Premature dissolution of the microsporocyte callose wall causes male sterility in transgenic tobacco.

Worrall, Dawn; Hird, Diane L.; Hodge, Rachel; Paul, Wyatt; Draper, John; Scott, Rod

doi:10.1105/tpc.4.7.759

Cited by 285 publications

(140 citation statements)

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“…In many other plants and in normal pollen development, soon after meiosis, cell separation generally occurs to release the free microspores from the tetrads (Figure 4.1E and F). During this process, a decrease of pH (Izhar and Frankel, 1971;Worrall et al, 1992) and a peak of β-(1,3)-glucanase activity were observed in the anther locular fluid (Stieglitz, 1977) suggesting that this enzyme may be involved in the degradation of the tetrad wall. Degradation of the callose wall requires a complex of endo-and exo-enzymes, called callase.…”

Section: Microspore Separationmentioning

confidence: 99%

“…A tight developmental regulation is de facto required to synchronize the production of wall-degrading enzymes by the tapetal cells with the maturation of the PMCs. Indeed, the premature dissolution of the callose wall or premature programmed cell death of the tapetum, which normally occurs during the late pollen formation, lead generally to a reduction in male fertility (Worrall et al, 1992;Tsuchiya et al, 1995;Ku et al, 2003). Several possible callase members have been described.…”

Section: Microspore Separationmentioning

confidence: 99%

“…In contrast, callose is one of the main wall polysaccharides of the PMCs, microspores and pollen tubes but its role in pollen development is not clear. It was suggested that callose could isolate the microspores and/or serve as a template for the proper formation of exine -the outer wall layer of the mature pollen grains (Worrall et al, 1992;Scott et al, 2004). In pollen tubes, the callose wall was recently implicated in protection against tension and compression stresses (Parre and Geitmann, 2005).…”

mentioning

confidence: 99%

“…In pollen tubes, the callose wall was recently implicated in protection against tension and compression stresses (Parre and Geitmann, 2005). Several studies with transgenic tobacco plants (Worrall et al, 1992;Tsuchiya et al, 1995) and Arabidopsis mutants (Dong et al, 2005b) have shown that an accurate callose wall deposition is a prerequisite for the normal development of the future pollen grains. In Arabidopsis, mutations in the CalS5 gene, encoding a callose synthase in PMCs, tetrads and microspores exhibited a lack of callose in the microspore wall leading to the abnormal formation of the exine wall and degeneration of the microspores (Dong et al, 2005b).…”

mentioning

confidence: 99%

“…This study supports the hypothesis that callose deposition, at the plasma membrane, may serve as a template for the proper synthesis of exine and this exine wall has an important function in pollen development. Nevertheless, the PMC callosic wall is apparently not essential for the proper nuclear meiotic processes (Worrall et al, 1992;Scott et al, 2004). …”

mentioning

confidence: 99%

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Cell Adhesion, Separation and Guidance in Compatible Plant Reproduction

Mollet¹,

Faugeron²,

Morvan³

Plant Cell Separation and Adhesion

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Section: Microspore Separationmentioning

confidence: 99%

Section: Microspore Separationmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Cell Adhesion, Separation and Guidance in Compatible Plant Reproduction

Mollet¹,

Faugeron²,

Morvan³

Plant Cell Separation and Adhesion

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Male Sterility and Hybrid Production Systems

Oliver

2004

Handbook of Plant Biotechnology

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The ability to exploit the long known phenomenon of hybrid vigor or heterosis, the superior performance of the F1 hybrid compared to either parent line, has greatly impacted the goal of production agriculture to meet world food demands. Hybrid production systems rely on an efficient and effective mechanism for inducing male sterility in one of the parental lines in order to ensure purity of the resultant hybrid seed. Natural male sterility systems are available but are limited in their availability for all crops and their effectiveness in those for which they have been developed. This chapter discusses the means by which modern techniques of genetic engineering have broadened our ability to develop male sterile lines and improve hybrid production strategies. The chapter discusses the development of dominant male sterility systems using genetic ablation and developmental disruption strategies, conditional male sterility strategies and the genetic engineering of maintainer lines. The generation of novel and improved systems for hybrid production in the ongoing search for crop improvement has been, and continues to be, one of the major targets for transgenic manipulations within the agricultural biotechnological community.

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Genome‐wide analysis of the callose enzyme families of fertile and sterile flower buds of the Chinese cabbage (Brassica rapa L. ssp. pekinensis)

Hou

Guo

et al. 2019

FEBS Open Bio

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Callose is a β‐1,3‐glucan commonly found in higher plants that plays an important role in regulating plant pollen development. It is synthesized by glucan synthase‐like (GSL) and is degraded by the enzyme endo‐1,3‐β‐glucosidase. However, genome‐wide analyses of callose GSL and endo‐1,3‐β‐glucosidase enzymes in fertile and sterile flower buds of Chinese cabbage have not yet been reported. Here, we show that delayed callose degradation at the tetrad stage may be the main cause of microspore abortion in Chinese cabbage with nuclear sterility near‐isogenic line ‘10L03’. Fifteen callose GSLs and 77 endo‐1,3‐β‐glucosidase enzymes were identified in Chinese cabbage. Phylogenetic, gene structural and chromosomal analyses revealed that the expansion occurred due to three polyploidization events of these two gene families. Expression pattern analysis showed that the GSL and endo‐1,3‐β‐glucosidase enzymes are involved in the development of various tissues and that the genes functionally diverged during long‐term evolution. Relative gene expression analysis of Chinese cabbage flowers at different developmental stages showed that high expression of the synthetic enzyme BraA01g041620 and low expression of AtA6‐homologous genes (BraA04g008040, BraA07g009320, BraA01g030220 and BraA03g040850) and two other genes (BraA10g020080 and BraA05g038340) for degrading enzymes in the meiosis and tetrad stages may cause nuclear sterility in the near‐isogenic line ‘10L03’. Overall, our data provide an important foundation for comprehending the potential roles of the callose GSL and endo‐1,3‐β‐glucosidase enzymes in regulating pollen development in Chinese cabbage.

show abstract

Premature dissolution of the microsporocyte callose wall causes male sterility in transgenic tobacco.

Cited by 285 publications

References 33 publications

Cell Adhesion, Separation and Guidance in Compatible Plant Reproduction

Cell Adhesion, Separation and Guidance in Compatible Plant Reproduction

Male Sterility and Hybrid Production Systems

Genome‐wide analysis of the callose enzyme families of fertile and sterile flower buds of the Chinese cabbage (Brassica rapa L. ssp. pekinensis)

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