Access the full text.
Sign up today, get DeepDyve free for 14 days.
(2006)
Plant genetic resources: foodgrain crops
(1993)
Development, current and future research strategies on finger millet in Zimbabwe
(1989)
Cropping systems, production technology, pests and diseases of finger millet in Uganda
Ibpgr (1985)
Descriptors for finger millet
M. Dida, Srinivasachary, S. Ramakrishnan, J. Bennetzen, M. Gale, K. Devos (2006)
The genetic map of finger millet, Eleusine coracanaTheoretical and Applied Genetics, 114
(1993)
Present status of small millets production in India
S. Neves, G. Swire-Clark, K. Hilu, W. Baird (2005)
Phylogeny of Eleusine (Poaceae: Chloridoideae) based on nuclear ITS and plastid trnT-trnF sequences.Molecular phylogenetics and evolution, 35 2
(1996)
Lost crops of Africa, volume I. Grains
L. M'ragwa, C. Watson (1994)
Registration of ‘KAT/PM‐1’ Pearl MilletCrop Science, 34
Kejun Liu, S. Muse (2005)
PowerMarker: an integrated analysis environment for genetic marker analysisBioinformatics, 21 9
KE Prasada Rao, JMJ Wet (1997)
Biodiversity in trust
L. M'ragwa, C. Watson (1994)
Registration of ‘KAT/FM-1’ Finger MilletCrop Science, 34
J. Pritchard, Matthew Stephens, P. Donnelly (2000)
Inference of population structure using multilocus genotype data.Genetics, 155 2
A. Seetharam, K. Riley, G. Harinarayana (1990)
Small Millets in Global Agriculture
J. Wet, C. Newell, D. Brink (1984)
COUNTERFEIT HYBRIDS BETWEEN TRIPSACUM AND ZEA (GRAMINEAE)American Journal of Botany, 71
FR Muza, DJ Lee, DJ Andrews, SC Gupta (1995)
Mitochondrial DNA variation in finger millet (Eleusine coracana)Euphytica, 81
Tasmanian Fishery (2005)
Assessment of the
K. Hilu, J. Wet, J. Harlan (1979)
ARCHAEOBOTANICAL STUDIES OF ELEUSINE CORACANA SSP. CORACANA (FINGER MILLET)American Journal of Botany, 66
F. Muza, D. Lee, D. Andrews, S. Gupta (2004)
Mitochondrial DNA variation in finger millet (Eleusine coracana L. Gaertn)Euphytica, 81
W. Barbeau, K. Hilu (1993)
Protein, calcium, iron, and amino acid content of selected wild and domesticated cultivars of finger milletPlant Foods for Human Nutrition, 43
KW Hilu, JMJ Wet, JR Harlan (1979)
Archaeobotanical studies of Eleusine coracana ssp. coracanaAm J Bot, 66
J. Wet, K. Rao, D. Brink, M. Mengesha (1984)
Systematics and evolution of Eleusine coracana (Gramineae)American Journal of Botany, 71
C. Werth, K. Hilu, C. Langner (1994)
Isozymes of Eleusine (Gramineae) and the Origin of Finger MilletAmerican Journal of Botany, 81
K. Hilu, J. Johnson (1992)
Ribosomal DNA variation in finger millet and wild species of Eleusine (Poaceae)Theoretical and Applied Genetics, 83
S. Tanksley, S. McCouch (1997)
Seed banks and molecular maps: unlocking genetic potential from the wild.Science, 277 5329
S. Tanksley, James Nelson (1996)
Advanced backcross QTL analysis: a method for the simultaneous discovery and transfer of valuable QTLs from unadapted germplasm into elite breeding linesTheoretical and Applied Genetics, 92
K. Hilu, J. Wet (1976)
Racial evolution in Eleusine coracana ssp. coracana (finger milletAmerican Journal of Botany, 63
(1986)
Incorporation of blast resistance to Indian elite finger millet cultivars from African cultivar
(1993)
PHYLIP (Phylogeny Inference Package) version 3.5c
(1993)
Improvement of finger millet in Uganda
S. Salimath, A. Oliveira, I. Godwin, J. Bennetzen (1995)
Assessment of genome origins and genetic diversity in the genus Eleusine with DNA markers.Genome, 38 4
K. Riley (1993)
Advances in small millets
A genotypic analysis of 79 finger millet accessions (E. coracana subsp. coracana) from 11 African and five Asian countries, plus 14 wild E. coracana subsp. africana lines collected in Uganda and Kenya was conducted with 45 SSR markers distributed across the finger millet genome. Phylogenetic and population structure analyses showed that the E. coracana germplasm formed three largely distinct subpopulations, representing subsp. africana, subsp. coracana originating from Africa and subsp. coracana originating from Asia. A few lines showed admixture between the African and Asian cultivated germplasm pools and were the result of either targeted or accidental intercrossing. Evidence of gene flow was also seen between the African wild and cultivated subpopulations, indicating that hybridizations among subspecies occur naturally where both species are sympatric. The genotyping, combined with phylogenetic and population structure analyses proved to be very powerful in predicting the origin of breeding materials. The genotypic study was complemented by a phenotypic evaluation. The wild and cultivated accessions differed by a range of domestication-related characters, such as tiller number, plant height, peduncle length, seed color and grain yield. Significant differences in plant architecture and yield were also identified between the Asian and African subpopulations. The observed population structure within cultivated finger millet is consistent with the theory that, after the introduction of finger millet from Africa into India via the trade routes some 3000 years ago, the two germplasm pools remained largely isolated until recent times. The significantly lower diversity present within the Asian subpopulation also suggests that it arose from a relatively small number of founder plants.
Tropical Plant Biology – Springer Journals
Published: Jun 18, 2008
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.