Ketan Doshi scite author profile

Main conclusion Using RNA profiling, we identified several silver thiosulfate-induced genes that potentially control the masculinization of female Cannabis sativa plants. Abstract Genetically female Cannabis sativa plants normally bear female flowers, but can develop male flowers in response to environmental and developmental cues. In an attempt to elucidate the molecular elements responsible for sex expression in C. sativa plants, we developed genetically female lines producing both female and chemically-induced male flowers. Furthermore, we carried out RNA-Seq assays aimed at identifying differentially expressed genes responsible for male flower development in female plants. The results revealed over 10,500 differentially expressed genes, of which around 200 potentially control masculinization of female cannabis plants. These genes include transcription factors and other genes involved in male organ (i.e., anther and pollen) development, as well as genes involved in phytohormone signalling and male-biased phenotypes. The expressions of 15 of these genes were further validated by qPCR assay confirming similar expression patterns to that of RNA-Seq data. These genes would be useful for understanding predisposed plants producing flowers of both sex types in the same plant, and help breeders to regulate the masculinization of female plants through targeted breeding and plant biotechnology.

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Anthocyanin expression in marker free transgenic wheat and triticale embryos

Doshi

Eudes

Laroche

et al. 2007

In Vitro Cell.Dev.Biol.-Plant

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Wheat and triticale plants were transformed by bombardment of isolated scutella with a genetic construct consisting of the two anthocyanin biosynthesis regulatory genes, C1 and Bperu, each under the control of the Ltp1 embryo-specific promoter. Transgenic plants were obtained in the absence of selective pressure and selectable marker gene at a transformation frequency of 0.93% and 1.55% in triticale and wheat, respectively. Initial screening of T 0 lines was performed by polymerase chain reaction (PCR), and further confirmation of PCR positives was done using realtime PCR and by phenotypic observation. In this study, quantitative real-time PCR (qRT-PCR) was developed to determine the transgene copy number in transgenic wheat and triticale. A conserved wheat housekeeping gene, puroindoline-b, was used as an internal control to calculate the transgene copy number in wheat and the SYBR green detection method with a standard curve, constructed on the basis of serially diluted plasmid, was used to calculate the transgene copy in triticale. Estimated transgene copies varied from 3 to 8 in wheat and 4 to 7 in triticale lines. The presence of anthocyanin regulatory genes, promoter, and termination sequences was detected in six wheat lines and four triticale lines. However, anthocyanin-pigmented embryos were only observed visually in mature T 1 seeds of two transgenic wheat lines and a single triticale line. Multisite insertion and reorganization of transgenes was likely the explanation for the failure of expression for the anthocyanin genes in the remaining wheat and triticale transgenic lines.

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Bringing plant-based veterinary vaccines to market: Managing regulatory and commercial hurdles

MacDonald

Doshi

Dussault

et al. 2015

Biotechnology Advances

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The production of recombinant vaccines in plants may help to reduce the burden of veterinary diseases, which cause major economic losses and in some cases can affect human health. While there is abundant research in this area, a knowledge gap exists between the ability to create and evaluate plant-based products in the laboratory, and the ability to take these products on a path to commercialization. The current report, arising from a workshop sponsored by an Organisation for Economic Co-operation and Development (OECD) Co-operative Research Programme, addresses this gap by providing guidance in planning for the commercialization of plant-made vaccines for animal use. It includes relevant information on developing business plans, assessing market opportunities, manufacturing scale-up, financing, protecting and using intellectual property, and regulatory approval with a focus on Canadian regulations.

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Agrobacterium-mediated transformation of tarwi (Lupinus mutabilis Sweet), a potential platform for the production of plant-made proteins

Polowick

Loukanina

Doshi

2014

In Vitro Cell.Dev.Biol.-Plant

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Ketan Doshi

The case for plant-made veterinary immunotherapeutics

Comparative RNA-Seq analysis reveals genes associated with masculinization in female Cannabis sativa

Anthocyanin expression in marker free transgenic wheat and triticale embryos

Bringing plant-based veterinary vaccines to market: Managing regulatory and commercial hurdles

Agrobacterium-mediated transformation of tarwi (Lupinus mutabilis Sweet), a potential platform for the production of plant-made proteins

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