Breeding
Plants for the Future
By Rita Pelczar
In 1856 an Austrian monk
named Gregor Mendel began a series of experiments with
garden peas. Systematically crossbreeding plants that
displayed visibly distinguishable traits, Mendel followed
the offspring through several generations, observing and
recording the incidence of these traits. His findings
unlocked the secrets of plant inheritance. Fast-forward
almost 150 years: Today's plant geneticists work with traits
that the eye cannot detect-at the molecular level-and have
successfully transferred genes between unrelated organisms.
Astounding advances in plant breeding have been realized in
the past one and a half century; some of these pose as many
questions as they do answers.
The
Changing Goals of Plant Improvement
Producing better plants has
always been the goal of plant breeders, but exactly what
constitutes improvement has changed over time. One hundred
years ago, resistance to chestnut blight was not considered
an essential trait for the robust species that dominated
eastern forests. But American chestnuts have all but
disappeared from our woodlands and landscapes. If-or perhaps
we should say when-a gene is discovered that imparts
resistance to the fungus that causes the blight, an American
treasure might be restored. Today's ornamental plant
breeders seek varieties that display tolerance to such
modern afflictions as air pollution and acid rain; these
traits were not a concern 50 or 60 years ago.
Increasing food production to
accommodate an ever-growing world population has been a
long-standing objective among breeders of food crops.
Production can be boosted either by improving productivity
of the land used to grow food, or expanding the amount of
land in production. Both approaches have benefited from
plant breeding, but since further increases in productivity
will likely not be as dramatic as those resulting from the
advent of hybrid varieties in the 20th century, the latter
may be the focus in the future. Thus developing crops that
will thrive on land now considered marginal or unusable for
agriculture has become a critical goal of plant breeders,
explains James Moore, professor emeritus of the University
of Arkansas. "Changing the plant genotype [genetic make-up]
through breeding," says Moore, "will be a key component in
this technology."
The
Improvement Process
Identifying the particular
quality that will lead to an improved variety is the first
step in a plant breeding program. The next is locating a
source of that characteristic, and transferring it to a
plant that displays all other desired attributes. Said fast,
sounds easy; in reality, this requires careful research, a
thorough understanding of breeding techniques, a keen sense
of observation, and the patience of Job.
It is the methods for
obtaining the desired trait and transferring it to a
specific plant that have changed most dramatically in the
last 30 years with the development of biotechnology. Until
recently, plant breeders developed new varieties by crossing
and backcrossing parent plants-nearly always members of the
same species-to obtain desired traits. Chance or induced
mutations provided further sources of new characteristics.
But until the advent of technologies such as tissue culture
and gene splicing, transferring traits between plants
depended on their sexual compatibility.
While advances in genetic
engineering have made it relatively easy to transfer genes
between otherwise incompatible organisms, finding and
isolating the gene responsible for a specific trait is still
often a troublesome task for molecular plant breeders.
Robert Griesbach, a plant breeder at the USDA laboratories
in Beltsville, Maryland, notes that "it is relatively easy
to physically introduce a foreign gene into a host plant,
but difficult to identify the appropriate gene to introduce,
and even more difficult to obtain that gene."
Mirroring the efforts of the
Human Genome Project, which is attempting to map the entire
human genetic code, plant geneticists have made great
headway toward determining the complete DNA sequence of
Arabidopsis thaliana, a modest meadow weed. Arabidopsis was
selected because it has the smallest amount of DNA in the
plant kingdom. "Once this sequence is obtained," Greisbach
explains, "it will be much easier to identify and isolate
genes, as well as understand the basic molecular processes
that controls growth and development in higher plants."
Progress
or Problems?
Bt potatoes. Roundup Ready
corn. Terminator technology. The development of genetically
modified organisms (GMOs) has stirred controversy among
scientists and consumers. How safe are these crops? Are they
the solution for world hunger? What effect will they have on
the environment? These are just a few of the questions that
have arisen since GMOs hit the market in the mid-1990s. The
issue is complex, exemplified by the use of a gene from the
bacterium Bacillus thuringiensis to produce Bt potatoes,
followed by similarly pest resistant Bt corn and Bt cotton.
