Linda V. Blomster

Mobilisation of the splenic monocyte reservoir and peripheral CX3CR1 deficiency adversely affects recovery from spinal cord injury

Macrophages in the injured spinal cord originate from resident microglia and blood monocytes. Whether this diversity in origins contributes to their seemingly dual role in immunopathology and repair processes has remained poorly understood. Here we took advantage of Cx₃cr1(gfp) mice to visualise monocyte-derived macrophages in the injured spinal cord via adoptive cell transfer and bone marrow (BM) chimera approaches. We show that the majority of infiltrating monocytes at 7 days post-injury originate from the spleen and only to a lesser extent from the BM. Prevention of early monocyte infiltration via splenectomy was associated with improved recovery at 42 days post-SCI. In addition, an increased early presence of infiltrating monocytes/macrophages, as a result of CX₃CR1 deficiency within the peripheral immune compartment, correlated with worsened injury outcomes. Adoptive transfer of identified Cx₃cr1(gfp/+) monocytes confirmed peak infiltration at 7 days post-injury, with inflammatory (Ly6C(high)) monocytes being most efficiently recruited. Focal SCI also changed the composition of the two major monocyte subsets in the blood, with more Ly6C(high) cells present during peak recruitment. Adoptive transfer experiments further suggested high turnover of inflammatory monocytes in the spinal cord at 7 days post-injury. Consistent with this, only a small proportion of infiltrating cells unequivocally expressed polarisation markers for pro-inflammatory (M1) or alternatively activated (M2) macrophages at this time point. Our findings offer new insights into the origins of monocyte-derived macrophages after SCI and their contribution to functional recovery, providing a basis for further scrutiny and selective targeting of Ly6C(high) monocytes to improve outcomes from neurotraumatic events.

CX3CL1/fractalkine regulates branching and migration of monocyte-derived cells in the mouse olfactory epithelium

The olfactory epithelium (OE) is a site of massive adult neurogenesis where olfactory sensory neurons (OSNs) are continuously turned over. Tissue macrophages have been implicated in phagocytosis of degenerating cells but the molecular mechanisms that allow for their recruitment while maintaining a neurogenic microenvironment are poorly understood. This study reports that the neuroprotective chemokine CX3CL1 is expressed by OSNs and olfactory ensheathing cells. Monocyte-derived cells in the OE depend on CX3CL1-signalling for intraepithelial migration and apical dendrite expression. These observations are first to demonstrate phenotypic differences in appearance and distribution of monocyte-derived cells in nervous tissue due to CX3CR1 deficiency.

CX3CR1 deficiency exacerbates neuronal loss and impairs early regenerative responses in the target-ablated olfactory epithelium

The olfactory epithelium is a site of sustained adult neurogenesis where olfactory sensory neurons are continuously replaced from endogenous stem/progenitor cells. Epithelial macrophages have been implicated in the phagocytosis of degenerating cells but the molecular mechanisms allowing for their recruitment and activation while maintaining a neurogenic microenvironment are poorly understood. We have previously shown that the chemokine fractalkine (CX₃CL1) is expressed by olfactory sensory neurons and ensheathing cells in the olfactory epithelium. In turn, the fractalkine receptor, CX₃CR1, is expressed on macrophages and dendritic cells within the olfactory epithelium. We report that a selective cell death of olfactory sensory neurons in the epithelium of CX₃CR1-deficient mice via target ablation (i.e. olfactory bulbectomy) results in an exacerbated loss of olfactory sensory neurons compared to wild-type mice. In addition, reduced proliferation of intraepithelial stem/progenitor cells was observed in lesioned CX₃CR1-deficient mice, suggesting an impaired regenerative response. Importantly, a lack of CX₃CL1-signaling caused increased recruitment of macrophages into the olfactory epithelium, which in turn contained higher levels of pro-inflammatory cytokines (e.g. TNF-α and IL-6) as determined by qPCR. We also present novel data showing that, relative to wild-type, CX₃CR1-deficient macrophages have diminished phagocytic activity following stimulation with CX₃CL1. Collectively, our data indicate that signaling through the CX₃CR1 receptor modulates macrophage activity, resulting in an environment conducive to olfactory sensory neuron clearance and targeted replacement from endogenous stem/progenitor cells.

Multifidus Muscle Changes After Back Injury Are Characterized by Structural Remodeling of Muscle, Adipose and Connective Tissue, but Not Muscle Atrophy: Molecular and Morphological Evidence.

