Degradation of oxidized extracellular proteins by microglia

Decellularized brain extracellular matrix based NGF-releasing cryogel for brain tissue engineering in traumatic brain injury

Traumatic brain injuries(TBI) pose significant challenges to human health, specifically neurological disorders and related motor activities. After TBI, the injured neuronal tissue is known for hardly regenerated and recovered to their normal neuron physiology and tissue compositions. For this reason, tissue engineering strategies that promote neuronal regeneration have gained increasing attention. This study explored the development of a novel neural tissue regeneration cryogel by combining brain-derived decellularized extracellular matrix (ECM) with heparin sulfate crosslinking that can perform nerve growth factor (NGF) release ability. Morphological and mechanical characterizations of the cryogels were performed to assess their suitability as a neural regeneration platform. After that, the heparin concnentration dependent effects of varying NGF concentrations on cryogel were investigated for their controlled release and impact on neuronal cell differentiation. The results revealed a direct correlation between the concentration of released NGF and the heparin sulfate ratio in cryogel, indicating that the cryogel can be tailored to carry higher loads of NGF with heparin concentration in cryogel that induced higher neuronal cell differentiation ratio. Furthermore, the study evaluated the NGF loaded cryogels on neuronal cell proliferation and brain tissue regeneration in vivo. The in vivo results suggested that the NGF loaded brain ECM derived cryogel significantly affects the regeneration of brain tissue. Overall, this research contributes to the development of advanced neural tissue engineering strategies and provides valuable insights into the design of regenerative cryogels that can be customized for specific therapeutic applications.

Modulation of microglial phenotypes by dexmedetomidine through TREM2 reduces neuroinflammation in heatstroke

No FDA approved pharmacological therapy is available to reduce neuroinflammation following heatstroke. Previous studies have indicated that dexmedetomidine (DEX) could protect against inflammation and brain injury in various inflammation-associated diseases. However, no one has tested whether DEX has neuro-protective effects in heatstroke. In this study, we focused on microglial phenotypic modulation to investigate the mechanisms underlying the anti-inflammatory effects of DEX in vivo and in vitro. We found that DEX treatment reduced the expression of CD68, iNOS, TNF-α, and IL-1β, and increased the expression of CD206, Arg1, IL-10 and TGF-β in microglia, ameliorating heatstroke induced neuroinflammation and brain injury in mice. TREM2, whose neuro-protective function has been validated by genetic studies in Alzheimer's disease and Nasu-Hakola disease, was significantly promoted by DEX in the microglia. TREM2 esiRNA reversed the DEX-induced activation of PI3K/Akt signalling. Overall these findings indicated that DEX may serve, as a potential therapeutic approach to ameliorate heatstroke induced neuroinflammation and brain injury via TREM2 by activating PI3K/Akt signalling.

Protective effects of melatonin on the white matter damage of neonatal rats by regulating NLRP3 inflammasome activity

OBJECTIVE

The aim of the study was to investigate the protective effects and relevant mechanisms of melatonin on the white matter damage (WMD) caused by endotoxin and ischemic hypoxia in neonatal rats.

METHODS

Seventy-two female neonatal rats (postnatal day 3) were randomly divided into the sham, melatonin-treated, and control groups (n = 24 for each group). The periventricular white matter was collected to evaluate the WMD and apoptosis. In addition, the reactive oxygen species (ROS) level was measured. The expression levels of nucleotide-binding domain-like receptor protein 3 (NLRP3), interleukin (IL)-1β, IL-18, pink1, parkin, Toll-like receptor (TLR)-4, and nuclear factor (NF)-κB were detected.

RESULTS

Hematoxylin and eosin and terminal-deoxynucleoitidyl transferase mediated nick end labeling staining showed that the WMD, as well as cell degeneration, necrosis, and apoptosis in the control group, were more severe than those in the melatonin-treated group. Endotoxin and ischemic hypoxia upregulated the expression of NLRP3 and downstream inflammatory factors such as IL-1β and IL-18, which could be reversed by melatonin treatment. Melatonin increased mitochondrial autophagy marker (pink1 and parkin) expression in the white matter and reduced ROS production. Moreover, melatonin-reduced TLR4 and NF-κB expression.

