Synaptically driven spikes and long-term potentiation in neocortical layer 2/3.

Recently, variation upon a well-established hippocampal model has given rise to a new paradigm in which the strength of synaptic inputs to neocortical layer 2/3 is estimated in vitro by recording synaptically driven extracellular potentials elicited there by electrical stimulation applied to underlying layer 4. The analysis of these potentials is commonly based upon an assumption that postsynaptic spiking has played no significant role in their generation. Here, we have tested this assumption by quantifying in rats (using data obtained by cell-attached recording) the rate at which unit spikes are elicited in layer 2/3 under commonly used conditions of stimulation and recording. We found that spike responses were regularly elicited at the same latencies as field potential peaks and the rising phases of intracellularly recorded synaptic currents, and the incidence of such spiking (the fractional rate of cells spiking versus cells sampled) was sufficient to give this higher-order activity a major role in determining response amplitudes. We then analyzed layer 2/3 waveform characteristics before and after inducing long-term potentiation (LTP) by theta-burst stimulation (TBS) and found that the induction of LTP succeeded only when the initial response included a strong spike component. We further observed that LTP expression was always accompanied by a pronounced enhancement of such components. Our data suggest that, unlike in hippocampal CA1, LTP elicited by TBS in this neocortical paradigm depends upon modification of synaptically driven spike activity, through either enhanced synchronization of unitary responses, the recruitment of additional responding units, or both. This potentiation of the spike response could arise (as previously proposed) through an increase in the efficacy of synapses mediating projection from layer 4 to 2/3, but other mechanisms may also contribute, such as modification of short-range recurrent connections within layer 2/3, which are likely to play an important role in defining local-network cell ensembles.

Short-term plasticity of extrinsic excitatory inputs to neocortical layer 1.

Previous studies have shown that different pyramidal cell inputs vary in the short-term plasticity expressed when they are subjected to repetition of use. Here, we describe short-term plasticity at synapses that mediate long-range input to neocortical layer 1 and compare it with that which normally occurs in the hippocampal Schaffer collateral pathway, which also involves projection by remote inputs onto apical dendrites. We isolated tangential inputs to layer 1 in neocortical slices, stimulated these with brief 40-Hz trains, and examined postsynaptic responses by recording extracellularly from layer 1 in somatosensory, prefrontal, and visual neocortex, and intracellularly from visually identified pyramidal cell somata in layer 2/3 in somatosensory and prefrontal neocortex. Train response amplitudes were characterized by calculating paired-pulse ratios, fifth-versus-first amplitude ratios (5th/1st ratios), and a center-of-mass index "M". As expected, the hippocampal train responses facilitated strongly. In contrast, layer-1 responses displayed strong synaptic depression in all regions examined. This depression was reflected in 5th/lst ratios and M scores, but not paired-pulse ratios because it did not consistently begin until the third responses in trains. It persisted unchanged in the presence of partially blocking levels of 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), but was converted to strong facilitation when slices were bathed in low-Ca++ media. Intracellularly, we observed response-train depression very similar to that recorded extracellularly. These findings show that long-range inputs to neocortical layer 1 display short-term plasticity markedly different from that which normally occurs at hippocampal Schaffer collateral synapses, but similar to that which has been described previously for excitatory inputs to pyramidal cells in deeper neocortical layers.

Structural factors contributing to insecticidal and selective actions of neonicotinoids.

