Calcium and Signal Transduction in Plants

Poovaiah, B. W.; Reddy, A. S. N.

doi:10.1080/713608046

Cited by 125 publications

(142 citation statements)

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“…Calmodulin, a ubiquitous and multifunctional Ca2+-binding protein in eukaryotes, interacts and modulates the activity/function of a number of proteins (Poovaiah and Reddy, 1993;Roberts and Harmon, 1992). Here, we show that the truncated KCBP containing the motor domain along with the calmodulin-binding region does not bind to tubulin subunits in the presence of Ca2+-calmodulin.…”

Section: Discussionmentioning

confidence: 81%

“…Among motor proteins, the heavy chain of some actin-based myosin motors and light chain of microtubule-based kinesin motors show calcium and calmodulin-dependent regulation (Matthies etal., 1993;Wolenski, 1995). The presence of a calmodulin-binding domain next to the motor domain in KCBP and its binding to calmodulin at micromolar calcium concentration raises an interesting possibility that calcium, an important messenger molecule in plant and animal systems (Gilroy and Trewavas, 1994;Poovaiah and Reddy, 1993;Roberts and Harmon, 1992), through calmodulin, may regulate the interaction of KCBP with tubulin. In the present study we have investigated the binding of KCBP to tubulin subunits and the possible role of Ca2+-calmodulin in modulating KCBP interaction with tubulin subunits.…”

Section: Introductionmentioning

confidence: 99%

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Interaction of Arabidopsis kinesin‐like calmodulin‐binding protein with tubulin subunits: modulation by Ca²⁺‐calmodulin

Narasimhulu

Kao

Reddy³

1997

The Plant Journal

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Section: Discussionmentioning

confidence: 81%

Section: Introductionmentioning

confidence: 99%

Interaction of Arabidopsis kinesin‐like calmodulin‐binding protein with tubulin subunits: modulation by Ca²⁺‐calmodulin

Narasimhulu

Kao

Reddy³

1997

The Plant Journal

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“…L'augmentation de la concentration intracellulaire de Ca 2+ joue un rôle fondamental dans plusieurs mécanismes incluant: 1) l'activation de la G-1,3-glucane synthase, l'enzyme impliquée dans la formation de callose, un polymère structural de të-1,3-glucanes (Kauss et al 1989); 2) la stimulation des protéines kinases impliquées dans la phosphorylation des protéines; 3) la formation du complexe Ca 2+ -calmoduline associé au cytosquelette; et 4) la transduction du signal au noyau (Poovaiah et Reddy 1993;fig. 5).…”

Section: Glycopeptideunclassified

La résistance induite : une nouvelle stratégie de défense des plantes contre les agents pathogènes

Benhamou¹,

Picard

2005

phyto

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Tout au long de leur co-évolution, les plantes et les microorganismes pathogènes ont développé des relations complexes résultant d'un échange constant d'informations moléculaires. Les agents pathogènes ont élaboré toute une gamme de stratégies offensives pour parasiter les plantes et en contrepartie, les plantes ont déployé un arsenal défensif similaire à bien des égards aux défenses immunitaires animales. Les percées récentes en biologie moléculaire et en transformation des végétaux ont démontré que sensibiliser une plante à répondre plus rapidement à l'infection pouvait lui conférer une protection accrue contre des microorganismes virulents. Un aspect important dans la mise en évidence du rôle joué par les molécules de défense au niveau de l'expression de la résistance est une connaissance exacte de leur localisation spatio-temporelle dans les tissus en état de stress. Afin de cerner le processus associé à l'induction de résistance chez les plantes, l'effet d'éliciteurs biologiques, microbiens et chimiques sur la réponse cellulaire des plantes envers une attaque pathogène a fait l'objet d'investigations et les mécanismes impliqués dans le phénomène ont été étudiés. Dans tous les cas, il a été montré qu'une corrélation existait entre la réponse globale de la plante et des changements dans la biochimie et la physiologie des cellules, lesquels étaient accompagnés de modifications structurales incluant la formation d'appositions pariétales riches en callose et l'infiltration de composés phénoliques aux sites de pénétration potentielle par l'agent pathogène. L'activation du sentier des phénylpropanoïdes est un phénomème crucial dans la restriction de la croissance de l'agent pathogène et dans la survie des cellules-hôtes en conditions de stress. Bien qu'il n'existe que peu d'exemples d'application pratique de la résistance induite en tant que méthode de lutte contre les maladies des plantes, les résultats obtenus à partir de quelques expériences menées en plein champ et en serre sont encourageants et indiquent que cette approche a le potentiel de devenir une stratégie de lutte efficace et durable contre toute une gamme d'agents pathogènes.During the course of their coevolution, plants and pathogens have evolved an intricate relationship resulting from a continuous exchange of molecular information. Pathogens have developed an array of offensive strategies to parasitize plants and, in turn, plants have deployed a wide range of defense mechanisms similar in some respects to the immune defenses produced in animais. The recent advances in molecular biology and plant transformation have provided evidence that sensitizing a plant to respond more rapidly to infection could confer increased protection against virulent pathogens. One important facet in ascertaining the significance of defense molecules in plant disease resistance isthe exact knowledgeof their spatio-temporal distribution in stressed plant tissues. In an effort to understand the process associated with the induction of plant disease resistance, the effect of ...

