Ezaz Al Mamun scite author profile

Low temperatures during rice ( Oryza sativa L.) pollen development cause pollen sterility and decreased grain yield. We show that the time of highest sensitivity to cold coincides with the time of peak tapetal activity: the transition of the tetrad to early uni-nucleate stage (young microspore, YM stage). Low temperatures at this stage of pollen development result in an accumulation of sucrose in the anthers, accompanied by decreased activity of cell wall bound acid invertase and depletion of starch in mature pollen grains. Expression analysis of two cell wall ( OSINV1, 4 ) and one vacuolar ( OSINV2 ) acid invertase genes showed that OSINV4 is anther-specific and downregulated by cold treatment. OSINV4 is transiently expressed in the tapetum cell layer at the YM stage, and later from the early binucleate stage in the maturing microspores. The down-regulation of OSINV4 expression in the tapetum at YM may cause a disruption in hexose production and starch formation in the pollen grains. In a cold-tolerant cultivar, OSINV4 expression was not reduced by cold; sucrose did not accumulate in the anthers and starch formation in the pollen grains was not affected.

show abstract

Effects of chilling on male gametophyte development in rice

Mamun

Alfred

Cantrill

et al. 2006

Cell Biology International

128

116

View full text Add to dashboard Cite

Chilling during male gametophyte development in rice inhibits development of microspores, causing male sterility. Changes in cellular ultrastructure that have been exposed to mild chilling include microspores with poor pollen wall formation, abnormal vacuolation and hypertrophy of the tapetum and unusual starch accumulation in the plastids of the endothecium in post-meiotic anthers. Anthers observed during tetrad release also have callose (1,3-beta-glucan) wall abnormalities as shown by immunocytochemical labelling. Expression of rice anther specific monosaccharide transporter (OsMST8) is greatly affected by chilling treatment. Perturbed carbohydrate metabolism, which is particularly triggered by repressed genes OsINV4 and OsMST8 during chilling, causes unusual starch storage in the endothecium and this also contributes to other symptoms such as vacuolation and poor microspore wall formation. Premature callose breakdown apparently restricts the basic framework of the future pollen wall. Vacuolation and hypertrophy are also symptoms of osmotic imbalance triggered by the reabsorption of callose breakdown products due to absence of OsMST8 activity.

show abstract

Cellular organisation in meiotic and early post-meiotic rice anthers

Mamun

Cantrill

Overall

et al. 2005

Cell Biology International

View full text Add to dashboard Cite

We have used fluorescent, confocal laser and transmission electron microscopy (TEM) to examine cellular organisations, including callose (1,3-beta-glucan) behaviour, in meiotic and early post-meiotic rice anthers. These features are critical for pollen formation and provide information to better understand pollen sterility caused by abiotic stress in rice and other monocotyledonous species. Among organelles during meiosis, abundant plastids, mitochondria and nuclei of the anther cells show distinctive features. Chloroplasts in the endothecium store starch and indicate a potential for photosynthetic activity. During meiosis, the middle layer cells are markedly compressed and at the tetrad stage are either vacuolated or filled with degenerating electron-opaque organelles. Viable mitochondria, stained with Rhodamine 123, are seen in the endothecium and tapetum, but the mitochondria in the middle layer are not stained during meiosis. The radial walls of the tapetum are disorganised and degenerating, indicating the formation of a syncytium; pro-orbicules are located at the locular walls at the tetrad stage. Immunohistochemical studies show that the sporogenous cells are entirely enveloped by a thick callosic layer at early meiosis. Cell plate callose was assembled in a plane between the dyad cells. In the tetrads, however, callose formed only at the centre, showing that the tetrad microspores are not enveloped but separated by callose walls. Thick, undulating electron-opaque walls around the tetrads indicate the beginning of exinous microspore wall differentiation.

show abstract

Cellular organisation and differentiation of organelles in pre-meiotic rice anthers

Mamun¹,

Cantrill²,

Overall³

et al. 2005

Cell Biology International

View full text Add to dashboard Cite

Pre-meiotic cellular organisation of rice anthers has a great significance in pollen formation. We have used a combination of confocal laser and transmission electron microscopy (TEM) to characterise and differentiate organelles in pre-meiotic rice anthers. Along with the characteristic organelles in the cytoplasm the epidermal cells of the pre-meiotic rice anther are coated on their outer surface by a conspicuous bi-lamellate cuticle. Chloroplasts of the endothecium contain immature grana, thylakoids and also starch granules. These plastids clearly contain photosynthetic pigments as shown by autofluorescence in confocal microscope studies. Both confocal and TEM studies reveal clusters of mitochondria in the middle layer. The tapetum contains electron opaque ribosomes, bundles of mitochondria and plastids. The nuclei of the tapetum occupy a large volume of the cytoplasm indicating the onset of mitotic prophase. Intense Rhodamine 123 staining reveals that a major portion of the structurally indistinguishable organelles that were seen throughout the densely ribosomic cytoplasm of sporogenous cells are mitochondria.

show abstract

Sorghum can Compensate for Chilling‐Induced Grain Loss

Wood¹,

Tan²,

Mamun³

et al. 2006

J Agronomy Crop Science

View full text Add to dashboard Cite

Chilling during male gametophyte development in sorghum (Sorghum bicolor L. Moench) inhibits development of microspores, causing male sterility. The aim of this study was to assess the effects of night chilling on yield components in sorghum. This study identified and employed collar distance as a morphological marker of anther development following chilling. Two cultivars Buster and Bonus, were subjected to three temperature regimes (25/20°C, 25/12°C and 25/8°C) for five consecutive nights at 0 cm collar distance, which corresponds to the meiotic stage of anther development. Pollen viability, grain number and harvest index were reduced in both cultivars at 12 and 8°C night temperatures. Total grain weight of cultivar Bonus was not reduced as much as Buster at 12°C because of the ability of Bonus to increase individual grain weight when grain number was low. This work further elucidates the mechanism and genetic potential of chilling-induced yield compensation for developing sorghum cultivars that are better adapted to low night temperatures.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Ezaz Al Mamun

Cold‐induced repression of the rice anther‐specific cell wall invertase gene OSINV4 is correlated with sucrose accumulation and pollen sterility

Effects of chilling on male gametophyte development in rice

Cellular organisation in meiotic and early post-meiotic rice anthers

Cellular organisation and differentiation of organelles in pre-meiotic rice anthers

Sorghum can Compensate for Chilling‐Induced Grain Loss

Contact Info

Product

Resources

About