Stuart H. Thompson

NO is necessary and sufficient for egg activation at fertilization.

The early steps that lead to the rise in calcium and egg activation at fertilization are unknown but of great interest—particularly with the advent of in vitro fertilization techniques for treating male infertility and whole-animal cloning by nuclear transfer. This calcium rise is required for egg activation and the subsequent events of development in eggs of all species. Injection of intact sperm or sperm extracts can activate eggs, suggesting that sperm-derived factors may be involved. Here we show that nitric oxide synthase is present at high concentration and active in sperm after activation by the acrosome reaction. An increase in nitrosation within eggs is evident seconds after insemination and precedes the calcium pulse of fertilization. Microinjection of nitric oxide donors or recombinant nitric oxide synthase recapitulates events of egg activation, whereas prior injection of oxyhaemoglobin, a physiological nitric oxide scavenger, prevents egg activation after fertilization. We conclude that nitric oxide synthase and nitric-oxide-related bioactivity satisfy the primary criteria of an egg activator: they are present in an appropriate place, active at an appropriate time, and are necessary and sufficient for successful fertilization.

LOCAL POSITIVE FEEDBACK BY CALCIUM IN THE PROPAGATION OF INTRACELLULAR CALCIUM WAVES

In many types of eukaryotic cells, the activation of surface receptors leads to the production of inositol 1,4,5-trisphosphate and calcium release from intracellular stores. Calcium release can occur in complex spatial patterns, including waves of release that traverse the cytoplasm. Fluorescence video microscopy was used to view calcium waves in single mouse neuroblastoma cells. The propagation of calcium waves was slowed by buffers that bind calcium quickly, such as BAPTA, but not by a buffer with slower on-rate, EGTA. This shows that a key feedback event in wave propagation is rapid diffusion of calcium occurring locally on a scale of < 1 micron. The length-speed product of wavefronts was used to determine that calcium acting in feedback diffuses at nearly the rate expected for free diffusion in aqueous solution. In cytoplasm, which contains immobile Ca2+ buffers, this rate of diffusion occurs only in the first 0.2 ms after release, within 0.4 micron of a Ca2+ release channel mouth. Calcium diffusion from an open channel to neighboring release sites is, therefore, a rate-determining regenerative step in calcium wave propagation. The theoretical limitations of the wave front analysis are discussed.

The spectral sensitivity of the lens eyes of a box jellyfish, Tripedalia cystophora (Conant)

SUMMARY Box jellyfish, or cubomedusae (class Cubozoa), are unique among the Cnidaria in possessing lens eyes similar in morphology to those of vertebrates and cephalopods. Although these eyes were described over 100 years ago, there has been no work done on their electrophysiological responses to light. We used an electroretinogram (ERG) technique to measure spectral sensitivity of the lens eyes of the Caribbean species Tripedalia cystophora. The cubomedusae have two kinds of lens eyes, the lower and upper lens eyes. We found that both lens eye types have similar spectral sensitivities, which likely result from the presence of a single receptor type containing a single opsin. The peak sensitivity is to blue-green light. Visual pigment template fits indicate a vitamin A-1 based opsin with peak sensitivity near 500 nm for both eye types.

Neural Correlates of Swimming Behavior in Melibe leonina

The nudibranch Melibe leonina swims by rhythmically bending from side to side at a frequency of 1 cycle every 2–4 s. The objective of this study was to locate putative swim motoneurons (pSMNs) that drive these lateral flexions and determine if swimming in this species is produced by a swim central pattern generator (sCPG). In the first set of experiments, intracellular recordings were obtained from pSMNs in semi-intact, swimming animals. About 10–14 pSMNs were identified on the dorsal surface of each pedal ganglion and 4–7 on the ventral side. In general, the pSMNs in a given pedal ganglion fired synchronously and caused the animal to flex in that direction, whereas the pSMNs in the opposite pedal ganglion fired in anti-phase. When swimming stopped, so did rhythmic pSMN bursting; when swimming commenced, pSMNs resumed bursting. In the second series of experiments, intracellular recordings were obtained from pSMNs in isolated brains that spontaneously expressed the swim motor program. The pattern of activity recorded from pSMNs in isolated brains was very similar to the bursting pattern obtained from the same pSMNs in semi-intact animals, indicating that the sCPG can produce the swim rhythm in the absence of sensory feedback. Exposing the brain to light or cutting the pedal-pedal connectives inhibited fictive swimming in the isolated brain. The pSMNs do not appear to participate in the sCPG. Rather, they received rhythmic excitatory and inhibitory synaptic input from interneurons that probably comprise the sCPG circuit.

Membrane toxicity of the protein kinase C inhibitor calphostin A by a free-radical mechanism.

The effects of calphostin A on cytoplasmic calcium levels, receptor-mediated calcium release, and membrane input resistance were measured in neuroblastoma cells. Calphostin A is a lipophilic, light-sensitive perylenequinone that generates singlet oxygen when illuminated. It inhibits the activity of protein kinase C (IC50 = 250 nM), but only in the presence of light. Phorbol esters normally attenuate carbachol-evoked calcium release. This effect was blocked by simultaneous exposure to light and calphostin A (40 nM) for 30 min. At higher doses (0.5-1 microM) calphostin A also approximately doubled the resting calcium level and decreased cell input resistance by 51%. These toxic effects did not occur in the dark or after preincubation with the antioxidant alpha-tocopherol. These data support the hypothesis that the calphostins act by partitioning into the membrane and producing singlet oxygen and endoperoxides which then irreversibly modify protein kinase C and other membrane proteins and lipids.

