Genomic in situ hybridization, a modification of fluorescence in situ hybridization technology,
is one of the most exciting and versatile research tools to be developed in recent years. It …

Recent developments that improve our ability to distinguish slightly diverged genomes from
each other, as well as to distinguish each of the nonhomologous chromosomes within a …

In situ hybridization is a fundamental method in modern plant molecular cytogenetics
research. It cannot be overstressed that good in situ hybridization results begin with good …

Key message The innovations in chromosome engineering have improved the efficiency of
interrogation breeding, and the identification and transfer of resistance genes from alien to …

The development of fluorescence in situ hybridization (FISH) has led to the advancement of
chromosome studies not only for physical mapping and genome analyses but also as a tool …

The past two decades have brought with them remarkable progress in plant chromosomal
research. The chromosome structure has been clarified in great detail, enabling …

Evidence is now increasing that many functions and processes of meiotic genes are similar
in yeast and higher eukaryotes. However, there are significant differences and, most notably …

The identification of causal genomic loci and their interactions underlying various traits in
plants has been greatly aided by progress in understanding the organization of the nuclear …

This review summarizes conventional and recent applications of genomic in situ
hybridization (GISH). GISH is a well recognized technique, but its modifications and …

Genomic in situ hybridization (GISH), which is a modification of fluorescent in situ
hybridization, has been widely used in the study of plants. It has become one of the most …