Activity-independent segregation of excitatory and inhibitory synaptic terminals in cultured hippocampal neurons

Inhibition of sphingolipid synthesis, but not degradation, alters the rate of dendrite growth in cultured hippocampal neurons

Axonal growth can be disrupted by various treatments that inhibit the synthesis of membrane components or their delivery by microtubule-based transport. In cultured hippocampal neurons, a direct correlation exists between the synthesis of sphingolipids, and particularly the simplest glycosphingolipid, glucosylceramide, and the ability of growth factors to stimulate axonal growth [S. Boldin, A.H. Futerman, J. Neurochem. 68 (1997) 882-885]. We now demonstrate that dendritic growth in hippocampal neurons also requires ongoing sphingolipid synthesis. Upon incubation with fumonisin B1 (FB1), an inhibitor of acylation of sphingoid long-chain bases, dendritic growth rates are approximately 25% slower than those of control cells, resulting in neurons with shorter dendritic arbors and less dendritic branch points per cell, and readily apparent differences in morphology compared to control cells after 10-14 days in culture. In contrast, FB1 had no effect on the initial growth of the minor processes, which are destined to become dendrites, even in cells in which FB1 affected the rate of axon growth. Inhibition of sphingolipid degradation, by incubation with conduritol-B-epoxide (an inhibitor of glucosylceramide degradation) had no effect on dendrite or minor process growth at any stage of development, and no aberrant neurite or ectopic dendrite formation was observed. Together, these data demonstrate that normal dendrite growth in hippocampal neurons requires sphingolipid synthesis, although the molecular requirements for sphingolipid synthesis may differ from those in axons.

Different effects of low and high dose cardiotonic steroids on cytosolic calcium in spontaneously active hippocampal neurons and in co-cultured glia

The Na+ pump is crucial for the regulation of [Na+]i (the intracellular Na+ concentration) in all cells. Three Na+ pump alpha subunit isoforms, alpha1, alpha2 and alpha3, are expressed in rat hippocampal neurons, and alpha1 and alpha2 are expressed in glia, but the significance of these isoforms is not understood. We exploited the different ouabain affinities of the Na+ pump alpha subunit isoforms in rat (alpha1, low ouabain affinity; alpha2 and alpha3, high ouabain affinity) to probe their possible physiological roles. Low and intermediate doses (1-10 microM) of ouabain and its readily reversible analog, dihydroouabain, altered the spontaneous elevations of [Ca2+]i (the intracellular Ca2+ concentration) in neurons and induced [Ca2+]i transients in glia. Complete inhibition of all Na+ pump isoforms (>/=100 microM ouabain) caused sustained increases in global neuronal [Ca2+]i in rat neuronal/glial hippocampal co-cultures and transient [Ca2+]i increases in surrounding glia. High dose ouabain was also associated with increased [Na+]i and [H+]i in neurons and glia. In contrast, 1 microM ouabain (a concentration that completely inhibits only alpha2 and alpha3) was not associated with sustained increases in global neuronal [Ca2+]i or the sustained derangements in [Na+]i and [H+]i observed with high dose ouabain. Reduction of [K+]o to 1 mM suppressed the spontaneous [Ca2+]i oscillations in neurons and induced Ca2+ transients in some glia; removal of external K+ induced sustained elevation of neuronal [Ca2+]i. These studies indicate that the alpha1 isoform is the 'housekeeper' required for maintenance of the global Na+ gradient. As suggested by their restricted plasmalemmal distribution, the high ouabain-affinity Na+ pump isoforms may have more specific roles in neurons and glia.

