Results 231 to 240 of about 19,367 (253)

Micropropagation of Sugarcane (Saccharum spp. Hybrid)

1997
Commercial sugarcane (Saccharum spp. hybrid) consists of six species, S. officinarum, S. robustum, S. spontaneum and S. edule. Species of Erianthus and Miscanthus are part of a closely related interbreeding group which formed part of the evolution of sugarcane (Daniels and Roach 1987).
openaire   +2 more sources

Selecting sugarcane genotypes (Saccharumspp.) according to sucrose accumulation

Journal of Crop Improvement, 2019
The sucrose accumulation curve represents the maturity profile of a genotype (G). Computing the accumulation curves helps determine optimal harvesting period and explore genetic variability.
Ostengo, Santiago, Rueda Calderón, María Angélica, Bruno, Cecilia Ines, Cuenya, María Inés, Balzarini, Monica Graciela   +4 more
openaire   +3 more sources

Sugarcane (Saccharumspp. hybrids) Tolerance to Clomazone

Weed Technology, 1996
Field studies were conducted over four years to determine sugarcane response to clomazone applied POST at 1.1 and 2.2 kg ai/ha. Sugarcane leaves present when clomazone was applied were chlorotic 2 WAT. Injury 4 WAT ranged from 0 to 38% following single applications in March and April.
openaire   +2 more sources

Solubility and availability to sugarcane (Saccharum Spp.) of two silicate materials

Fertilizer Research, 1988
Silicate materials, dicalcium orthosilicate (Ca2SiO4), calcium metasilicate (CaSiO3), and mini-granulated CaSiO3, were incorporated into three highly weathered, low-Si soils. The mixtures were moistened to field moisture-holding capacity and incubated in plastic bags for 60 days at approximately 25°C, after which Si was extracted.
O. A. Medina-Gonzales, R. P. Bosshart, R. L. Fox   +2 more
openaire   +2 more sources

Quantitative trait loci identified for sugar related traits in a sugarcane (Saccharum spp.) cultivar × Saccharum officinarum population

Theoretical and Applied Genetics, 2006
The identification of markers linked to quantitative trait loci (QTLs) for increased sugar accumulation could improve the effectiveness of current breeding strategies in sugarcane. Progeny from a cross between a high sucrose producing cultivar, (denotes Australian plant breeding rights), and a Saccharum officinarum clone, IJ76-514 were grown in two ...
Aitken, K. S., Jackson, P. A., McIntyre, C. L.   +2 more
openaire   +4 more sources

Osmoprotectants in the Sugarcane (Saccharum spp.) Transcriptome Revealed by in Silico Evaluation

2011
Environmental stresses such as drought and salinity limit crop productivity in worldwide level. These stresses often lead to the accumulation of osmoprotectants in most organisms, including plants. In the present work, a search of known osmoprotectants (P5CS, P5CR, INPS1, BADH, CMO, TPS, TPP, OASTL and SAT) was carried out in the sugarcane ...
Nina da Mota Soares-Cavalcanti, Ana Maria Benko-Iseppon, Gabriela S. Vieira-de-Melo, Petra Barros dos Santos   +3 more
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Specificity of the Bipolaris sacchari-Saccharum spp. Interaction

Plant Disease, 1987
J. L. Dean, M. S. Kang
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Genomic insights into the recent chromosome reduction of autopolyploid sugarcane Saccharum spontaneum

Nature Genetics, 2022
Bernard Kippelen, Haibao Tang, Yongjun Wang   +2 more
exaly  

A complete gap-free diploid genome in Saccharum complex and the genomic footprints of evolution in the highly polyploid Saccharum genus

Nature Plants, 2023
Haibao Tang, Lianfeng Gu, Jianping Wang
exaly  

Genetic Improvement of Sugarcane (Saccharum spp.) as an Energy Crop

2008
Robert M. Cobill, Thomas L. Tew
openaire   +2 more sources