B.S., Michigan State University, 1960
M.S., Purdue University, 1962
Ph.D., University of California at Berkeley, 1968
1968-1971, Michigan State University
1986-1987, Fulbright Fellow, Herbrew University, Jerusalem, Israel
Plant Cell and Development
The development of plants and animals and their ability to function requires the programmed death of individual cells. But plants are unique in that whole, differentiated organs, such as leaves and flowers, die as the plant continues to live. This process rids the continually growing plant of appendages that are no longer beneficial. We are investigating the factors that lead to organ death and are asking what initiates this program.
The daylily flower is an excellent model system to study organ senescence. The petals die synchronously and autonomously only 24 hours after the flower opens. We have shown that petal cell death is due in part to reactive oxygen species causing a loss of membrane permeability. Furthermore, the activities of suicide proteins such as proteinases and nucleases increase markedly just after the flower opens. We have also measured increases in the hormone, abscisic acid (ABA), whose addition prematurely causes many of the same changes that would only occur later during senescence.
Using differential display to identify mRNAs that are upregulated during normal senescence or after ABA treatment, 6 cDNAs have been cloned so far, two of which appear to be suicide genes. We are now poised to determine how the genes are regulated, either normally or after ABA additions. We also intend to look for expression of these genes in flowers of tobacco and Arabidopsis, where transformation experiments can be carried out more easily.
Stephenson, P. and Rubinstein, B. 1998. Characterization of proteolytic activity during senescence in daylilies. Physiol. Plant. (in press).
Panavas, T. and Rubinstein, B. 1998. Oxidative events during programmed cell death of daylily (Hemerocallis hybrid) petals. Plant Science 134: 1-9.
Panavas, T., Reid, P.D., and Rubinstein, B. 1998. Programmed cell death of daylily petals: activities of wall-based enzymes and effects of heat shock. Plant Physiol. Biochem. 36: 379-388.
Rubinstein, B. and Osborne, B.A. 1997. Dying for a living: plants do it too. Cell Death Differentiation. 4: 647-648.
Panavas, T. and Rubinstein, B. 1997. Effects of heat shock on wall-based enzymes and programmed cell death of daylily petals. Plant Physiol. and Biochem. (submitted).
Stephenson, P., Collins, B.A., Reid, P.D. and Rubinstein, B. 1996. Localization of ubiquitin to differentiating vascular tissues. Amer. J. Bot.83: 140-147.
Muller, M.L., Irkens-Keisecker, Rubinstein, B. and Taiz, L. 1996 On the mechanism of hyperacidification in lemon: comparison of the vacuolar H+-ATPase activities of fruits and epicotyls. J. Biol. Chem. 271: 1916-1924.
- Department at a Glance
- Current News
- Upcoming Events
- Job Openings
- How to Contact Us
- How to Find Us
- Administrative Services
- Computer Services
- Major Requirements
- Major Requirements Checklist (PDF)
- Recommended Course Sequences
- Integrative Experience
- Minor Requirements
- Departmental Honors
- Course Catalog
- Course Websites
- Course Applications
- Learning Goals
- Research Opportunities
- Awards & Scholarships
- BioSci Club
- Residential Programs
- Undergrad Handbook (PDF)
- Biology Computer Resource Center
- Central Microscopy
- Genomics & Bioinformatics
- Natural History Collections
- Single Molecule/Live Cell Imaging Facility
- Vibrating Probe Facility
- Zebrafish Facilities
- Make a Gift…