CONCLUSIONS

Melatonin can inhibit the hyperactivity of NLRP3 inflammasomes by enhancing mitochondrial autophagy and inhibiting TLR4/NF-κB pathway activity. Thus, melatonin may be a promising treatment for alleviating the WMD caused by endotoxin and ischemic hypoxia in neonatal rats.

Seasonal adaptations of the hypothalamo-neurohypophyseal system of the dromedary camel

The “ship” of the Arabian and North African deserts, the one-humped dromedary camel (Camelus dromedarius) has a remarkable capacity to survive in conditions of extreme heat without needing to drink water. One of the ways that this is achieved is through the actions of the antidiuretic hormone arginine vasopressin (AVP), which is made in a specialised part of the brain called the hypothalamo-neurohypophyseal system (HNS), but exerts its effects at the level of the kidney to provoke water conservation. Interestingly, our electron microscopy studies have shown that the ultrastructure of the dromedary HNS changes according to season, suggesting that in the arid conditions of summer the HNS is in an activated state, in preparation for the likely prospect of water deprivation. Based on our dromedary genome sequence, we have carried out an RNAseq analysis of the dromedary HNS in summer and winter. Amongst the 171 transcripts found to be significantly differentially regulated (>2 fold change, p value <0.05) there is a significant over-representation of neuropeptide encoding genes, including that encoding AVP, the expression of which appeared to increase in summer. Identification of neuropeptides in the HNS and analysis of neuropeptide profiles in extracts from individual camels using mass spectrometry indicates that overall AVP peptide levels decreased in the HNS during summer compared to winter, perhaps due to increased release during periods of dehydration in the dry season.

Stem Cell Therapy: A Promising Therapeutic Method for Intracerebral Hemorrhage

Spontaneous intracerebral hemorrhage (ICH) is one type of the most devastating cerebrovascular diseases worldwide, which causes high morbidity and mortality. However, efficient treatment is still lacking. Stem cell therapy has shown good neuroprotective and neurorestorative effect in ICH and is a promising treatment. In this study, our aim was to review the therapeutic effects, strategies, related mechanisms and safety issues of various types of stem cell for ICH treatment. Numerous studies had demonstrated the therapeutic effects of diverse stem cell types in ICH. The potential mechanisms include tissue repair and replacement, neurotrophy, promotion of neurogenesis and angiogenesis, anti-apoptosis, immunoregulation and anti-inflammation and so forth. The microenvironment of the central nervous system (CNS) can also influence the effects of stem cell therapy. The detailed therapeutic strategies for ICH treatment such as cell type, the number of cells, time window, and the routes of medication delivery, varied greatly among different studies and had not been determined. Moreover, the safety issues of stem cell therapy for ICH should not be ignored. Stem cell therapy showed good therapeutic effect in ICH, making it a promising treatment. However, safety should be carefully evaluated, and more clinical trials are required before stem cell therapy can be extensively applied to clinical use.

Oxidised protein metabolism: recent insights

The ‘oxygen paradox’ arises from the fact that oxygen, the molecule that aerobic life depends on, threatens its very existence. An oxygen-rich environment provided life on Earth with more efficient bioenergetics and, with it, the challenge of having to deal with a host of oxygen-derived reactive species capable of damaging proteins and other crucial cellular components. In this minireview, we explore recent insights into the metabolism of proteins that have been reversibly or irreversibly damaged by oxygen-derived species. We discuss recent data on the important roles played by the proteasomal and lysosomal systems in the proteolytic degradation of oxidatively damaged proteins and the effects of oxidative damage on the function of the proteolytic pathways themselves. Mitochondria are central to oxygen utilisation in the cell, and their ability to handle oxygen-derived radicals is an important and still emerging area of research. Current knowledge of the proteolytic machinery in the mitochondria, including the ATP-dependent AAA+ proteases and mitochondrial-derived vesicles, is also highlighted in the review. Significant progress is still being made in regard to understanding the mechanisms underlying the detection and degradation of oxidised proteins and how proteolytic pathways interact with each other. Finally, we highlight a few unanswered questions such as the possibility of oxidised amino acids released from oxidised proteins by proteolysis being re-utilised in protein synthesis thus establishing a vicious cycle of oxidation in cells.

