Pollen Tube Energetics: Respiration, Fermentation and the Race to the Ovule

Overview

Journal AoB Plants

Date 2012 Apr 6

PMID 22476489

Citations 31

Authors

Caleb M Rounds

Lawrence J Winship

Peter K Hepler

Affiliations

Soon will be listed here.

Abstract

Background: Pollen tubes grow by transferring chemical energy from stored cellular starch and newly assimilated sugars into ATP. This drives myriad processes essential for cell elongation, directly or through the creation of ion gradients. Respiration plays a central role in generating and regulating this energy flow and thus in the success of plant reproduction. Pollen tubes are easily grown in vitro and have become an excellent model for investigating the contributions of respiration to plant cellular growth and morphogenesis at the molecular, biochemical and physiological levels.

Scope: In recent decades, pollen tube research has become increasingly focused on the molecular mechanisms involved in cellular processes. Yet, effective growth and development requires an intact, integrated set of cellular processes, all supplied with a constant flow of energy. Here we bring together information from the current and historical literature concerning respiration, fermentation and mitochondrial physiology in pollen tubes, and assess the significance of more recent molecular and genetic investigations in a physiological context.

Conclusions: The rapid growth of the pollen tube down the style has led to the evolution of high rates of pollen tube respiration. Respiration rates in lily predict a total energy turnover of 40-50 fmol ATP s(-1) per pollen grain. Within this context we examine the energetic requirements of cell wall synthesis, osmoregulation, actin dynamics and cyclosis. At present, we can only estimate the amount of energy required, because data from growing pollen tubes are not available. In addition to respiration, we discuss fermentation and mitochondrial localization. We argue that the molecular pathways need to be examined within the physiological context to understand better the mechanisms that control tip growth in pollen tubes.

Citing Articles

Homeostasis of flavonoids and triterpenoids most likely modulates starch metabolism for pollen tube penetration in rice.

Wu H, Xie D, Jia P, Tang Z, Shi D, Shui G Plant Biotechnol J. 2023; 21(9):1757-1772.

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Post-pollination sepal longevity of female flower co-regulated by energy-associated multiple pathways in dioecious spinach.

Ma X, Fatima M, Li J, Zhou P, Zaynab M, Ming R Front Plant Sci. 2023; 13:1010149.

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Bioenergetics of pollen tube growth in Arabidopsis thaliana revealed by ratiometric genetically encoded biosensors.

Liu J, Lim S, Zhong J, Lim B Nat Commun. 2022; 13(1):7822.

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Cytosolic disproportionating enzyme2 is essential for pollen germination and pollen tube elongation in rice.

Chen L, Dong X, Yang H, Chai Y, Xia Y, Tian L Plant Physiol. 2022; 191(1):96-109.

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Depletion plays a pivotal role in self-incompatibility, revealing a link between cellular energy status, cytosolic acidification and actin remodelling in pollen tubes.

Wang L, Lin Z, Carli J, Gladala-Kostarz A, Davies J, Franklin-Tong V New Phytol. 2022; 236(5):1691-1707.

PMID: 35775998 PMC: 9796540. DOI: 10.1111/nph.18350.

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