Potatoes, both
S. tuberosum and most of its wild relatives, are
self-incompatible: they bear no useful fruit when self-pollinated. This trait is problematic for crop breeding, as all sexually produced plants must be
hybrids. The gene responsible for self-incompatibility, as well as mutations to disable it, are now known. Self-compatibility has successfully been introduced both to diploid potatoes (including a special line of
S. tuberosum) by
CRISPR-Cas9. This gene was cloned by
Wageningen University and
Solynta in 2021, which would allow for faster and more focused breeding.
Diploid hybrid potato breeding is a recent area of potato genetics supported by the finding that simultaneous
homozygosity and
fixation of donor alleles is possible.
Wild potato species useful for breeding blight resistance include
Solanum desmissum and
S. stoloniferum, among others.
Varieties There are some 5,000 potato varieties worldwide, 3,000 of them in the
Andes alone — mainly in Peru, Bolivia, Ecuador, Chile, and Colombia. Over 100 cultivars might be found in a single valley, and a dozen or more might be maintained by a single agricultural household. The
European Cultivated Potato Database is an online collaborative database of potato variety descriptions updated and maintained by the
Scottish Agricultural Science Agency within the framework of the European Cooperative Programme for Crop Genetic Resources Networks—which is run by the
International Plant Genetic Resources Institute. Around 80 varieties are commercially available in the UK. For culinary purposes, varieties are often differentiated by their waxiness: floury or mealy
baking potatoes have more
starch (20–22%) than waxy
boiling potatoes (16–18%). The distinction may also arise from variation in the comparative ratio of two different potato starch compounds:
amylose and
amylopectin. Amylose, a long-chain molecule, diffuses from the starch granule when cooked in water, and lends itself to dishes where the potato is mashed. Varieties that contain a slightly higher amylopectin content, which is a highly branched molecule, help the potato retain its shape after being boiled in water. Potatoes that are good for making
potato chips or potato crisps are sometimes called "chipping potatoes", which means they meet the basic requirements of similar varietal characteristics, being firm, fairly clean, and fairly well-shaped. Immature potatoes may be sold fresh from the field as "" or "" potatoes and are particularly valued for their taste. They are typically small in size and tender, with a loose skin, and flesh containing a lower level of
starch than other potatoes. In the United States they are generally either a
Yukon Gold potato or a red potato, called gold creamers or red creamers respectively. In the UK, the
Jersey Royal is a famous type of new potato. Dozens of potato
cultivars have been
selectively bred specifically for their skin or flesh
color, including gold, red, and blue varieties. These contain varying amounts of
phytochemicals, including
carotenoids for gold/yellow or
polyphenols for red or blue cultivars. Carotenoid compounds include
provitamin A alpha-carotene and
beta-carotene, which are converted to the
essential nutrient,
vitamin A, during digestion.
Anthocyanins mainly responsible for red or blue pigmentation in potato cultivars do not have nutritional significance, but are used for visual variety and consumer appeal. In 2010, potatoes were
bioengineered specifically for these pigmentation traits.
Genetic engineering starch Genetic research has produced several
genetically modified varieties. 'New Leaf', owned by
Monsanto Company, incorporates genes from
Bacillus thuringiensis (source of most
Bt toxins in
transcrop use), which confers resistance to the
Colorado potato beetle; 'New Leaf Plus' and 'New Leaf Y', approved by US regulatory agencies during the 1990s, also include resistance to
viruses.
McDonald's,
Burger King,
Frito-Lay, and
Procter & Gamble announced they would not use
genetically modified potatoes, and Monsanto published its intent to discontinue the line in March 2001. Potato starch contains two types of
glucan,
amylose and
amylopectin, the latter of which is most industrially useful. Waxy potato varieties produce
waxy potato starch, which is almost entirely amylopectin, with little or no amylose.
BASF developed the '
Amflora' potato, which was modified to express
antisense RNA to inactivate the gene for
granule bound starch synthase, an enzyme which catalyzes the formation of amylose. 'Amflora' potatoes therefore produce starch consisting almost entirely of
amylopectin, and are thus more useful for the starch industry. In 2010, the European Commission cleared the way for 'Amflora' to be grown in the European Union for industrial purposes only—not for food. Nevertheless, under EU rules, individual countries have the right to decide whether they will allow this potato to be grown on their territory. Commercial planting of 'Amflora' was expected in the Czech Republic and Germany in the spring of 2010, and Sweden and the Netherlands in subsequent years. The 'Fortuna' GM potato variety developed by BASF was made resistant to
late blight by
introgressing two resistance genes, and , from
S. bulbocastanum, a wild potato native to Mexico. is a
nucleotide-binding leucine-rich repeat (NB-LRR/NLR), an R-gene-produced immunoreceptor. In October 2011, BASF requested cultivation and marketing approval as a feed and food from the EFSA. In 2012, GMO development in Europe was stopped by BASF. In November 2014, the
United States Department of Agriculture (USDA) approved a genetically modified potato developed by
Simplot, which contains genetic modifications that prevent bruising and produce less
acrylamide when fried than conventional potatoes; the modifications do not cause new proteins to be made, but rather prevent proteins from being made via
RNA interference. Genetically modified varieties have met public resistance in the U.S. and in the European Union. == Cultivation ==