Niki Georgopoulou scite author profile

Control of cell cycle progression/exit and differentiation of neuronal precursors is of paramount importance during brain development. BM88 is a neuronal protein associated with terminal neuron-generating divisions in vivoThe formation of the nervous system is governed by a delicate balance between cell proliferation, subsequent cell cycle withdrawal, and differentiation to distinctive neuronal phenotypes (1, 2). Current observations have highlighted the existence of mechanisms coupling cell cycle exit and differentiation as well as functional cross-talk between intrinsic factors controlling these two mechanisms. A number of key factors regulating cell cycle progression have been implicated in cell fate determination and differentiation of neuronal precursors, whereas specification-and/or differentiation-inducing molecules are beginning to emerge as cell cycle regulators (3-6). However, there are still important questions regarding the timing control of the proliferation/differentiation switch that remain unanswered.In the central nervous system, control of cell cycle progression plays an essential role in the generation of the appropriate number of neurons and the formation of functional neuronal circuits. When a neuronal progenitor is committed to undergo differentiation, it exits from the G 1 phase of the cell cycle and enters into an irreversible quiescent state referred to as G 0 . The tumor suppressor proteins p53 and pRb 6 are central regulators of this progression (7). p53, when activated, causes G 1 arrest at the G 0 restriction point by inducing expression of p21 and consequent inhibition of D-type cyclins and related cyclin-dependent kinases (8 -10), thus preventing phosphorylation of pRb (7). Under these conditions, hypophosphorylated pRb associates with the E2F family of transcription factors, thus impairing their ability to transactivate genes required for cell cycle progression (11). As a consequence cells do not progress through the G 1 -to-S phase transition. Several studies have indicated that a critical event associated with cell cycle withdrawal and differentiation both in neuronal and non-neuronal cells is the cellular compartmentalization of cyclin D1, which shifts from a predominantly nuclear localization to cytoplasmic sequestration

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The role of the protein glycosylation state in the control of cellular transport of the amyloid β precursor protein

McFarlane

Georgopoulou

Coughlan

et al. 1999

Neuroscience

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Cloning, expression and localization of human BM88 shows that it maps to chromosome 11p15.5, a region implicated in Beckwith–Wiedemann syndrome and tumorigenesis

Gaitanou

Buanne

Pappa

et al. 2001

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Porcine BM88 is a neuron-specific protein that enhances neuroblastoma cell differentiation in vitro and may be involved in neuronal differentiation in vivo. Here we report the identification, by Western blotting, of homologous proteins in human and mouse brain and the isolation of their respective cDNAs. Several human and mouse clones were identified in the EST database using porcine BM88 cDNA as a query. A human and a mouse EST clone were chosen for sequencing and were found both to predict a protein of 149 amino acids, with 79.9% reciprocal identity, and 76.4% and 70.7% identities to the porcine protein, respectively. This indicated that the clones corresponded to the human and mouse BM88homologues. In vitro expression in a cell-free system as well as transient expression in COS7 cells yielded polypeptide products that were recognized by anti-BM88 antibodies and were identical in size to the native BM88 protein. Northern-blot analysis showed a wide distribution of the gene in human brain whereas immunohistochemistry on human brain sections demonstrated that the expression of BM88 is confined to neurons. The initial mapping assignment of human BM88 to chromosome 11p15.5, a region implicated in Beckwith–Wiedemann syndrome and tumorigenesis, was retrieved from the UniGene database maintained at the National Centre for Biotechnology Information (NCBI, Bethesda, MD, U.S.A.). We confirmed this localization by performing fluorescence in situ hybridization on BM88-positive cosmid clones isolated from a human genomic library. These results suggest that BM88 may be a candidate gene for genetic disorders associated with alterations at 11p15.5. Sequence data for the human and mouse BM88 cDNAs have been deposited in the EMBL/GenBank Nucleotide Sequence Databases under accession numbers AF235030 and AF243130, respectively.

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The role of post-translational modification in ϐ-amyloid precursor protein processing

Georgopoulou

McLaughlin

McFarlane

et al. 2001

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The ϐ-amyloid precursor protein (APP) plays a pivotal role in the early stages of neurodegeneration associated with Alzheimer's disease. An alteration in the processing pattern of the protein results in an increase in the generation of the 40-42-amino-acid ϐ-amyloid (Aϐ) peptide, which coalesces to form insoluble, extracellular amyloid deposits. A greater understanding of the factors that influence APP processing may assist in the design of effective therapeutic agents to halt progression of Alzheimer's disease. APP is a sialoglycoprotein with two potential N-linked glycosylation sites, one of which may contain a complex oligosaccharide chain. An alteration in the glycosylation state of APP by the generation of oligomannosyl oligosaccharides results in a decrease in the secretion of the neuroprotective, soluble form of the protein and a parallel increase in the deposition of the cellular protein within the perinuclear region of the cell. Conversely, the attachment of additional terminal sialic acid residues on to the oligosaccharide chain results in an increase in secretion of soluble APP (sAPPα). One factor that has been widely reported to alter APP processing is the activation of protein kinase C (PKC). This process has been characterized using synaptosomal preparations, which suggests that the PKC action is occurring at the level of the plasma membrane. Furthermore, when cells are transfected with the sialyltransferase enzyme, there is a direct relationship between the sialylation potential of APP and the fold stimulation of sAPPα, after PKC activation. These results suggest that the post-translational modification of APP by glycosylation is a key event in determining the processing of the protein.

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