Bacillus thuringiensis has
long been used as a topical biological insecticide for
control of the Colorado potato beetle. It produces a toxin
that is lethal to the beetle, but it does not persist for
long. Genetic engineers theorized that splicing the gene for
the toxin directly into the potato plant would protect it
from the pest without the need for sprays. Detractors of
this gene transfer ask whether such plants are safe for
human consumption, what effect will they have on non-target
insects, will it lead to resistance to the pest, and what
are the long-term ramifications of combining such genes from
unrelated and sexually incompatible organisms? These
questions, unanswered to the satisfaction of some consumers
and environmentalists, spurred international reaction,
especially when it was determined that many processed foods
such as corn syrup, cereals, and potato chips were being
produced from genetically altered crops.
In Europe, consumer concern
over the use of genetically modified plants in foods
escalated to the point that two food processing giants,
Nestlé and Unilever, announced last year that they would no
longer accept transgenic crops for their European foods. Two
of Japan's largest beer makers, Kirin and Sapporo, followed
suit, as did the largest tortilla maker in Mexico. The
economic impact on growers of transgenic crops has been
substantial.
In the United States today,
genetically altered crops are used in many processed foods.
Labeling to distinguish genetically altered sources from
conventional sources is not required. The feared dangers of
genetically modified foods have spurred research to confirm
or deny the concerns.
Tradition
and Technology
Insight into the debate
regarding molecular genetics and its effect on the plants we
grow can be gained by examining how it differs from
traditional-classical-breeding methods. What does it offer
that classical techniques do not?
Griesbach suggests that the
difference between classical and molecular breeding lies in
how a trait is defined. For example, flower color is defined
as a color detected by the human eye in a classical breeding
approach. In molecular breeding, however, flower color is
defined as a series of chemical reactions leading to the
biosynthesis of a pigment. While classical breeding relies
upon selecting plants with different gross characteristics,
molecular breeding relies upon selecting plants with
different molecular characteristics.
Tom Leustek, associate
professor of biotechnology at Rutgers University, says the
difference boils down to one word: precision. He compares
the methods using the analogy of finding a needle in a
haystack. According to Leustek, classical plant breeding "is
literally like searching straw by straw for the needle.
Genetic engineering is analogous to knowing precisely where
the needle is."
While he acknowledges that
genetic engineering offers tremendous new possibilities,
Mark Bridgen, professor of plant science at the University
of Connecticut, notes that "it will take some time before
these abilities will be fully realized because of legal
issues, moral issues, and-probably more importantly as a
breeder-the ability to find and incorporate these genes into
plants." Bridgen adds, "If the protocols for incorporating
genes are known, then the trait can be developed much faster
[using molecular breeding techniques] than through
traditional breeding. However, as a classical breeder, we
can use traits that have laid recalcitrant to produce
beautiful plants-even if it takes longer."
Classical and molecular
breeding researchers approach plants from different
perspectives, according to John Navazio, vegetable breeder
for Alf Christianson Seed Company in Mt. Vernon, Washington.
"The notion that a plant breeder chooses only one trait
worth improving and the rest of the genotype remains static
is very foreign to classical plant breeders," he asserts.
While molecular geneticists work with one single-gene trait
at a time, Navazio says that "most successful classical
plant breeders working on food or fiber crops are selecting
for a minimum of eight to 10 traits simultaneously. You're
working on a symphony of traits; you have to be the
conductor that brings all those traits together." He further
offers that most of the important traits in agriculture are
determined by multiple genes.
Impact of
Tissue Culture
Years ago, when a plant
breeder developed a new daylily or hosta, it took years
before sufficient stock was produced to bring it to market.
With the advent of tissue culture propagation-producing an
entire plant from a few cells of the parent under
controlled, sterile conditions-thousands of new plants can
be vegetatively propagated in a matter of months, often at a
significantly reduced cost. Orchids representing complex
crosses that were phenomenally expensive to reproduce
because they did not breed true from seed, are now being
inexpensively "cloned" through tissue culture techniques.
Terra Nova Nurseries in
Tigard, Oregon, specializes in tissue-culture-propagated
perennials, many of which are the product of the nursery's
own breeding program. "It is the use of tissue culture that
skyrockets the plant into sudden availability in a single
year, whereas conventional propagation could take three to
five years to produce the same number of plants," says owner
Dan Heims.
