Ecology
GroupHOWARD LAB - MEMBERS
W. Edwin Harris | Jason E. Jannot | Krista A. Larson
W. Edwin Harris
Allocation
of time and energy to reproduction influences the physiology, morphology
and behavior of both sexes. In this research, the causes and consequences
of patterns of sperm allocation in males will be investigated. Historically,
most research in this field has concentrated on egg production because
an egg is more costly to produce than a sperm is. However, although sperm
are smaller than eggs, each ejaculate of a male may contain enormous numbers
of sperm. Recent research has revealed that reproductive resources for
gamete production can be limited for males as well as for females in many
species. Critical to patterns of sperm investment by males is the degree
to which females mate with multiple males. Such multiple mating sets up
intense competition among sperm of different males to fertilize the same
ova. One consequence of such sperm competition is the production of large
ejaculates. A dynamic program model developed by W. E. Harris has provided
predictions for spermatophore allocation in the salamander, Ambystoma
texanum. This species is highly suitable for such a study because within
any breeding aggregation, each male may deposit 60+ spermatophores each
containing many thousand sperm, and each female may induct 20+ spermatophores
into their reproductive tract prior to egg deposition. Predictions from
the dynamic program model will be tested using controlled laboratory experiments.
Jason E. Jannot
The processes by which developmental
pathways evolve, and conversely, the effects of developmental processes
on the paths that evolution may take, has held the interest of developmental
biologists, ecologists, evolutionary biologists, paleobiologists, and
systematists for a long time. However, at the beginning of the 20th century,
a rift was manifest between developmental biology and ecological and evolutionary
studies. Our understanding of how the environment shapes development and
the influence of development on phenotypic variation has been hampered
by this historical split. Over the last twenty years, there has been renewed
interest in understanding the evolution of organismal form, initiated
by the 'reunification' of developmental biology with ecology and evolutionary
biology.
Several questions remain unanswered in this re-emerging
field, however. I wish to address two questions in particular. First,
how do developmental events and the timing of those events influence the
range of phenotypes observed? Second, how do developmental trade-offs
in the allocation of resources influence phenotypic and developmental
outcomes? Historically, these questions fall under the conceptual umbrella
of phenotypic plasticity. Phenotypic plasticity is the ability of a single
genotype to produce more than one alternative phenotype (physiological,
morphological, or behavioral) in response to environmental conditions.
The primary tool used in understanding phenotypic plasticity is the reaction
norm. The reaction norm of a trait is the response of a single genotype
to a single environmental factor (simplest case). Reaction norms describe
how development transforms a genotype into a phenotype under a given set
of environmental conditions.
Many organisms exhibit life cycles that incorporate
discrete, morphologically, behaviorally, and ecologically distinct phases,
termed complex life cycles (CLCs; e.g., insects, marine invertebrates,
amphibians. The developmental events, timing, and plasticity during transitions
between stages in a CLC (e.g., egg >larva >pupa > adult) can
influence the physiology, morphology and behavior of subsequent stages.
I am studying how developmental plasticity in relation to changes in resources
during the larval stage influences developmental events, developmental
timing, and adult morphological and behavioral phenotypes in the caddisfly,
Limnephilus externus (Trichoptera: Limnephilidae). I chose caddisflies
because they have CLC's , as well as, specific behavioral and life history
traits appropriate for such a study.
Krista A. Larson
Most studies of anuran mating behavior involve species that
produce simple advertisement vocalizations containing a repeated note
or trill that varies only in pitch, duration, and rate of emission. These
calls are given by males during the breeding season and function in long-range
attraction of females and in signaling presence and location to nearby
rival males in a chorus. However, several anuran species produce complex
advertisement calls consisting of multiple types of notes that vary in
number and temporal order. Whether or not complex calls provide additional
information to conspecifics, increase the attractiveness of callers to
potential mates, or are related to speciation events is unknown.
Click above image to hear a northern leopard frog vocalization
My
research investigates the largely undescribed but complex vocalization
system of the northern leopard frog (Rana pipiens). Preliminary observations
suggest that males possess a large repertoire of advertisement calls that
are produced in variable numbers and combinations during calling bouts.
The goals of my research project are: (1) to describe and categorize the
number of advertisement calls present in the vocal repertoire of leopard
frog males, (2) to document the general context in which these calls are
produced, and (3) to determine their function in breeding aggregations.
To accomplish this, I have recorded advertisement calls of individual
males from breeding choruses in Indiana and Minnesota. I am analyzing
the spectral properties and temporal patterning of these calls, as well
as examining differences in usage of calls at different spatial locations
in the chorus. Additionally, I am conducting playback experiments to quantify
how males and females respond to each of the different types of calls,
thereby distinguishing those calls that are used in male-male interactions
from those that are involved in mate attraction. With data obtained in
these experiments, I hope to discover why such a complex vocalization
system has evolved in this species. In addition, I hope to obtain information
on the behavior and habitat requirements of leopard frogs that may be
useful in reversing the present trends of population decline in this species
that are common throughout the study area.