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Butterfield M, 2007.
Marker assisted breeding in sugarcane:
A complex polyploid
. PhD diss., University of Stellen-
bosch, 164 pp.
Campo Zabala RR, Perez Orama SG, 2010. A new nobili-
sation system in sugarcane (
Saccharum
spp.).
Proc. Int.
Soc. Sugar Cane Technol.
27, 1-4.
Carlson CS, Eberle MA, Kruglyak L, Nickerson DA, 2004.
Mapping complex disease loci in whole-genome asso-
ciation studies.
Nature
429, 446-452.
http://dx.doi.org/
10.1038/nature02623
Cheavegatti-Gianotto A, de Abreu H, Arruda P, Bespalhok
Filho J, Burnquist W, Creste S, di Ciero L, Ferro J, de
Oliveira Figueira A, de Sousa Filgueiras T, Grossi-de-
Sa M, Guzzo E, Hoffmann H, de Andrade Landell M,
Macedo N, Matsuoka S, de Castro Reinach F, Romano
E, da Silva W, de Castro Silva Filho M, Cesar Ulian
E, 2011. Sugarcane (
Saccharum
X
officinarum
): A ref-
erence study for the regulation of genetically modified
cultivars in Brazil.
Tropical Plant Biology
4, 62-89.
Chenu K, Chapman SC, Tardieu F, McLean G, Welcker
C, Hammer GL, 2009. Simulating the yield impacts of
organ-level quantitative trait loci associated with drought
response in maize: A 'gene-to-phenotype' modeling
approach.
Genetics
183, 1507-1523.
Cordeiro GM, Eliott F, McIntyre CL, Casu RE, Henry
RJ, 2006. Characterisation of single nucleotide poly-
morphisms in sugarcane ESTs.
Theoretical and Applied
Genetics
for rust resistance linked with a RFLP marker in sugar-
cane cultivar 'R570'.
Theoretical and Applied Genetics
92, 1059-1064.
http://dx.doi.org/10.1007/BF00224049
De Araujo LM, Moura FBP, 2011. Bioethanol's dirty foot-
print in Brazil.
Nature
469, 299-299.
http://dx.doi.org/
Devlin B, Roeder K, 1999. Genomic control for associa-
tion studies.
Biometrics
55, 997-1004.
http://dx.doi.org/
D'Hont A (2005) Unraveling the genome structure of poly-
ploids using FISH and GISH; examples of sugarcane and
banana.
Cytogenetic and Genome Research
109:27-33.
http://dx.doi.org/10.1159/000082378
D'Hont A, Grivet L, Feldmann P, Glaszmann J, Rao S, Berd-
ing N, 1996. Characterisation of the double genome struc-
ture of modern sugarcane cultivars (
Saccharum
spp.) by
molecular cytogenetics.
Molecular and General Genetics
250:405-413.
http://dx.doi.org/10.1007/BF02174028
D'Hont A, Paulet F, Glaszmann JC, 2002. Oligoclonal
interspecific origin of 'North Indian' and 'Chinese'
sugarcanes.
Chromosome Research
10:253-262.
http://
D'Hont A, Souza GM, Menossi M, Vincentz M, Van-Sluys
MA, Glaszmann JC, Ulian E, 2008. Sugarcane: A major
source of sweetness, alcohol, and bio-energy, In: Moore
PH, Ming R (eds)
Genomics of Tropical Crop Plants.
New York: Springer, pp. 483-513.
Dias M, da Cunha M, Maciel Filho R, Bonomi A, Jesus C,
Rossell C, 2011a. Simulation of integrated first and sec-
ond generation bioethanol production from sugarcane:
Comparison between different biomass pretreatment
methods.
Journal of Industrial Microbiology & Biotech-
nology
38, 955-966.
http://dx.doi.org/10.1007/s10295-
010-0867-6
Dias MOS, Junqueira TL, Cavalett Ov, Cunha MP, Jesus
CDF, Rossell CEV, Maciel Filho R, Bonomi A, 2011b.
Integrated versus stand-alone second generation ethanol
production from sugarcane bagasse and trash.
Biore-
source technology
103, 152-161.
http://www.science
Dingkuhn M, Luquet D, Kim HK, Tambour L, Clement-Vidal
A, 2006. EcoMeristem, a model of morphogenesis and
competition among sinks in rice. 2. Simulating genotype
responses to phosphorus deficiency.
Functional Plant
Biology
33, 325-337.
http://dx.doi.org/10.1071/FP05267
Dingkuhn M, Luquet D, Quilot B, de Reffye P, 2005. Envi-
ronmental and genetic control of morphogenesis in crops:
Towards models simulating phenotypic plasticity.
Aus-
tralian Journal of Agricultural Research
56, 1289-1302.
Duailibe AK, 2010. Brazil's renewable energy suc-
cess.
Nature
468, 1041-1041.
http://dx.doi.org/10.1038/
4681041b
Edme SJ, Miller JD, Glaz B, Tai PYP, Comstock JC, 2005.
Genetic contribution to yield gains in the Florida sugar-
cane industry across 33 years.
Crop Science
45, 92-97.
113,
331-343.
s00122-006-0300-8
Costet L, Le Cunff L, Royeart S, Raboin L-M, Hervouet C,
Toubi L, Telismart H, Garsmeur O, Rousselle Y, Pauquet
J, Nibouche S, Glaszmann J-C, Hoarau J-Y, D'Hont A,
2012. Haplotype structure around
Bru
1 reveals a nar-
row genetic basis for brown rust resistance in mod-
ern sugarcane cultivars.
Theoretical and Applied Genet-
ics
125, 825-836.
http://dx.doi.org/10.1007/s00122-012-
1875-x
Cuadrado A, Acevedo R, De la Espina SMD, Jouve N,
De La Torre C, 2004. Genome remodelling in three
modern
S. officinarum
—
S. spontaneum
sugarcane cul-
tivars.
Journal of experimental botany
55, 847-854.
Da Silva JA, Bressiani JA, 2005. Sucrose synthase molecular
marker associated with sugar content in elite sugarcane
progeny.
Genetics and Molecular Biology
28, 294-298.
Dal-Bianco M, Carneiro MS, Hotta CT, Chapola RG,
Hoffmann HP, Garcia AAF, Souza GM, 2011. Sugar-
cane improvement: How far can we go?
Current Opin-
ion in Biotechnology
23, 265-270.
http://dx.doi.org/
Daniels J, Roach B, 1987. Taxonomy and evolution. Chapter
2, in: Heintz D (ed),
Sugarcane improvement through
breeding
. Amsterdam: Elsevier, pp. 7-84.
Daugrois J, Grivet L, Roques D, Hoarau J, Lombard H,
Glaszmann J, D'Hont A, 1996. A putative major gene
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