Biology Reference
In-Depth Information
Kholova J, Hash CT, Lava Kumar P, Yadav SR, KocovĀ“aM,
Vadez V. 2010a. Terminal drought-tolerant pearl millet
[
Pennisetum glaucum
(L.) R. Br.] have high leaf ABA and
limit transpiration at high vapor pressure deficit. Journal
of Exerimental Botany 61(5), 1431-1440.
Kholova J, Nepolean T, Hash CT, Supriya A, Rajaram V,
Senthilvel S, Kakkera A, Yadav RS, Vadez V. 2012.
Water saving traits co-map with a major terminal drought
tolerance quantitative trait locus in pearl millet (
Pen-
nisetum glaucum
(L.) R. Br.). Molecular Breeding DOI:
10.1007/s11032-012-9720-0.
Kim JS, Klein PE, Klein RR, Price HJ, Mullet JE and Stelly
DM. 2005. Chromosome identification and nomenclature
of
Sorghum bicolor
. Genetics 169:1169-1173.
Ludlow MM, Muchow RC. 1990. A critical evaluation of
traits for improving crop yields in water-limited environ-
ments. Advances in Agronomy 43, 107-153.
Mace ES and Jordan DR. 2010. Location of major effect
genes in sorghum (
Sorghum bicolor
(L.) Moench). The-
oretical and Applied Genetics, 121: 1339-1356.
Mackay AD, Barber SA 1986. Effect of nitrogen on root
growth of two genotypes in the field. Agronomy Journal
78, 699-703.
Mackill DJ, Ni J. 2000. Molecular mapping and marker
assisted selection for major-gene traits in rice. In: Khush
GS, Brar DS, Hardy B (eds.) Proc. Fourth International
Rice Genetics Symposium. International Rice Research
Institute, Los Ba nos, The Philippines, pp. 137-151.
Mahalakshmi V, Bidinger FR. 2002. Evaluation of stay-green
sorghum germplasm lines at ICRISAT. Crop Science
42(3), 965-974.
Manschadi AM, Christopher JT, Peter deVoil P, Hammer GL.
2006. The role of root architectural traits in adaptation
of wheat to water-limited environments. Functional Plant
Biology 33, 823-837.
McBee BB, Waskom RM, Miller FR, Creelman RA. 1983.
Effect of senescence and non-senescence on carbohy-
drates in sorghum during late kernel maturity states. Crop
Science 23, 372-376.
McBee GG, Miller FR. 1982. Carbohydrates in sorghum
culms as influenced by cultivars, spacing, and maturity
over a diurnal period. Crop Science 22, 381-385.
Mohler V, Singrun C. 2004. General considerations: Marker-
assisted selection. In: Lorz H, Wenzel G (eds.) Biotech-
nology in Agriculture and Forestry, Vol. 55: Molecular
Marker Systems. Springer, Berlin, pp. 305-317.
Mutava RN, Prasad PVV, Tuinstra MR, Kofoid KD, Yu
J. 2011. Characterization of sorghum genotypes for
traits related to drought tolerance. Field Crops Research
123(1), 10-18. doi: 10.1016/j.fcr.2011.04.006.
Nakamura T, Adu-Gyamfi JJ, Yamamoto A, Ishikawa S,
Nakano H, Ito O. 2002. Varietal differences in root growth
as related to nitrogen uptake by sorghum plants in low-
nitrogen environment. Plant and Soil 245, 17-24.
NelsonJC,WangS,WuY,LiX,AntohyG,WhiteFF,
Yu J. 2011. Single-nucleotide polymorphism discov-
ery by high-throughput sequencing in sorghum. BMC
Genomics 2011, 12:352.
http://www.biomedcentral.com
/1471-2164/12/352
Ougham H, Hortensteiner S, Armstead I, Donnison I, King
I, Thomas H, Mur L. 2008. The control of chlorophyll
catabolism and the status of yellowing as a biomarker of
leaf senescence. Plant Biology 10(Suppl. 1), 4-14.
Ozsolak F, Milos MM. 2011. RNA sequencing: Advances,
challenges and opportunities. Nature Reviews Genetics
12, 87-98.
Paterson AH, Bowers JE, Bruggmann R, Dubchak I, Grim-
wood J, Gundlach H, Haberer G, Hellsten U, Mitros T,
Poliakov A, Schmutz J, Spannagl M, Tang H, Wang X,
Wicker T, Bharti AK, Chapman J, Feltus FA, Gowik U,
Grigoriev IV, Lyons E, Maher CA, Martis M, Narecha-
nia A, Otillar RP, Penning BW, Salamov AA, Wang Y,
Zhang L, Carpita NC, Freeling M, Gingle AR, Hash CT,
Keller B, Klein P, Kresovich S, McCann MC, Ming R,
Peterson DG, Mehboob-ur-Rahman, Ware D, Westhoff P,
Mayer KFX, Messing J, Rokhsar DS. 2009. The
Sorghum
bicolor
genome and the diversification of grasses. Nature
457, 551-556.
Peleg ZV, Reguera M, Tumimbang E, Walia H, Blumwald
E. 2011. Cytokinin-mediated source/sink modifications
improve drought tolerance and increase grain yield in
rice under water-stress. Plant Biotechnology Journal, 1-
12. doi: 10.1111/j.1467-7652.2010.00584.x.
Rajcan I, Tollenaar M. 1999a. Source:sink ratio and leaf
senescence in maize. I. Dry matter accumulation and
partitioning during kernel filling. Field Crops Research
60, 245-253.
Rajcan I, Tollenaar M. 1999b. Source:sink ratio and leaf
senescence in maize. II. Nitrogen metabolism during ker-
nel filling. Field Crops Research 60, 255-265.
Ramu P, Deshpande SP, Senthilvel S, Jayashree B, Billot C,
Deu M, Reddy LA, Hash CT. 2010.
In silico
mapping
of important genes and markers available in the public
domain for efficient sorghum breeding. Molecular Breed-
ing 26, 409-418.
Ratnakumar P, Vadez V. 2011. Groundnut (
Arachis
hypogaea
L.) genotypes tolerant to intermittent drought
maintain a high harvest index and have small leaf canopy
under stress. Functional Plant Biology 38, 1016-1023.
Reddy BVS, Ramesh S, Sanjana Reddy P, Ashok Kumar
A. 2009. Genetic options for drought management in
sorghum. Plant Breeding Reviews 31:189-222.
Reymond M, Muller B, Leonardi A, Charcosset A, Tardieu
F. 2003. Combining quantitative trait loci analysis
and an ecophysiological model to analyze the genetic
variability of the responses of maize leaf growth to
temperature and water deficit. Plant Physiology 131,
664-675.
Rivero RM, Kojima M, Gepstein A, Sakakibara H, Mittler R,
Gepstein S, Blumwald E. 2007. Delayed leaf senescence
induces extreme drought tolerance in a flowering plant.
Proceedings of the National Academy of Sciences (USA)
104, 19631-19636.
Search WWH ::
Custom Search