Cell mutations are common in
tissue cultures; this can be frustrating to someone trying
to reproduce a crop exactly, but it is grist for the mill of
the plant breeder. It is from these mutations that many new
varieties arise. Mutations that occur as a result of tissue
culture are known as somaclonal variations, explains Bridgen,
whose work focuses on hardy and fragrant Peruvian lilies (Alstroemeria
spp.). For Bridgen, these variations have been the source of
numerous useful traits including pest tolerance,
variegation, height control, and double flowers. "You can
take natural characteristics that have been 'dormant' for
years," he says, "and revive them [with the aid of]
somaclonal variation."
Cell
Fusion
Cell fusion is a technique
made possible through tissue culture. It involves the union
of two non-reproductive (somatic) cells from different
organisms to create a replicating cell that contains the
genetic information from both of the unrelated parent cells.
Though these wide crosses are rarely stable, they provide a
means for genes of different species to come together, for
use in further breeding operations. Such combinations are
otherwise impossible. While this technology suggests
enormous potential for breeding plants in the future, some
question both the morality and safety of the unnatural
merging of genetic information that could potentially create
new organisms.
Tagging
the Trait
Mendel's groundbreaking
research focused on visible, easily identifiable
differences- tall or dwarf plants, smooth or wrinkled seed
coat, yellow or green seeds-among his peas. Other
characteristics that a breeder might strive to incorporate
into a plant are not as easily perceived: a tomato resistant
to fusarium wilt may look the same as one without
resistance, at least until the disease strikes. By
purposefully infecting test plants with a disease and
selecting those that survive, researchers are able to
identify those containing the resistant trait.
At the University of
Arkansas' vegetable sub-station near Alma, vegetable breeder
Teddy Morelock tests his spinach crosses on a nursery plot
that has been used for growing the crop for 24 years. This "cess
pool of spinach diseases" harbors nearly every disease known
to infect spinach in North America. By cropping breeding
lines through this nursery, disease-susceptible plants are
easily eliminated.
Many gardeners select the
seed of their best plants to save for next year's garden.
Perhaps one plant demonstrated a greater tolerance to heat,
produced larger crops or bigger flowers, or bore fruit with
better flavor than nearby plants of the same type. By saving
its seed and planting it the following year future crops are
more likely to exhibit the quality observed in the original
plant. Selecting seed from plants that display specific
traits is a long-standing technique that continues in
breeding programs today.
But technology has made the
process of selection faster and more exact. Plant breeders
can now determine the presence of a desired-or
undesired-trait using a method called marker-assisted
breeding. This technique, says Leustek, "relies on the fact
that traits are linked to specific DNA (gene) sequences,
which can be used as markers. Breeders use the markers to
identify whether a trait has been transferred to progeny of
a breeding experiment." This takes much of the guesswork out
of selection and eliminates the need to grow the plant to
maturity to determine if the cross was or was not
successful. This is particularly important when working with
trees and shrubs that may require eight to 10 years of
growth before the success of a breeding effort can be
effectively evaluated.
Merging
Methodologies
Biotechnology has much to
offer the field of plant improvement, particularly when
combined with classical breeding methodologies. "Molecular
genetics is a far bigger discipline than just genetic
manipulation across species boundaries," states Navazio.
"The information about the workings of DNA," he continues,
"is incredibly important to classical geneticists like
myself."
Biotechnology provides the
means for the transfer of specific alien genes into a plant
when natural barriers make this otherwise impossible. It
allows the rapid and accurate determination of the presence
of a trait in a new cross. And it opens doors to new
possibilities for controlling plant diseases and pests, as
well as increasing tolerance to environmental stresses.
"However, the ultimate worth of a cultivar," says Moore, "is
determined by thousands of genes working in harmony, and it
will be the role of plant breeders to mold the genetic
diversity created by biotechnology into usable cultivars." m
Rita Pelczar is associate
editor of The American Gardener.
Improving
Vegetables
By Rita Pelczar
John Navazio, who breeds
spinach, beets, and carrots for the Alf Christianson Seed
Company in Mt. Vernon, Washington, considers improving
resistance to diseases and the development of crops with
increased nutritional quality as major objectives facing
today's vegetable breeders.
Disease
Resistance
Protection from many
important vegetable diseases has been obtained by
incorporating a single gene that confers resistance.
Vertical resistance, as it is called, has been accomplished
both through classical breeding methods and genetic
engineering by transmitting these single resistant genes.
This resistance is absolute; the plant is completely
resistant to the disease-or at least to a specific race of
the disease. If the disease-causing organism mutates,
forming a new race of the disease, the resistance does not
hold up. "What this creates," says Navazio, "is the 'race
race'-constantly breeding for the next race...thereby
increasing happenstance mutations for pathogenicity of the
disease organism. It's a boom and bust cycle."
