Regulation Of Cell Division In Higher Plants Progress Report

Regulation of Cell Division in Higher Plants. Progress Report

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Page : 7 pages

File Size : 48,33 MB

Release : 1992

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Book Description

Cell division is arguably the most fundamental of all developmental processes. In higher plants, mitotic activity is largely confined to foci of patterned cell divisions called meristems. From these perpetually embryonic tissues arise the plant's essential organs of light capture, support, protection and reproduction. Once an adequate understanding of plant cell mitotic regulation is attained, unprecedented opportunities will ensue for analyzing and genetically controlling diverse aspects of development, including plant architecture, leaf shape, plant height, and root depth. The mitotic cycle in a variety of model eukaryotic systems in under the control of a regulatory network of striking evolutionary conservation. Homologues of the yeast cdc2 gene, its catalytic product, p34, and the cyclin regulatory subunits of the MPF complex have emerged as ubiquitous mitotic regulators. We have cloned cdc2-like and cyclin genes from pea. As in other eukaryotic model systems, p34 of Pisum sativum is a subunit of a high molecular weight complex which binds the fission yeast p13 protein and displays histone H1 kinase activity in vitro. Our primary objective in this study is to gain baseline information about the regulation of this higher plant cell division control complex in non-dividing, differentiated cells as well as in synchronous and asynchronous mitotic cells. We are investigating cdc2 and cyclin expression at the levels of protein abundance, protein phosphorylation and quaternary associations.



Regulation of Cell Division in Higher Plants. Progress Report, 1993

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Page : 4 pages

File Size : 33,23 MB

Release : 1993

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Recent work on the project has been focused almost exclusively on obtaining and characterizing CDNA clones encoding cylcin-dependent kinases (CDK), and cycling from pea. All of our work up to this time has relied on small PCR-generated CDNA clones of 2 putative pea CDKs and a putative pea mitotic cyclin, as well as anti-CDK antibodies of poor affinity and questionable specificity. Therefore, it has become a high priority for us to generate clones, probes and immunological tools in our own system. As of this writing, we have four putative CDKs (CdkPsl,2,3, & 4) and five putative cyclins (Cyc-Ps1,2,3,4, & 5), the DNA sequences of which have been determined to varying degrees of completeness.



Cell Division Control in Plants

Author : Desh Pal S. Verma

Publisher : Springer Science & Business Media

Page : 417 pages

File Size : 17,72 MB

Release : 2007-11-23

Category : Science

ISBN : 3540734872

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Book Description

This volume examines the molecular basis of all aspects of cell division and cytokinesis in plants. It features 19 chapters contributed by world experts in the specific research fields, providing the most comprehensive and up-to-date knowledge on cell division control in plants. The editors are veterans in the field of plant molecular biology and highly respected worldwide.



Regulation of Cell Division in Higher Plants. Final Technical Report

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Page : 7 pages

File Size : 29,14 MB

Release : 2000

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Research in the latter part of the grant period was divided into two parts: (1) expansion of the macromolecular tool kit for studying plant cell division; (2) experiments in which the roles played by plant cell cycle regulators were to be cast in the light of the emerging yeast and animal cell paradigm for molecular control of the mitotic cycle. The first objectives were accomplished to a very satisfactory degree. With regard to the second part of the project, we were driven to change our objectives for two reasons. First, the families of cell cycle control genes that we cloned encoded such closely related members that the prospects for success at raising distinguishing antisera against each were sufficiently dubious as to be impractical. Epitope tagging is not feasible in Pisum sativum, our experimental system, as this species is not realistically transformable. Therefore, differentiating the roles of diverse cyclins and cyclin-dependent kinases was problematic. Secondly, our procedure for generating mitotically synchronized pea root meristems for biochemical studies was far too labor intensive for the proposed experiments. We therefore shifted our objectives to identifying connections between the conserved proteins of the cell cycle engine and factors that interface it with plant physiology and development. In this, we have obtained some very exciting results.