Nicotinoids and neonicotinoids are characterized by the presence of the 3-pyridylmethylamine moiety in their structure. In the former, the amino nitrogen atom is ionized, while in the latter the corresponding nitrogen atom is not ionized but bears a partial positive charge. Both types of insecticides interact with nicotinic acetylcholine receptor (nAChR) of insect origin. The poor interaction of neonicotinoids with vertebrate nAChR was shown by its poor binding affinity to the nAChR from Torpedo electric organ and rat brain and poor activation with nAChR expressed in Xenopus oocytes. The full positive charge was essential to interact with the vertebrate nAChR, while the 3-pyridylmethylamine moiety with a partial positive charge was enough to interact with the insect nAChR. For penetration into the insect central nervous system, hydrophobicity seemed to play an important role, as indicated by the binding of the injected compounds to the housefly head nAChR. The ionization reduced hydrophobicity and limited the penetration of nicotinoids, resulting in less insecticidal activity. Among neonicotinoids, nitromethylene type compounds, though far higher in binding affinity, were less hydrophobic than the corresponding nitroimine type, and the net result was better or inferior insecticidal activity. A chlorine atom at the 6 position of the 3-pyridyl group found in commercialized neonicotinoids contributes to increased binding affinity and more importantly hydrophobicity, thus increasing insecticidal activity. N-Me-imidacloprid was found to be a propesticide of imidacloprid.

N-glycosylation at the conserved sites ensures the expression of properly folded functional ACh receptors.

The role of the conserved carbohydrate moiety in the expression of complete acetylcholine receptor (AChR), alpha2 beta gamma delta was re-investigated by expressing additional site-directed mutant subunits, lacking an N-glycosylation site, in Xenopus oocytes. All mutant subunits were stably expressed and appeared to associate with other normal subunits; however, removal of carbohydrate on the alpha subunit inhibited the formation of 125I-alpha-bungarotoxin (alpha-BuTX) binding sites and functional ACh-gated ion channels. 125I-alpha-BuTX binding to AChRs was also significantly reduced by removal of the conserved carbohydrate on the gamma or delta subunits. Immunoprecipitation with monoclonal antibodies that recognize the two distinct alpha-BuTX sites on the AChR indicated that the mutant gamma subunit did not interfere with efficient formation of the alpha-BuTX binding site at the alpha/delta interface, but loss of the carbohydrate did interfere with formation of the alpha-BuTX binding site at the alpha/mutant gamma interface. A similar result was obtained with the mutant delta subunit. Furthermore, the mutant gamma and mutant delta subunits were not incorporated efficiently into the mature (correct tertiary conformation capable of alpha-BuTX binding) alpha beta delta or alpha beta gamma complexes, respectively. Since both mutant gamma and mutant delta subunits were capable of assembling with the alpha subunits (immature assembly), these results suggest that the formation of the two alpha-BuTX binding sites requires correct folding of the alpha gamma and alpha delta complexes, which is aided by the conserved carbohydrate on the gamma and delta subunits. Electrophysiological experiments demonstrated that functional receptors containing mutant subunits were produced, but the functional properties of the mutant receptors were differentially altered, depending on the subunit mutated. Together, our results suggest that N-glycosylation of AChR subunits ensures the correct folding of important functional domains and expression of proper functional receptors in the plasma membrane.

Entrainment of aged, dysrhythmic rats to a restricted feeding schedule.

Aged rats often display abnormal circadian activity rhythms; the rhythm amplitude is low and entrainment to light-dark cycles is irregular. The activity rhythm of young rats can be entrained by both light and nonphotic cues, specifically food availability. In young rats, entrainment to restricted feeding cycles does not depend on intact suprachiasmatic nuclei, the presumed anatomical location of the light-entrainable oscillator. In this study, aged rats that displayed disrupted entrainment to light were assessed for their ability to entrain to restricted feeding schedules. Aged rats, young controls, and young suprachiasmatic nuclei-lesioned (SCN) rats were placed on a food restriction schedule (FR) for 14 days. Food was available for 2 h during the light phase of a 12-h light-dark cycle. Despite the absence of entrainment to light/dark cycles, both SCN-lesioned and aged groups showed entrainment to FR, with clear bouts of anticipatory activity during a period of complete food deprivation following 2 weeks of FR. The results suggest that the dysrhythmia of aged rats is a result of natural deterioration of a central circadian light-entrainable pacemaker, but that a secondary oscillator entrainable to food cycles is spared.