Recent Advances in the Study of Bipolar/Rod-Shaped Microglia and their Roles in Neurodegeneration

Microglia are the resident immune cells of the central nervous system (CNS) and they contribute to primary inflammatory responses following CNS injuries. The morphology of microglia is closely associated with their functional activities. Most previous research efforts have attempted to delineate the role of ramified and amoeboid microglia in the pathogenesis of neurodegenerative diseases. In addition to ramified and amoeboid microglia, bipolar/rod-shaped microglia were first described by Franz Nissl in 1899 and their presence in the brain was closely associated with the pathology of infectious diseases and sleeping disorders. However, studies relating to bipolar/rod-shaped microglia are very limited, largely due to the lack of appropriate in vitro and in vivo experimental models. Recent studies have reported the formation of bipolar/rod-shaped microglia trains in in vivo models of CNS injury, including diffuse brain injury, focal transient ischemia, optic nerve transection and laser-induced ocular hypertension (OHT). These bipolar/rod-shaped microglia formed end-to-end alignments in close proximity to the adjacent injured axons, but they showed no interactions with blood vessels or other types of glial cell. Recent studies have also reported on a highly reproducible in vitro culture model system to enrich bipolar/rod-shaped microglia that acts as a powerful tool with which to characterize this form of microglia. The molecular aspects of bipolar/rod-shaped microglia are of great interest in the field of CNS repair. This review article focuses on studies relating to the morphology and transformation of microglia into the bipolar/rod-shaped form, along with the differential gene expression and spatial distribution of bipolar/rod-shaped microglia in normal and pathological CNSs. The spatial arrangement of bipolar/rod-shaped microglia is crucial in the reorganization and remodeling of neuronal and synaptic circuitry following CNS injuries. Finally, we discuss the potential neuroprotective roles of bipolar/rod-shaped microglia, and the possibility of transforming ramified/amoeboid microglia into bipolar/rod-shaped microglia. This will be of considerable clinical benefit in the development of novel therapeutic strategies for treating various neurodegenerative diseases and promoting CNS repair after injury.

The association between laminin and microglial morphology in vitro

Microglia are immune cells in the central nervous system (CNS) that contribute to primary innate immune responses. The morphology of microglia is closely associated with their functional activities. The majority of microglial studies have focused on the ramified or amoeboid morphology; however, bipolar/rod-shaped microglia have recently received much attention. Bipolar/rod-shaped microglia form trains with end-to-end alignment in injured brains and retinae, which is proposed as an important mechanism in CNS repair. We previously established a cell culture model system to enrich bipolar/rod-shaped microglia simply by growing primary microglia on scratched poly-D-lysine (PDL)/laminin-coated surfaces. Here, we investigated the role of laminin in morphological changes of microglia. Bipolar/rod-shaped microglia trains were transiently formed on scratched surfaces without PDL/laminin coating, but the microglia alignment disappeared after 3 days in culture. Amoeboid microglia digested the surrounding laminin, and the gene and protein expression of laminin-cleaving genes Adam9 and Ctss was up-regulated. Interestingly, lipopolysaccharide (LPS)-induced transformation from bipolar/rod-shaped into amoeboid microglia increased the expression of Adam9 and Ctss, and the expression of these genes in LPS-treated amoeboid-enriched cultures remained unchanged. These results indicate a strong association between laminin and morphological transformation of microglia, shedding new light on the role of bipolar/rod-shaped microglia in CNS repair.

Development of non-viral vehicles for targeted gene transfer into microglia via the integrin receptor CD11b

Microglial activation is a central event in neurodegeneration. Novel technologies are sought for that specifically manipulate microglial function in order to delineate their role in onset and progression of neuropathologies. We investigated for the first time whether non-viral gene delivery based on polyethyleneglycol-polyethyleneimine conjugated to the monoclonal anti-CD11b antibody OX42 ("OX42-immunogene") could be used to specifically target microglia. We first conducted immunofluorescence studies with the OX42 antibody and identified its microglial integrin receptor CD11b as a potential target for receptor-mediated gene transfer based on its cellular specificity in mixed glia culture and in vivo and found that the OX42 antibody is rapidly internalized and trafficked to acidic organelles in absence of activation of the respiratory burst. We then performed transfection experiments with the OX42-immunogene in vitro and in rat brain showing that the OX42-immunogene although internalized was degraded intracellularly and did not cause substantial gene expression in microglia. Investigation of specific barriers to microglial gene transfer revealed that aggregated OX42-immunogene polyplexes stimulated the respiratory burst that likely involved Fcγ-receptors. Transfections in the presence of the endosomolytic agent chloroquine improved transfection efficiency indicating that endosomal escape may be limited. This study identifies CD11b as an entry point for antibody-mediated gene transfer into microglia and takes important steps toward the further development of OX42-immunogenes.