The Plant Cell Cycle

Author : Dirk Inzé

Publisher : Springer Science & Business Media

Page : 240 pages

File Size : 17,60 MB

Release : 2011-06-27

Category : Science

ISBN : 9401009368

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Book Description

In recent years, the study of the plant cell cycle has become of major interest, not only to scientists working on cell division sensu strictu , but also to scientists dealing with plant hormones, development and environmental effects on growth. The book The Plant Cell Cycle is a very timely contribution to this exploding field. Outstanding contributors reviewed, not only knowledge on the most important classes of cell cycle regulators, but also summarized the various processes in which cell cycle control plays a pivotal role. The central role of the cell cycle makes this book an absolute must for plant molecular biologists.



The Cell Division Cycle in Plants: Volume 26, The Cell Division Cycle in Plants

Author : J. A. Bryant

Publisher : CUP Archive

Page : 280 pages

File Size : 35,73 MB

Release : 1985-05-02

Category : Science

ISBN : 9780521300469

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Book Description

Control points within the cell cycle. The organization of replicons. Enzymic controls of DNA replication. DNA replication in relation to DNA C values. Chromatin structure, gene espression and the cell cycle. Changes in chromatin structure during the cell cycle. The cytoskeleton and the cell cycle. Growth substances, calcium and the regulation of cell division. Regulation of the cell division cycle in cultured plant cells. Genetic and epigenetic control of the plant cell cycle. The control of the cell cycle in relation to floral induction. The DNA endoredduplication cycles. The chloroplast division cycle and its relationship to the cell division cycle.



Regulation of Cell Division in Higher Plants

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Publisher :

Page : 7 pages

File Size : 13,77 MB

Release : 1992

Category :

ISBN :

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Book Description

Cell division is arguably the most fundamental of all developmental processes. In higher plants, mitotic activity is largely confined to foci of patterned cell divisions called meristems. From these perpetually embryonic tissues arise the plant's essential organs of light capture, support, protection and reproduction. Once an adequate understanding of plant cell mitotic regulation is attained, unprecedented opportunities will ensue for analyzing and genetically controlling diverse aspects of development, including plant architecture, leaf shape, plant height, and root depth. The mitotic cycle in a variety of model eukaryotic systems in under the control of a regulatory network of striking evolutionary conservation. Homologues of the yeast cdc2 gene, its catalytic product, p34, and the cyclin regulatory subunits of the MPF complex have emerged as ubiquitous mitotic regulators. We have cloned cdc2-like and cyclin genes from pea. As in other eukaryotic model systems, p34 of Pisum sativum is a subunit of a high molecular weight complex which binds the fission yeast p13 protein and displays histone H1 kinase activity in vitro. Our primary objective in this study is to gain baseline information about the regulation of this higher plant cell division control complex in non-dividing, differentiated cells as well as in synchronous and asynchronous mitotic cells. We are investigating cdc2 and cyclin expression at the levels of protein abundance, protein phosphorylation and quaternary associations.





Role of Ca{sup ++}/calmodulin in the Regulation of Microtubules in Higher Plants. Progress Report, FY 1992

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Page : 7 pages

File Size : 11,27 MB

Release : 1992

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Book Description

The cytoskeleton including its microtubule (Mt) component participates in processes that directly affect growth and development in higher plants. Normal cytoskeletal function requires the precise and orderly arrangement of Mts into several cell cycle and developmentally specific arrays. The cortical array somehow directs the deposition of cellulose. Little molecular information is available regarding the formation of these arrays or the cellular signals to which they respond. Experimental data described here suggests that plant cells use calcium, in the form of a Ca{sup ++}/calmodulin complex, to affect the dynamics of Mts within the cortical array. Owing to the importance of Ca{sup ++} as a regulatory ion in higher plants we are probing for a putative Ca{sup ++}/Mt transduction pathway which may serve to integrate Mt activities within the growing and developing plant cell. We are using a lysed cell model in conjunction with immunocytochemical and biochemical methodologies to dissect how Ca{sup ++}/calmodulin interacts with Mts to affect their function.