The microglial networks of the brain and their role in neuronal network plasticity after lesion

Degenerative and protective reactions of the rat trigeminal motor nucleus after removal of the masseter and temporal muscles

BACKGROUND

Microsurgical reconstruction techniques have allowed treatment of advanced head and neck carcinomas; however, it remains difficult to achieve long-term, functional reconstruction of the faciocervical muscles. To address this issue, in this we developed a rat trigeminal nerve denervation model that closely simulates the effects of oral surgery.

METHODS

The rat trigeminal nerve denervation model was developed by removing the masseter and temporal muscles, and degeneration process of the trigeminal motor nucleus was investigated by immunohistochemistry with particular focus on microglial/astrocytic reactions and motoneuron degeneration.

RESULTS

Atrophy of the trigeminal motor nucleus was observed at 8 weeks after denervation. A microglial reaction peaked at 3 days post-operation, while an astrocytic reaction was evident within 2 weeks, and peaked around 4 weeks post-operation. Expression of the stress protein HSP27 and an autophagy marker Rab24 was also upregulated in the injured trigeminal motor nucleus.

CONCLUSIONS

The results from this study suggest that this model is a practical and useful tool help to develop a further understanding of the pathology of the trigeminal motor nucleus after surgical denervation.

Noradrenaline reduces the ATP-stimulated phosphorylation of p38 MAP kinase via beta-adrenergic receptors-cAMP-protein kinase A-dependent mechanism in cultured rat spinal microglia

To elucidate the involvement of the noradrenergic system in the regulation of spinal microglial activity, we examined the effects of noradrenaline (NA) on the phosphorylation of three MAP kinases (extracellular signal-regulated kinase (ERK), p38, or c-Jun N-terminal kinase (JNK)) stimulated by ATP in rat cultured spinal microglia using Western blotting. ATP (100 microM) quickly induced the phosphorylation of three MAP kinases and MKK3/6, which are upstream kinases of p38. Under these conditions, NA inhibited only the ATP-stimulated phosphorylation of p38 in a time (30-60 min)- and dose (10-100 microM)-dependent manner, but did not affect those of ERK, JNK, or MKK3/6. The inhibitory action of NA was completely reversed by pretreatment with propranolol, an antagonist for beta-adrenoceptors, or both atenolol and ICI118551, selective antagonists for beta1 and beta2, respectively. Treatment with dibutyryl cAMP or the selective activator of PKA mimicked the inhibitory effect of NA. Furthermore, treatment with KT5720, an inhibitor of protein kinase A, completely blocked the action of NA. These data suggest that NA could control the activation of p38 through the beta1/2-adrenergic pathways, which include the production of cAMP and the activation of PKA. Simultaneously, we found that NA also markedly inhibited the ATP-induced increase in the expression of tumor necrosis factor (TNF)-alpha mRNA through beta-adrenergic pathways. Furthermore, preincubation with either actinomycin D or cyclohexamide, general inhibitors of transcription or protein synthesis, respectively, almost completely blocked the inhibitory action of NA on the ATP-stimulated phosphorylation of p38. These results suggest that de novo synthesis of certain factors by NA through beta-adrenoceptors would participate in the modulation of p38 activity. Thus, the inhibitory system via beta1/2-adrenergic pathways in spinal microglia appears to have an important role in the modulation of microglial functions through the downregulation of p38 activity.

The HLA genomic loci map: expression, interaction, diversity and disease

The human leukocyte antigen (HLA) super-locus is a genomic region in the chromosomal position 6p21 that encodes the six classical transplantation HLA genes and at least 132 protein coding genes that have important roles in the regulation of the immune system as well as some other fundamental molecular and cellular processes. This small segment of the human genome has been associated with more than 100 different diseases, including common diseases, such as diabetes, rheumatoid arthritis, psoriasis, asthma and various other autoimmune disorders. The first complete and continuous HLA 3.6 Mb genomic sequence was reported in 1999 with the annotation of 224 gene loci, including coding and non-coding genes that were reviewed extensively in 2004. In this review, we present (1) an updated list of all the HLA gene symbols, gene names, expression status, Online Mendelian Inheritance in Man (OMIM) numbers, including new genes, and latest changes to gene names and symbols, (2) a regional analysis of the extended class I, class I, class III, class II and extended class II subregions, (3) a summary of the interspersed repeats (retrotransposons and transposons), (4) examples of the sequence diversity between different HLA haplotypes, (5) intra- and extra-HLA gene interactions and (6) some of the HLA gene expression profiles and HLA genes associated with autoimmune and infectious diseases. Overall, the degrees and types of HLA super-locus coordinated gene expression profiles and gene variations have yet to be fully elucidated, integrated and defined for the processes involved with normal cellular and tissue physiology, inflammatory and immune responses, and autoimmune and infectious diseases.

