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Vivian Irish, PhD

Eaton Professor of Molecular, Cellular and Developmental Biology and Professor of Ecology and Evolutionary Biology
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About

Titles

Eaton Professor of Molecular, Cellular and Developmental Biology and Professor of Ecology and Evolutionary Biology

Biography

Dr. Vivian Irish is the Daniel C. Eaton Professor of Molecular, Cellular and Developmental Biology. She obtained her Ph.D. from Harvard University, where she characterized the role of the DPP/TGFbeta signaling pathway in specifying dorsal-ventral polarity in the Drosophila embryo. After postdoctoral work investigating anterior-posterior patterning in Drosophila, she turned her attention to exploring patterning processes in the Arabidopsis flower. For a number of years she has focused on characterizing the genes and pathways regulating organogenesis and growth in the flower. She has also explored the extent to which these pathways are conserved across different flowering plant species. Using molecular, genetic and modeling approaches, her current research is centered on understanding how cells and tissues are patterned, epigenetic control of developmental processes, and how stem cell activity is regulated in plants. Additionally, part of her work focuses on biotechnological applications to improve agriculture.


Appointments

Other Departments & Organizations

Education & Training

Postdoctoral Fellow
Yale University (1991)
Postdoctoral Fellow
Cambridge University (1989)
PhD
Harvard University, Cell and Developmental Biology (1986)
BA
Wesleyan University, Biology (1980)

Research

Overview

The Irish lab is interested in understanding plant growth and development. Our current research efforts are described below.

Stem cell proliferation and arrest in Citrus

In plants, cells of the shoot apical meristem (SAM) act as stem cells, giving rise to more stem cells as well as specialized cell types contributing to the leaves, branches and fruit. We are investigating the basis for thorn development in Citrus as a means to understand how the termination of stem cell proliferation is controlled. Thorns arise from SAM cells that fail to self-renew, and instead terminally differentiate, providing a unique opportunity to explore how SAM cell proliferation is controlled. We are using a combination of transcriptomics, molecular genetics and newly developed transgenic approaches to identify the genes and processes responsible for thorn development and how this unusual stem cell arrest process is controlled. Citrus plant growth, fruit yield and harvest costs are all affected by thorniness, and so understanding how to manipulate thorn production will also greatly impact the economics of this valuable fruit crop.

Control of petal organogenesis

Organ formation, whether in animals or plants, depends on several processes. These include delimitation of where an organ will form, growth of the organ, and its consequent differentiation. Using the Arabidopsis petal as a model organ system, we are investigating the genes and cellular processes that contribute to the development of this seemingly simple organ type. We are examining how a transcriptional repressor, RBE, coordinately regulates both organ boundary formation and organ growth. We have shown that RBE acts early in petal development to control the formation of organ boundaries, and recent results suggest that RBE also regulates a transcriptional cascade of events that act as a timing mechanism to control organ growth. We are currently investigating the cellular basis for growth control in petals, and how transcriptional changes are manifested as changes in cell proliferation.

Control of petal cell type differentiation

Petal conical epidermal cells are covered in radiate nanoridges that give these cells unique physical properties. The nanoridges are vital for pollinator attraction, iridescence, wettability, and can provide tactile cues. However, the molecular, cellular, and mechanical bases for how this unusual cell type is formed and functions is not well understood. We are using a combination of biochemical, molecular genetic, and modeling approaches to develop a mechanistic understanding of how conical epidermal cell morphology is achieved.

Medical Research Interests

Arabidopsis; Biological Evolution; Developmental Biology; Ecology; Genetics; Human Development; Molecular Biology

Research at a Glance

Yale Co-Authors

Frequent collaborators of Vivian Irish's published research.

Publications

2024

2023

2021

2020

2018

2017

Academic Achievements & Community Involvement

  • honor

    Fellow

  • honor

    Elected Member

  • honor

    Daniel C. Eaton Professor

  • honor

    President

  • honor

    Visiting Professor

Get In Touch

Contacts

Locations

  • Yale Science Building

    Academic Office

    260 Whitney Avenue, Ste Room 425

    New Haven, CT 06511