Neuropathological changes in scrapie and Alzheimer's disease are associated with increased expression of apolipoprotein E and cathepsin D in astrocytes

Diedrich, J.F.; Minnigan, Hal; Carp, Richard I.; Whitaker, J. N.; Race, Richard E.; Frey, William H.; Haase, Ashley T.

doi:10.1128/jvi.65.9.4759-4768.1991

Cited by 271 publications

(82 citation statements)

References 45 publications

(26 reference statements)

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“…Apolipoprotein E is involved in neural repair and contributes to neuronal survival (Beffert et al, 2006;Gutman et al, 1997;Poirier et al, 1991). Moreover, increased expression of apolipoprotein E and immunohistological co-localization of apolipoprotein E and PrP have been described in animal models of transmissible spongiform encephalopathies (Diedrich et al, 1991;Hochstrasser et al, 1997;Nakamura et al, 2000), suggesting that apolipoprotein E is involved in the pathogenesis of prion diseases. Similarly, enhanced clusterin/apolipoprotein J levels have been found in prion-related encephalopathies.…”

Section: Discussionmentioning

confidence: 99%

Improvement of neuronal cell survival by astrocyte‐derived exosomes under hypoxic and ischemic conditions depends on prion protein

Guitart

Loers

Buck

et al. 2016

Glia

151

107

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Prion protein (PrP) protects neural cells against oxidative stress, hypoxia, ischemia, and hypoglycemia. In the present study we confirm that cultured PrP-deficient neurons are more sensitive to oxidative stress than wild-type neurons and present the novel findings that wild-type, but not PrP-deficient astrocytes protect wild-type cerebellar neurons against oxidative stress and that exosomes released from stressed wild-type, but not from stressed PrP-deficient astrocytes reduce neuronal cell death induced by oxidative stress. We show that neuroprotection by exosomes of stressed astrocytes depends on exosomal PrP but not on neuronal PrP and that astrocyte-derived exosomal PrP enters into neurons, suggesting neuronal uptake of astrocyte-derived exosomes. Upon exposure of wild-type astrocytes to hypoxic or ischemic conditions PrP levels in exosomes were increased. By mass spectrometry and Western blot analysis, we detected increased levels of 37/67 kDa laminin receptor, apolipoprotein E and the ribosomal proteins S3 and P0, and decreased levels of clusterin/apolipoprotein J in exosomes from wild-type astrocytes exposed to oxygen/glucose deprivation relative to exosomes from astrocytes maintained under normoxic conditions. The levels of these proteins were not altered in exosomes from stressed PrP-deficient astrocytes relative to unstressed PrP-deficient astrocytes. These results indicate that PrP in astrocytes is a sensor for oxidative stress and mediates beneficial cellular responses, e.g. release of exosomes carrying PrP and other molecules, resulting in improved survival of neurons under hypoxic and ischemic conditions.

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Section: Discussionmentioning

confidence: 99%

Improvement of neuronal cell survival by astrocyte‐derived exosomes under hypoxic and ischemic conditions depends on prion protein

Guitart

Loers

Buck

et al. 2016

Glia

151

107

View full text Add to dashboard Cite

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“…In the present study we failed to determine astrocyte subtypes with phase-contrast microscopy of autoradiographs in cell culture dishes due to poor resolution. Various biochemical changes have been shown to occur in association with reactive astrocytosis (Diedrich et al, 1991;Schwarcz, 1992;Tanaka et al, 1991) and such changes may lead to substantial alterations in regional metabolism. It is generally regarded that gliotic alterations appear secondarily to other processes causing neuronal cell death; yet, several recent works suggest a role of the astroglial reaction as a pathogenetic mechanism in neuronal degeneration (for review see Frederickson, 1992).…”