Study Design. Longitudinal case-controlled animal study. Objective. To investigate putative cellular mechanisms to explain structural changes in muscle and adipose and connective tissues of the back muscles after intervertebral disc (IVD) injury. Summary of Background Data. Structural back muscle changes are ubiquitous with back pain/injury and considered relevant for outcome, but their exact nature, time course, and cellular mechanisms remain elusive. We used an animal model that produces phenotypic back muscle changes after IVD injury to study these issues at the cellular/molecular level. Methods. Multifidus muscle was harvested from both sides of the spine at L1–L2 and L3–L4 IVDs in 27 castrated male sheep at 3 (n = 10) or 6 (n = 17) months after a surgical anterolateral IVD injury at both levels. Ten control sheep underwent no surgery (3 mo, n = 4; 6 mo, n = 6). Tissue was harvested at L4 for histological analysis of cross-sectional area of muscle and adipose and connective tissue (whole muscle), plus immunohistochemistry to identify proportion and cross-sectional area of individual muscle fiber types in the deepest fascicle. Quantitative polymerase chain reaction measured gene expression of typical cytokines/signaling molecules at L2. Results. Contrary to predictions, there was no multifidus muscle atrophy (whole muscle or individual fiber). There was increased adipose and connective tissue (fibrotic proliferation) cross-sectional area and slow-to-fast muscle fiber transition at 6 but not 3 months. Within the multifidus muscle, increases in the expression of several cytokines (tumor necrosis factor &agr; and interleukin-1&bgr;) and molecules that signal trophic/atrophic processes for the 3 tissue types (e.g., growth factor pathway [IGF-1, PI3k, Akt1, mTOR], potent tissue modifiers [calcineurin, PCG-1&agr;, and myostatin]) were present. Conclusion. This study provides cellular evidence that refutes the presence of multifidus muscle atrophy accompanying IVD degeneration at this intermediate time point. Instead, adipose/connective tissue increased in parallel with the expression of the genes that provide putative mechanisms for multifidus structural remodeling. This provides novel targets for pharmacological and physical interventions. Level of Evidence: N/A

Can proinflammatory cytokine gene expression explain multifidus muscle fiber changes after an intervertebral disc lesion

Study Design. Longitudinal case-controlled animal study. Objective. To investigate the effect of an intervertebral disc (IVD) lesion on the proportion of slow, fast, and intermediate muscle fiber types in the multifidus muscle in sheep, and whether muscle fiber changes were paralleled by local gene expression of the proinflammatory cytokines tumor necrosis factor &agr; (TNF-&agr;) and interleukin 1-&bgr;. Summary of Background Data. Structure and behavior of the multifidus muscle change in acute and chronic back pain, but the mechanisms are surprisingly poorly understood and the link between structure and behavior is tenuous. Although changes in muscle fiber types have the potential to unify the observations, the effect of injury on muscle fiber distribution has not been adequately tested, and understanding of possible mechanisms is limited. Methods. The L1–L2, L3–L4, and L5–L6 IVDs of 11 castrated male sheep received anterolateral lesions. Six control sheep underwent no surgical procedures. Multifidus muscle tissue was harvested at L4 for muscle fiber analysis using immunohistochemistry and L2 for cytokine analysis with polymerase chain reaction for local gene expression of TNF-&agr; and interleukin-1&bgr;. Results. The proportion of slow muscle fibers in multifidus was significantly less in the lesioned animals both ipsilateral and contralateral to the IVD lesion. The greatest reduction in slow fibers was in the deep medial muscle region. A greater prevalence of intermediate fibers on the uninjured side implies a delayed fiber-type transformation on that side. TNF-&agr; gene expression in multifidus was greater on both sides in the lesion animals than in the muscle of control animals. Interleukin-1&bgr; was increased only on the injured side. Conclusion. These data provide evidence of muscle fiber changes after induction of an IVD lesion and a parallel increase in TNF-&agr; expression. Proinflammatory cytokine changes provide a novel mechanism to explain behavioral and structural changes in multifidus. Level of Evidence: N/A

Localization of Na(v)1.7 in the normal and injured rodent olfactory system indicates a critical role in olfaction, pheromone sensing and immune function

Loss-of-function mutations in the pore-forming α subunit of the voltage-gated sodium channel 1.7 (Nav1.7) cause congenital indifference to pain and anosmia. We used immunohistochemical techniques to study Nav1.7 localization in the rat olfactory system in order to better understand its role in olfaction. We confirm that Nav1.7 is expressed on olfactory sensory axons and report its presence on vomeronasal axons, indicating an important role for Nav1.7 in transmission of pheromonal cues. Following neuroepithelial injury, Nav1.7 was transiently expressed by cells of monocytic lineage. These findings support an emerging role for Nav1.7 in immune function. This sodium channel may provide an important pharmacological target for treatment of inflammatory injury and inflammatory pain syndromes.

Detection of endogenous iron deposits in the injured mouse spinal cord through high-resolution ex vivo and in vivo MRI

