Human Aquaporins: Production, Characterization and Interactions
Abstract
Membrane proteins are essential components of the cell and responsible for the communication with the outside environment and transport of molecules across the membrane. Water transport is facilitated by aquaporins, which are water selective transmembrane pores that serve to maintain cell homeostasis. Aquaporins have been well characterized in terms of structure and function and a broad variety of cell based assays have given insight into their mechanism of regulation, including membrane localization and conformational changes. High-resolution structural information on aquaporins has emerged mainly using X-ray crystallography, which require large quantities of pure and homogenous protein.
This thesis presents the importance of codon optimization and clone selection in the first step of the pipeline to obtain high yields of recombinant membrane protein. This, in turn, enables biochemical characterization of the protein of interest. One such target, the human aquaporin 10, was found to be glycosylated in P. pastoris, increasing the protein stability in vitro but without any measurable impact on function. Aquaporin function is regulated by both physiological signals and interactions with other proteins. The regulation of the plasma membrane abundance of hAQP5 shows that three independent mechanisms – phosphorylation at Ser156, protein kinase A activity and extracellular tonicity – work in synergy to fine-tune the fraction of membrane localized protein. Furthermore, an overview of the literature of AQP protein:protein interactions reveal that the C-terminus is the most diverse sequence between aquaporins and that the majority of the known interactions map there.Obtaining high-resolution structural information of protein:protein complexes is one of the future challenges in structural biology. We developed a novel method for the characterization and purification of membrane protein complexes using hAQP0 and calmodulin as the proof-of-principle interaction partners. Our approach combined bimolecularfluorescence complementation to characterize the interaction and
fluorescence detection to detect the complex throughout purification. This resulted in a versatile method to purify intact protein complexes in enough yields for crystallization, potentially facilitating future structural determination by X-ray crystallography or electron microscopy.
Parts of work
Paper I. Öberg F, Sjöhamn J, Conner M. T, Bill R. M, Hedfalk K. (2011) Improving recombinant eukaryotic membrane
protein yields in Pichia pastoris: the importance of codon
optimization and clone selection. Mol. Membr. Biol. 28(6)
398–411 ::PMID::21770695 Paper II. Öberg F, Sjöhamn J, Fischer G, Moberg A, Pedersen A,Neutze R, Hedfalk K. (2011) Glycosylation increases the
thermostability of human aquaporin 10 protein. J. Biol.
Chem. 286(36), 31915–31923 ::PMID::21733844 Paper III. Kitchen P, Öberg F, Sjöhamn J, Hedfalk K, Bill RM, Conner AC, Conner MT, Törnroth-Horsefield S. (2015) Plasma membrane abundance of human aquaporin 5 is dynamically regulated by multiple pathways. Accepted for publication in PLOS ONE. Paper IV. Sjöhamn J, Hedfalk K . ( 2014) Unraveling aquaporin
interaction partners. Biochim Biophys Acta 1840 (5), 1614-
1623 ::PMID::24252279 Paper V. Sjöhamn J, Båth P, Neutze R, Hedfalk K. (2015) A strategy for expressing membrane protein:protein complexes for structural studies - bimolecular fluorescence complementation for membrane protein complex purification. Submitted
Degree
Doctor of Philosophy
University
University of Gothenburg. Faculty of Science
Institution
Department of Chemistry and Molecular Biology ; Institutionen för kemi och molekylärbiologi
Disputation
Fredagen den 27 november 2015, kl 13:00, Ivan Östholm, Medicinaregatan 13, Göteborg
Date of defence
2015-11-27
jennie.sjohamn@chem.gu.se
Date
2015-11-06Author
Sjöhamn, Jennie
Keywords
aquaporins
membrane protein
protein production
protein characterization
protein:protein interactions
structural biochemistry
Publication type
Doctoral thesis
ISBN
978-91-628-9574-7
Language
eng
Metadata
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