Your search keyword '"Nettleship, Joanne E."' showing total 7 results

1. Recent advances in the production of proteins in insect and mammalian cells for structural biology.

Author

Nettleship JE, Assenberg R, Diprose JM, Rahman-Huq N, and Owens RJ

Subjects

Animals, Baculoviridae genetics, CHO Cells, COS Cells, Cell Culture Techniques methods, Cell Line, Chlorocebus aethiops, Cloning, Molecular methods, Cricetinae, Cricetulus, Genetic Vectors genetics, HEK293 Cells, HeLa Cells, Humans, Luminescent Proteins genetics, Luminescent Proteins metabolism, Proteins chemistry, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Spodoptera, Vero Cells, Proteins genetics, Proteins metabolism

Abstract

The production of proteins in sufficient quantity and of appropriate quality is an essential pre-requisite for structural studies. Escherichia coli remains the dominant expression system in structural biology with nearly 90% of the structures in the Protein Data Bank (PDB) derived from proteins produced in this bacterial host. However, many mammalian and eukaryotic viral proteins require post-translation modification for proper folding and/or are part of large multimeric complexes. Therefore expression in higher eukaryotic cell lines from both invertebrate and vertebrate is required to produce these proteins. Although these systems are generally more time-consuming and expensive to use than bacteria, there have been improvements in technology that have streamlined the processes involved. For example, the use of multi-host vectors, i.e., containing promoters for not only E. coli but also mammalian and baculovirus expression in insect cells, enables target genes to be evaluated in both bacterial and higher eukaryotic hosts from a single vector. Culturing cells in micro-plate format allows screening of large numbers of vectors in parallel and is amenable to automation. The development of large-scale transient expression in mammalian cells offers a way of rapidly producing proteins with relatively high throughput. Strategies for selenomethionine-labelling (important for obtaining phase information in crystallography) and controlling glycosylation (important for reducing the chemical heterogeneity of glycoproteins) have also been reported for higher eukaryotic cell expression systems.

Published

2010

2. Methods for protein characterization by mass spectrometry, thermal shift (ThermoFluor) assay, and multiangle or static light scattering.

Author

Nettleship JE, Brown J, Groves MR, and Geerlof A

Subjects

Glycosylation, Polymerase Chain Reaction, Temperature, Light, Proteins chemistry, Scattering, Radiation, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization methods, Thermodynamics

Abstract

Mass spectrometry (MS) is widely used within structural and functional proteomics for a variety of tasks including protein quality assessment, identification, and characterization. MS is used routinely for the determination of the total mass of proteins, including N-glycosylated proteins, analysis of selenomethionine incorporation, crystal content verification, and analysis of N-glycosylation site occupancy. Protocols for sample preparation, data collection, and analysis are given.A recent development is the fluorescence-based thermal shift (ThermoFluor) assay. It uses an environmentally sensitive dye, Sypro Orange, to monitor the thermal stability of a protein and investigate factors (e.g., buffers, additives, and ligands) affecting this stability. This chapter describes the application of this method using a 96-condition in-house screen. The measurements are performed on a commercially available real-time PCR machine. Multiangle or static light scattering (SLS) is a very powerful technique to determine the conformational state of proteins in solution, especially when used in combination with size exclusion chromatography (SEC). In the authors' experimental set-up the SLS detector is connected in-line to a standard protein purification machine (e.g., the Akta Purifier) equipped with an analytical SEC column. The data collection and analysis are performed using commercial software.

Published

2008

3. Sample preparation and mass-spectrometric characterization of crystal-derived protein samples.

Author

Nettleship JE, Walter TS, Aplin R, Stammers DK, and Owens RJ

Subjects

Chromatography, High Pressure Liquid, Crystallization, Mass Spectrometry, Muramidase chemistry, Phosphorylation, Spectrometry, Mass, Electrospray Ionization, Proteins chemistry

Abstract

Mass spectrometry is often used to ascertain the accurate mass of purified protein samples prior to crystallization screening. However, in many cases data regarding the form of the protein crystallizing can also be useful, as this may differ from the original sample. Development of a simple method for the preparation and mass spectrometry of crystal-derived protein samples is described. The method is exemplified by the determination of the phosphorylation state of protein in a crystal derived from a mixture of phosphorylated and unphosphorylated protein.

