Genetic Control of Storage Root Development

Genetic Control of Storage Root Development

The formation of plants' storage organs, in particular the storage root, is an example of plants’ specialization in the accumulation of substances. Studying the genetic mechanisms for the development of the storage root is very relevant in connection with the economic importance of root crops....

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Bibliographic Details
Published in:Russian journal of plant physiology Vol. 67; no. 4; pp. 589 - 605
Main Authors: Kuznetsova, K. A., Dodueva, I. E., Pautov, A. A., Krylova, E. G., Lutova, L. A.
Format: Journal Article
Language:English
Published: Moscow Pleiades Publishing 01-07-2020
Springer Nature B.V
Subjects:
Accumulation
Biomedical and Life Sciences
Brassica
Carrots
Cassava
Cell proliferation
Crops
Economic importance
Genetic control
Homeobox
Life Sciences
Meristems
Nutrients
Organs
Peptides
Plant Physiology
Plant Sciences
Potatoes
Regulators
Reviews
Root development
Signal peptides
Specialization
Storage organs
Sweet potatoes
Transcription factors
Xylem
xylem
storage root
cambium
transcription factors
plant
phloem
starch
lignin
root crop
root tubers
phytohormones
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Summary:The formation of plants' storage organs, in particular the storage root, is an example of plants’ specialization in the accumulation of substances. Studying the genetic mechanisms for the development of the storage root is very relevant in connection with the economic importance of root crops. Nevertheless, the genetic control of storage root’s development is currently poorly studied. The major volume of dicotyledonous plants' storage root is usually occupied by highly parenchymatous secondary conducting tissues (phloem and/or xylem), which are formed as a result of proliferation of cambium cells and are specialized in the accumulation of nutrients. Currently, a number of regulators of cambium development have been identified. The WOX-CLAVATA system (including the CLE signal peptides, their receptors, and their targets: homeodomain-containing WOX transcription factors), as well as transcription factors of other families and phytohormones, control the activity of the cambium meristem. The review presents up-to-date data on the mechanisms of cambium activity’s regulation, differentiation of conductive tissues and nutrient storage, and data on conservative and specific regulators of the development of storage roots in the best studied root crops: radishes, turnips, beets, carrots, sweet potatoes, and cassava.
ISSN:1021-4437
1608-3407
DOI:10.1134/S102144372004010X