Abstract
Molecular phylogenetics of Bivalvia mainly inferred
from nuclear ribosomal and COI sequences, though
yielding some valuable results, has not resolved
important questions like, e.g., the relationships of the
major taxa. Complete mitochondrial genome sequences
are valuable sources for phylogenetic signal providing
both nucleotide and genomic data, i.e. gene content and
gene order. Contrasting vertebrates and arthropods,
molluscan mitochondrial gene order varies
considerably, especially within the Bivalvia. We present
phylogenetic analyses of complete mitochondrial
genomes of 18 bivalve and 16 other molluscan species.
The gene order in Bivalvia is highly heterogeneous.
Even closely related species show several
rearrangements, and none except for Nucula, the single
protobranch representative, resembles the putative
plesiomorphic condition in molluscs. With the Nucula
gene order differing by only two rearrangements from
that of the polyplacophoran Katharina, the high
rearrangement rates must have arisen within Bivalvia.
Consequently, phylogenetic inference using gene order
data with the present taxon sample and analysis methods
yield unreliable results. Maximum likelihood and
Bayesian inference of nucleotide and amino acid data
yield robust Autobranchia, Pteriomorpha, and
Heterodonta. Bivalve monophyly is not supported as
Nucula clusters with Haliotis and Katharina at the base
of the tree. This notable similarity of gene order and
sequence trees suggests a rate correlation of nucleotide
substitutions and gene rearrangements. Given these
initial results, what can mitochondrial genomics do for
bivalve phylogeny? The trees based on the combined
sequences of the protein coding genes yield much better
results than studies using COI alone and match those
based on 18S rRNA and morphology data. Especially
within the Heterodonta the resolution is likely to be
superior to all other available data sets. Little hope
remains, however, that gene order data will resolve the
sistergroup of bivalves. Improving both the taxon
sampling and analysis methods will show the taxonomic
level - or time window - gene order data contain robust
phylogenetic signal. With a growing number of
complete genomes, in particular that of closely related
species, additional genomic characters, such as gene
duplication and loss, rearrangement hotspots, and
occurrence of doubly uniparental inheritance, are likely
to be assessed.
Originalsprache | Englisch |
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Seiten (von - bis) | 327 |
Seitenumfang | 1 |
Fachzeitschrift | Organisms Diversity & Evolution |
Jahrgang | 6 |
Ausgabenummer | 4 |
Publikationsstatus | Veröffentlicht - 2006 |
ÖFOS 2012
- 106023 Molekularbiologie