Bt. Destasio, DIEL VERTICAL AND HORIZONTAL MIGRATION BY ZOOPLANKTON - POPULATION BUDGETS AND THE DIURNAL DEFICIT, Bulletin of marine science, 53(1), 1993, pp. 44-64
Diel horizontal and vertical distributions of zooplankton in Bullhead
Pond, Rhode Island, USA were determined from March until June 1988, th
e period of occurrence of the major species of copepod, Diaptomus sang
uineus. As water temperatures rise during this time period, activity o
f the major planktivore (sunfish) has been shown to increase, causing
a drastic elevation in mortality rates of diaptomid copepods. Males di
d not undergo significant diel vertical migration (DVM) until June, wh
ile ovigerous females began to migrate in April. In March no diel diff
erences in distribution patterns of ovigerous females were discernable
and these copepods exhibited no directed movement patterns. Beginning
in April, however, ovigerous female D. sanguineus were concentrated i
n the middle, deepest part of the lake during the day, and were found
more evenly dispersed and near shore at night. This behavioral pattern
should reduce the risk of predation by visually foraging planktivores
in the euphotic and littoral zones of lakes. Evidence that horizontal
migration behavior of D. sanguineus is due to the presence of fish is
indicated by its response to a fish manipulation experiment in a neig
hboring pond (Little Bullhead Pond). During late April 1988, at noon D
. sanguineus adults were concentrated deep in the middle of a quarter
containing sunfish and evenly dispersed at night. In a quarter without
fish, copepods were randomly dispersed during both day and night. Pop
ulation budgets indicate that abundances of copepods at midnight were
generally greater than at noon (i.e., a diurnal deficit). In both Bull
head and Little Bullhead Pond diurnal deficits were probably in part d
ue to extreme migration by copepods into the sediments, and perhaps du
e to diel horizontal migrations. Taken together, results from Bullhead
and Little Bullhead Pond suggest that this copepod avoids areas of hi
ghest predation risk and may be able to change behaviors as activity p
atterns of predators vary. Responses appear to depend on the life hist
ory phenology of the copepod as well as other possible anti-predator a
daptations available.