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Exploring Florida Native plants for specialized metabolites of pharmaceutical value

We are interested in exploring medicinally relevant species, initially belonging to plant families Lamiaceae, Plantagiaceae and Rubiaceae for plant specialized metabolites to identify bioactive compounds, their spatio-temporal patterns of accumulation and decipher metabolic pathways.

Medicinal plants 

Scutellaria, a Florida native ornamental with potential anti-cancer properties

Scutellaria spp has tremendous potential for the ornamental and medicinal plant industry in Florida. The root extract of S. baicalensis has been widely used for medicine in Asia for over 2,000 years, and it has a variety of bioactivities, e.g., anti-inflammatory, anti-cancer and neuro-psychologic properties due to synthesis of unique flavonoids and indolic compounds. Commercially, it has a scutellaria-integrifoliamarket for ornamental and medicinal applications including supplement capsules, dried plants for tea, powdered or liquid extracts. Florida native species, S. integrifolia and S. arenicola also synthesize these active medicinal compounds and in order to develop Scutellaria crop as a new enterprise crop, we need to identify germplasm and best production practices, while evaluating the metabolite profiles under controlled environments to maximize the synthesis of active pharmaceuticals. This project is a part of a new UF team “MICE (Medicinals In Controlled Environments)” across UF IFAS and College of Pharmacy

As a part of “Support for Emerging Enterprise Development Integration Teams” (SEEDIT), we will evaluate Florida native Scutellaria species in FL landscape locations for ornamental & medicinal purposes, manipulate controlled environment in order to maximize pharmaceutically active metabolites, quantify price and quality of existing Scutellaria products and develop enterprise budget and communicate project outcomes with producers, processors and entrepreneurs.

Genome-wide evaluation of off-targets from gene editing reagents in seed vs. vegetatively propagated crop species

Gene-editing by CRISPR systems provide an unprecedented advancement in genome engineering due to precise DNA manipulation. Genome-editing is being widely applied in plants and has revolutionized crop improvement by offering the ability to generate transgene-free plants. Tremendous progress has been made recently to increase the specificity of CRISPR reagents by structure-guided protein Camelina - researchengineering to develop variants of Cas9 such as hyper-accurate Cas9 (Hypa Cas9). As alternative CRISPR-Cas12a is also emerging as an effective reagent for gene-editing in plants. Base-editing technology based on CRISPR/Cas9 system generates base substitutions without requiring dsDNA cleavage. There are no studies to date that characterize genome-editing reagents’ specificity in plants. The recently streamlined regulatory processes by the USDA opened up new opportunities for scientists to develop improved crops and useful agricultural products. Therefore, there is a need to be able to effectively assess this emerging technology in terms of genome-wide off-target effects before it is applied to new crop varieties. As a part of USDA – Biotechnology risk assessment Grant project, we will use CRISPR/Cas9, Cas12a, HypaCas9, base editors and TALENs to target economically important candidate genes in vegetatively propagated potato and seed propagated Camelina sativa, an alternative oilseed crop in order to quantify the frequency of off-target variation caused by gene-editing reagents by whole genome sequencing. This study would provide comprehensive risk assessment of gene-editing in crop species.

Genome engineering in medicinal plants using CRISPR systems


Although CRISPR/Cas9 has been applied to various crop species, its application in medicinal plant species has been limited, mainly due to lack of genomic resources and established genetic engineering protocols in various species. With recent efforts in development of genomic resources, for example Mint Genome Project ( would facilitate studies on evolution of specialized metabolites in the Lamiaceae family, genes contributing to their diversity in phenotype and chemistry. Functional characterization of biosynthetic enzymes has mostly been done in heterologous expression systems. However, in order to achieve pathway engineering by manipulating the metabolic pathways and regulating the metabolic flux to produce increased bioactive compounds, established plant genetic transformation and gene-editing protocols would be important along with the availability of genomic resources. We are interested to explore these possibilities in medicinal plants specific to our study.