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    Characterization of ZmSnRK1 genes and their response to aphid feeding, drought and cold stress
    (Springer, 2024) Akbudak, M. Aydin; Yildiz, Kubra; Cetin, Durmus; Filiz, Ertugrul; Yukselbaba, Utku; Srivastava, Vibha
    The SnRK1 complex in plants regulates metabolism in response to environmental stresses and glucose depletion, for stress adaptation and energy homeostasis. Through phosphorylation of various targets, SnRK1 orchestrates intricate regulatory mechanisms involved in autophagy, nutrient remobilization, and TOR activity inhibition, showcasing its pivotal role in coordinating plant metabolism and stress responses. The present study aimed to identify members of the SnRK1 gene family in the maize genome and characterize them using bioinformatics and expression analyses under aphid feeding, drought, and cold stress. The focus of the study was to conduct a comprehensive analysis towards determining gene diversity of ZmSnRK1 genes, constructing intricate 3D structures, and identifying stress-related cis-elements. Four SnRK1 genes were identified, which were named ZmSnRK1.1, ZmSnRK1.2, ZmSnRK1.3, and ZmSnRK1.4. The SnRK1 proteins were found to have a distribution of conserved motifs; however, the distinction between monocots and dicots in the phylogenetic tree was clearly demonstrated. Analysis of the promoter region revealed that the ZmSnRK1 genes contain stress-related cis-elements. Compared to the control, ZmSnRK1.3 significantly upregulated in response to aphid feeding and cold stress, while ZmSnRK1.2 showed elevated expression under drought conditions. The expression of the other two genes under these treatments was generally unperturbed. The findings of this study are poised to establish a valuable scientific foundation for future research on the roles of the SnRK1 gene family in plants, providing valuable insights for enhancing genetic resilience to stress and optimizing yield traits.
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    Genes involved in mRNA surveillance are induced in Brachypodium distachyon under cadmium toxicity
    (Springer, 2021) Aksoy, Emre; Uncu, Ali Tevfik; Filiz, Ertugrul; Orman, Sule; Cetin, Durmus; Akbudak, M. Aydin
    Background Cd accumulation in plant cells results in dramatic problems including oxidative stress and inhibition of vital enzymes. It also affects mineral uptakes by disrupting membrane permeability. Interaction among Cd and other plant nutrient elements changes the nutritional contents of crops and reduces their yield. Methods and results In the present study, Cd stress in Brachypodium distachyon led to the upregulation of some heavy metal transport genes (influx or efflux) encoding cation-efflux proteins, heavy metal-associated proteins and NRAMP proteins. The Arabidopsis orthologs of the differentially expressed B. distachyon genes (DEGs) under Cd toxicity were identified, which exhibited Bradi4g26905 was an ortholog of AtALY1-2. Detailed co-expression network and gene ontology analyses found the potential involvement of the mRNA surveillance pathway in Cd tolerance in B. distachyon. These genes were shown to be downregulated by sulfur (S) deficiency. Conclusions This is the first transcriptomic study investigating the effect of Cd toxicity in B. distachyon, a model plant for genomic studies in Poaceae (Gramineae) species. The results are expected to provide valuable information for more comprehensive research related to heavy metal toxicity in plants.
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    Genome-wide exploration and analysis of plant stress-responsive CAMTA transcription factor genes in Brachypodium distachyon and their expression patterns under environmental challenges
    (Elsevier, 2024) Akbudak, M. Aydin; Cetin, Durmus; Filiz, Ertugrul; Srivastava, Vibha
    Calmodulin-binding transcription activators (CAMTAs) is a family of transcriptional factors, which are highly sensitive to various stressors and hormone signals. They are involved in regulating plant growth, development, stress response, and have distinct biological roles in different plant compartments. Although the gene families coding the CAMTA transcription factors have been identified and functionally characterized in many plant species, it has not been previously reported in Brachypodium distachyon, which is a model organism for genomic research in cereals and grasses. In the present study, seven novel CAMTA genes were identified in the B. distachyon genome, all of which contain the CG-1 (pfam03859) domain. Their sequence details were provided with exon numbers ranging from 10 to 13 and protein length varying from 836 to 1034 amino acid residues. All BdCAMTA proteins, except BdCAMTA1, were found to be acidic and localized to the nucleus. The BdCAMTA genes exhibit diverse responses to cold, drought, and salinity stresses, without being specific to any stress. Therefore, upcoming studies should prioritize the investigation of molecular mechanisms governing functional specificity and redundancy among individual members of CAMTA. These findings establish a valuable scientific foundation for future research concerning the roles of the CAMTA gene family in plants. (c) 2024 SAAB. Published by Elsevier B.V. All rights reserved.