Intracellular calcium release in N1E-115 neuroblastoma cells is mediated by the M1 muscarinic receptor subtype and is antagonized by McN-A-343 ☆

Experiments using muscarinic receptor antagonists were done to determine which muscarinic receptor subtypes(s) mediate carbachol-evoked calcium release in N1E-115 cells. McN-A-343 and a new analog, (+/-)BN228, were weak antagonists and neither compound caused release on its own. The rank order of potency was 4-DAMP greater than pirenzepine greater than AFDX116 greater than (+/-)BN228 and McN-A-343. This profile, pirenzepines high potency (19-fold greater than AFDX116) and its IC50 of 31 nM suggest that calcium release in this neuronal cell line is mediated by the M1 muscarinic receptor subtype.

A-type potassium channel clusters revealed using a new statistical analysis of loose patch data

The spatial distribution of ion channels over the surface of a neuron is an important determinant of its excitable properties. We introduce two measures of channel clustering for use in patch-clamp experiments: a normalized chi-squared statistic (eta) and the number of zero-channel patches in a data set (Z). These statistics were calculated for data sets describing the distribution of A-type potassium channels on neurons of the nudibranch Doriopsilla and measurements of Ca-dependent outward current channels on bullfrog hair cells, as well as simulated channel distributions. When channels are clustered, eta is approximately equal to the amount of current in a cluster. The analysis shows that somatic A-channels in the nudibranch are distributed in clusters of approximately 50 channels each. The clusters are < 2 microns wide and are separated, on average, by 3.2 microns. Outward current channels on hair cells occur in clusters of approximately 27 channels each, in agreement with the original analysis. Channel clustering may reflect properties of the insertion or regulation of channels in the membrane.

Temperature effects on low-light vision in juvenile rockfish (genus Sebastes) and consequences for habitat utilization.

The absolute low-light sensitivity of four congeneric species of rockfish (genus Sebastes) was studied from analysis of electroretinograms measured in living fish. The purpose was: (1) to determine if temperature sensitive noise in rod photoreceptors affects the absolute limit to low-light sensitivity at environmentally realistic temperatures and light levels, and (2) to examine whether interspecific variations in habitat utilization within rockfish communities correlate with differences in visual sensitivity. It was found that the low-light sensitivity of individual retinae is inversely dependent on temperature, decreasing tenfold with a 10°C increase in temperature. While in all four species, temperature had a similar effect on sensitivity, the absolute sensitivity levels were different. The four species could be divided into two groups based on measured sensitivity. Kelp and olive rockfish form a high-sensitivity group capable of responding to light levels approximately 50-fold lower than blue and black rockfish. The sensitivity groups correlated with reported diel activity patterns; the high-sensitivity group forages nocturnally, whereas members of the low-sensitivity group are quiescent during twilight and night and forage during the day.

Measurement of nonuniform current densities and current kinetics in Aplysia neurons using a large patch method

A large patch electrode was used to measure local currents from the cell bodies of Aplysia neurons that were voltage-clamped by a two-microelectrode method. Patch currents recorded at the soma cap, antipodal to the origin of the axon, and whole-cell currents were recorded simultaneously and normalized to membrane capacitance. The patch electrode could be reused and moved to different locations which allowed currents from adjacent patches on a single cell to be compared. The results show that the current density at the soma cap is smaller than the average current density in the cell body for three components of membrane current: the inward Na current (INa), the delayed outward current (Iout), and the transient outward current (IA). Of these three classes of ionic currents, IA is found to reach the highest relative density at the soma cap. Current density varies between adjacent patches on the same cell, suggesting that ion channels occur in clusters. The kinetics of Iout, and on rare occasions IA, were also found to vary between patches. Possible sources of error inherent to this combination of voltage clamp techniques were identified and the maximum amplitudes of the errors estimated. Procedures necessary to reduce errors to acceptable levels are described in an appendix.

Mechanism of postinhibitory rebound in molluscan neurons

SYNOPSIS. Postinhibitory rebound (PIR) is an intrinsic property of many neurons but the underlying mechanism is not well understood. We studied PIR and its relationship to spike adaptation in B-cells isolated from the buccal ganglia of Aplysia. These neurons exhibit PIR following inhibitory synaptic input and following direct membrane hyperpolarization. Hyperpolarizing and depolarizing voltage clamp pulses from the resting potential evoke slow changes in membrane current that persist in the form of tail currents following the pulses. A subtraction method was used to isolate slow tail currents for study. Current-voltage measurements indicate that slow outward tail currents following depolarizing pulses result from increases in membrane conductance, while inward tail currents following hyperpolarizations to 250 and 260 mV result from conductance decreases. The reversal potential of both outward and inward tail current is between 260 and 270 mV. Tail currents activated by pulses more positive than 260 mV are sensitive to the external K concentration and blocked by injection of Cs and TEA. When Ca21 influx is prevented by bathing cells in Ca21 free saline or by adding Co21 or Ni21, the tail currents are reduced but a significant fraction of the current is insensitive to these treatments. More negative conditioning pulses activate a second component of inward tail current that is weakly sensitive to K but more strongly effected by substitution of N-methyl glucamine or Li for external Na. We conclude that both PIR and adaptation result from slow changes in a voltage dependent, noninactivating K conductance that is active at voltages near the resting potential and is not tightly coupled to Ca21 influx. In addition, a second inward current is activated by large hyperpolarizing pulses that results from an increase in Na and K conductance. This second process is likely to contribute to PIR under particular circumstances.