<i>In Vivo</i> Morphological Changes in Animal Models of Amyotrophic Lateral Sclerosis and Alzheimer's‐Like Disease: MRI Approach

Anđjus, Pavle R.; Bataveljić, Danijela; Vanhoutte, Greetje; Mitrečić, Dinko; Pizzolante, Fabrizio; Djogo, Nevena; Nicaise, Charles; Kengne, Fabrice Gankam; Gangitano, Carlo; Michetti, Fabrizio; Linden, Annemie Van der; Pochet, Roland; Bačić, Goran

doi:10.1002/ar.20995

Cited by 61 publications

(37 citation statements)

References 67 publications

(88 reference statements)

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“…Thus, the human mSOD1 murine model is the most widely used in the evaluation of the involved molecular targets, biomarkers and novel drugs/treatments for ALS. Apart from developing loss of MNs and symptoms that resemble human ALS by mSOD1, the model evidences molecular links between genetic and non-genetic cases of ALS (Andjus et al, 2009; Synofzik et al, 2010). To note, that non-genetic perturbations of the wild-type (wt) SOD1 protein may lead to SOD1 misfolding with a conformation much similar to genetic SOD1 variants (Cereda et al, 2006).…”

Section: Introductionmentioning

confidence: 87%

“…The interaction between all these components provides a sustainable environment for neural function while restricting permeability and transport. Alterations in barrier properties and dynamics were observed in transgenic SOD1 rats (Andjus et al, 2009; Nicaise et al, 2009). In particular, it was noticed a reduction of endothelial tight junctions (Zhong et al, 2008), together with the disruption of the neurovascular unit and up-regulation of MMP-9 (Miyazaki et al, 2011) prior to MN degeneration.…”

Section: Neurodegenerative Networking In Alsmentioning

confidence: 99%

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Microglia centered pathogenesis in ALS: insights in cell interconnectivity

Brites

Vaz

2014

Front. Cell. Neurosci.

170

126

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Amyotrophic lateral sclerosis (ALS) is the most common and most aggressive form of adult motor neuron (MN) degeneration. The cause of the disease is still unknown, but some protein mutations have been linked to the pathological process. Loss of upper and lower MNs results in progressive muscle paralysis and ultimately death due to respiratory failure. Although initially thought to derive from the selective loss of MNs, the pathogenic concept of non-cell-autonomous disease has come to the forefront for the contribution of glial cells in ALS, in particular microglia. Recent studies suggest that microglia may have a protective effect on MN in an early stage. Conversely, activated microglia contribute and enhance MN death by secreting neurotoxic factors, and impaired microglial function at the end-stage may instead accelerate disease progression. However, the nature of microglial–neuronal interactions that lead to MN degeneration remains elusive. We review the contribution of the neurodegenerative network in ALS pathology, with a special focus on each glial cell type from data obtained in the transgenic SOD1G93A rodents, the most widely used model. We further discuss the diverse roles of neuroinflammation and microglia phenotypes in the modulation of ALS pathology. We provide information on the processes associated with dysfunctional cell–cell communication and summarize findings on pathological cross-talk between neurons and astroglia, and neurons and microglia, as well as on the spread of pathogenic factors. We also highlight the relevance of neurovascular disruption and exosome trafficking to ALS pathology. The harmful and beneficial influences of NG2 cells, oligodendrocytes and Schwann cells will be discussed as well. Insights into the complex intercellular perturbations underlying ALS, including target identification, will enhance our efforts to develop effective therapeutic approaches for preventing or reversing symptomatic progression of this devastating disease.

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Section: Introductionmentioning

confidence: 87%

Section: Neurodegenerative Networking In Alsmentioning

confidence: 99%

Microglia centered pathogenesis in ALS: insights in cell interconnectivity

Brites

Vaz

2014

Front. Cell. Neurosci.

170

126

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“…Pathophysiology of ALS is poorly understood and likely multifactorial. Proposed starting points for this complex disease targeting the motor neuron population include mitochondrial dysfunction, intracellular protein aggregation, disturbances of RNA metabolism, extracellular toxic environment, impairment at the level of axonal transport and at the neuromuscular synapse (reviewed by [81] ), together with extrinsic events: blood-brain barrier breakdown, glial cell reaction/dysfunction and neuroinflammation [82][83][84][85][86][87][88] . It is known that dying motor neurons influence surrounding cells, of which astrocytes are most commonly investigated.…”

Section: What Is Amyotrophic Lateral Sclerosis?mentioning

confidence: 99%

Transplantation of stem cell-derived astrocytes for the treatment of amyotrophic lateral sclerosis and spinal cord injury