Published

2005

4. Methods for protein characterization by mass spectrometry, thermal shift (ThermoFluor) assay, and multiangle or static light scattering

Author

Nettleship, Joanne E, Brown, James, Groves, Matthew R, Geerlof, Arie, Drug Design, and Medicinal Chemistry and Bioanalysis (MCB)

Subjects

Glycosylation, Light, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Temperature, Proteins, Scattering, Radiation, Thermodynamics, Polymerase Chain Reaction

Abstract

Mass spectrometry (MS) is widely used within structural and functional proteomics for a variety of tasks including protein quality assessment, identification, and characterization. MS is used routinely for the determination of the total mass of proteins, including N-glycosylated proteins, analysis of selenomethionine incorporation, crystal content verification, and analysis of N-glycosylation site occupancy. Protocols for sample preparation, data collection, and analysis are given.A recent development is the fluorescence-based thermal shift (ThermoFluor) assay. It uses an environmentally sensitive dye, Sypro Orange, to monitor the thermal stability of a protein and investigate factors (e.g., buffers, additives, and ligands) affecting this stability. This chapter describes the application of this method using a 96-condition in-house screen. The measurements are performed on a commercially available real-time PCR machine. Multiangle or static light scattering (SLS) is a very powerful technique to determine the conformational state of proteins in solution, especially when used in combination with size exclusion chromatography (SEC). In the authors' experimental set-up the SLS detector is connected in-line to a standard protein purification machine (e.g., the Akta Purifier) equipped with an analytical SEC column. The data collection and analysis are performed using commercial software.

Published

2008

5. Novel structural features in two ZHXhomeodomains derived from a systematic study ofsingle and multiple domains.

Author

Bird, Louise E., Ren, Jingshan, Nettleship, Joanne E., Folkers, Gert E., Owens, Raymond J., and Stammers, David K.

Subjects

ZINC, GENES, PROTEINS, GENOMICS, BIOINFORMATICS

Abstract

Background: Zhx1 to 3 (zinc-fingers and homeoboxes) form a set of paralogous genes encoding multi-domain proteins. ZHX proteins consist of two zinc fingers followed by five homeodomains. ZHXs have biological roles in cell cycle control by acting as co-repressors of the transcriptional regulator Nuclear Factor Y. As part of a structural genomics project we have expressed single and multi-domain fragments of the different human ZHX genes for use in structure determination. Results: A total of 30 single and multiple domain ZHX1-3 constructs selected from bioinformatics protocols were screened for soluble expression in E. coli using high throughput methodologies. Two homeodomains were crystallized leading to structures for ZHX1 HD4 and ZHX2 HD2. ZHX1 HD4, although closest matched to homeodomains from 'homez' and 'engrailed', showed structural differences, notably an additional C-terminal helix (helix V) which wrapped over helix I thereby making extensive contacts. Although ZHX2 HD2-3 was successfully expressed and purified, proteolysis occurred during crystallization yielding crystals of just HD2. The structure of ZHX2 HD2 showed an unusual open conformation with helix I undergoing 'domain-swapping' to form a homodimer. Conclusions: Although multiple-domain constructs of ZHX1 selected by bioinformatics studies could be expressed solubly, only single homeodomains yielded crystals. The crystal structure of ZHX1 HD4 showed additional hydrophobic interactions relative to many known homeodomains via extensive contacts formed by the novel C-terminal helix V with, in particular, helix I. Additionally, the replacement of some charged covariant residues (which are commonly observed to form salt bridges in non-homeotherms such as the Drosophila 'engrailed' homeodomain), by apolar residues further increases hydrophobic contacts within ZHX1 HD4, and potentially stability, relative to engrailed homeodomain. ZHX1 HD4 helix V points away from the normally observed DNA major groove binding site on homeodomains and thus would not obstruct the putative binding of nucleic acid. In contrast, for ZHX2 HD2 the observed altered conformation involving rearrangement of helix I, relative to the canonical homeodomain fold, disrupts the normal DNA binding site, although protein-protein binding is possible as observed in homodimer formation. [ABSTRACT FROM AUTHOR]