The main aim of this study was to employ high‐resolution MRI to investigate the spatiotemporal development of pathological features associated with contusive spinal cord injury (SCI) in mice. Experimental mice were subjected to either sham surgery or moderate contusive SCI. A 16.4‐T small‐animal MR system was employed for nondestructive imaging of post‐mortem, fixed spinal cord specimens at the subacute (7 days) and more chronic (28–35 days) stages post‐injury. Routine histological techniques were used for subsequent investigation of the observed neuropathology at the microscopic level. The central core of the lesion appeared as a dark hypo‐intense area on MR images at all time points investigated. Small focal hypo‐intense spots were also observed spreading through the dorsal funiculi proximal and distal to the site of impact, an area that is known to undergo gliosis and Wallerian degeneration in response to injury. Histological examination revealed these hypo‐intense spots to be high in iron content as determined by Prussian blue staining. Quantitative image analysis confirmed the increased presence of iron deposits at all post‐injury time points investigated (p < 0.05). Distant iron deposits were also detectable through live imaging without the use of contrast‐enhancing agents, enabling the longitudinal investigation of this pathology in individual animals. Further immunohistochemical evaluation showed that intracellular iron deposits localised to macrophages/microglia, astrocytes and oligodendrocytes in the subacute phase of SCI, but predominantly to glial fibrillary acidic protein‐positive, CC‐1‐positive astrocytes at later stages of recovery. Progressive, widespread intracellular iron accumulation is thus a normal feature of SCI in mice, and high‐resolution MRI can be effectively used to detect and monitor these neuropathological changes with time. Copyright

Bone marrow chimeric mice reveal a role for CX3CR1 in maintenance of the monocyte-derived cell population in the olfactory neuroepithelium

Macrophages in the olfactory neuroepithelium are thought to play major roles in tissue homeostasis and repair. However, little information is available at present about possible heterogeneity of these monocyte‐derived cells, their turnover rates, and the role of chemokine receptors in this process. To start addressing these issues, this study used Cx3cr1gfp mice, in which the gene sequence for eGFP was knocked into the CX3CR1 gene locus in the mutant allele. Using neuroepithelial whole‐mounts from Cx3cr1gfp/+ mice, we show that eGFP+ cells of monocytic origin are distributed in a loose network throughout this tissue and can be subdivided further into two immunophenotypically distinct subsets based on MHC‐II glycoprotein expression. BM chimeric mice were created using Cx3cr1gfp/+ donors to investigate turnover of macrophages (and other monocyte‐derived cells) in the olfactory neuroepithelium. Our data indicate that the monocyte‐derived cell population in the olfactory neuroepithelium is actively replenished by circulating monocytes and under the experimental conditions, completely turned over within 6 months. Transplantation of Cx3cr1gfp/gfp (i.e., CX3CR1‐deficient) BM partially impaired the replenishment process and resulted in an overall decline of the total monocyte‐derived cell number in the olfactory epithelium. Interestingly, replenishment of the CD68lowMHC‐II+ subset appeared minimally affected by CX3CR1 deficiency. Taken together, the established baseline data about heterogeneity of monocyte‐derived cells, their replenishment rates, and the role of CX3CR1 provide a solid basis to further examine the importance of different monocyte subsets for neuroregeneration at this unique frontier with the external environment.

Encenicline, an α7 Nicotinic Acetylcholine Receptor Partial Agonist, Reduces Immune Cell Infiltration in the Colon and Improves Experimental Colitis in Mice.

The α7 pentamer nicotinic acetylcholine receptors (nAChRs) are a target in transduction of anti-inflammatory signals from the central nervous system to the gastrointestinal (GI) tract. The aim of this study was to investigate the anti-inflammatory action of the novel α7 nAChR partial agonist encenicline and to determine the mechanism underlying its activity. Anti-inflammatory activity of encenicline was evaluated using trinitrobenzenesulfonic acid (TNBS)- and dextran sulfate sodium (DSS)-induced models of colitis. Macroscopic score, ulcer score, colon length and thickness, as well as myeloperoxidase (MPO) activity were recorded. Immunohistochemistry (IHC) was used to measure the infiltration of immune cells in the colon. Furthermore, we employed flow cytometry to determine the effect of encenicline on frequencies of FoxP3+ and interleukin (IL)-17A+ T cells in the mouse colon. Encenicline attenuated TNBS- and DSS-induced colitis in mice via α7 nAChRs, as indicated by significantly reduced macroscopic parameters and MPO activity. Treatment with encenicline significantly reduced the infiltration of macrophages, neutrophils, and B cells in the colon of TNBS-treated animals, as indicated by IHC. In the TNBS model encenicline reduced the frequency of FoxP3+ IL-17A+ T cells in the colon. In the DSS-model treatment encenicline increased the frequency of FoxP3+ T cells and reduced IL-17A+ T cells. Stimulation of α7 nAChR with partial agonist encenicline alleviates colitis via alteration of the number and/or activation status of the immune cells in the gut, emphasizing a potential role of α7 nAChRs as a target for anticolitic drugs.

Potassium channel expression and function in microglia: Plasticity and possible species variations

ABSTRACT Potassium channels play important roles in microglia functions and thus constitute potential targets for the treatment of neurodegenerative diseases like Alzheimer, Parkinson and stroke. However, uncertainty still prevails as to which potassium channels are expressed and at what levels in different species, how the expression pattern changes upon activation with M1 or M2 polarizing stimuli compared with more complex exposure paradigms, and - most importantly - how these findings relate to the in vivo situation. In this mini-review we discuss the functional potassium channel expression pattern in cultured neonatal mouse microglia in the light of data obtained previously from animal disease models and immunohistochemical studies and compare it with a recent study of adult human microglia isolated from epilepsy patients. Overall, microglial potassium channel expression is very plastic and possibly shows species differences and therefore should be studied carefully in each disease setting and respective animal models.