Nicaise

Mitrečić

Falnikar

et al. 2015

WJSC

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in experimental ALS and SCI models and we discuss avenues for future directions based on latest molecular findings regarding astrocyte biology. Core tip: Amyotrophic lateral sclerosis (ALS) and spinal cord injury (SCI) result in incurable neurological dysfunction due to loss of spinal motor neurons and axonal degeneration, amongst other mechanisms. Astrocytes are increasingly recognized as being necessary for neuroprotection and regeneration in the central nervous system as they promote axonal growth and deliver essential neurotrophic factors under both physiological and pathophysiological conditions. Given the central role played by astrocytes, we gathered convincing results from ALS and SCI literature that argue in favor of stem cell-based astrocyte replacement therapies and stress the scientific community to investigate more deeply the molecular understanding of astrocyte biology. MULTIPLE FACETS OF ASTROCYTES IN THE CENTRAL NERVOUS SYSTEM Astrocyte functionsAstrocytes are the most abundant cells in the central nervous system (CNS), outnumbering neuronal cells by several fold in some CNS regions. They have long been relegated to a secondary position, behind neurons or oligodendrocytes, as many thought that astrocytes were barely by-standers of the CNS. Accounting for a large fraction of the brain volume, their particular shape and tissue distribution are known to elaborate an extensive network of fine interconnected processes. Their star-shaped morphology projecting long branched processes provides a large coverage of CNS structures and the ensheathment of the brain or spinal cord in the pia matter. They draw the whole brain microanatomy by secreting astrocyte-derived extracellular matrix proteins (e.g., chondroitin sulfate proteoglycans, hyaluronan, tenascin proteins family, thrombospondin), thereby providing structural support for nervous system cells. Beside their structural role, astrocytes are recognized to fulfill and support many, if not all, functions of the healthy CNS [1] . Astrocyte endfeet cover more than 90% of the CNS vasculature and come in contact with endothelial cells. Expressing key glucose transporter-1, astrocytes convoy glucose from blood vessels to nervous system cells, most of them being devoid of direct access to this high-end source of energy. Hence, astrocytes synthetize via specific metabolic pathways glycogen and lactate, main energy fuels for neurons or distant synapses. Through humoral factors released at the perivascular space, astrocytes control local cerebral blood flow and bloodbrain barrier (BBB) integrity. Transforming growth factor-beta, glial-derived neurotrophic factor (GDNF), fibroblast growth factor 2 (FGF2) and angiopoietin 1 (binding the endothelium-specific receptor TIE2), all secreted at the vascular end-feet, act on endothelial cells in order to induce or maintain an operational BBB [2,3] . Astrocytes-released growth factors [e.g., brainderived neurotrophic factor, BDNF; ciliary neurotrophic factor (CNTF)] exert beneficial effects far beyond the perivascular spa...

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“…[84][85][86] Similarly, brain atrophy has been used as an indicator of neuroaxonal injury in PD, AD and ALS. [76,87,88] However, the degree of change in these measures over a 1-year observation period tends to be small. For example, in untreated MS subjects the percentage decrease in brain volume that occurs in 1 year is between 0.5% and 1.0%, with some patients showing no change while others show more dramatic changes.…”

Section: Assessing Neurodegeneration/ Neuroprotection/disease Stabilimentioning

confidence: 96%

Targeting Progressive Neuroaxonal Injury

et al. 2011

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Neurodegenerative diseases, such as Alzheimer's disease (AD), Parkinson's disease (PD) and amyotrophic lateral sclerosis (ALS), are characterized by progressive neuroaxonal injury, suggesting a common pathophysiological pathway. Identification and development of neuroprotective therapies for such diseases has proven a major challenge, particularly because of an already substantial neuroaxonal compromise at the time of initial onset of clinical symptoms. Methods for early identification of neurodegeneration are therefore vital to ensure that neuroprotective therapies are applied as early as possible. Recent investigations have enhanced our understanding of the role of neuroaxonal injury in multiple sclerosis (MS). As MS generally manifests earlier in life and can be diagnosed much earlier in the course of the disease than the above-mentioned 'classic' neurodegenerative diseases, it is possible that MS could be used as a model disease to study degeneration and regeneration of the CNS. The mechanism of neuroaxonal injury in MS is believed to be inflammation-led neurodegeneration; however, the reverse may also be true (i.e. neuroaxonal degeneration may precede inflammation). Animal models of PD, AD and ALS have shown that it is likely that most cases of disease are due to initial inflammation, followed by a degenerative process, providing a parallel between MS and the classic neurodegenerative diseases. Other common factors between MS and the neurodegenerative diseases include iron and mitochondrial dysregulation, abnormalities in α-synuclein and tau protein, and a number of immune mediators. Conventional MRI techniques, using markers such as T2-weighted lesions, gadolinium-enhancing lesions and T1-weighted hypointensities, are readily available and routinely used in clinical practice; however, the utility of these MRI measures to predict disease progression in MS is limited. More recently, MRI techniques that provide more pathology-specific data have been applied in MS studies, including magnetic resonance spectroscopy, magnetization transfer ratio and myelin water imaging. Optical coherence tomography (OCT) is a non-MRI technique that quantifies optic nerve integrity and retinal ganglion cell loss as markers of neuroaxonal injury; more research is needed to evaluate whether information obtained from OCT is a reliable marker of axonal injury and long-term disability in MS. Using these advanced techniques, it may become possible to follow degeneration and regeneration longitudinally in patients with MS and to better differentiate the effects of drugs under investigation. Currently available immune-directed therapies that are approved by the US FDA for the first-line treatment of MS (interferon-β and glatiramer acetate) have been shown to decelerate the inflammatory process in MS; however, such therapy is less effective in preventing the progression of the disease and neuroaxonal injury. The use of MS as a clinical model to study modulation of neuroaxonal injury in the brain could have direct implications for the deve...

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In Vivo Morphological Changes in Animal Models of Amyotrophic Lateral Sclerosis and Alzheimer's‐Like Disease: MRI Approach

Cited by 61 publications

References 67 publications

Microglia centered pathogenesis in ALS: insights in cell interconnectivity

Microglia centered pathogenesis in ALS: insights in cell interconnectivity

Transplantation of stem cell-derived astrocytes for the treatment of amyotrophic lateral sclerosis and spinal cord injury

Targeting Progressive Neuroaxonal Injury

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