Chronically active: activation of microglial proteolysis in ageing and neurodegeneration

One of the microglial cell functions is the removal of modified extracellular proteins in the brain. The connection between protein oxidation, proteolysis, and microglial activation is the topic of this review. The effect of various activation agents on microglial cells with regard to changes in substrate uptake, proteolytic capacity and degradation efficiency of different types of oxidized protein materials is reviewed. It is shown that different activation stimuli initiate substrate-specific modulation for uptake and proteolysis, influencing an array of factors including receptor expression, lysosomal pH, and proteasome subunit composition. Age-related alterations in activation and proteolytic capacity in microglial cells are also discussed. In ageing, proteolytic effectiveness is diminished, while microglial cells are chronically activated and lose the oxidative burst ability, possibly supporting a 'vicious circle' of macrophage-induced neurodegeneration.

Lipofuscin inhibits the proteasome by binding to surface motifs

Lipofuscin, a highly oxidized aggregate, consists of covalently cross-linked proteins, lipids, and sugar residues and is one of the major life-span-limiting factors in postmitotic aging cells. An artificial model of this material, showing characteristics and effects comparable to those of the natural form, has turned out to be very useful for in vitro studies. Artificial lipofuscin was used to investigate its effects on the viability of human fibroblasts, its rate of uptake, and its ability to inhibit the proteasomal system. The inhibition of the proteasomal system is one of the major aspects of the cytotoxic effects of lipofuscin. We present here that this proteasomal inhibition is due to proteasomal binding to the lipofuscin surface motifs, degradable by protease K. Furthermore, removal of the surface peptide structures by protease K strongly reduces the cytotoxic effects of lipofuscin and binding of cellular proteins and proteasomes to intracellular protein aggregates.

Cathepsin D is one of the major enzymes involved in intracellular degradation of AGE-modified proteins

Oxidized and cross-linked modified proteins are known to accumulate in ageing. Little is known about whether the accumulation of proteins modified by advanced glycation end products (AGEs) is due to an affected intracellular degradation. Therefore, this study was designed to determine whether the intracellular enzymes cathepsin B, cathepsin D and the 20S proteasome are able to degrade AGE-modified proteins in vitro. It shows that AGE-modified albumin is degraded by cathepsin D, while cathepsin B was less effective in the degradation of aldehyde-modified albumin and the 20S proteasome was completely unable to degrade them. Mouse primary embryonic fibroblasts isolated from a cathepsin D knockout animals were found to have an extensive intracellular AGE-accumulation, mainly in lysosomes, and a reduction of AGE-modified protein degradation compared to cells isolated from wild type animals. In summary, it can be assumed that cathepsin D plays a significant role in the removal of AGE-modified proteins.

Cerebrospinal fluid brain specific proteins in relation to nitric oxide metabolites during relapse of multiple sclerosis

This study investigated the cerebrospinal fluid (CSF) levels of ferritin, S100B as biomarkers for glial activation and NfH(SM135)--a biomarker of axonal damage--in relation to nitric oxide (NO) metabolites: nitrate and nitrite (NOx) during acute multiple sclerosis (MS) relapse. Thirty-four relapsing-remitting MS (RR-MS) patients during acute relapse and 12 controls were enrolled. Patients were assessed on Expanded Disability Status Scale (EDSS) and underwent lumbar puncture within two weeks following relapse. Twenty patients were available for further follow-up and were assessed on EDSS 6-8 weeks since the relapse onset. The CSF NOx (P<0.0001), NfH(SM135) (P=0.01) and S100B (P=0.009) but not ferritin (P>0.05) were significantly raised in MS group. There was a significant correlation between CSF ferritin and S100B in RR-MS group (P=0.004). CSF NOx did not correlate with S100B and ferritin in study groups. RR-MS patients with detectable NfH(SM135) levels had higher NOx compared with subjects having undetectable NfH(SM135) (P=0.03). In the follow-up study, raised baseline levels of NOx (P=0.016) or NfH(SM135) (P=0.04) inversely correlated with the clinical recovery grade expressed as relative EDSS change between baseline and follow-up. In conclusion, NO metabolites were increased and because of their correlation with a biomarker of axonal degeneration (neurofilaments) and a measure for clinical disability (EDSS), relapse-related nitrosative stress is likely to be relevant to the development of sustained disability in an individual patient.

