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| Glassy-Winged Sharpshooter - Vector of Pierce's Disease of Grapes |
Most of the “GMO Crops” that have been commercialized are
either insect resistant or herbicide tolerant. Biotechnology can also be used to generate crops that are
resistant to plant diseases. So
far, there are only two examples of disease resistance available to farmers:
the papayas resistant to ringspot virus and squash resistant to zucchini yellow
mosaic and watermelon mosaic viruses.
That narrow offering is not for a lack of need or technical
potential. In fact, biotech
approaches could uniquely address some of the most significant disease issues
in global agriculture. The
limitation mainly reflects the success of the anti-GMO movement in creating
controversy. This has induced
brand-sensitive food system players to use their leverage to prevent the
development or introduction of “GMO” disease resistant versions of crops where
they would make the most sense.
If we let ourselves imagine what could be, there are three
important categories of plant disease of particular interest for the use of
genetic engineering:
- Systemic diseases spread by insect vectors
- Diseases of crops for which conventional breeding is far too slow and/or disruptive to key quality attributes
- Crop diseases which are not amenable to safe and effective chemical control
Systemic diseases
spread by insect vectors
Fungi cause most plant diseases, but plants can also be
infected by viruses and bacteria.
In most of these cases, specific insects spread the pathogens from plant
to plant in much the same way that the Aedes
aegypti mosquito spreads a human disease like Yellow Fever. For plants, the vector insects are the
ones that use specialized mouthparts to penetrate plant cells to suck out
nutrients – things like aphids, thrips, mealy bugs and psyllids. The viruses or bacteria have specific
associations that allow them to be picked up from an infected plant on the
mouthparts of the “bug” and then released inside of the next plant. Those infections can severely damage
the plant and even kill it. In
many cases, the only way such diseases can be controlled is to use insecticides
to kill the vectors. Often it
requires nearly complete insect control to adequately protect the crop. That means intensive insecticide use in
some cases, but in other cases it isn’t feasible to stop the spread of the
disease. That was the case with papaya
ringspot virus which was seriously compromising production Hawaii in the
early 1990s - the farmers were fighting a losing battle to save their
plantings. The introduction of transgenic
virus resistance in 1998 saved the papaya industry. Currently there is a new, deadly, bacterial disease of
citrus which is threatening
the orange industry in Florida.
Insecticide programs have only slowed the progress of the disease, and
without something like a transgenic solution, that industry will soon
collapse. Another bacterium is
threatening the California wine industry because of the introduction of a more
problematic vector in the late 1980s.
Insecticide programs and quarantine programs are limiting the issue to
Southern California for now, but it would be much more desirable to have a
resistance option to deploy to protect the key production areas to the North. Laurel Wilt disease of avocado is
another similar challenge.
Diseases of crops for which conventional breeding is far too slow and/or disruptive to key quality attributes
One of the main ways that plant diseases are managed is
through conventional breeding programs.
This can be quite effective, particularly for annual grains or
vegetables for which breeding programs can progress fairly quickly. For a crop like potatoes, breeding is
difficult and slow because the plants don’t normally make any seeds. That is why the 100+ year-old Russett
Burbank is still a major commercial cultivar. There is a severe disease called
Potato Late Blight which caused the infamous Potato Famine and which requires
very frequent fungicide applications today. There are genes for resistance in wild or semi-wild
ancestral potatoes in the Andes, and using biotechnology, such genes have been
moved into the potatoes we now grow, at least on an
experimental basis. This trait
involves a potato gene in a potato.
Coffee also has a
major rust disease that is causing increasing problems in the high quality,
“Arabica” coffee production areas of Central and South America. There are resistance genes in various
other coffee species around the world, but to move those traits into high
quality lines requires things like chromosome doubling and decades of
back-crossing. If the genes were
moved via genetic engineering methods, the end result would be a coffee-based
resistance gene in a coffee variety with a well-characterized quality
background.
Bananas are an extreme case where genetic engineering would
allow moving a resistance trait from some non-commercial, seeded banana, into
the seedless banana of commerce which is threatened by Panama Wilt and other
diseases. Similarly, genetic engineering may be a way to deal with something
like Frosty Pod in cacao without compromising quality attributes.
Even with a crop like wheat, there are so many different
types for different uses around the world that it would be helpful to speed up
the breeding process for the new, UG99
Wheat Stem Rust threat, which is moving around the world. A desirable gene found in one category
of wheat (e.g. Hard Red Spring) could be moved to elite breeding lines for
other types like Durum or Soft White Winter.
Diseases that are not amenable to safe, effective chemical control
There are many crop/disease combinations that can be
effectively controlled using fungicide treatments with low mammalian toxicity
and low environmental impact.
However, there are some diseases that are not amenable to that sort of
control. A disease of tomatoes,
called Bacterial Leaf Spot, is a big issue in wetter growing regions like
Florida. It is currently managed
with a combination of biological agents and copper-based products, but coppers
are not as safe as most modern pesticides. Foliar bacterial diseases do not comprise a large enough
global market to justify the investment of >$200MM that it takes to develop
a new synthetic pesticide. There
is a very effective resistance gene for this disease in peppers, but although
they are related to tomatoes they are too distant for conventional
cross-breeding. That pepper gene has been
moved to tomato and the plants performed well in field tests. Fusarium
Head Blight of wheat is a serious disease risk that limits the feasibility
of adding wheat to Midwestern corn/soy rotations. That disease is difficult to control with fungicides, but there
was once a nearly commercialized trait for resistance.
There are a number of crops including
field corn that can be infected by the opportunistic fungal pathogen, Aspergillus flavus, when there has been
drought stress and/or insect damage.
Fungicides are not very effective against this problem, and the aflatoxin that the
fungus can produce renders the grain unsuitable for normal feed or food uses. Indeed, aflatoxin is one of the leading
causes of death in the developing world where it can contaminate important food
crops like maize or peanuts. There
are several ideas for how to address that issue with biotechnology.
Biotech crops have been planted on hundreds of millions of
acres of land each year since 1996.
Many generations of animals have been raised on these crops both in the
countries where “GMO” crops are grown, and also in the EU, Japan, China and
many other importing regions. The
arguments against this basic technology have not proven to be of actual concern. At some point, we should be able to
start applying these well-tested technologies to the prevention of problematic
diseases that affect crops.
Glassy-Winged Sharpshooter image from California Department of Food and Agriculture
Biotech potato image from Jonathan Jones Lab at Sainsbury Laboratory
Corn infected by Aspergillus image from Iowa State University
You are welcome to comment here and/or to email me at savage.sd@gmail.com. I may not be answering comments quickly as I'm on vacation in Colorado :)
