Pain and itch processing by subpopulations of molecularly diverse spinal and trigeminal projection neurons.

A remarkable molecular and functional heterogeneity of the primary sensory neurons and dorsal horn interneurons transmits pain- and or itch-relevant information, but the molecular signature of the projection neurons that convey the messages to the brain is unclear. Here, using retro-TRAP (translating ribosome affinity purification) and RNA sequencing, we reveal extensive molecular diversity of spino- and trigeminoparabrachial projection neurons. Among the many genes identified, we highlight distinct subsets of Cck+ -, Nptx2+ -, Nmb+ -, and Crh+ -expressing projection neurons. By combining in situ hybridization of retrogradely labeled neurons with Fos-based assays, we also demonstrate significant functional heterogeneity, including both convergence and segregation of pain- and itch-provoking inputs into molecularly diverse subsets of NK1R- and non-NK1R-expressing projection neurons.

Development and sensory experience dependent regulation of microglia in barrel cortex.

The barrel cortex is within the primary somatosensory cortex of the rodent, and processes signals from the vibrissae. Much focus has been devoted to the function of neurons, more recently, the role of glial cells in the processing of sensory input has gained increasing interest. Microglia are the principal immune cells of the nervous system that survey and regulate the cellular constituents of the dynamic nervous system. We investigated the normal and disrupted development of microglia in barrel cortex by chronically depriving sensory signals via whisker trimming for the animals' first postnatal month. Using immunohistochemistry to label microglia, we performed morphological reconstructions as well as densitometry analyses as a function of developmental age and sensory experience. Findings suggest that both developmental age and sensory experience has profound impact on microglia morphology. Following chronic sensory deprivation, microglia undergo a morphological transition from a monitoring or resting state to an altered morphological state, by exhibiting expanded cell body size and retracted processes. Sensory restoration via whisker regrowth returns these morphological alterations back to age-matched control values. Our results indicate that microglia may be recruited to participate in the modulation of neuronal structural remodeling during developmental critical periods and in response to alteration in sensory input.

Spinal cord projection neurons: a superficial, and also deep, analysis.

Today there are extensive maps of the molecular heterogeneity of primary afferents and dorsal horn interneurons, yet there is a dearth of molecular and functional information regarding the projection neurons that transmit pain and itch information to the brain. Additionally, most contemporary research into the spinal cord and medullary projection neurons focuses on neurons in the superficial dorsal horn; the contribution of deep dorsal horn and even ventral horn projection neurons to pain and itch processing is often overlooked. In the present review we integrate conclusions from classical as well as contemporary studies and provide a more balanced view of the diversity of projection neurons. A major question addressed is the extent to which labeled-lines are maintained in these different populations or whether the brain generates distinct pain and itch percepts by decoding complex convergent inputs that engage projection neurons.

Cue-induced resumption of heroin and cocaine seeking in rats using a conflict model of abstinence and relapse.

RATIONALE AND OBJECTIVES: Most animal research on drug relapse involves the reinstatement model where abstinence is a result of drug removal (extinction). However, abstinence in humans often results from the aversive consequences that accompany drug seeking (conflict situation). This study was aimed at using a conflict-based animal model of abstinence/relapse in rats self-administering heroin or cocaine. METHODS: Rats were trained to self-administer heroin (0.05 mg kg(-1) injection(-1)) or cocaine (0.5 mg kg(-1) injection(-1)) with each injection paired with a light cue. After stable responding was demonstrated, the floor near the levers was electrified, creating a barrier, in order to model the negative consequences of continued drug seeking. Shock intensities were increased over sessions until no responses occurred for three consecutive sessions. During a relapse test, where shock was maintained,the capacity of noncontingent drug cue presentations to induce active lever pressing was assessed. RESULTS: Ten of ten heroin animals and three of eight cocaine animals exposed to noncontingent cue presentations resumed responding. During the relapse test, for both drug groups, active lever pressing was significantly higher than during abstinence but only in the heroin group was it significantly higher than inactive lever pressing. CONCLUSIONS: The implementation of negative consequences for drug seeking can result in its cessation just as they might in human addicts. Similarly, exposure to drug cues can lead to resumption of drug seeking. This model may be useful for studying the mechanisms underlying abstinence and relapse and for developing strategies to prevent relapse.