Section: Discussionmentioning

confidence: 99%

Monoamine oxidase‐B in astrocytes

Ekblom

Jossan²,

Bergström

et al. 1993

Glia

119

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In the present report we describe the astrocytic localization and content of monoamine oxidase-B (MAO-B) by means of a 3H-L-deprenyl emulsion autoradiography in primary cultures of rat astrocytes, in cryosectioned astrocytoma surgical specimen, and in cryosections of human spinal cords from patients dying in amyotrophic lateral sclerosis (ALS) and controls. The occurrence of MAO-B enzyme protein depends on the degree of cellular differentiation as demonstrated by studies on astrocytes in primary cultures analyzed at two different stages of maturation. Highly differentiated cells exhibited high relative enzyme concentration whereas glioblasts lacked or showed very low contents of MAO-B enzyme. This was further substantiated by studies performed on human astrocytoma tissue using 3H-L-deprenyl emulsion autoradiography in combination with immunohistochemical detection of glial fibrillary acidic protein (GFAP). Regional increases of MAO-B concentration were found in ALS lumbar sections with quantitative 3H-L-deprenyl autoradiography. On the basis of results obtained from double staining for GFAP and MAO-B, the increase in MAO-B seemed to be due to an increased number of astrocytes as well as an increased content of MAO-B in reactive species of astrocytes. A cell culture model has been used that produces cells with morphology and GFAP-content similar to reactive cells. These astrocytes exhibited high relative content of the MAO-B enzyme protein. In the light of the presented data, taking into account the finding that a subpopulation of reactive cells contained low levels of MAO-B, a heterogeneity among reactive astrocytes was observed.

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“…There is no exchange of brain-derived and peripheral ApoE; therefore, the CNS represents a distinct compartment in terms of ApoE metabolism [19]. Astrocytes are the primary source of ApoE in the brain; however, ApoE is also expressed by oligodendrocytes, ependymal layer cells, microglia and, under certain physiological circumstances, in neurons [33][34][35][36][37][38][39][40][41]. The upstream promoter region of the APOE gene contains several regulatory regions that can bind a variety of different transcription factors (TFs) [42][43][44][45][46][47][48][49].…”

Section: Apoementioning

confidence: 99%

Apolipoproteins in the brain: implications for neurological and psychiatric disorders

Elliott

Weickert

Garner

2010

Clinical Lipidology

176

158

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The brain is the most lipid-rich organ in the body and, owing to the impermeable nature of the blood-brain barrier, lipid and lipoprotein metabolism within this organ is distinct from the rest of the body. Apolipoproteins play a well-established role in the transport and metabolism of lipids within the CNS; however, evidence is emerging that they also fulfill a number of functions that extend beyond lipid transport and are critical for healthy brain function. The importance of apolipoproteins in brain physiology is highlighted by genetic studies, where apolipoprotein gene polymorphisms have been identified as risk factors for several neurological diseases. Furthermore, the expression of brain apolipoproteins is significantly altered in several brain disorders. The purpose of this article is to provide an up-to-date assessment of the major apolipoproteins found in the brain (ApoE, ApoJ, ApoD and ApoA-I), covering their proposed roles and the factors influencing their level of expression. Particular emphasis is placed on associations with neurological and psychiatric disorders. Keywords apolipoprotein; brain; CNS; lipid; neurological disease Structure & function of apolipoproteinsThe definition of 'apolipoprotein' can be some-what misleading. Textbooks and medical dictionaries tend to define apolipoproteins as "Any of various proteins that combine with a lipid to form a lipoprotein, such as HDL and LDL" [301], or "The protein components of lipoproteins, which remain after the lipids to which the proteins are bound have been removed" [302]. However, there are apolipoproteins, such as ApoD and Apo(a), that are not capable of forming even a nascent lipoprotein particle on their own, but rather associate with lipoproteins via hydrophobic surface features or through disulfide linkage to another Financial & competing interests disclosureThe authors have no other relevant affiliations or financial involvement with any organization or entity with a financial interest in or financial conflict with the subject matter or materials discussed in the manuscript apart from those disclosed. No writing assistance was utilized in the production of this manuscript. We should also acknowledge that a great volume of data related to apolipoprotein mRNA or protein expression, especially when the human brain is considered, may only be relevant for a specific brain region at a specific time in development or aging. Related to this, we have assembled apolipoprotein gene microarray data from a study, first described by Weickert et al. in 2009 [6], accessible at the National Center for Biotechnology Information Gene Expression Omnibus data-base [7,8,303], which highlights the dramatic changes in the expression of the quantitatively major apolipoproteins expressed in the human brain ( Figures 1-5). These data indicate that, of the 22 apolipoprotein genes analyzed in the prefrontal cortex, only three (APOD [ Figure 3C], APOE [ Figure 3D] and CLU [ Figure 4C]) are expressed at high levels. Furthermore, the expression of all three of ...

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Neuropathological changes in scrapie and Alzheimer's disease are associated with increased expression of apolipoprotein E and cathepsin D in astrocytes

Cited by 271 publications

References 45 publications

Improvement of neuronal cell survival by astrocyte‐derived exosomes under hypoxic and ischemic conditions depends on prion protein

Improvement of neuronal cell survival by astrocyte‐derived exosomes under hypoxic and ischemic conditions depends on prion protein

Monoamine oxidase‐B in astrocytes

Apolipoproteins in the brain: implications for neurological and psychiatric disorders

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