Using potato’s wild relatives to increase genetic diversity within crops
Crops are products of artificial evolutionary processes, which results from the genotype manipulation of plants with some nutritional or economic value for human1. As a result, genetic variability is lost over the time, and features such as flower and seed production, and also defense mechanisms are...
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| Format: | Article |
| Language: | English |
| Published: |
Selva Andina Research Society
2022-11-01
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| Series: | Journal of the Selva Andina Biosphere |
| Online Access: | http://www.scielo.org.bo/scielo.php?script=sci_arttext&pid=S2308-38592022000200066&lng=es&nrm=iso&tlng=en |
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| Summary: | Crops are products of artificial evolutionary processes, which results from the genotype manipulation of plants with some nutritional or economic value for human1. As a result, genetic variability is lost over the time, and features such as flower and seed production, and also defense mechanisms are also lost2. Although, in agriculture these characteristics may not be relevant to plant survival, the decrease in genetic variability leads to diseases, null stress tolerance and reduced nutritional value. Becoming a concern for farmers and leading us to the question: What can we do to conserve genetic diversity within crops?
One of the most widely used ways to increase genetic variability is to hybridize cultivated species with their wild relatives. In potato’s (Solanum tuberosum) case, there are approximately 110 wild relatives, 34 of which are native to Bolivia and 21 are endemic3. There are also 12 species records with some risk category4. These species are not edible, but are resistant to pests like fungus Phytophthora infestans and the nematode Globodera pallida4, similarly, these wild potatoes are resistant to drought and have the ability to grow in poor and stony soils4.
Potato research focuses on increasing and maintaining the size and quality of tubers, while enhancing other characteristics (resistance to pests, diseases and abiotic conditions). For example, hybridization tests between Solanum berthaultii and Solanum microdontum were found to maintain the agronomic quality in the product with a reduced tuber size5. Likewise, experiments were conducted with S. albornozii, S. andreanum, S. lesteri, S. longiconicum, S. morelliforme, S. stenophyllidium, S. mochiquense, S. cajamarquense, and S. huancabambense to improve the resistance to the fungus P. infestans6. But in Bolivia, what is the research status of potato wild relatives?
As one of the potato origin centers, Bolivia has a great diversity of cultivable varieties7. It is known at least 500 varieties used for consumption and added to the diversity of wild relatives, we have more than 600 species of the genus Solanum that produce tubers. Becoming Bolivia an important country for the conservation of the genetic diversity of potato crops. Unfortunately, few experimental studies on the subject are conducted in Bolivia, and most research is descriptive of morphology, ecology, and usage of potato wild relatives. This leaves us with important information gaps that would help in the improvement. |
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| ISSN: | 2308-3867 2308-3859 |