent nearly 10% of living species diversity in the family. Taxa were chosen to reflect morphological, geographical, and ecological diversity. The analyses provide support for monophyly of subgenera Selaginella and Tetragonostachys. Stachygynandrum and Heterostachys are polyphyletic. Monophyly of Ericetorum is uncertain. Results also indicate a large number of new groupings not previously recognized on morphological grounds. Some of these new groups seem to have corresponding morphological synapomorphies, such as the presence of rhizophores (distinctive root-like structures), aspects of rhizophore development, and leaf and stem morphology. Others share distinctive ecological traits (e.g., xerophytism). For many groups, however, no morphological, ecological, or physiological markers are known. This could reflect patchy sampling and a lack of detailed knowledge about many species. Despite a lengthy fossil record dating from the Carboniferous Period, cladogram topology indicates that most of the living tropical species are probably the products of more recent diversifications. Resurrection plants, extreme xerophytes characterized by aridity-driven inrolling of branches and rapid revival on rehydration, have evolved at least three times in quite different clades.
Bibliography:petra.korall@botan.su.se
)
The authors thank S. Stefanovic (University of Washington, Seattle) for providing some important DNA extracts for this analysis, J. Therrien (University of Kansas, Lawrence) for providing an
sequence, the many other people who have contributed material to this study, and Catarina Rydin and Torsten Eriksson for comments on the manuscript. This work was financially supported by the Swedish Natural Science Research Council (NFR research grants to Paul Kenrick: B‐AA/BU 10728‐301, and to Paul Kenrick and PO Karis: B 1393/1999), and Helge Ax:son Johnsons Stiftelse (grant to Petra Korall).
Author for reprint requests
rbcL
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0002-9122
1537-2197
DOI:10.3732/ajb.89.3.506