TY - JOUR
T1 - Using analytical ultracentrifugation to study compositional variation in vertebrate genomes
AU - Clay, Oliver
AU - Douady, Christophe J.
AU - Carels, Nicolas
AU - Hughes, Sandrine
AU - Bucciarelli, Giuseppe
AU - Bernardi, Giorgio
N1 - Funding Information:
Acknowledgements We thank Salvatore Bocchetti for expert work on the XL-A, Giacomo Bernardi, Adam Pavlícˇ ek, Gabriel Macaya, Carl W. Schmid, Kamel Jabbari, Francois Catzeflis, Ralph Chamberlin, Laura Giangiacomo, Tom Laue and Peter Schuck for helpful discussions and information, John E. Hearst for clarifications, Stéphane Cruveiller and Borries Demeler for XL-A and software advice, and many people for contributing DNA samples. This work was funded by TMR grant FRMX-CT98-0221 from the European Community.
Copyright:
Copyright 2008 Elsevier B.V., All rights reserved.
PY - 2003/8
Y1 - 2003/8
N2 - Although much attention has recently been directed to analytical ultracentrifugation (AUC), the revival of interest has hardly addressed the applications of this technology in genome analysis, and the extent to which AUC studies can quickly and effectively complement modern sequence-based analyses of genomes, e.g. by anticipating, extending or checking results that can be obtained by cloning and sequencing. In particular, AUC yields a quick overview of the base compositional structure of a species' genome even if no DNA sequences are available and the species is unlikely to be sequenced in the near future. The link between AUC and DNA sequences dates back to 1959, when a precise linear relation was discovered between the GC (guanine + cytosine) level of DNA fragments and their buoyant density in CsCl as measured at sedimentation equilibrium. A 24-hour AUC run of a high molecular weight sample of a species' total DNA already yields the GC distribution of its genome. AUC methods based on this principle remain sensitive tools in the age of genomics, and can now be fine-tuned by comparing CsCl absorbance profiles with the corresponding sequence histograms. The CsCl profiles of vertebrates allow insight into structural and functional properties that correlate with base composition, and their changes during vertebrate evolution can be monitored by comparing CsCl profiles of different taxa. Such comparisons also allow consistency checks of phylogenetic hypotheses at different taxonomic levels. We here discuss some of the information that can be deduced from CsCl profiles, with emphasis on mammalian DNAs.
AB - Although much attention has recently been directed to analytical ultracentrifugation (AUC), the revival of interest has hardly addressed the applications of this technology in genome analysis, and the extent to which AUC studies can quickly and effectively complement modern sequence-based analyses of genomes, e.g. by anticipating, extending or checking results that can be obtained by cloning and sequencing. In particular, AUC yields a quick overview of the base compositional structure of a species' genome even if no DNA sequences are available and the species is unlikely to be sequenced in the near future. The link between AUC and DNA sequences dates back to 1959, when a precise linear relation was discovered between the GC (guanine + cytosine) level of DNA fragments and their buoyant density in CsCl as measured at sedimentation equilibrium. A 24-hour AUC run of a high molecular weight sample of a species' total DNA already yields the GC distribution of its genome. AUC methods based on this principle remain sensitive tools in the age of genomics, and can now be fine-tuned by comparing CsCl absorbance profiles with the corresponding sequence histograms. The CsCl profiles of vertebrates allow insight into structural and functional properties that correlate with base composition, and their changes during vertebrate evolution can be monitored by comparing CsCl profiles of different taxa. Such comparisons also allow consistency checks of phylogenetic hypotheses at different taxonomic levels. We here discuss some of the information that can be deduced from CsCl profiles, with emphasis on mammalian DNAs.
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U2 - 10.1007/s00249-003-0294-y
DO - 10.1007/s00249-003-0294-y
M3 - Research Article
C2 - 12684711
AN - SCOPUS:0041357134
SN - 0175-7571
VL - 32
SP - 418
EP - 426
JO - European Biophysics Journal
JF - European Biophysics Journal
IS - 5
ER -