Studying Neuronal Function Ex Vivo Using Optogenetic Stimulation and Patch Clamp.

Optogenetics has become a key method to interrogate the function of neural populations and circuits in the brain. This technique combines the targeted expression of light-activated proteins with subsequent manipulation of neural activity by light. Opsins such as Channelrhodopsin-2 (ChR2), which is a light-gated cation-channel, can be fused to or coexpressed with fluorescent proteins to allow for visualization and concurrent activation of neurons and their axonal projections. Via stereotaxic delivery of viral vectors, ChR2 can be constitutively or conditionally expressed in specific neurons in defined brain regions. Subsequently, identified axonal projections can be studied functionally ex vivo in combination with patch-clamp recordings in brain slices. This optogenetic mapping of neural circuitry has enabled the identification and characterization of novel synaptic connections and the detailed investigation of known anatomical connections previously not amenable with electrical stimulation techniques. Here, we describe a protocol for investigating functional properties of local and long-range connectivity in the brain using blue-light activated ChR2 variants and whole-cell patch-clamp recordings in acute brain slices.

The combination of postnatal maternal separation and social stress in young adulthood does not lead to enhanced inflammatory pain sensitivity and depression-related behavior in rats.

The cumulative and match/mismatch hypotheses of stress are still under discussion regarding the effects of early life stress (ELS) on the vulnerability or resilience to psychopathology. In this context, an additional stress in later life (second hit) often leads to stress-related disorders that frequently include comorbid pain states. We previously observed that maternal separation (MS), a model of ELS, reduces vulnerability to neuropathic and inflammatory pain in rats. In the present study, we investigated the effects of an additional later stressor on the vulnerability to inflammatory pain. Sprague Dawley pups were divided into 4 groups: controls (CON, no stress), MS, social stress (SS) and MS+SS. At young adult age (from 7 to 15 weeks), stress- as well as pain-related parameters were evaluated prior and during 21 days following the induction of paw inflammation with complete Freund's adjuvant (CFA). Finally spinal glutamatergic transmission, immunocompetent cells, pro-inflammatory cytokines and growth factors were examined using qPCR. None of the stress conditions had a significant impact on corticosterone levels and anhedonia. In the forced swim test, MS and SS displayed increased passive coping whereas the combination of both stressors revoked this effect. The different stress conditions had no influence on basal mechanical thresholds and heat sensitivity. At 4 days post-inflammation all stress groups displayed lower mechanical thresholds than CON but the respective values were comparable at 7, 10, and 14 days. Only on day 21, MS rats were more sensitive to mechanical stimulation compared to the other groups. Regarding noxious heat sensitivity, MS+SS animals were significantly less sensitive than CON at 10 and 21 days after CFA-injection. qPCR results were mitigated. Despite the finding that stress conditions differentially affected different players of glutamatergic transmission, astrocyte activity and NGF expression, our biochemical results could not readily be related to the behavioral observations, precluding a congruent conclusion. The present results do neither confirm the cumulative nor corroborate or disprove the match/mismatch hypothesis.

Neonatal maternal separation leads to a dampening of inflammation-related mechanical and thermal hypersensitivity in juvenile rats.

Early life stress (ELS) constitutes a risk factor for the later development of psychopathological disorders partly displaying pain comorbidity. Since ELS may hence be expected to have an impact on pain processing the present study investigates whether ELS could be a factor of vulnerability or resilience against an enhancement of noxious sensitivity in the framework of inflammatory pain in later life. Rats were exposed to the maternal separation (MS) paradigm, an established ELS model. At adulthood, corticosterone levels and anxiety-related behaviors were evaluated. Subsequently, paw edema, noxious mechanical and thermal sensitivity were measured prior and during an inflammation induced by intraplantar injection of Complete Freunds Adjuvant (CFA). The open field test and the corticosterone measures showed no effect of MS. MS did not change mechanical thresholds prior to inflammation but reduced mechanical hyperalgesia after CFA-injection. MS animals did however present shorter latencies to display nocifensive behaviors compared to controls (CON). Furthermore, in CON but not MS, the repetitive noxious heat testing induced a decrease in reaction latencies. Moreover, MS dampened CFA-induced heat hyperalgesia. Altogether, our results suggest that ELS may have a protective impact on inflammatory pain.

Maternal separation stress leads to resilience against neuropathic pain in adulthood.

Early life stress (ELS) leads to a permanent reprogramming of biochemical stress response cascades that may also be relevant for the processing of chronic pain states such as neuropathy. Despite clinical evidence, little is known about ELS-related vulnerability for neuropathic pain and the possibly underlying etiology. In the framework of experimental studies aimed at investigating the respective relationships we used the established ELS model of maternal separation (MS). Rat dams and neonates were separated for 3 h/day from post-natal day 2-12. At adulthood, noxious mechanical and thermal thresholds were assessed before and during induction of neuropathic pain by chronic constriction injury (CCI). The potential involvement of spinal glutamatergic transmission, glial cells, pro-inflammatory cytokines and growth factors was studied by using qPCR. MS per se did not modify pain thresholds. But, when exposed to neuropathic pain, MS rats exhibited a marked reduction of thermal sensitivity and a delayed development of mechanical allodynia/hyperalgesia when compared to control animals. Also, MS did not alter glucocorticoid receptor mRNA levels, but prevented the CCI-induced down-regulation of NR1 and NR2 sub-units of the NMDA receptor and of the glutamate transporter EAAT3 as observed at 21 days post-surgery. Additionally, CCI-provoked up-regulation of glial cell markers was either prevented (GFAP for astrocytes) or dampened (Iba1 for microglia) by MS. Pro-inflammatory cytokine mRNA expression was either not affected (IL-6) or reduced (IL-1ß) by MS shortly after CCI. The growth factors GDNF and NGF were only slightly downregulated 4 days after CCI in the MS-treated animals. The changes in glutamatergic signaling, astroglial and cytokine activation as well as neurotrophin expression could, to some extent, explain these changes in pain behavior. Taken together, the results obtained in the described experimental conditions support the mismatch theory of chronic stress where an early life stress, rather than predisposing individuals to certain pathologies, renders them resilient.

Chronic Social Stress Time-Dependently Affects Neuropathic Pain-Related Cold Allodynia and Leads to Altered Expression of Spinal Biochemical Mediators.

Clinical data have shown that chronic exposure to stress may be accompanied by an enhancement of inflammation-related pain sensitivity. In this context, little is however known on the impact of stress on neuropathic pain. In the present study we addressed this issue by combining the chronic constriction injury (CCI) model with an ongoing social stress (OSS) paradigm. Cold plate and von Frey tests were performed in 48 rats divided into four groups: OSS exposed to OSS, CCI subjected to chronic nerve constriction, OSS+CCI with a combination of neuropathy and stress and CON, a control group lacking any manipulation. While we did not observe any stress-related differences in mechanical sensitivity throughout the observation period, CCI rats were more sensitive to cold stimulation than OSS+CCI in the initial phase of neuropathy. A switch was observed at a later stage, leading to a hypersensitivity of the OSS+CCI compared to the CCI rats. At this time point we investigated the spinal mRNA expression of neuron and glia related molecules potentially involved in neuropathic pain and stress. The combination of psychosocial stress and neuropathic pain seemed to enhance glial cell activation, pro-inflammatory cytokine and neurotrophic factor mRNA levels, rather than glutamatergic transmission. Our data show that long lasting social stress may lead to time-dependent alteration of neuropathy-related cold pain sensitivity while mechanically-induced pain remains unchanged.