Mallesham Bulle | Plant Biotechnology | Outstanding Scientist Award

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Dr. Mallesham Bulle | Plant Biotechnology | Outstanding Scientist Award

Lousiana State University | United States

Dr. Mallesham Bulle, Ph.D., is a dedicated plant scientist with over a decade of experience in physiological, biochemical, and molecular investigations of abiotic stress tolerance in major crops, including chili pepper, rice, cotton, soybean, and maize. His research expertise spans plant transformation, CRISPR-Cas-mediated genome editing, phytohormone signaling, stress-response mechanisms, chloroplast and nuclear genome engineering, and omics-based approaches such as transcriptomics, metabolomics, and hormonomics. Dr. Bulle has led and contributed to multiple interdisciplinary projects, including climate-resilient rice and drought-tolerant legumes, securing significant research grants from USDA, NIFA, DBT, and United Soybean Board. He has developed robust plant regeneration and transformation systems, delivered novel transgenic and genome-edited crops, and mentored graduate and undergraduate researchers. His work demonstrates impactful contributions to crop improvement and abiotic stress resilience. His research interests include elucidating signaling pathways, deciphering fruit ripening mechanisms, exploring nitric oxide and phytohormone crosstalk, and discovering novel genes for crop stress tolerance. Dr. Bulle’s work has been recognized through patents for extending produce shelf-life and innovations in plant biotechnology. He continues to drive transformative research aimed at sustainable agriculture and climate-resilient crop development.

Profiles: Google Scholar | Orcid

Featured Publications

Bulle, M., Abbagani, S., & Raza, A. (2025). Genome blaze: Engineering chilli pepper chloroplasts for sustainable production of capsaicinoids through organellar genome editing. Plant Biology.

Bulle, M., Rahman, M. M., Islam, M. R., & Abbagani, S. (2025). Strategies to develop climate-resilient chili peppers: Transcription factor optimization through genome editing. Planta.

Rahman, M. M., Keya, S. S., Bulle, M., Ahsan, S. M., Rahman, M. A., Roni, M. S., Al Noor, M. M., & Hasan, M. (2025). Past trauma, better future: How stress memory shapes plant adaptation to drought. Functional Plant Biology.

Keya, S. S., Islam, M. R., Pham, H., Rahman, M. A., Bulle, M., Patwary, A., Kanika, M. M.-A.-R., Hemel, F. H., Ghosh, T. K., & Huda, N. (2025). Thirsty, soaked, and thriving: Maize morpho-physiological and biochemical responses to sequential drought, waterlogging, and re-drying. Plant Stress.

Bulle, M., Venkatapuram, A. K., Rahman, M. M., Attia, K. A., Mohammed, A. A., Abbagani, S., & Kirti, P. B. (2024). Enhancing drought tolerance in chilli pepper through AdDjSKI-mediated modulation of ABA sensitivity, photosynthetic preservation, and ROS scavenging. Physiologia Plantarum.

Azime Gökçe | Plant Physiology | Best Researcher Award

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Dr. Azime Gökçe | Plant Physiology | Best Researcher Award

Ege University, Faculty of Science, Department of Biology | Turkey

Dr. Azime Gökçe is a Postdoctoral Researcher at Ege University, Türkiye, specializing in plant physiology and stress biology. She received her Ph.D. in Plant Physiology in 2023 and currently holds a TÜBİTAK 2218 Postdoctoral Research Fellowship. Her research integrates molecular, biochemical, and physiological approaches to understand plant responses to abiotic stress, with a particular focus on redox homeostasis, ROS–RNS signalling, glutamate receptor-like (GLR) genes, nitric oxide pathways, and antioxidant defense mechanisms. Dr. Gökçe has published impactful studies in journals such as Plant Cell Reports, Plant Physiology and Biochemistry, Plant Growth Regulation, and Journal of Plant Research. She has led and contributed to multiple national and international projects funded by TÜBİTAK and collaborated with institutions including Syngenta and the Olive Research Institute. Her work also explores seed priming and biostimulant strategies to improve crop resilience under salinity, drought, and biotic stresses. With active roles as a reviewer and editorial board member, she contributes to scientific knowledge dissemination. As an early-career researcher, she has established herself as a promising scientist in plant stress physiology, aiming to translate fundamental discoveries into agricultural sustainability solutions.

Profile: Google Scholar

Featured Publications

Sekmen Çetinel, A. H., Gokce, A., Erdik, E., Cetinel, B., & Cetinkaya, N. (2021). The effect of Trichoderma citrinoviride treatment under salinity combined with Rhizoctonia solani infection in strawberry (Fragaria × ananassa Duch.). Agronomy.

Gokce, A., Sekmen Çetinel, A. H., & Turkan, I. (2024). Involvement of GLR-mediated nitric oxide effects on ROS metabolism in Arabidopsis plants under salt stress. Journal of Plant Research.

Sekmen Çetinel, A. H., Yalcinkaya, T., Akyol, T. Y., Gokce, A., & Turkan, I. (2021). Pretreatment of seeds with hydrogen peroxide improves deep-sowing tolerance of wheat seedlings. Plant Physiology and Biochemistry.

