Muscle ciliary neurotrophic factor receptor α contributes to motor neuron STAT3 activation following peripheral nerve lesion.

Expression of the ciliary neurotrophic factor (CNTF) receptor essential ligand binding subunit, CNTF receptor α (CNTFRα), is induced in motor neurons and skeletal muscle following peripheral nerve lesion. We previously found muscle CNTFRα promotes motor neuron axon regeneration post-lesion. Both nerve lesion and CNTF administration activate motor neuron signal transducer and activator of transcription 3 (STAT3), a transcription factor implicated in axon growth, suggesting CNTF receptors may contribute to the lesion-induced STAT3 activation. However, many receptor types signal through STAT3, and if CNTF receptors contribute, motor neuron receptors seemed most likely to regulate motor neuron STAT3. To determine the role played by muscle CNTFRα, we used in vivo, muscle-specific CNTFRα depletion in mice and report here that this selectively impairs the second phase, sustained motor neuron STAT3 activation post-lesion. Thus, muscle CNTFRα makes an essential contribution to motor neuron STAT3 activation during axon regeneration and may thereby promote axon regeneration through such signaling. We also report CNTFRα quantitative PCR suggesting involvement of many denervated muscle types, as well as muscle damaged at the lesion site. The present data add to the evidence suggesting that enhancing muscle CNTFRα expression may promote motor neuron regeneration in trauma and disease.

Affinity Maturation Is Impaired by Natural Killer Cell Suppression of Germinal Centers.

Somatic hypermutation of immunoglobulin sequences in germinal center (GC) reactions must be optimized to elicit high-affinity, protective antibodies after vaccination. We expose natural killer (NK) cells as robust negative regulators of somatic hypermutation in antigen-reactive B cells. NK cells restrict follicular helper T cell (TFH) and GC B cell frequencies and titers of antigen-specific immunoglobulin after administration of alum-adjuvanted hapten-protein conjugate vaccines. This inhibition is perforin dependent, suggesting that NK cells kill one or more cells critical for GC development. In the presence of perforin-competent NK cells, antigen-specific GC B cells acquire fewer mutations, including less frequent generation of non-synonymous substitutions and mutations associated with increased antibody affinity. Thus, NK cells limit the magnitude of GC reactions and thereby restrain vaccine elicitation of high-affinity antibodies. Circumventing this activity of NK cells during vaccination has strong potential to enhance humoral immunity and facilitate vaccine-elicited prevention of disease.

Adult ciliary neurotrophic factor receptors help maintain facial motor neuron choline acetyltransferase expression in vivo following nerve crush.

Exogenous ciliary neurotrophic factor (CNTF) administration promotes the survival of motor neurons in a wide range of models. It also increases the expression of the critical neurotransmitter enzyme choline acetyltransferase (ChAT) by in vitro motor neurons, likely independent of its effects on their survival. We have used the adult mouse facial nerve crush model and adult-onset conditional disruption of the CNTF receptor α (CNTFRα) gene to directly examine the in vivo roles played by endogenous CNTF receptors in adult motor neuron survival and ChAT maintenance, independent of developmental functions. We have previously shown that adult activation of the CreER gene construct in floxed CNTFRα mice depletes this essential receptor subunit in a large subset of motor neurons (and all skeletal muscle, as shown in this study) but has no effect on the survival of intact or lesioned motor neurons, indicating that these adult CNTF receptors play no essential survival role in this model, in contrast to their essential role during embryonic development. Here we show that this same CNTFRα depletion does not affect ChAT labeling in nonlesioned motor neurons, but it significantly increases the loss of ChAT following nerve crush. The data suggest that, although neither motor neuron nor muscle CNTF receptors play a significant, nonredundant role in the maintenance of ChAT in intact adult motor neurons, the receptors become essential for ChAT maintenance when the motor neurons are challenged by nerve crush. Therefore, the data suggest that the receptors act as a critical component of an endogenous neuroprotective mechanism. J. Comp. Neurol. 525:1206-1215, 2017. © 2016 Wiley Periodicals, Inc.

Muscle and motor neuron ciliary neurotrophic factor receptor α together maintain adult motor neuron axons in vivo.

The molecular mechanisms maintaining adult motor innervation are comparatively unexplored relative to those involved during development. In addition to the fundamental neuroscience question, this area has important clinical ramifications given that loss of neuromuscular contact is thought to underlie several adult onset human neuromuscular diseases including amyotrophic lateral sclerosis. Indirect evidence suggests that ciliary neurotrophic factor (CNTF) receptors may contribute to adult motor neuron axon maintenance. To directly address this in vivo, we used adult onset mouse genetic disruption techniques to deplete motor neuron and muscle CNTF receptor α (CNTFRα), the essential ligand binding subunit of the receptor, and incorporated reporters labelling affected motor neuron axons and terminals. The combined depletion of motor neuron and muscle CNTFRα produced a large loss of motor neuron terminals and retrograde labelling of motor neurons with FluoroGold indicated axon die-back well beyond muscle, together revealing an essential role for CNTFRα in adult motor axon maintenance. In contrast, selective depletion of motor neuron CNTFRα did not affect motor innervation. These data, along with our previous work indicating no effect of muscle specific CNTFRα depletion on motor innervation, suggest that motor neuron and muscle CNTFRα function in concert to maintain motor neuron axons. The data also raise the possibility of motor neuron and/or muscle CNTFRα as therapeutic targets for adult neuromuscular denervating diseases.

