Nyegaard M

References (2)

Title : SorLA regulates the activity of lipoprotein lipase by intracellular trafficking - Klinger_2011_J.Cell.Sci_124_1095
Author(s) : Klinger SC , Glerup S , Raarup MK , Mari MC , Nyegaard M , Koster G , Prabakaran T , Nilsson SK , Kjaergaard MM , Bakke O , Nykjaer A , Olivecrona G , Petersen CM , Nielsen MS
Ref : Journal of Cell Science , 124 :1095 , 2011
Abstract : Many different tissues and cell types exhibit regulated secretion of lipoprotein lipase (LPL). However, the sorting of LPL in the trans Golgi network has not, hitherto, been understood in detail. Here, we characterize the role of SorLA (officially known as SorLA-1 or sortilin-related receptor) in the intracellular trafficking of LPL. We found that LPL bound to SorLA under neutral and acidic conditions, and in cells this binding mainly occurred in vesicular structures. SorLA expression changed the subcellular distribution of LPL so it became more concentrated in endosomes. From the endosomes, LPL was further routed to the lysosomes, which resulted in a degradation of newly synthesized LPL. Consequently, an 80% reduction of LPL activity was observed in cells that expressed SorLA. By analogy, SorLA regulated the vesicle-like localization of LPL in primary neuronal cells. Thus, LPL binds to SorLA in the biosynthetic pathway and is subsequently transported to endosomes. As a result of this SorLA mediated-transport, newly synthesized LPL can be routed into specialized vesicles and eventually sent to degradation, and its activity thereby regulated.
ESTHER : Klinger_2011_J.Cell.Sci_124_1095
PubMedSearch : Klinger_2011_J.Cell.Sci_124_1095
PubMedID: 21385844

Title : Common variants conferring risk of schizophrenia - Stefansson_2009_Nature_460_744
Author(s) : Stefansson H , Ophoff RA , Steinberg S , Andreassen OA , Cichon S , Rujescu D , Werge T , Pietilainen OP , Mors O , Mortensen PB , Sigurdsson E , Gustafsson O , Nyegaard M , Tuulio-Henriksson A , Ingason A , Hansen T , Suvisaari J , Lonnqvist J , Paunio T , Borglum AD , Hartmann A , Fink-Jensen A , Nordentoft M , Hougaard D , Norgaard-Pedersen B , Bottcher Y , Olesen J , Breuer R , Moller HJ , Giegling I , Rasmussen HB , Timm S , Mattheisen M , Bitter I , Rethelyi JM , Magnusdottir BB , Sigmundsson T , Olason P , Masson G , Gulcher JR , Haraldsson M , Fossdal R , Thorgeirsson TE , Thorsteinsdottir U , Ruggeri M , Tosato S , Franke B , Strengman E , Kiemeney LA , Melle I , Djurovic S , Abramova L , Kaleda V , Sanjuan J , de Frutos R , Bramon E , Vassos E , Fraser G , Ettinger U , Picchioni M , Walker N , Toulopoulou T , Need AC , Ge D , Yoon JL , Shianna KV , Freimer NB , Cantor RM , Murray R , Kong A , Golimbet V , Carracedo A , Arango C , Costas J , Jonsson EG , Terenius L , Agartz I , Petursson H , Nothen MM , Rietschel M , Matthews PM , Muglia P , Peltonen L , St Clair D , Goldstein DB , Stefansson K , Collier DA
Ref : Nature , 460 :744 , 2009
Abstract : Schizophrenia is a complex disorder, caused by both genetic and environmental factors and their interactions. Research on pathogenesis has traditionally focused on neurotransmitter systems in the brain, particularly those involving dopamine. Schizophrenia has been considered a separate disease for over a century, but in the absence of clear biological markers, diagnosis has historically been based on signs and symptoms. A fundamental message emerging from genome-wide association studies of copy number variations (CNVs) associated with the disease is that its genetic basis does not necessarily conform to classical nosological disease boundaries. Certain CNVs confer not only high relative risk of schizophrenia but also of other psychiatric disorders. The structural variations associated with schizophrenia can involve several genes and the phenotypic syndromes, or the 'genomic disorders', have not yet been characterized. Single nucleotide polymorphism (SNP)-based genome-wide association studies with the potential to implicate individual genes in complex diseases may reveal underlying biological pathways. Here we combined SNP data from several large genome-wide scans and followed up the most significant association signals. We found significant association with several markers spanning the major histocompatibility complex (MHC) region on chromosome 6p21.3-22.1, a marker located upstream of the neurogranin gene (NRGN) on 11q24.2 and a marker in intron four of transcription factor 4 (TCF4) on 18q21.2. Our findings implicating the MHC region are consistent with an immune component to schizophrenia risk, whereas the association with NRGN and TCF4 points to perturbation of pathways involved in brain development, memory and cognition.
ESTHER : Stefansson_2009_Nature_460_744
PubMedSearch : Stefansson_2009_Nature_460_744
PubMedID: 19571808