Cellular therapy using microglial cells

Recent insights into the function and dysfunction of microglia may inform future therapies to combat neurodegeneration. We hypothesise how different aspects of microglial activity including migration, activation, oxidative response, phagocytosis, proteolysis, and replenishment could be targeted by novel therapeutic approaches. A combined approach is suggested, encompassing opsonization and anti-inflammatory strategies in conjunction with an engineering of microglial precursors. Xenoproteases for bioremediation could be used to enhance intracellular and extracellular proteolytic capacity. The capacity of microglial precursors to cross the blood-brain barrier and to home in on sites of neural damage and inflammation might prove to be particularly useful for future therapeutic strategies.

Microglial senescence: does the brain's immune system have an expiration date?

Microglia are seen as the sentries in the CNS who provide a first line of defense whenever there is injury or disease. Microglia and related perivascular macrophages perform various functions, ranging from immunological surveillance to neuroprotection. Recent work in the aged human brain has provided morphological evidence of structural deterioration of microglia, and work in rodents suggests that microglia are subject to replicative senescence (loss of mitotic ability after repeated rounds of replication). Together these observations raise the possibility that old age, and perhaps other factors (genetic and epigenetic) adversely affect viability and self-renewal capacity of microglia, resulting in the generation of senescent and/or dysfunctional cells. Such attrition of the brain's immune system could contribute to the development of neurodegenerative disease by diminishing glial neuroprotection.

Tocopherol-mediated modulation of age-related changes in microglial cells: turnover of extracellular oxidized protein material

Proteins accumulate during aging and form insoluble protein aggregates. Microglia are responsible for their removal from the brain. During aging, changes within the microglia might play a crucial role in the malfunctioning of these cells. Therefore, we isolated primary microglial cells from adult rats and compared their activation status and their ability to degrade proteins to that of microglial cells isolated from newborn animals. The ability of adult microglial cells to degrade proteins is substantially decreased. However, the preincubation of microglial cells with vitamin E improves significantly the degradation of such modified proteins. The degradation of proteins from apoptotic vesicles is decreased in microglia isolated from adult rats. This might be the result of a suppression of the CD36 receptor due to vitamin E treatment. We concluded that microglial cells isolated from adult organisms have different metabolic properties and seem to be a more valuable model to study age-related diseases.

Degradation of glycated bovine serum albumin in microglial cells

Glycated protein products are formed upon binding of sugars to lysine and arginine residues and have been shown to accumulate during aging and in pathologies such as Alzheimer disease and diabetes. Often these glycated proteins are transformed into advanced glycation end products (AGEs) by a series of intramolecular rearrangements. In the study presented here we tested the ability of microglial cells to degrade BSA-AGE formed by glycation reactions of bovine serum albumin (BSA) with glucose and fructose. Microglial cells are able to degrade BSA-AGEs to a certain degree by proteasomal and lysosomal pathways. However, the proteasome and lysosomal proteases are severely inhibited by cross-linked BSA-AGEs. BSA-AGEs are furthermore able to activate microglial cells. This activation is accompanied by an enhanced degradation of BSA-AGE. Therefore, we conclude that microglial cells are able to degrade glycated proteins, although cross-linked protein-AGEs have an inhibitory effect on proteolytic systems in microglial cells.