Roles of natural killer cells in antiviral immunity.

Natural killer (NK) cells are important in immune defense against virus infections. This is predominantly considered a function of rapid, innate NK-cell killing of virus-infected cells. However, NK cells also prime other immune cells through the release of interferon gamma (IFN-γ) and other cytokines. Additionally, NK cells share features with long-lived adaptive immune cells and can impact disease pathogenesis through the inhibition of adaptive immune responses by virus-specific T and B cells. The relative contributions of these diverse and conflicting functions of NK cells in humans are poorly defined and likely context-dependent, thereby complicating the development of therapeutic interventions. Here we focus on the contributions of NK cells to disease in diverse virus infections germane to human health.

Boosting vaccine efficacy the natural (killer) way.

Coordination of the innate and adaptive immune systems is paramount to the development of protective humoral and cellular immunity following vaccination. Natural killer (NK) cells are front-line soldiers of the innate immune system, and recent studies have revealed functions for NK cells in long-lived immune memory and the regulation of adaptive immune responses. These findings suggest that NK cells may play important roles in the development of efficacious vaccines, as well as, in some contexts, failed immunizations. Here, we review the current understanding of the immunomodulatory and memory differentiation capabilities of NK cells. We examine the context dependency of the mechanisms and the nature of NK cell-mediated modulation of the immune response, and discuss how these insights may impact immunization strategies and the development of next-generation vaccines.

Generation of cellular immune memory and B-cell immunity is impaired by natural killer cells.

The goal of most vaccines is the induction of long-lived memory T and B cells capable of protecting the host from infection by cytotoxic mechanisms, cytokines and high-affinity antibodies. However, efforts to develop vaccines against major human pathogens such as HIV and HCV have not been successful, thereby highlighting the need for novel approaches to circumvent immunoregulatory mechanisms that limit the induction of protective immunity. Here, we show that mouse natural killer (NK) cells inhibit generation of long-lived virus-specific memory T- and B cells as well as virus-specific antibody production after acute infection. Mechanistically, NK cells suppressed CD4 T cells and follicular helper T cells (T(FH)) in a perforin-dependent manner during the first few days of infection, resulting in a weaker germinal centre (GC) response and diminished immune memory. We anticipate that innovative strategies to relieve NK cell-mediated suppression of immunity should facilitate development of efficacious new vaccines targeting difficult-to-prevent infections.

Exacerbation of allergen-induced eczema in TLR4- and TRIF-deficient mice.

Despite its presence on resident skin cells, the role of TLR4 in skin diseases remains poorly understood. This is highly significant because the skin biome is rich with potential TLR4 agonists. We aimed to establish the contribution of TLR4 to atopic dermatitis and determine the mechanism by which TLR4 acts in an experimental model of atopic dermatitis. MyD88, TLR4, or Toll-IL-1R domain-containing adapter-inducing IFN-ß (TRIF)-deficient and wild-type mice were epicutaneously exposed to Aspergillus fumigatus allergen over 3 wk. Impaired skin barrier function was assessed by measuring transepidermal water loss (TEWL). Skin levels of innate and adaptive genes were quantified. In an experimental model of atopic dermatitis, TEWL, allergic sensitization, and epidermal thickness were increased following cutaneous allergen exposure, and these were further enhanced in the absence of TLR4. Increased allergen-induced skin levels of innate (S100A8/A9, IL-1ß, TNF-α, and CXCL2) and Th17 genes (IL-17A and IL-17F) were observed in TLR4-deficient mice compared with wild-type mice. The absence of MyD88 alleviated disease (decreased TEWL, skin thickness, proinflammatory cytokines), whereas TRIF deficiency exacerbated disease. In conclusion, signaling through the TLR4 and TRIF pathways limits skin barrier dysfunction, cutaneous allergic sensitization, and proinflammatory cytokine production.

The contribution of ciliary neurotrophic factor receptors to adult motor neuron survival in vivo is specific to insult type and distinct from that for embryonic motor neurons.

Exogenous ciliary neurotrophic factor (CNTF) promotes motor neuron (MN) survival following trauma and in genetic models of MN disease. Unconditional disruption of the mouse CNTF receptor α (CNTFRα) gene leads to MN loss, demonstrating a developmental role for endogenous CNTF receptor signaling. These data also suggest that CNTF receptors may promote adult MN survival and that appropriately manipulating the receptors could effectively treat adult MN disorders. This effort would greatly benefit from a better understanding of the roles played by CNTF receptors in adult MNs. We have previously found that adult onset disruption of CNTFRα in facial MNs of "floxed CNTFRα" mice by AAV-Cre vector injection leads to significantly more MN loss than in identically treated controls. While indicating that CNTF receptors can promote adult MN survival, the data did not distinguish between potential roles in MN maintenance versus roles in protecting MNs from the injection associated trauma or the toxicity of the chronic Cre recombinase (Cre) produced by the AAV-Cre. Here we used an inducible Cre gene construct to produce adult-onset CNTFRα disruption in facial MNs without the traumatic and toxic effects of the AAV-Cre procedure. The MNs survive without CNTFRα, even when challenged by facial nerve crush or the injection-associated trauma, thereby suggesting, in conjunction with our previous study, that endogenous CNTF receptor signaling can protect MNs against toxic insult, such as that produced by chronic Cre. The data also indicate that in vivo CNTF receptors play very different roles in adult and embryonic MNs.