Your search keyword '"Manfrini, L."' showing total 2 results

1. Changes in vascular and transpiration flows affect the seasonal and daily growth of kiwifruit (Actinidia deliciosa) berry

Author

Luigi Manfrini, Luca Corelli Grappadelli, Pasquale Losciale, Brunella Morandi, Marco Zibordi, Morandi B., Manfrini L., Losciale P., Zibordi M., and Corelli Grappadelli L.

Subjects

WATER RELATIONSHIPS, Vapour Pressure Deficit, Actinidia, Hydrostatic pressure, Growth, Plant Science, Phloem, Xylem, Photosynthesis, Transpiration, Actinidia deliciosa, Plant Stems, biology, Diurnal temperature variation, Water, food and beverages, Biological Transport, Plant Transpiration, Original Articles, ACTINIDIA DELICIOSA, biology.organism_classification, Vascular bundle, VAPOUR PRESSURE DEFICIT, Plant Leaves, FRUIT TRANSPIRATION, Agronomy, FRUIT GROWTH, Fruit, Seasons, Plant Shoots

Abstract

Background and Aims The kiwifruit berry is characterized by an early stage of rapid growth, followed by a relatively long stage of slow increase in size. Vascular and transpiration flows are the main processes through which water and carbon enter/exit the fruit, determining the daily and seasonal changes in fruit size. This work investigates the biophysical mechanisms underpinning the change in fruit growth rate during the season. † Methods The daily patterns of phloem, xylem and transpiration in/outflows have been determined at several stages of kiwifruit development, during two seasons. The different flows were quantified by comparing the diurnal patterns of diameter change of fruit, which were then girdled and subsequently detached while measurements continued. The diurnal courses of leaf and stem water potential and of fruit pressure potential were also monitored at different times during the season. † Key Results Xylem and transpiration flows were high during the first period of rapid volume growth and sharply decreased with fruit development. Specific phloem import was lower and gradually decreased during the season, whereas it remained constant at whole-fruit level, in accordance with fruit dry matter gain. On a daily basis, transpiration always responded to vapour pressure deficit and contributed to the daily reduction of fruit hydrostatic pressure. Xylem flow was positively related to stem-to-fruit pressure potential gradient during the first but not the last part of the season, when xylem conductivity appeared to be reduced. †Conclusions The fruit growth model adopted by this species changes during the season due to anatomical modifications in the fruit features.

Published

2010

2. Changes in vascular and transpiration flows affect the seasonal and daily growth of kiwifruit (Actinidia deliciosa) berry.

Author

Morandi B, Manfrini L, Losciale P, Zibordi M, and Corelli Grappadelli L

Subjects

Actinidia physiology, Biological Transport physiology, Phloem physiology, Photosynthesis, Plant Leaves physiology, Plant Shoots physiology, Plant Stems physiology, Seasons, Water physiology, Actinidia growth & development, Fruit growth & development, Growth physiology, Plant Shoots growth & development, Plant Transpiration physiology, Xylem physiology

Abstract

Background and Aims: The kiwifruit berry is characterized by an early stage of rapid growth, followed by a relatively long stage of slow increase in size. Vascular and transpiration flows are the main processes through which water and carbon enter/exit the fruit, determining the daily and seasonal changes in fruit size. This work investigates the biophysical mechanisms underpinning the change in fruit growth rate during the season., Methods: The daily patterns of phloem, xylem and transpiration in/outflows have been determined at several stages of kiwifruit development, during two seasons. The different flows were quantified by comparing the diurnal patterns of diameter change of fruit, which were then girdled and subsequently detached while measurements continued. The diurnal courses of leaf and stem water potential and of fruit pressure potential were also monitored at different times during the season., Key Results: Xylem and transpiration flows were high during the first period of rapid volume growth and sharply decreased with fruit development. Specific phloem import was lower and gradually decreased during the season, whereas it remained constant at whole-fruit level, in accordance with fruit dry matter gain. On a daily basis, transpiration always responded to vapour pressure deficit and contributed to the daily reduction of fruit hydrostatic pressure. Xylem flow was positively related to stem-to-fruit pressure potential gradient during the first but not the last part of the season, when xylem conductivity appeared to be reduced., Conclusions: The fruit growth model adopted by this species changes during the season due to anatomical modifications in the fruit features.

Published

2010