Oligodendrocyte lineage regulation during development, adult life, inflammatory lesions and hypoxia/ischemia insults. Focus on Nuclear Receptors.

Oligodendrocyte precursor cells (OPCs) are the main actors involved in developmental myelination and adult myelination dynamic, including remyelination. The recapitualtion hypothesis states that adult remyelination is a complete recapitulation of developmental myelination. However, their different nature could reflect different myelination mechanism and response to demyelinating insults. The main objective of the present study is the investigation of foetal and adult OPCs vulnerability to demyelinating diseases environment. Cell-based high content screening approach was set up as the elective technique in order to obtain robust and reproducible data. First we analysed the physiological differentiation process, driven by thyroid hormone and exerted by nuclear receptors. We described different expression of NRs in early precursors, different response to T3-mediated differentiation, the selective importance of PARP activity for foetal OPCs and the fundamental role of RXRγ in both systems. Differences in physiological differentiation can reflect different responses to noxious stimuli. Thus, we exposed OPCs to inflammatory cytokines mix or to oxygen-glucose deprivation (OGD), in order to mimic demyelinating disease environment. OGD was first characterized in primary neuronal cultures and tested for its reliability in disease model studies and pharmacological analysis. Foetal and adult OPCs show both a cytokines-mediated differentiation block, linked to an increase of deiodinase 3 (D3), the enzyme inactivating T3. However, only foetal OPCs/OLs are sensitive to OGD. Since we found an increase in D3 expression after OGD, further studies will elucidate the mechanism underlying the foetal-selective OPCs cell death, analysing the role of D3 in the process and glutamate-mediated excitotxicity, the major triggerer of HI-induced cell death. The better understanding of OPCs biology and mechanisms underlying physiological and pathological conditions, bound to information about differences in foetal and adult OPCs, will open the way to new therapies based on differential strategies for demyelinating diseases affecting foetal or adult life

Neuroprotection and neuroregeneration: roles for the white matter

Efficient strategies for neuroprotection and repair are still an unmet medical need for neurodegenerative diseases and lesions of the central nervous system. Over the last few decades, a great deal of attention has been focused on white matter as a potential therapeutic target, mainly due to the discovery of the oligodendrocyte precursor cells in the adult central nervous system, a cell type able to fully repair myelin damage, and to the development of advanced imaging techniques to visualize and measure white matter lesions. The combination of these two events has greatly increased the body of research into white matter alterations in central nervous system lesions and neurodegenerative diseases and has identified the oligodendrocyte precursor cell as a putative target for white matter lesion repair, thus indirectly contributing to neuroprotection. This review aims to discuss the potential of white matter as a therapeutic target for neuroprotection in lesions and diseases of the central nervous system. Pivot conditions are discussed, specifically multiple sclerosis as a white matter disease; spinal cord injury, the acute lesion of a central nervous system component where white matter prevails over the gray matter, and Alzheimer's disease, where the white matter was considered an ancillary component until recently. We first describe oligodendrocyte precursor cell biology and developmental myelination, and its regulation by thyroid hormones, then briefly describe white matter imaging techniques, which are providing information on white matter involvement in central nervous system lesions and degenerative diseases. Finally, we discuss pathological mechanisms which interfere with myelin repair in adulthood

In vitro exposure to very low-level laser modifies expression level of extracellular matrix protein RNAs and mitochondria dynamics in mouse embryonic fibroblasts

BACKGROUND: Low-level lasers working at 633 or 670 nm and emitting extremely low power densities (Ultra Low Level Lasers - ULLL) exert an overall effect of photobiostimulation on cellular metabolism and energy balance. In previous studies, it was demonstrated that ULLL pulsed emission mode regulates neurite elongation in vitro and exerts protective action against oxidative stress. METHODS: In this study the action of ULLL supplied in both pulsed and continuous mode vs continuous LLL on fibroblast cultures (Mouse Embryonic Fibroblast-MEF) was tested, focusing on mitochondria network and the expression level of mRNA encoding for proteins involved in the cell-matrix adhesion. RESULTS: It was shown that ULLL at 670 nm, at extremely low average power output (0.21 mW/ cm(2)) and dose (4.3 mJ/ cm(2)), when dispensed in pulsed mode (PW), but not in continuous mode (CW) supplied at both at very low (0.21 mW/cm(2)) and low levels (500 mW/cm(2)), modifies mitochondria network dynamics, as well as expression level of mRNA encoding for selective matrix proteins in MEF, e.g. collagen type 1α1 and integrin α5. CONCLUSIONS: We suggest that pulsatility, but not energy density, is crucial in regulating expression level of collagen I and integrin α5 in fibroblasts by ULLL

Time-Course Changes of Extracellular Matrix Encoding Genes Expression Level in the Spinal Cord Following Contusion Injury: A Data-Driven Approach