Age and region-specific responses of microglia, but not astrocytes, suggest a role in selective vulnerability of dopamine neurons after 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine exposure in monkeys

Little is known about the effects of aging, the strongest risk factor for Parkinson's disease (PD), on glial responses to dopamine (DA) neuron degeneration in midbrain subregions that display selective vulnerability to degeneration. We evaluated the impact of aging on astrocytes and microglia in a regionally specific manner in a monkey model of PD. 1-Methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) was delivered unilaterally via the internal carotid artery of young, middle-aged, and old-aged rhesus monkeys. Astrocytes and microglia were identified using glial fibrillary acidic protein and human leukocyte antigen-DR (HLA-DR) immunolabeling, respectively. Glial reactivity was assessed using (1) stereological cell counting, (2) fluorescence intensity, and (3) a morphology rating scale. In the midbrain contralateral and ipsilateral to the MPTP injection, astrocyte number and intensity did not change with age. In both sides of the midbrain, cellular morphology suggested astrocyte hypertrophy in middle-age dissipated in old-age, irrespective of DA subregion and regional differences in vulnerability to degeneration. In the contralateral midbrain, microglia became mildly activated (increased cell number and intensity, and morphological changes) with advancing age. Inflammation was evident at 3 months postlesion by severe microglial activation in the ipsilateral midbrain. HLA-DR fluorescence intensity and an abundance of activated microglia (based on morphological criteria) were consistently exacerbated in the vtSN of both sides of the midbrain. These results suggest the glial responses accompanying aging and DA neuron degeneration following a toxic insult represent persistent alterations in the microenvironment of surviving DA neurons that are important factors in understanding regional differences in susceptibility to degeneration.

Brain inflammation and adult neurogenesis: the dual role of microglia

In the adult mammalian brain, neurogenesis from neural stem/progenitor cells continues in two regions: the subgranular zone in the dentate gyrus and the subventricular zone lining the lateral ventricles. The generated neuroblasts migrate to their appropriate location and differentiate to mature granule cells and olfactory bulb interneurons, respectively. Following injury such as stroke, neuroblasts generated in the subventricular zone migrate also into areas which are not normally neurogenic, e.g. striatum and cerebral cortex. In the initial studies in rodents, brain inflammation and microglia activation were found to be detrimental for the survival of the new hippocampal neurons early after they had been born. The role of inflammation for adult neurogenesis has, however, turned out to be much more complex. Recent experimental evidence indicates that microglia under certain circumstances can be beneficial and support the different steps in neurogenesis, progenitor proliferation, survival, migration, and differentiation. Here we summarize the current knowledge on the role of inflammation and in particular of microglia in adult neurogenesis in the intact and injured mammalian brain. We conclude that microglia activation, as an indicator of inflammation, is not pro- or antineurogenic per se but the net outcome is dependent on the balance between secreted molecules with pro- and antiinflammatory action.

Microglial clearance function in health and disease

Microglial cells are of hematopoietic origin, populate the CNS during early development and form the brain's innate immune cell type. Besides their well-known role in immune defense, microglia have an active and homeostatic function in the normal CNS based on high motility of their ramified processes and endocytic clearance of apoptotic vesicular material. During development microglia contribute to the reorganization of neuronal connections, however microglia have also pivotal roles during acute and chronic neurodegeneration. Microglia become attracted to site of injury by nucleotides released from damaged neurons. Scavenger receptors expressed on microglia bind to debris and microglial phagocytic receptors signal via immunoreceptor tyrosine-based activation motif (ITAM)--containing adaptor proteins to promote phagocytosis of extracellular material. Insufficient clearance by microglia appears to be prevalent in neurodegenerative diseases such as Alzheimer's disease.

Debris clearance by microglia: an essential link between degeneration and regeneration

Microglia are cells of myeloid origin that populate the CNS during early development and form the brain's innate immune cell type. They perform homoeostatic activity in the normal CNS, a function associated with high motility of their ramified processes and their constant phagocytic clearance of cell debris. This debris clearance role is amplified in CNS injury, where there is frank loss of tissue and recruitment of microglia to the injured area. Recent evidence suggests that this phagocytic clearance following injury is more than simply tidying up, but instead plays a fundamental role in facilitating the reorganization of neuronal circuits and triggering repair. Insufficient clearance by microglia, prevalent in several neurodegenerative diseases and declining with ageing, is associated with an inadequate regenerative response. Thus, understanding the mechanism and functional significance of microglial-mediated clearance of tissue debris following injury may open up exciting new therapeutic avenues.

Microglia: active sensor and versatile effector cells in the normal and pathologic brain

Microglial cells constitute the resident macrophage population of the CNS. Recent in vivo studies have shown that microglia carry out active tissue scanning, which challenges the traditional notion of 'resting' microglia in the normal brain. Transformation of microglia to reactive states in response to pathology has been known for decades as microglial activation, but seems to be more diverse and dynamic than ever anticipated--in both transcriptional and nontranscriptional features and functional consequences. This may help to explain why engagement of microglia can be either neuroprotective or neurotoxic, resulting in containment or aggravation of disease progression. Moreover, little is known about the heterogeneity of microglial responses in different pathologic contexts that results from regional adaptations or from the progression of a disease. In this review, we focus on several key observations that illustrate the multi-faceted activities of microglia in the normal and pathologic brain.

VEGF reduces astrogliosis and preserves neuromuscular junctions in ALS transgenic mice

Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disease resulting from motor neuron loss in the spinal cord and brain stem. In the present study, we found that systemic administration of recombinant vascular endothelial growth factor (VEGF) significantly diminished astrogliosis and increased the number of neuromuscular junctions in a Cu/Zn superoxide dismutase (SOD1) transgenic mouse model of ALS. Our results thus demonstrate a novel regulatory role of VEGF on astrocytes and are suggestive of protective effects of VEGF both in the peripheral and central nervous system in the SOD1 transgenic mouse model. These findings warrant further evaluation of the mechanism(s) of regulatory effects of VEGF on neuronal and non-neuronal cells, and the relation of these events to motor neuron degeneration and the onset and progression of ALS.