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Literature DB >> 16937052

The extracellular pollen coat in members of the Brassicaceae: composition, biosynthesis, and functions in pollination.

Abstract

I have used cellular and molecular genetic and bioinformatic approaches to characterise the components of the pollen coat in plants of the family Brassicaceae, including Arabidopsis thaliana and several brassicas including Brassica napus, B. oleracea, and B. rapa. The pollen coat in these species is mostly made up of a unique mixture of lipids that is highly enriched in acylated compounds, such as sterol esters and phospholipids. These acyl lipids are characterised by an unusually high degree of saturation. The fatty acids typically contain 70-90% saturated acyl residues such as myristate, palmitate, and stearate. The major sterol components of the pollen coat are saturated fatty acyl esters of stigmasterol, campesterol, and campestdienol. In addition to lipids, the second major component of the pollen coat is a specific group of proteins that is dominated by a family of proteins that we term pollenins. Although pollenins are by far the major protein components of the pollen coat of members of the Brassicaceae, proteomic analysis reveals that there are several additional protein components, including lipases, protein kinases, a pectin esterase, and a caleosin. The biosynthesis of these lipids and proteins and their significance for overall pollen function are reviewed and discussed.

Entities: Chemical Gene Species

Mesh：

Substances：
Plant Proteins

Year: 2006 PMID： 16937052 DOI： 10.1007/s00709-006-0163-5

Source DB: PubMed Journal: Protoplasma ISSN： 0033-183X Impact factor: 3.356

35 in total

Review 1. Pollen recognition and rejection during the sporophytic self-incompatibility response: Brassica and beyond.

Authors: Simon J Hiscock; Stephanie M McInnis
Journal: Trends Plant Sci Date: 2003-12 Impact factor: 18.313

2. Characterization of anther-expressed genes encoding a major class of extracellular oleosin-like proteins in the pollen coat of Brassicaceae.

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Journal: Plant J Date: 1996-05 Impact factor: 6.417

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Journal: Prog Lipid Res Date: 1998 Jul-Aug Impact factor: 16.195

5. Inflorescence-specific genes from Arabidopsis thaliana encoding glycine-rich proteins.

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Journal: Plant J Date: 1993-04 Impact factor: 6.417

6. Isolation and characterization of neutral-lipid-containing organelles and globuli-filled plastids from Brassica napus tapetum.

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Journal: Proc Natl Acad Sci U S A Date: 1997-11-11 Impact factor: 11.205

7. Molecular identification of cytosolic, patatin-related phospholipases A from Arabidopsis with potential functions in plant signal transduction.

Authors: André Holk; Steffen Rietz; Marc Zahn; Hartmut Quader; Günther F E Scherer
Journal: Plant Physiol Date: 2002-09 Impact factor: 8.340

8. Oleosins in the gametophytes of Pinus and Brassica and their phylogenetic relationship with those in the sporophytes of various species.

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Journal: Planta Date: 1994 Impact factor: 4.116

9. Maize tapetum xylanase is synthesized as a precursor, processed and activated by a serine protease, and deposited on the pollen.

Authors: Sherry S H Wu; Der Fen Suen; Han Chang Chang; Anthony H C Huang
Journal: J Biol Chem Date: 2002-10-03 Impact factor: 5.157

10. Modifying the pollen coat protein composition in Brassica.

Authors: Elizabeth Foster; Danielle Schneiderman; Michel Cloutier; Stephen Gleddie; Laurian S Robert
Journal: Plant J Date: 2002-08 Impact factor: 6.417

26 in total

Review 1. The dynamic roles of intracellular lipid droplets: from archaea to mammals.

Authors: Denis J Murphy
Journal: Protoplasma Date: 2011-10-15 Impact factor: 3.356

2. A pollen coat-inducible autoinhibited Ca2+-ATPase expressed in stigmatic papilla cells is required for compatible pollination in the Brassicaceae.

Authors: Megumi Iwano; Motoko Igarashi; Yoshiaki Tarutani; Pulla Kaothien-Nakayama; Hideki Nakayama; Hideki Moriyama; Ryo Yakabe; Tetsuyuki Entani; Hiroko Shimosato-Asano; Masao Ueki; Gen Tamiya; Seiji Takayama
Journal: Plant Cell Date: 2014-02-25 Impact factor: 11.277

3. A dye combination for the staining of pollen coat and pollen wall.

Authors: Xin-Lei Jia; Jing-Shi Xue; Fang Zhang; Chi Yao; Shi-Yi Shen; Chang-Xu Sui; Yu-Jia Peng; Qin-Lin Xu; Yi-Feng Feng; Wen-Jing Hu; Ping Xu; Zhong-Nan Yang
Journal: Plant Reprod Date: 2021-04-26 Impact factor: 3.767

4. Defective Pollen Wall 2 (DPW2) Encodes an Acyl Transferase Required for Rice Pollen Development.

Authors: Dawei Xu; Jianxin Shi; Carsten Rautengarten; Li Yang; Xiaoling Qian; Muhammad Uzair; Lu Zhu; Qian Luo; Gynheung An; Fritz Waßmann; Lukas Schreiber; Joshua L Heazlewood; Henrik Vibe Scheller; Jianping Hu; Dabing Zhang; Wanqi Liang
Journal: Plant Physiol Date: 2016-05-31 Impact factor: 8.340

5. Pollen-Specific Aquaporins NIP4;1 and NIP4;2 Are Required for Pollen Development and Pollination in Arabidopsis thaliana.

Authors: Juliana Andrea Pérez Di Giorgio; Gerd Patrick Bienert; Nicolás Daniel Ayub; Agustín Yaneff; María Laura Barberini; Martín Alejandro Mecchia; Gabriela Amodeo; Gabriela Cynthia Soto; Jorge Prometeo Muschietti
Journal: Plant Cell Date: 2016-04-19 Impact factor: 11.277