TY - JOUR
T1 - The granule-bound starch synthase (GBSSI) gene in the Rosaceae
T2 - Multiple loci and phylogenetic utility
AU - Evans, Rodger C.
AU - Alice, Lawrence A.
AU - Campbell, Christopher S.
AU - Kellogg, Elizabeth A.
AU - Dickinson, Timothy A.
N1 - Funding Information:
The authors are grateful to Roberta Mason-Gamer and Sarah Mathews for sharing their expertise in cloning and sequencing of single-copy genes, discussion of Southern results, and comments on early versions of the manuscript; two anonymous reviewers for their thorough reviews and many useful comments; Bess Wong and Neil Straus from the Department of Botany at the University of Toronto for their expertise and help with the Southern hybridization analysis and for reading an early draft of the manuscript; Stephen Palumbi and lab from Harvard’s Department of Organismal and Evolutionary Biology for use of their ABI377 automated sequencer; Patty Singer of the DNA Sequencing Facility at the University of Maine for technical advice and sequencing; and Wesley A. Wright for help with data collection. This research was supported by a University of Toronto Open Fellowship and funds from the Department of Botany to R.C.E., UMaine Association of Graduate Students Research grant to L.A.A., National Science Foundation Grant DEB-9806945 and Maine Agricultural and Forestry Experiment Station (MAFES) grant to C.S.C., National Science Foundation Grant DEB-9419748 to E.A.K., and Natural Sciences and Engineering Research Council of Canada Research Grant A3430 to T.A.D. This is Contribution Number 157 from the ROM Centre for Biodiversity and Conservation Biology and MAFES external publication number 2430.
PY - 2000
Y1 - 2000
N2 - We sampled the 5′ end of the granule-bound starch synthase gene (GBSSI or waxy) in Rosaceae, sequencing 108 clones from 18 species in 14 genera representing all four subfamilies (Amygdaloideae, Maloideae, Rosoideae, and Spiraeoideae), as well as four clones from Rhamnus catharticus (Rhamnaceae). This is the first phylogenetic study to use the 5′ portion of this nuclear gene. Parsimony and maximum-likelihood analyses of 941 bases from seven complete and two partial exons demonstrate the presence of two loci (GBSSI-1 and GBSSI-2) in the Rosaceae. Southern hybridization analyses with locus-specific probes confirm that all four Rosaceae subfamilies have at least two GBSSI loci, even though only one locus has been reported in all previously studied diploid flowering plants. Phylogenetic analyses also identify four clades representing four loci in the Maloideae. Phylogenetic relationships inferred from GBSSI sequences are largely compatible with those from chloroplast (cpDNA: ndhF, rbcL) and nuclear ribosomal internal transcribed spacer (nrITS) DNA. Large clades are marked by significant intron variation: a long first intron plus no sixth intron in Maloideae GBSSI-1, a long fourth intron in Rosoideae GBSSI-1, and a GT to GC mutation in the 5′ splice site of the fourth intron in all GBSSI-2 sequences. Our data do not support the long-held hypothesis that Maloideae originated from an ancient hybridization between amygdaloid and spiraeoid ancestors. Instead, Spiraeoideae genera (Kageneckia and Vauquelinia) are their closest relatives in all four GBSSI clades.
AB - We sampled the 5′ end of the granule-bound starch synthase gene (GBSSI or waxy) in Rosaceae, sequencing 108 clones from 18 species in 14 genera representing all four subfamilies (Amygdaloideae, Maloideae, Rosoideae, and Spiraeoideae), as well as four clones from Rhamnus catharticus (Rhamnaceae). This is the first phylogenetic study to use the 5′ portion of this nuclear gene. Parsimony and maximum-likelihood analyses of 941 bases from seven complete and two partial exons demonstrate the presence of two loci (GBSSI-1 and GBSSI-2) in the Rosaceae. Southern hybridization analyses with locus-specific probes confirm that all four Rosaceae subfamilies have at least two GBSSI loci, even though only one locus has been reported in all previously studied diploid flowering plants. Phylogenetic analyses also identify four clades representing four loci in the Maloideae. Phylogenetic relationships inferred from GBSSI sequences are largely compatible with those from chloroplast (cpDNA: ndhF, rbcL) and nuclear ribosomal internal transcribed spacer (nrITS) DNA. Large clades are marked by significant intron variation: a long first intron plus no sixth intron in Maloideae GBSSI-1, a long fourth intron in Rosoideae GBSSI-1, and a GT to GC mutation in the 5′ splice site of the fourth intron in all GBSSI-2 sequences. Our data do not support the long-held hypothesis that Maloideae originated from an ancient hybridization between amygdaloid and spiraeoid ancestors. Instead, Spiraeoideae genera (Kageneckia and Vauquelinia) are their closest relatives in all four GBSSI clades.
UR - https://www.scopus.com/pages/publications/0034514038
U2 - 10.1006/mpev.2000.0828
DO - 10.1006/mpev.2000.0828
M3 - Article
C2 - 11133193
AN - SCOPUS:0034514038
SN - 1055-7903
VL - 17
SP - 388
EP - 400
JO - Molecular Phylogenetics and Evolution
JF - Molecular Phylogenetics and Evolution
IS - 3
ER -