Published

2010

6. The structure of a reduced form of OxyR fromNeisseria meningitidis.

Author

Sainsbury, Sarah, Ren, Jingshan, Nettleship, Joanne E., Saunders, Nigel J., Stuart, David I., and Owens, Raymond J.

Subjects

PATHOGENIC microorganisms, NEISSERIA meningitidis, HYDROGEN peroxide, IMMUNE system, PROTEINS

Abstract

Background: Survival of the human pathogen, Neisseria meningitidis, requires an effective response to oxidative stress resulting from the release of hydrogen peroxide by cells of the human immune system. In N. meningitidis, expression of catalase, which is responsible for detoxifying hydrogen peroxide, is controlled by OxyR, a redox responsive LysR-type regulator. OxyR responds directly to intracellular hydrogen peroxide through the reversible formation of a disulphide bond between C199 and C208 in the regulatory domain of the protein. Results: We report the first crystal structure of the regulatory domain of an OxyR protein (NMB0173 from N. meningitidis) in the reduced state i.e. with cysteines at positions 199 and 208. The protein was crystallized under reducing conditions and the structure determined to a resolution of 2.4 Å. The overall fold of the Neisseria OxyR shows a high degree of similarity to the structure of a C199S mutant OxyR from E. coli, which cannot form the redox sensitive disulphide. In the neisserial structure, C199 is located at the start of helix a3, separated by 18 Å from C208, which is positioned between helices a3 and a4. In common with other LysR-type regulators, full length OxyR proteins are known to assemble into tetramers. Modelling of the full length neisserial OxyR as a tetramer indicated that C199 and C208 are located close to the dimer-dimer interface in the assembled tetramer. The formation of the C199-C208 disulphide may thus affect the quaternary structure of the protein. Conclusion: Given the high level of structural similarity between OxyR from N. meningitidis and E. coli, we conclude that the redox response mechanism is likely to be similar in both species, involving the reversible formation of a disulphide between C199-C208. Modelling suggests that disulphide formation would directly affect the interface between regulatory domains in an OxyR tetramer which in turn may lead to an alteration in the spacing/orientation of the DNA-binding domains and hence the interaction of OxyR with its DNA binding sites. [ABSTRACT FROM AUTHOR]

Published

2010

7. Lysine Methylation as a Routine Rescue Strategy for Protein Crystallization

Author

Walter, Thomas S., Meier, Christoph, Assenberg, Rene, Au, Kin-Fai, Ren, Jingshan, Verma, Anil, Nettleship, Joanne E., Owens, Raymond J., Stuart, David I., and Grimes, Jonathan M.

Subjects

*CRYSTALLIZATION, *PROTEINS, *LYSINE, *METHYLATION

Abstract

Summary: Crystallization remains a critical step in X-ray structure determination. Because it is not generally possible to rationally predict crystallization conditions, commercial screens have been developed which sample a wide range of crystallization space. While this approach has proved successful in many cases, a significant number of proteins fail to crystallize despite being soluble and monodispersed. It is established that chemical modification can facilitate the crystallization of otherwise intractable proteins. Here we describe a method for the reductive methylation of lysine residues which is simple, inexpensive, and efficient, and report on its application to ten proteins. We describe the effect of methylation on the physico-chemical properties of these proteins, and show that it led to diffraction-quality crystals from four proteins and structures for three that had hitherto proved refractory to crystallization. The method is suited to both low- and high-throughput laboratories. [Copyright &y& Elsevier]

Published

2006