The involvement of the extracellular matrix (ECM) in lesion evolution and functional outcome is well recognized in spinal cord injury. Most attention has been dedicated to the "core" area of the lesion and scar formation, while only scattered reports consider ECM modification based on the temporal evolution and the segments adjacent to the lesion. In this study, we investigated the expression profile of 100 genes encoding for ECM proteins at 1, 8 and 45 days post-injury, in the spinal cord segments rostral and caudal to the lesion and in the scar segment, in a rat model. During both the active lesion phases and the lesion stabilization, we observed an asymmetric gene expression induced by the injury, with a higher regulation in the rostral segment of genes involved in ECM remodeling, adhesion and cell migration. Using bioinformatic approaches, the metalloproteases inhibitor Timp1 and the hyaluronan receptor Cd44 emerged as the hub genes at all post-lesion times. Results from the bioinformatic gene expression analysis were then confirmed at protein level by tissue analysis and by cell culture using primary astrocytes. These results indicated that ECM regulation also takes place outside of the lesion area in spinal cord injury

Molecular mechanisms of skin wound healing in non-diabetic and diabetic mice in excision and pressure experimental wounds

Experimental models for chronic skin lesions are excision and pressure ulcer, defined as "open" and "closed" lesions, respectively, only the latter characterized by tissue hypoxia. Moreover, systemic diseases, such as diabetes mellitus, affect wound repair. Thus, models for testing new therapies should be carefully selected according to the expected targets. In this study, we present an extensive and comparative histological, immunohistochemical, and molecular characterization of these two lesions in diabetic (db/db) and non-diabetic (C57BL/6 J) mice. In db/db mice, we found significant reduction in PGP9.5-IR innervation, reduction of capillary network, and reduced expression of NGF receptors. We found an increase in VEGF receptor Kdr expression, and the PI3K-Akt signaling pathway at the core of the altered molecular network. Db/db mice with pressure ulcers showed an impairment in the molecular regulation of hypoxia-related genes (Hif1a, Flt1, and Kdr), while extracellular matrix encoding genes (Itgb3, Timp1, Fn1, Col4a1) were upregulated by hyperglycemia and lesions. Overall, the molecular analysis suggests that db/db mice have a longer inflammatory phase of the wound repair process, delaying the progression toward the proliferation and remodeling phases

Retinoic acid receptor beta protects striatopallidal medium spiny neurons from mitochondrial dysfunction and neurodegeneration

Retinoic acid is a powerful regulator of brain development, however its postnatal functions only start to be elucidated. We show that retinoic acid receptor beta (RAR beta), is involved in neuroprotection of striatopallidal medium spiny neurons (spMSNs), the cell type affected in different neuropsychiatric disorders and particularly prone to degenerate in Huntington disease (HD). Accordingly, the number of spMSNs was reduced in the striatum of adult Rar beta(-/-) mice, which may result from mitochondrial dysfunction and neurodegeneration. Mitochondria morphology was abnormal in mutant mice whereas in cultured striatal Rar beta(-/-) neurons mitochondria displayed exacerbated depolarization, and fragmentation followed by cell death in response to glutamate or thapsigargininduced calcium increase. In vivo, Rar beta(-/-)spMSNs were also more vulnerable to the mitochondrial toxin 3-nitropropionic acid (3NP), known to induce HD symptoms in human and rodents. In contrary, an RAR beta agonist, AC261066, decreased glutamate-induced toxicity in primary striatal neurons in vitro, and diminished mitochondrial dysfunction, spMSN cell death and motor deficits induced in wild type mice by 3NP. We demonstrate that the striatopallidal pathway is compromised in Rar beta(-/-) mice and associated with HD-like motor abnormalities. Importantly, similar motor abnormalities and selective reduction of spMSNs were induced by striatal or spMSNspecific inactivation of RAR beta, further supporting a neuroprotective role of RAR beta in postnatal striatum

Nerve Growth Factor Biodelivery: A Limiting Step in Moving Toward Extensive Clinical Application?