Proteasomal defense of oxidative protein modifications

The proteasome has an important role in the degradation of normal, damaged, mutant, or misfolded proteins. This includes the degradation of normal and regulatory proteins in the cellular metabolism and additionally the removal of damaged proteins as a stress response. The two well-described proteasome regulators, the 11S and the 19S regulators, forming together with the 20S 'core' proteasome various forms of the proteasome, including the ATP-stimulated 26S proteasome. As a result of aerobic metabolism, reactive oxygen species (ROS) are constantly generated during the lifetime of biological organisms. Consequently a permanent generation of oxidative damage takes place. This includes the formation of oxidatively modified proteins. These oxidized protein derivatives tend to aggregate, and accumulation of these aggregates may lead to cell death. To prevent this, such oxidatively modified proteins are selectively recognized and either repaired or degraded by the proteasome. The current knowledge of the repair systems and the degradation mechanism is reviewed here. The possible interactions between the ubiquitin-proteasome-system, the chaperone system, the protein repair mechanisms, and other antioxidative defense strategies are highlighted.

Neuronal apoptotic bodies: phagocytosis and degradation by primary microglial cells

Neuronal loss via apoptosis is a key element in numerous neurodegenerative diseases. To avoid accumulation of apoptotic material, the remains of apoptotic cells should be degraded. It was suggested that microglial cells are phagocytosing and degrading apoptotic material. There is only limited information available concerning the fate of the remains of apoptotic neurons. In this study, we investigated the ability of microglial cells to take up and degrade neuronal apoptotic material. We isolated primary microglial cells and used apoptotic bodies of apoptotic neuron-like PC12 cells as a substrate. The apoptotic material was taken up and degraded within the microglial cells. The uptake is clearly activation dependent. We were able to demonstrate that the CD36 scavenger receptor is involved in the uptake of the apoptotic material via competition studies, antibody blockage, and use of a CD36 mutant rat strain. Blockage of other uptake mechanisms was also able to inhibit the uptake to some extent. Furthermore, we were able to demonstrate the role of the microglial lysosomal and proteasomal pathways in the degradation of proteins originating from apoptotic bodies.

Oxidative Stress: a common denominator in the pathogenesis of amyotrophic lateral sclerosis

PURPOSE OF REVIEW

Amyotrophic lateral sclerosis, or Lou Gehrig disease, is a progressive neurodegenerative disease of adult onset characterized by a loss of motor neurons in the spinal cord and motor cortex. In the last several years, substantial progress has been made in defining the pathogenesis of motor neuron injury and relationships between disease mechanisms and the selective vulnerability of the motor neuron in both familial and sporadic forms of amyotrophic lateral sclerosis.

RECENT FINDINGS

Current theories have shifted from a neuron-centered pathology to a focus on the interaction between motor neurons and glia, and their respective contributions to pathways implicated in amyotrophic lateral sclerosis. Although multiple mechanisms clearly can contribute to the pathogenesis of motor neuron injury, recent advances suggest that oxidative stress may play a significant role in the amplification, and possibly the initiation, of disease.

SUMMARY

This article reviews the clinical aspects of amyotrophic lateral sclerosis and potential mechanisms of disease pathogenesis in the context of recent data supporting a major role for oxidative stress throughout the disease course. Evidence suggesting an important role for intercellular signaling is emphasized.

Temporal relationships between HIV-1 Tat-induced neuronal degeneration, OX-42 immunoreactivity, reactive astrocytosis, and protein oxidation in the rat striatum

HIV-1 transactivating protein Tat is neurotoxic and is believed to play a role in the development of AIDS-associated dementia complex. Neurotoxicity of Tat may be associated with oxidative stress. In this study we examined temporal progression of histopathological changes induced by a single microinjection of Tat 1-72 into the rat striatum. Degenerating neural cells, detected by Fluoro-Jade B staining and increased protein oxidation, determined by protein carbonyl immunostaining, were observed in the striatum as soon as 2 h following the microinjection. Further progression of neuronal degeneration was associated with pronounced infiltration of the area surrounding Tat 1-72 injection site by OX-42 positive macrophages/microglia, which was evident at the 24 h time point. Signs of reactive astrocytosis were found in the striatum of Tat 1-72 injected animals as late as 7 days following the single microinjection. Increased GFAP immunoreactivity and changes in the morphology of astrocytes coincided with a second phase of increased protein carbonyl formation, but not with neuronal degeneration. Control polypeptide, nontoxic Tat delta 31-61, did not cause any cell death, inflammatory reaction or oxidative damage. Results of our study support the hypothesis that oxidative stress may be an early step in the mechanism of Tat neurotoxicity.

