Structural and biochemical studies of small G protein effectors

Bailey, Laura Kate

January 2010

No description available.

572

Proteins ; Biochemistry

Novel approaches to large scale protein purification and analysis /

Snoswell, Mark Andrew.

January 1990

Thesis (Ph. D.)--University of Adelaide, Dept. of Biochemistry, 1992. / Cover title: Novel approaches to protein purification and analysis: counter-current electrophoretic filtering: spectral enhancement. Spine title: Protein purification and analysis. Includes bibliographical references.

Biochemical analysis of cell division protein complexes in Streptomyces coelicolor

Kotun, Allen M.

January 2007

Thesis (M.S.)--Duquesne University, 2007. / Title from document title page. Abstract included in electronic submission form. Includes bibliographical references (p. 81-88) and appendix.

Structural studies of cell surface signalling molecules for neuronal guidance and connectivity

Mitakidis, Nikolaos

January 2013

Signal transduction is critical during the lifetime of a neuron as it navigates to reach its targets, forms functional synaptic connections and adjusts the molecular architecture of these connections in an activity-dependent manner. Understanding the molecular organisation of components required for neuronal signalling will provide novel biological insight and can contribute to the design of therapeutics for neurodevelopmental and neurodegenerative disorders. The focus of the thesis is on determining mechanistic molecular details of a number of distinct cell surface systems implicated in neuronal signalling. Crystallographic studies on the cell surface complex between Eph receptor A4 and ephrinA5 contributed to understanding how the modes of higher order arrangements of receptors involved in guidance affect signal transduction across the membrane. A set of structural and biophysical studies addressed the proteoglycan regulation of RPTPσ-TrkCtrans-synaptic interaction and contributed to deciphering the principles of the switch from axonal growth to synapse establishment and formation. A crystallographic and biochemical analysis of the neuronal C1q-like family, enabled mapping their interactions with potential synaptic partners, and guided functional studies aimed at elucidating their roles in the maintenance of synaptic integrity. Preliminary work on the neuronal Sigma-1 receptor chaperone laid the foundations for the structural determination of this receptor.

612.8

Membrane protein biosynthesis at the endoplasmic reticulum

Guna, Alina-Ioana

January 2018

The biosynthesis of integral membrane proteins (IMPs) is an essential cellular process. IMPs comprise roughly 20-30% of the protein coding genes of all organisms, nearly all of which are inserted and assembled at the endoplasmic reticulum (ER). The defining structural feature of IMPs is one or more transmembrane domains (TMDs). TMDs are typically stretches of predominately hydrophobic amino acids that span the lipid bilayer of biological membranes as an alpha helix. TMDs are remarkably diverse in terms of their topological and biophysical properties. In order to accommodate this diversity, the cell has evolved different sets of machinery that cater to particular subsets of proteins. Our knowledge of how the TMDs of IMPs are selectively recognized, chaperoned into the lipid bilayer, and assembled remains incomplete. This thesis is broadly interested in investigating how TMDs are correctly inserted and assembled at the ER. To address this the biosynthesis of multi-pass IMPs was first considered. Multi-pass IMPs contain two to more than twenty TMDs, with TMDs that vary dramatically in terms of their biophysical properties such as hydrophobicity, length, and helical propensity. The beta-1 adrenergic receptor (β1-AR), a member of the G-protein-coupled receptor (GPCR) family was established as a model substrate in an in vitro system where the insertion and folding of its TMDs could be interrogated. Assembly of β1-AR is not a straightforward process, and current models of insertion fail to explain how the known translocation machinery correctly identifies, inserts, and assembles β1-AR TMDs. An in vivo screen in mammalian cells was therefore conducted to identify additional factors which may be important for multi-pass IMP assembly. The ER membrane protein complex (EMC), a well conserved ER-resident complex of unknown biochemical function, was identified as a promising hit potentially involved in this assembly process. The complexity of working with multi-pass IMPs in an in vitro system prompted the investigation of a simpler class of proteins. Tail-anchored proteins (TA) are characterized by a single C-terminal hydrophobic domain that anchors them into membranes. Though structurally simpler compared to multi-pass IMPs, the TMDs of TA proteins are similarly diverse. We found that known TA insertion pathways fail to engage low-to-moderately hydrophobic TMDs. Instead, these are chaperoned in the cytosol by calmodulin (CaM). Transient release from CaM allows substrates to sample the ER, where resident machinery mediates the insertion reaction. The EMC was shown to be necessary for the insertion of these substrates both in vivo and in vitro. Purified EMC in synthetic liposomes catalysed insertion of its TA substrates in a fully reconstituted system to near-native levels. Therefore, the EMC was rigorously established as a TMD insertase. This key functional insight may explain its critical role in the assembly of multi- pass IMPs – which is now amenable to biochemical dissection.

Conformational Studies On Cyclic Pentapeptides And Structural Features In Globular Proteins

Nagarajaram, H A

01 1900

No description available.

Pentapeptides - Biochemistry

Proteins - Biochemistry

Peptides - Biochemistry

Cyclic Peptide

cyclic Pentapeptide

Cis Peptlde

Globular Proteins

Biochemistry

Functional perspectives on the evolution of argasid tick salivary gland protein superfamilies

Mans, Ben J. (Barend Johannes)

12 October 2005

Please read the abstract in the section 00front of this document / Thesis (PhD (Biochemistry))--University of Pretoria, 2002. / Biochemistry / unrestricted

Argasidae salivary proteins biochemistry

Argasidae salivary proteins evolution

UCTD