• EEB Home
• Find EEB People
  • All EEB people
  • Faculty-EEB
  • Faculty-Affiliated
  • PostDocs
  • Grad students
  • Advising Staff
  • Administrative Staff
  • All Staff
  • Former Grad Students
  • Search EEB People
• Faculty Research
  • By research interest
  • By study organism
  • EEB Faculty list
• Courses
  • EEB course websites
  • Schedule of Classes
  • Course Descriptions
  • Room Schedule of EEB Courses
• News & Events
  • Upcoming events
  • Current news
  • Monday seminar
  • Tuesday seminar
  • Jobs at EEB
  • The Drift (weekly newsletter)
  • News and Views (twice-yearly alumni newsletter)
  • Attachments
• Business Office
  • Business Office Home
  • Hiring
  • Purchasing
  • Grant Budgeting
  • Travel
  • Risk Management
  • Facilities
• Resources
  • Affiliated departments
  • Outreach
  • Collections
  • Facilities
• Help & Info
  • EEB help desk
  • Locate/contact EEB
  • Search eebweb
  • About EEB
  • About eebweb

Tuesday "Noon" Seminar : Sept. 19

12:30-1:45 p.m. in Biosciences West (map of building location), Room 208

Talk Abstract

Adaptive plasticity allows populations to adjust rapidly to environmental change. If this is useful only rarely, plasticity may undergo mutational degradation and be lost from a population. We consider a population of constant size N undergoing loss of plasticity at functional mutation rate m and with selective advantage s associated with loss. Environmental change events occur at rate theta per generation, killing all individuals that lack plasticity. The expected time until loss of plasticity in a fluctuating environment is always at least tau, the expected time until loss of plasticity in a static environment. When mN > 1 and N*theta >> 1, we find that plasticity will be maintained for an average of at least 10^8 generations in a single population provided tau > 18/theta. In a metapopulation, plasticity is retained under the more lenient condition tau > 1.3/theta, irrespective of mN, for a modest number of demes. We calculate both exact and approximate solutions for tau and find that it is linearly dependent on only the logarithm of N, and so surprisingly, both the population size and the number of demes in the metapopulation make little difference to the retention of plasticity. Instead, tau is dominated by the term 1/(m + s/2).