A new approach to neural cell culture for long-term studies

Within the mammalian hypothalamus, the suprachiasmatic nucleus (SCN) contains a circadian clock for timing of diverse neuronal, endocrine, and behavioral rhythms. By culturing cells from neonatal rat SCN on fixed microelectrode arrays, we have been able to record spontaneous action potentials from individual SCN neurons for days or weeks, revealing prominent circadian rhythms in firing rate. Despite abundant functional synapses, circadian rhythms expressed by neurons in the same culture are not synchronized. After reversible blockade of neuronal firing lasting 2.5 days, circadian firing rhythms re-emerge with unaltered phases. These data suggest that the SCN contains a large population of autonomous, single-cell circadian oscillators, and that synapses formed in vitro are neither necessary for operation of these oscillators nor sufficient for synchronizing them.

Activity-dependent modification of synaptic efficacy is widely recognized as a cellular basis of learning, memory, and developmental plasticity. Little is known, however, of the consequences of such modification on network activity. Using electrode arrays, we examined how a single, localized tetanic stimulus affects the firing of up to 72 neurons recorded simultaneously in cultured networks of cortical neurons, in response to activation through 64 different test stimulus pathways. The same tetanus produced potentiated transmission in some stimulus pathways and depressed transmission in others. Unexpectedly, responses were homogeneous: for any one stimulus pathway, neuronal responses were either all enhanced or all depressed. Cross-correlation of responses with the responses elicited through the tetanized site revealed that both enhanced and depressed responses followed a common principle: activity that was closely correlated before tetanus with spikes elicited through the tetanized pathway was enhanced, whereas activity outside a 40-ms time window of correlation to tetanic pathway spikes was depressed. Response homogeneity could result from pathway-specific recurrently excitatory circuits, whose gain is increased or decreased by the tetanus, according to its cross-correlation with the tetanized pathway response. The results show how spatial responses following localized tetanic stimuli, although complex, can be accounted for by a simple rule for activity-dependent modification.

The study of development and plasticity of hippocampal circuitry would greatly benefit from methods which allow the long-term culture of neurons at low density under precisely defined culture conditions. We report that isolated hippocampal neurons from embryonic day 18 rats can be cultured for several weeks at low densities which permits the determination of individual connections. A serum-free medium was modified from the formulation of Romijn to include the biological anti-oxidants vitamin E, glutathione, pyruvate, catalase and superoxide dismutase. Neuronal survival of 80% and neuritogenesis greatly exceeded that seen in serum-based cultures. It appeared that vitamins E, A and linolenic acid promoted neuritogenesis. The beneficial effects of the antioxidants suggested a toxic role of oxygen. To directly test this, cultures were incubated in reduced oxygen (9%) and compared to those in the normal 19.7% oxygen (95% air). After 3 days in culture, neurons with processes in 9% oxygen were more than double those in normal oxygen. Neuronal survival and neurite growth could be improved if the cells were grown on a substrate-coated surface covered with a coverslip. Under this condition, cells show a ring of growth between the center and the edge of the coverslip. In 9% oxygen, this ring was closer to the edge of the coverslip than in normal oxygen. The coverslip did not serve as an additional substrate for attachment since it left the neurons attached to the original substrate. However, removal of the coverslip leads to cell death within 24 h, suggesting that the cells had been exposed to a toxic factor. Variations in glial cell content (less than 10%), pH, and pCO2 were demonstrated to be unlikely explanations of the higher survival. These results suggest that growth in a diffusion-limited space, reduction of oxygen concentration to physiological levels and control of toxic oxidation with physiological antioxidants can greatly improve the survival and neuritogenesis of isolated hippocampal neurons in primary culture.