Analysis of the Tomato Fruit Growth Response to Temperature and Plant Fruit Load in Relation to Cell Division, Cell Expansion and DNA Endoreduplication

doi:10.1093/aob/mci042

AOBPreview originally published online on December 6, 2004
Annals of Botany 2005 95(3):439-447; doi:10.1093/aob/mci042

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Analysis of the Tomato Fruit Growth Response to Temperature and Plant Fruit Load in Relation to Cell Division, Cell Expansion and DNA Endoreduplication

N. BERTIN^*

Unité Plantes et Systèmes de culture Horticoles, INRA, Site Agroparc, F-84914 Avignon Cedex 9, France

^* For correspondence. E-mail nadia.bertin{at}avignon.inra.fr

Received: 8 July 2004 Returned for revision: 20 September 2004 Accepted: 15 October 2004 Published electronically: 6 December 2004

• Background and Aims To better understand the regulationof fruit growth in response to environmental factors, the effectsof temperature and plant fruit load on cell number, cell sizeand DNA endoreduplication were analysed.

• Methods Plants were grown at 20/20 °C, 25/25 °Cand 25/20 °C day/night temperatures, and inflorescenceswere pruned to two (‘2F’) or five (‘5F’)flowers.

• Key Results and Conclusions Despite a lower fruit growthrate at 20/20 °C, temperature did not affect final fruitsize because of the compensation between cell number and size.The higher cell number at 20/20 °C (9·0 x 10⁶ against7·9 x 10⁶ at 25/25 °C and 7·7 x 10⁶ at 25/20°C) resulted from an extended period of cell division, andthe smaller cell size was due to a shorter period of expansionrather than a lower expansion rate. By contrast, the lower fruitgrowth rate and size of 5F fruits compared with 2F fruits resultedfrom the slow down of cell expansion, whereas the number ofcells was hardly affected in the proximal fruit. However, withinthe inflorescence the decreasing gradient of fruit size fromproximal to distal fruits was due to a decrease in cell numberwith similar cell size. Fruit size variations within each treatmentwere always positively correlated to variations in cell number,but not in cell size. Negative correlations between cell sizeand cell number suggested that cells of tomato pericarp canbe seen as a population of competing sinks. Mean ploidy wasslightly delayed and reduced in 5F fruits compared with 2F fruits.It was highest at 25/25 °C and lowest at 25/20 °C. Treatmentsdid not affect ploidy and cell size in similar ways, but withineach treatment, positive correlations existed between mean ploidyand cell size, though significant only in the 2F-25/20 treatment.

Key words: Cell division, cell size, endoreduplication, ploidy, temperature, competition, tomato, Lycopersicon esculentum Mill

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