Development of spontaneous synaptic transmission in the rat spinal cord

Dorsal root afferents form synaptic connections on motoneurons a few days after motoneuron clustering in the rat lumbar spinal cord, but frequent spontaneous synaptic potentials are detected only after birth. To increase our understanding of the mechanisms underlying the differentiation of synaptic transmission, we examined the developmental changes in properties of spontaneous synaptic transmission at early stages of synapse formation. Spontaneous postsynaptic currents (PSCs) and tetrodotoxin (TTX)-resistant miniature PSCs (mPSCs) were measured in spinal motoneurons of embryonic and postnatal rats using whole cell patch-clamp recordings. Spontaneous PSC frequencies were higher than mPSC frequencies in both embryonic and postnatal motoneurons, suggesting that even at embryonic stages, when action-potential firing rate was low, presynaptic action potentials played an important role in triggering spontaneous PSCs. After birth, the twofold increase in spontaneous PSC frequency was attributed to an increase in action-potential-independent quantal release rather than to a higher rate of action-potential firing. In embryonic motoneurons, the fluctuations in peak amplitude of spontaneous PSCs were normally distributed around single peaks with modal values similar to those of mPSCs. These data indicated that early in synapse differentiation spontaneous PSCs were primarily composed of currents generated by quantal release. After birth, mean mPSC amplitude increased by 50% but mean quantal current amplitude did not change. Synchronous, multiquantal release was apparent in postnatal motoneurons only in high-K+ extracellular solution. Comparison of the properties of miniature excitatory and inhibitory postsynaptic currents (mEPSCs and mIPSCs) demonstrated that mean mEPSC frequency was higher than mIPSC frequency, suggesting that either excitatory synapses outnumbered inhibitory synapses or that the probability of excitatory transmitter release was higher than the release of inhibitory neurotransmitters. The finding that mIPSC duration was several-fold longer than mEPSC duration implied that despite their lower frequency, inhibitory currents could modulate motoneuron synaptic integration by shunting incoming excitatory inputs for prolonged time intervals.

Activity-dependent scaling of quantal amplitude in neocortical neurons

Information is stored in neural circuits through long-lasting changes in synaptic strengths. Most studies of information storage have focused on mechanisms such as long-term potentiation and depression (LTP and LTD), in which synaptic strengths change in a synapse-specific manner. In contrast, little attention has been paid to mechanisms that regulate the total synaptic strength of a neuron. Here we describe a new form of synaptic plasticity that increases or decreases the strength of all of a neuron's synaptic inputs as a function of activity. Chronic blockade of cortical culture activity increased the amplitude of miniature excitatory postsynaptic currents (mEPSCs) without changing their kinetics. Conversely, blocking GABA (gamma-aminobutyric acid)-mediated inhibition initially raised firing rates, but over a 48-hour period mESPC amplitudes decreased and firing rates returned to close to control values. These changes were at least partly due to postsynaptic alterations in the response to glutamate, and apparently affected each synapse in proportion to its initial strength. Such 'synaptic scaling' may help to ensure that firing rates do not become saturated during developmental changes in the number and strength of synaptic inputs, as well as stabilizing synaptic strengths during Hebbian modification and facilitating competition between synapses.

Recruitment of functional GABA(A) receptors to postsynaptic domains by insulin

Modification of synaptic strength in the mammalian central nervous system (CNS) occurs at both pre- and postsynaptic sites. However, because postsynaptic receptors are likely to be saturated by released transmitter, an increase in the number of active postsynaptic receptors may be a more efficient way of strengthening synaptic efficacy. But there has been no evidence for a rapid recruitment of neurotransmitter receptors to the postsynaptic membrane in the CNS. Here we report that insulin causes the type A gamma-aminobutyric acid (GABA[A]) receptor, the principal receptor that mediates synaptic inhibition in the CNS, to translocate rapidly from the intracellular compartment to the plasma membrane in transfected HEK 293 cells, and that this relocation requires the beta2 subunit of the GABA(A) receptor. In CNS neurons, insulin increases the expression of GABA(A) receptors on the postsynaptic and dendritic membranes. We found that insulin increases the number of functional postsynaptic GABA(A) receptors, thereby increasing the amplitude of the GABA(A)-receptor-mediated miniature inhibitory postsynaptic currents (mIPSCs) without altering their time course. These results provide evidence for a rapid recruitment of functional receptors to the postsynaptic plasma membrane, suggesting a fundamental mechanism for the generation of synaptic plasticity.

Dendritic compartmentation of NMDA receptor mRNA in cultured hippocampal neurons

The intracellular localization of mRNA encoding the obligatory subunit for the N-methyl-D-aspartate (NMDA) receptor complex (NMDAR1) was determined in cultured hippocampal neurons by in situ hybridization. From the time at which dendrites begin to develop, labeling for NMDAR1 mRNA extended beyond cell somata into incipient dendritic processes. By 10 days in culture, label was found throughout dendritic arbors in a distribution pattern similar to that for microtublin associated proteins 2 mRNA, but contrasted sharply with that for GluR1 or beta-actin mRNAs, both of which were restricted to cell somata. NMDAR1 mRNA was also expressed in astrocytes, where it was diffusely localized throughout the cytoplasm. These data suggest that transport of NMDAR1 mRNA may serve as a mechanism to target and manipulate local concentrations of NMDA receptors.