Nerve growth factor (NGF) was the first-discovered member of the neurotrophin family, a class of bioactive molecules which exerts powerful biological effects on the CNS and other peripheral tissues, not only during development, but also during adulthood. While these molecules have long been regarded as potential drugs to combat acute and chronic neurodegenerative processes, as evidenced by the extensive data on their neuroprotective properties, their clinical application has been hindered by their unexpected side effects, as well as by difficulties in defining appropriate dosing and administration strategies. This paper reviews aspects related to the endogenous production of NGF in healthy and pathological conditions, along with conventional and biomaterial-assisted delivery strategies, in an attempt to clarify the impediments to the clinical application of this powerful molecule

A novel mutation in SPART gene causes a severe neurodevelopmental delay due to mitochondrial dysfunction with complex I impairments and altered pyruvate metabolism

Funding: Royal Society grant RG110387 (S.P.)Loss-of-function mutations in the SPART gene cause Troyer syndrome, a recessive form of spastic paraplegia resulting in muscle weakness, short stature, and cognitive defects. SPART encodes for Spartin, a protein linked to endosomal trafficking and mitochondrial membrane potential maintenance. Here, we identified with whole exome sequencing (WES) a novel frameshift mutation in the SPART gene in 2 brothers presenting an uncharacterized developmental delay and short stature. Functional characterization in an SH-SY5Y cell model shows that this mutation is associated with increased neurite outgrowth. These cells also show a marked decrease in mitochondrial complex I (NADH dehydrogenase) activity, coupled to decreased ATP synthesis and defective mitochondrial membrane potential. The cells also presented an increase in reactive oxygen species, extracellular pyruvate, and NADH levels, consistent with impaired complex I activity. In concordance with a severe mitochondrial failure, Spartin loss also led to an altered intracellular Ca2+ homeostasis that was restored after transient expression of wild-type Spartin. Our data provide for the first time a thorough assessment of Spartin loss effects, including impaired complex I activity coupled to increased extracellular pyruvate. In summary, through a WES study we assign a diagnosis of Troyer syndrome to otherwise undiagnosed patients, and by functional characterization we show that the novel mutation in SPART leads to a profound bioenergetic imbalance.PreprintPeer reviewe

Cell death in pure-neuronal and neuron-astrocyte mixed primary culture subjected to oxygen-glucose deprivation: The contribution of poly(ADP-ribose) polymerases and caspases

Primary cortical neurons subjected oxygen-glucose deprivation (OGD) is an . in vitro model that mimics fundamental aspects of neonatal hypoxic-ischemic encephalopathy (HIE) and is widely used to test neuroprotective treatments. However, controversial results characterize the existing literature on the OGD model. To shed some light on the initial cell death triggers in OGD, we first investigated the contribution of glucose- or oxygen-deprivation, alone or in combination, to cell viability/death in two cell systems, i.e. pure neuronal: 98% neurons; 2% astrocytes- vs. mixed neuron/astrocytes: 50% neurons; 50% astrocytes- culture. Cell viability was evaluated biochemically (MTT, and LDH release) and morphologically by high-content screening. We first found that neuronal death triggered by OGD (3. h OGD. +. 24. h re-oxygenation) was mainly driven by glucose rather than oxygen deprivation. Astrocytes survival was not substantially affected. Caspase-3 activation was found both in neuronal and mixed neuron/astrocytes cultures, whereas PARP activation was evident only in pure neuronal cultures. To pharmacologically dissect the contribution of these pathways, we measured the effect of TIQ-A (PARP 1 inhibitor) and ZVAD-fmk (pan-caspase inhibitor), individually or in combination, on culture viability after 3. h OGD. We found that only the combination treatment exerts a significant neuroprotective effect particularly evident in pure neuronal cultures. In sum, glucose deprivation is the major cell death trigger in OGD and neurons are more sensitive to OGD than astrocytes. Both PARP and caspases are concurrently activated in pure neuronal cultures and both contribute to neuronal cell death suggesting that neuroprotective strategies may require the simultaneous inhibition of multiple death pathways to be effective

Synthetic Thyroid Hormone Receptor-β Agonists Promote Oligodendrocyte Precursor Cell Differentiation in the Presence of Inflammatory Challenges

Oligodendrocytes and their precursors are the cells responsible for developmental myelination and myelin repair during adulthood. Their differentiation and maturation processes are regulated by a complex molecular machinery driven mainly by triiodothyronine (T3), the genomic active form of thyroid hormone, which binds to thyroid hormone receptors (TRs), regulating the expression of target genes. Different molecular tools have been developed to mimic T3 action in an attempt to overcome the myelin repair deficit that underlies various central nervous system pathologies. In this study, we used a well-established in vitro model of neural stem cell-derived oligodendrocyte precursor cells (OPCs) to test the effects of two compounds: the TRβ1 ligand IS25 and its pro-drug TG68. We showed that treatment with TG68 induces OPC differentiation/maturation as well as both the natural ligand and the best-known TRβ1 synthetic ligand, GC-1. We then described that, unlike T3, TG68 can fully overcome the cytokine-mediated oligodendrocyte differentiation block. In conclusion, we showed the ability of a new synthetic compound to stimulate OPC differentiation and overcome inflammation-mediated pathological conditions. Further studies will clarify whether the compound acts as a pro-drug to produce the TRβ1 ligand IS25 or if its action is mediated by secondary mechanisms such as AMPK activation