A conserved disulfide loop facilitates conformational maturation in the subunits of the acetylcholine receptor.

To examine the structural determinants for the assembly of ligand-gated receptors, we constructed mutant alpha, beta, gamma and delta subunits of the Torpedo acetylcholine receptor (AChR), lacking one of the conserved cysteine residues which forms a 13-amino acid disulfide loop in the amino terminal domain of each subunit. Mutant subunits were co-expressed with complementary wild-type subunits in Xenopus oocytes. Using subunit-specific antisera and monoclonal antibodies that recognize the two distinct alpha-bungarotoxin (alpha-BuTX) sites on the AChR, we were able to distinguish immature subunit associations from conformationally mature AChR complexes. Removal of the disulfide loop on the alpha subunit completely destroyed the formation of the two toxin-binding sites, while removal of the structure on the beta subunit had little effect. While mutant gamma and delta subunits were capable of forming associations (immature assembly) with other subunits, the formation of alpha-BTX sites between alpha and mutant gamma or mutant delta subunits was diminished. Interestingly, assembly of alpha beta gamma subunits remained efficient in the presence of mutant delta subunits, whereas assembly of alpha beta delta subunits was inefficient in the presence of mutant gamma subunits. Thus, these results indicate that the formation of the disulfide loop facilitates the conformational maturation of alpha gamma and alpha delta complexes, which may be conditional for correct subunit coupling in assembling receptors. Furthermore, it seems likely that the correct coupling between the alpha and gamma subunits is the most important step in subunit assembly.

Disruption of circadian regulation by brain grafts that overexpress Alzheimer beta/A4 amyloid.

Alzheimer disease patients exhibit irregularities in the patterns of normally circadian (daily) rhythms. Alzheimer-type pathology has been reported in the hypothalamus and in the suprachiasmatic nuclei, the putative site of the circadian oscillator. We examined the relationship between the neuropathology of Alzheimer disease, as modeled by an animal system, and circadian dysregulation by grafting genetically transformed cells that overexpress beta/A4 amyloid into the suprachiasmatic nuclei of adult rats. Grafts of beta/A4-positive cells, but not of control cells, significantly altered the pattern of activity of implanted rats. Although experimental conditions included light-dark cycles that normally tend to drive rats to 24-h rhythms, animals with grafts of beta/A4-positive cells showed abnormally high levels of activity during the light phase in addition to a disrupted circadian pattern. Periodogram analysis demonstrated significant rhythms outside of a circadian range. The body temperature rhythm of these animals was also weak 6 weeks after grafting; however, unlike activity patterns, body temperature regained a circadian period by 8 weeks after cell implantation. These data indicate that disruption of circadian activity is a behavioral measure of the consequences of beta/A4 accumulation in brain implants.

Colocalization of amino terminal and A4 (beta-amyloid) antigens in Alzheimer plaques: evidence for coordinated processing of the amyloid precursor protein.

The mechanism by which the A4 (beta-amyloid) domain of the Alzheimer amyloid precursor protein (APP) is deposited in plaques is unknown, and limited information is available concerning the extent to which other APP sites are associated with plaques. To address these issues, we prepared antiserum to a peptide adjacent to the N-terminus of the APP (referred to as N1) and examined its distribution in brain relative to A4 by double-immunostaining techniques. Anti-N1 localized to both neurons and glia in control and Alzheimer patients. In the Alzheimer brain, anti-N1 detected plaques. Quantitation revealed that 85% of thioflavin-positive plaques, and 91% of A4-positive plaques were also N1 positive. Double-staining methods directly demonstrated colocalization of distant APP sites. The data suggest that suggest that proposed mechanisms for amyloid deposition during plaque formation must take into account the extracytoplasmic domain, in addition to the A4 region, rather than be confined exclusively to the A4 site.