Tshegofatso Bridget Dikobe scite author profile

Adenylate cyclases (ACs), much like guanylate cyclases (GCs), are increasingly recognized as essential parts of many plant processes including biotic and abiotic stress responses. In order to identify novel ACs, we have applied a search motif derived from experimentally tested GCs and identified a number of Arabidopsis thaliana candidates including a clathrin assembly protein (AT1G68110; AtClAP). AtClAP contains a catalytic centre that can complement the AC-deficient mutant cyaA in E. coli, and a recombinant AtClAP fragment (AtClAP261–379) can produce cyclic adenosine 3′,5′ monophosphate (cAMP) from adenosine triphosphate (ATP) in vitro. Furthermore, an integrated analysis of gene expression and expression correlation implicate cAMP in pathogen defense and in actin cytoskeletal remodeling during endocytic internalization.

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Recombinant Expression and Functional Testing of Candidate Adenylate Cyclase Domains

Ruzvidzo

Dikobe

Kawadza

et al. 2013

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Adenylate cyclases (ACs) are enzymes capable of converting adenosine-5'-triphosphate to cyclic 3', 5'--adenosine monophosphate (cAMP). In animals and lower eukaryotes, ACs and their product cAMP have firmly been established as important signalling molecules with important roles in several cellular signal transduction pathways. However, in higher plants, the only annotated and experimentally confirmed AC is a Zea mays pollen protein capable of generating cAMP. Recently a number of candidate AC-encoding genes in Arabidopsis thaliana have been proposed based on functionally assigned amino acids in the catalytic center of annotated and/or experimentally tested nucleotide cyclases in lower and higher eukaryotes. Here we detail the cloning and recombinant expression of functional candidate AC domains using, as an example, the A. thaliana pentatricopeptide repeat-containing protein (AtPPR-AC; At1g62590). Through a complementation test, in vivo adenylate cyclase activity of candidate recombinant molecules can be prescreened and promising candidates can subsequently be further evaluated in an in vitro AC immunoassay.

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Distinct Morpho-Physiological Responses of Maize to Salinity Stress

Dikobe¹,

Mashile²,

Sinthumule³

et al. 2021

AJPS

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Most plants demonstrate wide interactive and complex adaptive morphological, biochemical, and physiological responses when subjected to salinity stress. Salt stress negatively impacts agricultural yields more especially cultivated crops throughout the world. Of interest to this study is maize a saltsensitive crop that is widely grown worldwide, and receiving most attention due to its significant attributes and ability to serve as a great model for stress response studies. We exposed QN701 maize cultivar, to simulated salinity stress and investigated its morphological and physiological responses. Salinity negatively induced various morphological responses such as the reduction in plant height, number of leaves, shoot and root (length and biomass), and leaf width; however, it significantly increased the leaf area. On the physiological aspect, salt stress decreased the number of stomata, stomatal density, and photosynthesis, while it increased the respiration rate. This study expanded our knowledge of the morphological and physiological responses of maize to salinity stress. Additionally, these findings may serve as a recommendation for salinity breeding programs in maize and related cereal crops.

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Detection of E. coli Isolates in Water from Setumo Dam Mmabatho Area – North West Province, South Africa Using mdh Specific PCR Analysis

Dikobe

Sithebe

Ateba

2011

Journal of Human Ecology

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Identification and characterization of a soybean protein with adenylyl cyclase activity

Bobo¹,

Sehlabane²,

Dikobe³

et al. 2022

Commun. Plant Sci.

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Soybean [Glycine max (L.) Merrill] is a high value leguminous crop characterized by its excellent protein content and ability to improve soil quality through nitrogen fixation. Whereas this plant has attractive human and animal feed attributes in addition to its pharmaceutical and industrial uses, its growth and yield are severely affected by drought. Thus any research aimed at understanding the genome response of this plant to drought and other related environmental stress factors would be worthwhile. In plants, in general, second messengers have a key role in linking and coordinating environmental stimuli to cellular communication and responses. One group of such messengers are adenylyl cyclases (ACs) and their catalytic product 3′,5′-cyclic adenosine monophosphate (cAMP), involved in plant growth, cell division, reproduction, development and response to stress. However, while ACs have been reported in some plant species such as Arabidopsis and maize, their presence together with their cAMP-dependent systems in G. max have largely remained unavailable. Fortunately, a putative molecule, Glyma.07G251000 (accession number: XP_003529590), with a predicted function as an AC in G. max has at some point been reported. This molecule harbors a domain annotated AC catalytic center and therefore, was herein targeted for study. In order to characterize the Glyma.07G251000, we cloned and expressed it, followed by purification of the resultant recombinant protein (GmAC). When tested in vitro for AC activity, the GmAC protein showed a Mn 2+ -dependent activity that is positively enhanced by calcium. GmAC also complemented the AC-deficiency (cyaA mutation) of an SP850 mutant strain when expressed in Escherichia coli. When analysed by a web-based approach system, the GmAC protein was found to be co-expressed and co-regulated with various other proteins responsible for early plant development and stress response, strongly suggesting that it has a central role in these two key cellular processes. In addition, the GmAC protein conferred stress resistance to EXPRESS BL21 (DE3) pLysS DUOs cells when expressed in these host cells under salt (200 mM NaCl) and oxidative stress (0.2 mM H2O2). Conceivably, our findings showed that GmAC is an AC protein with a role in early plant development and stress response. Highlighted Conclusions1. GmAC is an adenylyl cyclase and the first ever such protein to be identified in soybean. 2. GmAC confers stress tolerance to Escherichia coli and is co-expressed/co-regulated with other soybean proteins responsible for early plant development and stress response.

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