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“…(e) Autoradiograph showing Ca# + -activated phosphorylation of histone (used as a model substrate) by a CDPK extracted from nonhormone treated aleurone tissue assayed as in (c) Ca# + and calmodulin. Changes in the concentrations of cytoplasmic Ca# + , often mediated through the regulatory protein CaM, are recognized as ubiquitous signal transduction elements in animal and plant cells (reviewed in Gilroy, Bethke & Jones, 1993 ;Poovaiah & Reddy, 1993 ;Bush, 1995). The cytoplasmic Ca# + concentration ([Ca# + ]) of barley and wheat aleurone cells is elevated from 100 n to around 500 n by GA, whereas ABA reduces Ca# + concentrations ( Fig.…”

Section: Transduction Of the Ga Signalmentioning

confidence: 99%

Gibberellins: regulating genes and germination

Ritchie

Gilroy

1998

New Phytologist

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The range of processes regulated by gibberellins (GAs) covers all aspects of the life history of the plant from seed germination to vegetative growth and flowering. In seeds there has been an intensive search, using the techniques of both biochemistry and cell biology, for the regulatory molecules linking GA perception to gene regulation and the events of germination. Although a GA receptor has yet to be identified, the site of perception has been localized to the plasma membrane. Calmodulin, Ca2+ and cGMP have also been identified as elements of the GA signal transduction pathway. These regulators parallel many of the signalling elements identified in the transduction of other signals such as phytochrome and ABA. Studies of GA‐regulated gene expression, principally of the α‐amylases of cereal aleurone, have identified core GA‐responsive promoter elements, such as the gibberellin response element (GARE), box‐1 and pyrimidine boxes, as well as elements that may lend specificity to GA‐regulated expression, such as the Opaque‐2‐similar element (O2S), and TRE and CRE motifs. One of the most striking features of all of these studies of the molecular basis of GA action is the interaction of GA‐dependent regulatory elements with those of other factors such as ABA. GA‐response elements also appear to be conserved between disparate GA‐response systems. For example, Myb transcription factors appear to regulate a multitude of GA‐induced genes in cereal aleurone as well as to alter GA responses when expressed in Arabidopsis. Thus the study of GA signal transduction and response systems is highlighting the conservation of regulatory elements used by plants. These common factors, used by distinct signal transduction systems, provide a molecular basis for the integration of the GA signal with other growth regulators that is the hallmark of plant growth and development.

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Calcium and Signal Transduction in Plants

Cited by 125 publications

References 0 publications

Interaction of Arabidopsis kinesin‐like calmodulin‐binding protein with tubulin subunits: modulation by Ca²⁺‐calmodulin

Interaction of Arabidopsis kinesin‐like calmodulin‐binding protein with tubulin subunits: modulation by Ca²⁺‐calmodulin

La résistance induite : une nouvelle stratégie de défense des plantes contre les agents pathogènes

Gibberellins: regulating genes and germination

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Calcium and Signal Transduction in Plants

Cited by 125 publications

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Interaction of Arabidopsis kinesin‐like calmodulin‐binding protein with tubulin subunits: modulation by Ca2+‐calmodulin

Interaction of Arabidopsis kinesin‐like calmodulin‐binding protein with tubulin subunits: modulation by Ca2+‐calmodulin

La résistance induite : une nouvelle stratégie de défense des plantes contre les agents pathogènes

Gibberellins: regulating genes and germination

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Interaction of Arabidopsis kinesin‐like calmodulin‐binding protein with tubulin subunits: modulation by Ca²⁺‐calmodulin

Interaction of Arabidopsis kinesin‐like calmodulin‐binding protein with tubulin subunits: modulation by Ca²⁺‐calmodulin