Kazuhiro Sato mainly focuses on Hordeum vulgare, Genetics, Agronomy, Gene mapping and Quantitative trait locus. His Hordeum vulgare research integrates issues from Chromosome, Genome, Doubled haploidy and Oryza sativa. In most of his Genetics studies, his work intersects topics such as Computational biology.
Kazuhiro Sato has included themes like Regulator, Vernalization and Vernalization response in his Agronomy study. He interconnects Genetic marker, Microsatellite and Amplified fragment length polymorphism in the investigation of issues within Gene mapping. His study in the field of Homology and Gene expression is also linked to topics like Voltage clamp and Heterologous expression.
His scientific interests lie mostly in Genetics, Hordeum vulgare, Gene, Quantitative trait locus and Genome. His studies deal with areas such as Doubled haploidy and Genetic diversity as well as Hordeum vulgare. Kazuhiro Sato combines subjects such as Molecular biology and Computational biology with his study of Gene.
His Quantitative trait locus research is multidisciplinary, incorporating elements of Plant disease resistance, Chromosome, Genetic linkage and Allele. His Genome study integrates concerns from other disciplines, such as Ploidy, DNA sequencing and Genomic library. His study looks at the intersection of Botany and topics like Domestication with Crop.
Kazuhiro Sato spends much of his time researching Genetics, Gene, Hordeum vulgare, Genome and Chemical engineering. His study in Genetics concentrates on Ploidy, Locus, Genetic marker and Genome-wide association study. His work on Mutant, Meristem and Transposable element as part of general Gene research is frequently linked to Structure function, thereby connecting diverse disciplines of science.
Hordeum vulgare is a subfield of Agronomy that Kazuhiro Sato tackles. His Genome research is multidisciplinary, relying on both Exome and DNA sequencing. His research in Chemical engineering intersects with topics in Portable water purification and Granulation.
Kazuhiro Sato mainly focuses on Genetics, Gene, Ploidy, Locus and Hordeum vulgare. His research in Genome and Genetic marker are components of Genetics. His Genetic marker research incorporates elements of Aegilops umbellulata, Aegilops tauschii and Synteny.
His DEC1, Downregulation and upregulation, Meristem and Transcription factor study, which is part of a larger body of work in Gene, is frequently linked to Cell division, bridging the gap between disciplines. His work carried out in the field of Locus brings together such families of science as Mutant and Shotgun sequencing. His Hordeum vulgare research includes themes of Genetic diversity, DNA, Major gene, Retrotransposon and Genetic variation.
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A physical, genetic and functional sequence assembly of the barley genome
Klaus F.X. Mayer;Robbie Waugh;Peter Langridge;Timothy J. Close.
Development and implementation of high-throughput SNP genotyping in barley
Timothy J Close;Prasanna R Bhat;Prasanna R Bhat;Stefano Lonardi;Yonghui Wu;Yonghui Wu.
BMC Genomics (2009)
Unlocking the Barley Genome by Chromosomal and Comparative Genomics
Klaus F. X. Mayer;Mihaela Martis;Pete E. Hedley;Hana Simkova.
The Plant Cell (2011)
An Aluminum-Activated Citrate Transporter in Barley
Jun Furukawa;Naoki Yamaji;Hua Wang;Namiki Mitani.
Plant and Cell Physiology (2007)
Barley grain with adhering hulls is controlled by an ERF family transcription factor gene regulating a lipid biosynthesis pathway.
Shin Taketa;Satoko Amano;Yasuhiro Tsujino;Tomohiko Sato.
Proceedings of the National Academy of Sciences of the United States of America (2008)
QTL analysis of malting quality in barley based on the doubled-haploid progeny of two elite North American varieties representing different germplasm groups
L. A. Marquez-Cedillo;P. M. Hayes;A. Kleinhofs;W. G. Legge.
Theoretical and Applied Genetics (2001)
Comprehensive Sequence Analysis of 24,783 Barley Full-Length cDNAs Derived from 12 Clone Libraries
Takashi Matsumoto;Tsuyoshi Tanaka;Hiroaki Sakai;Naoki Amano.
Plant Physiology (2011)
The International Barley Sequencing Consortium—At the Threshold of Efficient Access to the Barley Genome
Daniela Schulte;Timothy J. Close;Andreas Graner;Peter Langridge.
Plant Physiology (2009)
Molecular mapping of the Oregon Wolfe Barleys: a phenotypically polymorphic doubled-haploid population
J. M. Costa;A. Corey;P. M. Hayes;C. Jobet.
Theoretical and Applied Genetics (2001)
Power transmission device, power transmission method, power reception device, power reception method, and power transmission system
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