Gokce, A., Sekmen Çetinel, A. H., & Turkan, I. (2024). Carnitine modulates antioxidative defense in ABI2 mutant under salt stress. Plant Growth Regulation.

Sekmen Çetinel, A. H., Çetinel, B., Gokce, A., Tatli, C., & Erdik, E. (2022). Molecular mechanisms–relayed plant defense responses against fungal pathogens. In Phytomycology and Molecular Biology of Plant–Pathogen Interactions.

Hieronim Golczyk | Plant Genetics | Best Researcher Award

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Assoc. Prof. Dr. Hieronim Golczyk | Plant Genetics | Best Researcher Award

The John Paul II Catholic University of Lublin | Poland

Dr. Hieronim Golczyk is an Associate Professor at the Institute of Biological Sciences, The John Paul II Catholic University of Lublin, Poland. He earned his Habilitation in Biological Sciences with a specialization in Cytogenetics and Genetics from Adam Mickiewicz University in 2015. With over two decades of academic experience, including positions at the Jagiellonian University and collaborations with leading European research centers such as IPK Gatersleben and the Max Planck Institute, Dr. Golczyk has established himself as a distinguished figure in molecular cytogenetics. His research focuses on chromosome structure and function, genome evolution, fluorescence in situ hybridization (FISH) methodologies, and organelle genetics. He has pioneered several innovative cytogenetic techniques, including ImmunoFISH and EC-FISH, and contributed to landmark discoveries on genome transfer and chloroplast competition published in Nature and Plant Cell. Dr. Golczyk has authored over 60 scientific papers with an h-index of 16, more than 830 citations, and over 34 document reads. His achievements have been recognized by multiple Polish Genetic Society Awards and Rector’s Awards. As an active reviewer, educator, and member of advisory scientific boards, Dr. Golczyk continues to advance the understanding of genetic mechanisms underlying plant evolution and genome architecture.

Profiles: Scopus | Orcid

Featured Publications

Golczyk, H. (2025). A new efficient immunoprotocol to detect chromosomal/nuclear proteins along with repetitive DNA in squash preparations of formalin-fixed, long-stored root tips. Plant Methods.

Jach, M. E. (2023). The role of probiotics and their metabolites in the treatment of depression. Frontiers in Cellular and Infection Microbiology.

Golczyk, H., Hřibová, E., Doležel, J., Cuadrado, Á., Garbsch, F., Greiner, S., Janeczko, M., Szklarczyk, M., Masłyk, M., & Kubiński, K. (2022). Migration of repetitive DNAs during evolution of the permanent translocation heterozygosity in the oyster plant (Tradescantia section Rhoeo).

Saliha Ahmad | Plant Ecology | Best Researcher Award

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Ms. Saliha Ahmad | Plant Ecology | Best Researcher Award

Case Western Reserve University | United States

Saliha Ahmad is a PhD candidate in Biology whose research focuses on plant–microbe interactions, particularly microbial community dynamics under biotic and abiotic stresses. She has an h-index of 5, with approximately 193 citations to date (Google Scholar, ResearchGate). With an MPhil and MSc in Plant Sciences (both top-grade) and a strong undergraduate foundation in chemistry, botany, and zoology, she is currently pursuing her doctoral studies at Case Western Reserve University. Her expertise spans field sampling, molecular biology techniques such as DNA/RNA extraction, sequencing, gene expression, and bioinformatics, including microbial diversity analyses and statistical modeling in R (ResearchGate). Her research interests include the influence of water and nutrient stress on beneficial microbial assembly, microbial detoxification of pesticides, soil microbiome roles in plant health, and applications for sustainable agriculture and conservation. She has contributed publications on microbial detoxification of dimethoate, heavy metal biosorption by bacteria, and the role of poultry manure in crop growth and yield (ResearchGate, American Chemical Society Publications). She has also been recognized with multiple grants and awards for research excellence, travel, and merit, highlighting her growing recognition in the field (ResearchGate). Overall, Saliha Ahmad represents an emerging scholar who integrates empirical, laboratory, and computational approaches to address pressing challenges at the interface of microbiology, ecology, and agriculture, with a steadily increasing global impact reflected in her publications and citations.

Profile: Google Scholar

Featured Publications

“Bacillus thuringiensis PM25 ameliorates oxidative damage of salinity stress in maize via regulating growth, leaf pigments, antioxidant defense system, and stress …”

“Effects of poultry manure on the growth, physiology, yield, and yield-related traits of maize varieties”

“Microbial detoxification of dimethoate through mediated hydrolysis by Brucella sp. PS4: molecular profiling and plant growth-promoting traits”

“Dimethoate residues in Pakistan and mitigation strategies through microbial degradation: a review”
“Biosorption potential of Bacillus anthracis PM21 for the sequestration of cadmium, chromium, and nickel from contaminated water”

“Fungal communities driven by Rhododendron species correlate with pathogen protection against Phytophthora cinnamomi”