Increased morphological diversity of microglia in the activated hypothalamic supraoptic nucleus

Microglia are the immune cells of the CNS. In the normal adult mammalian brain, the majority of these cells is quiescent and exhibits a ramified morphology. Microglia are perhaps best known for their swift transformation to an activated ameboid morphology in response to pathological insults. Here we have observed the responsiveness of these cells to events surrounding the normal activation of neurosecretory neurons in the hypothalamic supraoptic nucleus (SON), a well studied model of structural plasticity in the CNS. Neurons in the SON were activated by substituting 2% saline for drinking water. Brain sections were collected from four experimental groups [controls (C), 2 d-dehydrated (2D), 7 d-dehydrated (D7), and 7 d-dehydrated/21 d-rehydrated animals (R21)] and stained with Isolectin-B4-HRP to visualize microglial cells. Based on morphological criteria, we quantified ramified, hypertrophied, and ameboid microglia using unbiased stereological techniques. Statistical analyses showed significant increases in the number of hypertrophied microglia in the D2 and D7 groups. Moreover, there was a significant increase in the number of ameboid microglia in the D7 group. No changes were seen across conditions in the number of ramified cells, nor did we observe any significant phenotypic changes in a control area of the cingulate gyrus. Hence, increased morphological diversity of microglia was found specifically in the SON and was reversible with the cessation of stimulation. These results indicate that phenotypic plasticity of microglia may be a feature of the normal structural remodeling that accompanies neuronal activation in addition to the activation that accompanies brain pathology.

Selective degradation of oxidatively modified protein substrates by the proteasome

Oxidative stress in mammalian cells is an inevitable consequence of their aerobic metabolism. Oxidants produce modifications to proteins leading to loss of function (or gain of undesirable function) and very often to an enhanced degradation of the oxidized proteins. For several years it has been known that the proteasome is involved in the degradation of oxidized proteins. This review summarizes our knowledge about the recognition of oxidized protein substrates by the proteasome in in vitro systems and its applicability to living cells. The majority of studies in the field agree that the degradation of mildly oxidized proteins is an important function of the proteasomal system. The major recognition motif of the substrates seems to be hydrophobic surface patches that are recognized by the 20S 'core' proteasome. Such hydrophobic surface patches are formed by partial unfolding and exposure of hydrophobic amino acid residues during oxidation. Oxidized proteins appear to be relatively poor substrates for ubiquitination, and the ubiquitination system does not seem to be involved in the recognition or targeting of oxidized proteins. Heavily oxidized proteins appear to first aggregate (new hydrophobic and ionic bonds) and then to form covalent cross-links that make them highly resistant to proteolysis. The inability to degrade extensively oxidized proteins may contribute to the accumulation of protein aggregates during diseases and the aging process.

Impairment of protein homeostasis and decline of proteasome activity in microglial cells from adult Wistar rats

Common symptoms of different neurodegenerative diseases start to develop in the second half of the human life. Several of these diseases, including Alzheimer's and Parkinson's disease, are accompanied by severe disturbances of protein metabolism and homeostasis in the brain. Because microglial cells are, to some extent, responsible for the maintenance of this homeostasis, age-related functional changes of the microglia are important. We established, therefore, the preparation of cultures of primary microglial cells isolated from adult animals in comparison to the widely used standard model, primary microglial cells isolated from newborn animals. In addition, we investigated changes in the activation and in the protein homeostasis within these cells. The protein turnover seems to be significantly impaired in microglial cells isolated from adult animals and this seems to be accompanied by a decline in proteasomal function, but not in the protease content. We were also able to demonstrate higher cell surface molecule expression and a higher basal NO release of microglia isolated from adult animals in comparison to the microglia isolated from newborn rats; however, the PMA stimulated oxidative burst was abolished completely in cells from adult animals. Microglia from adult animals were also not able to upregulate their protein metabolism after activation. From these investigations it was concluded that microglial cells from adult animals have significantly different metabolic properties in comparison to the widely used microglial cells from newborn animals.