Downy mildew is a serious
disease of spinach for which vertical resistance was
obtained in the early 50s. But the fungus that causes the
disease has undergone several mutations, each requiring a
new line of resistance. Today American spinach growers worry
about race 6 of downy mildew, and in Europe, race 7. And the
fungus that causes the disease phytophthora in soybeans has
developed 28 races-20 of them in just the last 20 years!
A better approach, according
to Navazio, is to breed plants that bear a broader, though
not absolute, resistance. This is called horizontal
resistance and it is controlled by multiple genes. It
imparts "varying amounts of resistance to a disease in any
situation," remarks Navazio.
Breeding for horizontal
resistance begins by identifying plants that display a
fairly high level of resistance to a disease-what farmers
call field tolerance-and interbreeding them. Offspring are
inoculated with the disease and survivors are inter-bred.
The result is a stacking or pyramid affect of the desired
traits, obtaining significantly raised levels of resistance,
often in very few generations. These plants are equally
resistant to any strain of the disease, including new
strains. When coupled with cultural practices, horizontal
resistance can reduce disease damage to a level that doesn't
affect quality. According to Navazio, "This has huge
implications for lowered pesticide use."
Breeding
for Nutrition and Health Benefits
Plant breeders have made
great progress in increasing traditional essential
nutrients-vitamins and minerals-in the vegetables we eat.
More recently, they have been working to increase
phytonutrients-compounds that enhance natural functions and
promote a long and healthy life. "We have only begun to
understand the role of phytonutrients in human nutrition,"
remarks Navazio. "It is a very ripe area of research."
Plant breeders have begun
working with colleagues in the medical profession to develop
varieties that contain higher amounts of natural compounds
that may be important in maintaining human health. James
Moore, professor emeritus of the University of Arkansas,
cites the potential of anti-oxidants and isoprenoids-compounds
found in plants that contribute to their distinctive flavors
and fragrances-to suppress cancer and heart disease.
"Studies on these compounds are new," states Moore, "but a
few have been shown to suppress human cancer in cells in
laboratory tests." Among these are limonene and lycopene-two
isoprenoids common in tomatoes.
USDA plant researcher Phil
Simon at the University of Wisconsin and Teddy Morelock at
the University of Arkansas are both working on the
phytonutrient, lutein, which is critical in preventing age
related macular degeneration, a condition that restricts
vision. Lutein also possesses great anti-oxidant potential;
it is capable of blending with and deactivating free
radicals-highly reactive molecules that have been linked to
the development of certain cancers. Normally present in dark
leafy greens, winter squash, and yellow and green summer
squash, researchers have discovered that the lutein content
in vegetables is directly related to the depth of color. New
varieties are now being selected for high lutein content.
Gardeners can sample
vegetables that have been bred for increased nutrients and
phytonutrients. High levels of beta-carotene are available
from Johnny's Selected Seeds' carrot 'Sugarsnax', and Garden
City Seeds' 'Vita Gold' tomato. Johnny's offers 'Raven'
zucchini, which boasts a high lutein content. Health-minded
gardeners may also select Territorial Seed Company's 'Nutri-Red'
carrot which contains the anti-oxidant lycopene, and 'Doublerich'
tomato which provides twice the normal level of Vitamin C.
Many more varieties with improved nutritional value will be
showing up in seed catalogs soon.
Plant breeders are adding
considerable weight to Mom's chant of "Eat your
vegetables!"-Rita Pelczar
Resources
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Wiley and Sons, New York, New York. 1988.
Breeding Ornamental Plants
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Breeding Your Own Vegetable
Varieties: The Gardener's and Farmer's Guide to Plant
Breeding and Seed Saving by Carol Deppe. Chelsea Green,
White River Junction, Vermont. 2000.
Plant Propagation: Principles
and Practices edited by Hudson T. Hartmann. Prentice Hall,
New York, New York. 1996.
Plants for the Future: A
Gardener's Wishbook by Jerome Malitz. Timber Press,
Portland, Oregon, 1996.
Principles of Plant Breeding
by Robert W. Allard. John Wiley and Sons, New York, New
York. 1999.
Return to Resistance:
Breeding Crops to Reduce Pesticide Dependence by Raoul A.
Robinson. AgAccess, Davis, California, 1996.
