Showing papers by "Michael W. Salter published in 2020"

Sex-Dependent Mechanisms of Chronic Pain: A Focus on Microglia and P2X4R.

Abstract: For over two decades, purinergic signaling in microglia has persisted in the spotlight as a major pathomechanism of chronic pain. Of the many purinoreceptors, the P2X4R of the ionotropic family, has a well-described causal role underlying chronic neuropathic pain. This review will briefly examine microglial P2X4R signaling in the spinal cord as it relates to chronic pain through a historical lens, followed by a more in-depth examination of recent work, which has revealed major sex differences. We also discuss the generalizability of sex differences in microglial and P2X4R signaling in other pain conditions as well as in nonspinal regions. Finally, we speculate on remaining gaps in the literature as well as what can be done to address them with the ultimate goal of using our collective knowledge to treat chronic pain effectively and in both sexes. SIGNIFICANCE STATEMENT: Effective treatments are lacking for chronic pain sufferers, and this may be explained by the vast sex differences underlying chronic pain mechanisms. In this minireview, we focus on the roles of microglia and P2X4R in chronic pain, with specific attention to the circumstances under which these pathomechanisms differ between males and females. By delineating the ways in which pain occurs differently between the sexes, we can start developing successful therapies for all.

Tripartite signalling by NMDA receptors.

Abstract: N-methyl-d-aspartate receptors (NMDARs) are excitatory glutamatergic receptors that are fundamental for many neuronal processes, including synaptic plasticity. NMDARs are comprised of four subunits derived from heterogeneous subunit families, yielding a complex diversity in NMDAR form and function. The quadruply-liganded state of binding of two glutamate and two glycine molecules to the receptor drives channel gating, allowing for monovalent cation flux, Ca2+ entry and the initiation of Ca2+-dependent signalling. In addition to this ionotropic function, non-ionotropic signalling can be initiated through the exclusive binding of glycine or of glutamate to the NMDAR. This binding may trigger a transmembrane conformational change of the receptor, inducing intracellular protein-protein signalling between the cytoplasmic domain and secondary messengers. In this review, we outline signalling cascades that can be activated by NMDARs and propose that the receptor transduces signalling through three parallel streams: (i) signalling via both glycine and glutamate binding, (ii) signalling via glycine binding, and (iii) signalling via glutamate binding. This variety in signal transduction mechanisms and downstream signalling cascades complements the widespread prevalence and rich diversity of NMDAR activity throughout the central nervous system and in disease pathology.

Intracellular Calcium Responses Encode Action Potential Firing in Spinal Cord Lamina I Neurons

Abstract: Maladaptive plasticity of neurons in lamina I of the spinal cord is a lynchpin for the development of chronic pain, and is critically dependent on intracellular calcium signaling. However, the relationship between neuronal activity and intracellular calcium in these neurons is unknown. Here we combined two-photon calcium imaging with whole-cell electrophysiology to determine how action potential firing drives calcium responses within subcellular compartments of male rat spinal cord lamina I neurons. We found that single action potentials generated at the soma increase calcium concentration in the somatic cytosol and nucleus, and these calcium responses invade dendrites and dendritic spines by active backpropagation. Calcium responses in each compartment were dependent on voltage-gated calcium channels, and somatic and nuclear calcium responses were amplified by release of calcium from ryanodine-sensitive intracellular stores. Grouping single action potential-evoked calcium responses by neuron type demonstrated their presence in all defined types, as well as a high degree of similarity in calcium responses between neuron types. With bursts of action potentials, we found that calcium responses have the capacity to encode action potential frequency and number in all compartments, with action potential number being preferentially encoded. Together, these findings indicate that intracellular calcium serves as a readout of neuronal activity within lamina I neurons, providing a unifying mechanism through which activity may regulate plasticity, including that seen in chronic pain.SIGNIFICANCE STATEMENT Despite their critical role in both acute pain sensation and chronic pain, little is known of the fundamental physiology of spinal cord lamina I neurons. This is especially the case with respect to calcium dynamics within these neurons, which could regulate maladaptive plasticity observed in chronic pain. By combining two-photon calcium imaging and patch-clamp electrophysiological recordings from lamina I neurons, we found that action potential firing induces calcium responses within the somatic cytosol, nucleus, dendrites, and dendritic spines of lamina I neurons. Our findings demonstrate the presence of actively backpropagating action potentials, shifting our understanding of how these neurons process information, such that calcium provides a mechanism for lamina I neurons to track their own activity.

Single-cell RNA sequencing reveals time- and sex-specific responses of spinal cord microglia to peripheral nerve injury and links ApoE to neuropathic pain

Abstract: Activation of microglia in the spinal cord following peripheral nerve injury is critical for the development of long-lasting pain hypersensitivity. However, it remains unknown whether distinct microglia subpopulations or states contribute to different stages of pain development and maintenance. We show, using single-cell RNA-sequencing, that nerve injury induces the generation of a male-specific inflammatory microglia subtype, and demonstrate increased proliferation of microglia in males as compared to females. We also show time- and sex-specific transcriptional changes in different microglial subpopulations following injury. Apolipoprotein E (Apoe) is the top upregulated gene in microglia at chronic time points after nerve injury in mice and polymorphisms in the APOE gene in humans are associated with chronic pain. Single-cell analysis of human spinal cord microglia reveals a subpopulation with a disease-related transcriptional signature. Our data provide a detailed analysis of transcriptional states of mouse and human spinal cord microglia, and identify a previously unrecognized role for ApoE in neuropathic pain.

Wide phenotypic spectrum of human stem cell-derived excitatory neurons with Rett syndrome-associated MECP2 mutations

Abstract: Rett syndrome (RTT) is a severe neurodevelopmental disorder primarily caused by heterozygous loss-of-function mutations in the X-linked gene methyl-CpG-binding protein 2 (MECP2) that is a global transcriptional regulator. Mutations in the methyl-binding domain (MBD) of MECP2 disrupt its interaction with methylated DNA required for proper function in the brain. Here, we investigate the effect of a novel MECP2 L124W missense mutation in the MBD in comparison to MECP2 null mutations. L124W protein had a limited ability to disrupt heterochromatic chromocenters due to decreased binding dynamics. We isolated two pairs of isogenic WT and L124W induced pluripotent stem cell lines. L124W induced excitatory neurons expressed stable protein, exhibited only increased input resistance and impaired voltage-gated Na+ and K+ currents, and their neuronal dysmorphology was limited to reduced dendritic complexity. Three isogenic pairs of MECP2 null neurons had the expected more pronounced morphological and electrophysiological phenotypes, exhibiting decreased soma area, dendrite length, capacitance and excitatory synaptic function. We examined development and maturation of excitatory neural networks using micro-electrode arrays to detect alterations in RTT connectivity. The L124W neurons had no detectable changes in network circuitry features, in contrast to MECP2 null neurons that suffered a significant change in synchronous network burst frequency and a transient extension of network burst duration. Our results from stem cell-derived RTT excitatory neurons reveal a wide range of morphological, electrophysiological and circuitry phenotypes that reflect the severity of the MECP2 mutation.