Over the last 35 years the soil bacterium Agrobacterium tumefaciens has been the workhorse tool for
plant genome engineering.
Not exact matches
The newer process of genetic
engineering, which involves inserting genes from unrelated species into a
plant's
genome to add desirable traits, has been used in crops such as corn, soy, and potatoes.
This type of research involves interdisciplinary teams of climate - change scientists, biologists, geneticists, modellers and
engineers who are using and developing new technologies and research platforms to unlock the vast stores of information within
plant genomes.
Some crop
plants have recently been
engineered by modifying their nuclear
genomes to produce dsRNA against certain insects.
Prof Inzé (VIB - Ghent University): «This study provided major insights into how
plants cope with water - limiting conditions, which can direct advanced breeding and
genome engineering efforts to create high - performing, drought - tolerant crop
plants.
The study provided major insights into how
plants cope with water - limiting conditions, which can direct advanced breeding and
genome engineering efforts to create high - performing, drought - tolerant crop
plants.
Genetically
engineered maize is created by introducing a gene into the
plant genome that expresses a toxic protein from a bacterium, i.e. Bacillus thuringiensis (Bt).
«Altering
plant function through chloroplast genome engineering» Physiological and Molecular Plant Biology Seminar Series University of Ill
plant function through chloroplast
genome engineering» Physiological and Molecular
Plant Biology Seminar Series University of Ill
Plant Biology Seminar Series University of Illinois
His development of a method for stable transformation of land
plant chloroplast
genomes, once thought to be impossible, established the field of chloroplast
genome engineering in higher
plants and has led to an explosion of research concerning the chloroplast
genome's role in photosynthesis, functional analysis of plastid genes by reverse genetics, and mechanisms of plastid gene regulation.
Recent advances in
genome engineering make it possible to precisely alter DNA sequences in living cells, providing unprecedented control over a
plant's genetic material.
His research interest focuses on 1) development and application of TALEN and CRISPR technologies for targeted
genome editing in
plant species, and 2) molecular mechanism of
plant / microbe interactions and crop disease resistance
engineering by using the bacterial blight of rice as a model.
This type of research involves interdisciplinary teams of climate - change scientists, biologists, geneticists, modelers and
engineers who are using and developing new technologies and research platforms to unlock the vast stores of information within
plant genomes.