His primary areas of investigation include Genetics, Chromosome, Genetic marker, Gene and Genome. His studies link SYT1 with Genetics. His research related to Chromosome regions, Centromere and Chromosome Arm might be considered part of Chromosome.
His Genetic marker study incorporates themes from Physical Chromosome Mapping, Recombination, Restriction fragment length polymorphism and Gene map. His research on Gene focuses in particular on Triticeae. His studies examine the connections between Gene mapping and genetics, as well as such issues in Complementary DNA, with regards to Deletion mapping and Genetic distance.
Kulvinder S. Gill focuses on Genetics, Gene, Chromosome, Genome and Agronomy. His study in Genetic marker, Gene mapping, Expressed sequence tag, Locus and Triticeae is carried out as part of his studies in Genetics. His Genetic marker research is multidisciplinary, relying on both Recombination, Plant breeding, Gene map and Restriction fragment length polymorphism, Genotype.
His Gene mapping study combines topics in areas such as Complementary DNA and Genetic linkage. His Expressed sequence tag research is multidisciplinary, incorporating elements of Genome project and Oryza sativa. His biological study deals with issues like Ploidy, which deal with fields such as Botany and Bromus inermis.
His scientific interests lie mostly in Gene, Genetics, Agronomy, Cultivar and Gene expression. His work deals with themes such as Botany and Cell biology, which intersect with Gene. Intron, Gene silencing, Chromosome, DNA sequencing and Single-nucleotide polymorphism are among the areas of Genetics where the researcher is concentrating his efforts.
His Cultivar research integrates issues from Quantitative trait locus, Tiller, Coleoptile and Gene mapping. As a part of the same scientific study, he usually deals with the Gene mapping, concentrating on Genetic distance and frequently concerns with Allele. His Gene family research focuses on Secondary cell wall and how it relates to Genome.
Kulvinder S. Gill spends much of his time researching Genetics, Gene, Botany, Spring and Irrigation. His Genetics research incorporates elements of Stamen and Gynoecium. His studies in Gene integrate themes in fields like Endosperm, Thermostability and DNA.
His biological study spans a wide range of topics, including Mutagenesis, Arabidopsis thaliana, Arabidopsis and Allele. Spring is intertwined with Horticulture, Grain quality, Time of day, Grain filling and Germination in his study. His Irrigation research incorporates Reflectivity and Soil science.
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Comparative DNA Sequence Analysis of Wheat and Rice Genomes
Mark E. Sorrells;Mauricio La Rota;Catherine E. Bermudez-Kandianis;Robert A. Greene.
Genome Research (2003)
A chromosome bin map of 16,000 expressed sequence tag loci and distribution of genes among the three genomes of polyploid wheat.
L. L. Qi;B. Echalier;S. Chao;S. Chao;G. R. Lazo.
A genetic linkage map of Triticum tauschii (DD) and its relationship to the D genome of bread wheat (AABBDD)
K. S. Gill;E. L. Lubbers;B. S. Gill;W. J. Raupp.
Identification and High-Density Mapping of Gene-Rich Regions in Chromosome Group 1 of Wheat
Kulvinder S. Gill;Kulvinder S. Gill;Bikram S. Gill;Takashi R. Endo;Teri Taylor.
MOLECULAR-GENETIC MAPS FOR GROUP 1 CHROMOSOMES OF TRITICEAE SPECIES AND THEIR RELATION TO CHROMOSOMES IN RICE AND OAT
Deynze Ae;Nelson Jc;Sorrells Me;McCouch.
The Organization and Rate of Evolution of Wheat Genomes Are Correlated With Recombination Rates Along Chromosome Arms
Eduard D. Akhunov;Andrew W. Goodyear;Shu Geng;Li-Li Qi.
Genome Research (2003)
Demarcating the gene-rich regions of the wheat genome
Mustafa Erayman;Devinder Sandhu;Deepak Sidhu;Muharrem Dilbirligi.
Nucleic Acids Research (2004)
Assessment of genetic diversity and relationship among a collection of US sweet sorghum germplasm by SSR markers
M. L. Ali;J. F. Rajewski;P. S. Baenziger;K. S. Gill.
Molecular Breeding (2008)
A chromosome region-specific mapping strategy reveals gene-rich telomeric ends in wheat
K. S. Gill;B. S. Gill;T. R. Endo.
IRS and TOR nutrient-signaling pathways act via juvenile hormone to influence honey bee caste fate
Navdeep S. Mutti;Adam Gregory Dolezal;Florian Wolschin;Florian Wolschin;Jasdeep S. Mutti;Jasdeep S. Mutti.
The Journal of Experimental Biology (2011)
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