Genomics, Bioinformatics, and Systems Biology
The Baltrus lab is interested in understanding microbial evolution with a focus on the mechanisms and costs of adaptation and guided by expectations from genomics and population genetics.
The focus of my lab is functional evolution in the plant family Brassicaceae. Currently my group uses protein diversity from across land plants to decode the evolutionary history of plant signaling systems. We collaborate in these efforts with...
Research focus: (i) Dynamics of distribution, prevalence, and co-diversification driving emergent hemipteran-transmitted plants pathogens in cultivated and natural scapes, including the phytobiome (ii) Functional genomic-identification of...
Our research aims to comprehend the mechanistic interactions between plants, microbiomes, and ecosystem processes. Understanding this interplay is necessary for advancing sustainable agriculture and addressing climate change.
His research centers around the development of new technologies and methods for the analysis of eukaryotes. Recognized as a pioneer in flow cytometry, his recent contributions have greatly improved our understanding of cell-specific gene expression.
My research program is directed at understanding the systems biology that controls seed composition and biotechnology to create seed traits including low allergen content, animal feed, and as a protein bio-factory.
Understanding the structure, evolution, and dynamics of genomes.
Dr. McMahon researches phylogenetic and phylogenomic methods, systematics of the legume family (Fabaceae), and phylogenetic diversity of regional floras. She also directs the UA Herbarium.
In the Melandri Lab we investigate physiological and biochemical mechanisms able to confer heat and drought stress tolerance to crops and we try to identify their genetic control.
Eukaryotes contain an array of small RNAs capable of transcriptional and post-transcriptional gene regulation. These ubiquitous molecules are part of many biological processes, including development, response to the environment, and disease....
Develop new tomato varieties that are high yielding even under heat stress. Overcoming reproductive hybridization barriers in Brassicaceae model plants so that we can generate tools to break species barrier and generate novel hybrids.
Research focus is on biofortification of crops and the alteration of both lipid and protein composition
The Schomer lab studies bacterial behaviors involved in the formation and maintenance of soil microbiomes. We use -omics enabled approaches to understand bacterial adaptations that allow them to locate and colonize host plants.
Our research is focused on understanding how cellular energy transduction is regulated and the molecular evolution of genes that control plant adaptation. These two projects intersect in their importance for plant growth in saline environments.
Our lab is focused on structural and evolutionary genomics of crop plants, and is leading an international effort to generate reference genome sequences for all 24 species of the genus Oryza, which contains the world most important food crop – rice.
My research aims to understand the intricate interplays between viruses and their plant hosts during infection, mechanisms of plant resistance to viral infections, RNA virus evolution, and viral population genomics.
Transcriptional regulation of early plant development.
