Physiology of Aplysia Californica

Summaries of research papers on the Aplysia Californica are presented. Thirty three works are cited. Emphasis is on the nervous system organization of this animal

Beitrag zum Problem der heterosynaptischen Facilitation in Aplysia californica

1. Heterosynaptic facilitation (H.S.F.) of single neurons in the central nervous system of Aplysia can be repeated virtually indefinitely, provided sufficient time is allowed for recovery between the trials.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/47439/1/424_2004_Article_BF00362956.pd

Patterns of Proteins Synthesized in the R15 Neuron of Aplysia: Temporal Studies and Evidence for Processing

The time-course of changes in the pattern of newly synthesized proteins in the R15 neuron of the parietovisceral ganglion of Aplysia californica has been studied at 14 degrees C. 5% polyacrylamide gels containing sodium dodecyl sulfate (SDS) have been used to separate newly synthesized (leucine-labeled) proteins from the neuron. We have demonstrated that the pattern of newly synthesized proteins from the R15 neuron does not change significantly if 5-h pulses of labeled leucine are given during the first 72 h of in vitro incubation of the excised ganglion. However, the level of leucine incorporation begins to decline somewhere between 17 and 43 h after the ganglion is isolated; at 43 and 69 h the levels of incorporation fell to 29 and 10% of the initial level, respectively. A number of conclusions have been drawn from the use of a sequential, double-label type of experiment in the same cell. There is processing of SDS-soluble, 12,000-dalton (12k) material to 6,000-9,000-dalton (6-9k) material. These materials are the two major peaks on gels after long labeling periods and together account for about 35% of all newly synthesized proteins. After synthesis of 12k material, there is a gradual disappearance of 12k (half-life about 8 h) and simultaneous appearance of 6-9k material on the gels, as the postsynthesis "chase" period of ganglia incubation is increased. The processing of 12k to 6-9k material occurs even in the presence of anisomycin, a protein syntehsis inhibitor, during the chase period. While the rate of 12k to 6-9k conversion can vary from cell to cell, it appears to remain consistent within, and is characteristic of, any individual R15. We detect no circadian rhythm in either the rate of 12k synthesis or the rate of 12k to 6-9k processing with 5-h label periods. These results are discussed in relation to the roles of 12k and 6-9k material in the R15 neuron.</p

The differential effects of ionizing radiation on the circadian oscillator and other functions in the eye of Aplysia.

Ionizing radiation has been used to selectively separate the circadian oscillator function of the eye of Aplysia from some of its other functions--synchronous compound action potential (CAP) generation, the light response, synaptic transmission between photoreceptors and output neurons, and the bursting pacemaker mechanism. Doses of 4-krad (50 kV peak) x-rays have a minimal effect on the circadian rhythm of CAP frequency, measured from the otpic nerve, whereas irradiation with a 40-krad dose abolishes the rhythm without affecting any of the four other functions of this eye (1 rad = 0.01 J/kg = 0.01/Gy). We estimate a 50% survival of the oscillator function at doses of about 6 krad. The oscillators of irradiated eyes are not merely desynchronized when the rhythm is abolished, because in vitro light-dark entrainment does not restore free-running rhythmicity. The results, including those from selective irradiation of the anterior or posterior poles of the eye, suggest that there are a number of circadian oscillators in the eye--most of them in the posterior portion near the optic nerve. An approximate target size has been obtained from target theory approximately equal to 10(8) A3, which is somewhat larger than the target size for viral infectivity function, as one example. There are reservations about estimating target size in a complex organ such as the eye. However, this approximate target size and the fact that recovery or repair can occur in vivo suggest that the oscillator may involve nucleic acid molecules