16 research outputs found
GLRB allelic variation associated with agoraphobic cognitions, increased startle response and fear network activation : a potential neurogenetic pathway to panic disorder
The molecular genetics of panic disorder (PD) with and without agoraphobia (AG) are still largely unknown and progress is hampered by small sample sizes. We therefore performed a genome-wide association study with a dimensional, PD/AG - related anxiety phenotype based on the Agoraphobia Cognition Questionnaire (ACQ) in a sample of 1,370 healthy German volunteers of the CRC TRR58 MEGA study wave 1. A genome-wide significant association was found between ACQ and single non-coding nucleotide variants of the GLRB gene (rs78726293, p=3.3x10-8; rs191260602, p=3.9x10-8). We followed up on this finding in a larger dimensional ACQ sample (N=2,547) and in independent samples with a dichotomous AG phenotype based on the Symptoms Checklist (SCL-90; N=3,845) and a case control sample with the categorical phenotype PD/AG (Ncombined =1,012) obtaining highly significant p-values also for GLRB single nucleotide variants rs17035816 (p=3.8x10-4) and rs7688285 (p=7.6x10-5). GLRB gene expression was found to be modulated by rs7688285 in brain tissue as well as cell culture. Analyses of intermediate PD/AG phenotypes demonstrated increased startle reflex and increased fear network as well as general sensory activation by GLRB risk gene variants rs78726293, rs191260602, rs17035816 and rs7688285. Partial Glrb knockout-mice demonstrated an agoraphobic phenotype. In conjunction withthe clinical observation that rare coding GLRB gene mutations are associated with the neurological disorder hyperekplexia characterized by a generalized startle reaction and agoraphobic behavior, our data provide evidence that non-coding, though functional GLRB gene polymorphisms may predispose to PD by increasing startle response and agoraphobic cognitions.PostprintPeer reviewe
Protein Production in Yarrowia lipolytica Via Fusion to the Secreted Lipase Lip2p.
We established a strategy for protein production and purification via expression in Yarrowia lipolytica as Lip2p fusion protein. To evaluate the expression system a cysteine-rich miniprotein, an antibody fragment and an enzyme showing galactose oxidase activity were chosen. These proteins have varying disulfide bond content, size, and structural complexity. Endogenous lipase Lip2p was used as a fusion partner to direct the fused proteins to the extracellular medium. A linker sequence was introduced at the junction of Lip2p and the respective fused protein that contains a hexahistidine tag followed by a TEV protease cleavage site. This allows for a specific and simple purification via IMAC for capturing the secreted proteins from the supernatant followed by a second IMAC for removing all contaminants after proteolytic release of the protein of interest. Up to 174Â mg/L fusion protein was obtained using shake flask cultivation. Functionality of each of the purified proteins was confirmed by individual assays. Expression of proteins of interest via Lip2p fusion not only provides a convenient expression and purification scheme but also enables for an online monitoring of accumulation of secreted fusion proteins in the medium by exploiting the intrinsic lipase activity of the fusion
Fluorescent Modular Boron Systems Based on NNN- and ONO-Tridentate Ligands:Self-Assembly and Cell Imaging
<p>We have synthesized a series of new fluorescent boron systems 1a-c and 2a-d based on nitrogen (NNN) or nitrogen and oxygen (ONO)-containing tridentate ligands. These novel dyes are characterized by high thermal and chemical stability. They show large Stokes shifts (mostly above 3200 cm(-1)) and quantum yields in solution and in the solid state up to 40%. The easy, modular synthesis facilitates the convenient variation of the axial substituent on the central boron atom, allowing the functionalization of this dye for biochemical use. Introducing a long alkyl chain with a phenyl spacer at this axial position enables the self-assembly of the boron compound 2d to form a fluorescent vesicle, which is able to encapsulate small molecules such as sulforhodamine. Additionally, boron compound 2d was found to serve as a dye for cell imaging since it has the capability of binding to the nuclear membranes of HeLa cells. With phospholipids such as DOPC, giant unilamelar vesicles (GUV) are formed. These results demonstrate the wide applicability of this new boron system in supramolecular and medicinal chemistry.</p>
Fluorescent Modular Boron Systems Based on NNN- and ONO-Tridentate Ligands: Self-Assembly and Cell Imaging
We
have synthesized a series of new fluorescent boron systems <b>1a</b>–<b>c</b> and <b>2a</b>–<b>d</b> based
on nitrogen (NNN) or nitrogen and oxygen (ONO)-containing
tridentate ligands. These novel dyes are characterized by high thermal
and chemical stability. They show large Stokes shifts (mostly above
3200 cm<sup>–1</sup>) and quantum yields in solution and in
the solid state up to 40%. The easy, modular synthesis facilitates
the convenient variation of the axial substituent on the central boron
atom, allowing the functionalization of this dye for biochemical use.
Introducing a long alkyl chain with a phenyl spacer at this axial
position enables the self-assembly of the boron compound <b>2d</b> to form a fluorescent vesicle, which is able to encapsulate small
molecules such as sulforhodamine. Additionally, boron compound <b>2d</b> was found to serve as a dye for cell imaging since it has
the capability of binding to the nuclear membranes of HeLa cells.
With phospholipids such as DOPC, giant unilamelar vesicles (GUV) are
formed. These results demonstrate the wide applicability of this new
boron system in supramolecular and medicinal chemistry
Fluorescent Modular Boron Systems Based on NNN- and ONO-Tridentate Ligands: Self-Assembly and Cell Imaging
We
have synthesized a series of new fluorescent boron systems <b>1a</b>–<b>c</b> and <b>2a</b>–<b>d</b> based
on nitrogen (NNN) or nitrogen and oxygen (ONO)-containing
tridentate ligands. These novel dyes are characterized by high thermal
and chemical stability. They show large Stokes shifts (mostly above
3200 cm<sup>–1</sup>) and quantum yields in solution and in
the solid state up to 40%. The easy, modular synthesis facilitates
the convenient variation of the axial substituent on the central boron
atom, allowing the functionalization of this dye for biochemical use.
Introducing a long alkyl chain with a phenyl spacer at this axial
position enables the self-assembly of the boron compound <b>2d</b> to form a fluorescent vesicle, which is able to encapsulate small
molecules such as sulforhodamine. Additionally, boron compound <b>2d</b> was found to serve as a dye for cell imaging since it has
the capability of binding to the nuclear membranes of HeLa cells.
With phospholipids such as DOPC, giant unilamelar vesicles (GUV) are
formed. These results demonstrate the wide applicability of this new
boron system in supramolecular and medicinal chemistry