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Cold-modulated expression of genes encoding for key enzymes of the sugar metabolism in spring and autumn cvs. of Beta vulgaris L.

Published online by Cambridge University Press:  21 February 2011

D. Pacifico
Affiliation:
CRA-CIN (Centro di ricerca per le Colture Industriali), via di Corticella, 133, 40128Bologna, Italy
C. Onofri
Affiliation:
CRA-CIN (Centro di ricerca per le Colture Industriali), via di Corticella, 133, 40128Bologna, Italy
G. Mandolino*
Affiliation:
CRA-CIN (Centro di ricerca per le Colture Industriali), via di Corticella, 133, 40128Bologna, Italy
*
*Corresponding author. E-mail: giuseppe.mandolino@entecra.it

Abstract

An integrated approach based on the use of bioinformatics and gene expression analysis tools was carried out to evaluate the organ-specific transcription modulation of nine genes relevant to sugar metabolism of Beta vulgaris L. plantlets of the autumn cv. Franca and spring cv. Bianca, in response to low-temperature (LT) treatments. Different growth cycles imply different plant capability to adapt to the environment that includes variations in gene expression of key metabolic enzymes. The transcriptional response was evaluated by quantitative PCR analysis before, during and after the LT treatments. The results were correlated with the LT-induced electrolyte leakage measure and the carbohydrate content. Stress-induced transcript level alterations were detected in the two cultivars, suggesting a modulation of sucrose synthesis and carbohydrate partitioning. Cold stress induced deep changes in the autumn cultivar, especially in fructose-1,6-biphosphatase gene expression, irrespective of temperature or exposure time. These differential features of expression profiles constitute first clues on the molecular basis of the differential LT response of sugarbeet autumn and spring cultivars.

Type
Research Article
Copyright
Copyright © NIAB 2011

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