Date post: | 21-Jan-2018 |
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TRANSGENICS IN BIOTIC STRESS MANAGEMENT
BIOTIC STRESS
Biotic stress is a stress that occurs as a result of damage done to plants
by other living organisms, such as bacteria, viruses, fungi, parasites,
beneficial and harmful insects, weeds, and cultivated or native plants.
It is a major focus of agricultural research, due to the vast economic
losses caused by biotic stress to cash crops. The relationship between
biotic stress and plant yield affects economic decisions as well as
practical development.
Biotic stress also impacts horticultural plant health and
natural habitats ecology. It also has dramatic changes in the host
recipient.
Response of plants to stress
Plants have co-evolved with their parasites for several hundred
million years. This co-evolutionary process has resulted in the
selection of a wide range of plant defences against microbial
pathogens and herbivorous pests which act to minimise frequency
and impact of attack. These defences include both physical and
chemical adaptations.For example, utilization of high metal ion
concentrations derived from the soil allow plants to reduce the
harmful effects of biotic stressors (pathogens, herbivores etc). At the
same time, successful pests and pathogens have evolved
mechanisms to overcome both constitutive and induced resistance in
their particular host species.
BIOTIC STRESS MANAGEMENT
It is nothing but making the plants resistant/tolerant to the biotic
stresses either naturally or artificially to improve the yield thereby
saving the economy.
ICAR-National Institute of Biotic Stress Management –
NIBSM, unique institute to take up research and education on Biotic
stresses in agriculture is situated at Baronda, Raipur (Chattisgarh),
Baronda, it is located in a rural setting, about 30 km away from the
Raipur city en-route to Baloda Bazar.
TRANSGENIC CROPS
Bt crops:
Bacillus thuringiensis is a Gram+ bacterium that produces
proteinaceous crystalline (Cry) inclusion bodies. It also produces
cytotoxins that synergize the activity of Cry toxins. Cry proteins are
toxic to insects (mainly against lepidopters), but non-toxic to human
and animals.
Bt maize has been transformed with either cry1Ab, cry1Ac or cry9C to
protect it against Ostrinia nubilalis and Sesamia nonagriodes, or
with cry1F to protect it against Spodoptera frugiperda, and
with cry3Bb, cry34Ab and cry35Ab to protect it against the rootworms
of the genus Diabrotica.
Bt brinjal is another crop which was targeted for control
of Leucinodes orbonalis and commercialized in India in
2008. Bt crucifer vegetables are under development and are targeted
against Plutella xylostella. Bt rice expressing the Bacillus
thuringiensis toxin, is also released.
Several genetically-modified (GM) rice varieties have entered and
passed field and environmental release trials, and four varieties
entered preproduction trials in farmers’ fields in 2001.
Also, Bt alfalfa has been produced using cry3a gene against Hypera
postica for the first time in Iran. Finally, the Bt trait has been
introduced in soybean through either one or two cry genes
among cry1Ab, cry1Ac, cry1F.
PROTEASE INHIBITORS:
Plant protease inhibitors (PI) are able to protect
plants against insect attacks by interfering with the proteolytic activity
of insects digestive gut. Among the proteic PIs, serine and cysteine PIs
are abundant in plant seeds and storage tissues and may contribute to
their natural defense system against insect predation. The first PI gene
that was successfully transferred artificially to plant species resulting in
enhanced insect resistance was isolated from cowpea and encoded the
trypsin/trypsin inhibitor.
RESISTANCE TO FUNGAL DISEASES
Chitin constitutes one of the major components of the cell walls of many
fungal pathogens such as Rhizoctonia solani and it can be hydrolyzed by
chitinase. On the other hand, β-1,3-glucanase is known to degrade glucans
which are also present in the fungal cell walls.
In recent years, the possibility of transforming plants with genes encoding
β-1,3-glucanase and chitinase (mostly of plant origin) has been explored.
Several laboratories have been able to transfer plant or microbial-derived
chitinase genes into plants and develop transgenic crops with enhanced
resistance to fungal diseases. These plants include: grapevine, peanut and
cotton. The combined expression of chitinase and glucanase in transgenic
carrot, tomato and tobacco resulted in a much more effective prevention of
fungal disease development.
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