Your search keyword '"Recombinant Protein Purification"' showing total 6 results

1. Understanding the biochemical properties and physiological function of the protein syncollin

Author

Waters, Rosie, Edwardson, Michael, and Robinson, James

Subjects

Antimicrobial peptide, Host defence, Pancreatic zymogen granule, Membrane permeabilisation, Recombinant protein purification

Abstract

Syncollin is a 16-kDa protein that was originally isolated from the pancreatic zymogen granule. It is now known also to be expressed in the gut, the spleen and in neutrophils. The protein contains intramolecular disulphide bonds and is present both free within the ZG lumen and tightly associated with the luminal leaflet of the ZG membrane; it is also secreted into the pancreatic juice. Syncollin is able to oligomerize, and assemble into doughnut-shaped structures, which might explain its known pore-forming activity. Syncollin appears to be involved in a number of gut-based disease states. For instance, syncollin expression was found to be down-regulated in the colon when a bacterial suspension was administered to germ-free mice, and in mice with chemically-induced colitis-associated cancer. The available evidence suggests that syncollin plays an important role in the gut, and possibly elsewhere. This dissertation describes my attempts to understand this role and its structural basis. I first assessed various methods for purification of recombinant syncollin. Syncollin was expressed with various epitope tags (including His, GST and Strep) in bacteria, insect cells and mammalian cells. The best results were obtained by expressing syncollin bearing a double-Strep tag at its C terminus (syncollin-Strep) in mammalian (tsA-201) cells and purifying the protein from the cell supernatant using the Strep-Tactin XTTM system. Syncollin-Strep purified in this way contained intra-molecular disulphide bonds and recapitulated the ability of the native protein to bind to syntaxin 2 and permeabilize membranes. In the pancreatic juice, syncollin will encounter an environment rich in proteolytic activity. One might expect, therefore, that its structure would be highly stable. To test this hypothesis, I assessed the thermal stability of the protein using circular dichroism (CD) spectroscopy. The CD spectrum of syncollin-Strep indicated a predominantly beta-sheet structure. When the protein was subjected to a temperature ramp up to 90°C, the spectrum became flattened, although complete unfolding did not occur, indicating that the protein does indeed have a very high thermal stability. A model for syncollin, based on its primary sequence, predicts a predominantly beta-sheet structure, consistent with my CD data, and suggests the presence of intramolecular disulphide bonds. When I disrupted potential bonds by mutation of appropriate cysteine residues, syncollin-Strep retained its antibacterial efficacy, but its thermal stability was reduced, suggesting the involvement of disulphide bonding in stabilizing the structure of the protein. With regard to its potential role in the gut, I found that syncollin-Strep binds to bacterial peptidoglycan, and restricts the growth of representative Gram-positive (Lactococcus lactis) and Gram-negative (Escherichia coli) bacteria. Syncollin induces propidium iodide uptake into E. coli (but not L. lactis), indicating permeabilization of the bacterial membrane. In support of this idea, I confirmed that syncollin-Strep, like native syncollin, has pore-forming properties. Syncollin-Strep causes surface structural damage in both L. lactis and E. coli, as visualized by scanning electron microscopy. In addition, syncollin-Strep had additive effects on L. lactis when combined with either ampicillin (bactericidal) or tetracycline (bacteriostatic) in L. lactis. In light of these results, I propose that syncollin is a previously unidentified member of a large group of antimicrobial polypeptides that control the gut microbiome. I found that expression of syncollin in neutrophils is punctate and granular. Upon activation of the neutrophils, syncollin became mobilized at the plasma membrane, and was also secreted from the cells. Secreted syncollin bound to decondensed chromatin structures characteristic of neutrophil extracellular traps (NETs). Further, when neutrophils were activated in the presence of bacteria, the bacteria became coated with secreted syncollin, consistent with the anti-bacterial role proposed above. In conclusion, the results presented in this dissertation indicate that, through its antibacterial effects, syncollin plays a role in host defence in both the gut and the bloodstream.

Published

2021

2. Rational stabilization of the C-LytA affinity tag by protein engineering

Author

Hernandez-Rocamora, V.M., Maestro García-Donas, María Beatriz, Molla-Morales, A., Sanz, J.M., Hernandez-Rocamora, V.M., Maestro García-Donas, María Beatriz, Molla-Morales, A., and Sanz, J.M.

Abstract

The C-LytA protein constitutes the choline-binding module of the LytA amidase from Streptococcus pneumoniae. Owing to its affinity for choline and analogs, it is regularly used as an affinity tag for the purification of proteins in a single chromatographic step. In an attempt to build a robust variant against thermal denaturation, we have engineered several salt bridges on the protein surface. All the stabilizing mutations were pooled in a single variant, C-LytAm7, which contained seven changes: Y25K, F27K, M33E, N51K, S52K, T85K and T108K. The mutant displays a 7°C thermal stabilization compared with the wild-type form, together with a complete reversibility upon heating and a higher kinetic stability. Moreover, the accumulation of intermediates in the unfolding of C-LytA is virtually abolished for C-LytAm7. The differences in stability become more evident when the proteins are bound to a DEAE-cellulose affinity column, as most of wild-type C-LytA is denatured at ∼65°C, whereas C-LytAm7 may stand temperatures up to 90°C. Finally, the change in the isoelectric point of C-LytAm7 enhances its solubility at acidic pHs. Therefore, C-LytAm7 behaves as an improved affinity tag and supports the engineering of surface salt bridges as an effective approach for protein stabilization., Ministerio de Educación y Ciencia (MEC), Fundación SALVAT-Inquifarma, Depto. de Bioquímica y Biología Molecular, Fac. de Ciencias Biológicas, TRUE, unpub

Published

2024

3. The Analysis of Folate-Dependent Transcription Factor Zinc Finger Protein 410

Author

Xu, Feifan and Xu, Feifan

Abstract

A previous study that introduced dietary folate to mice in the form of folic acid to determine if gene activity would be altered based on this biological molecule demonstrated that mice without folic acid had cognition deficits, and this phenomenon was correlated with altered gene expression in their brains. The included bioinformatic analysis revealed two main transcription factors that bind to proteins in the nucleus, and one is known as the Zinc Finger Protein 410 (Zfp410). Due to the lack of literature explaining the function of this transcription factor, this project is intended to analyze Zfp410 in detail from scratch. Zfp410 cDNA sequence was purchased along with a plasmid vector, transferred to E. coli, and used to purify the recombinant protein. The purified protein was then injected into a rabbit for antibody production, and the collected Zfp410 antibody was characterized using several molecular techniques. Within high efficiency of targeting its antigen, Zfp410 antibody was used to identify any interacting proteins of Zfp410 by co-immunoprecipitation along with silver stain and western blot. The results demonstrated several Zfp410 interacting partners which suggested transcription factor Zfp410’s role in folate-dependent genes’ regulations.

Published

2021

4. Production of Self-Purifying Proteins in a Variety of Expression Hosts with Focus on Organophosphorus Hydrolase

Author

OHIO STATE UNIV RESEARCH FOUNDATION COLUMBUS, Wood, David W, OHIO STATE UNIV RESEARCH FOUNDATION COLUMBUS, and Wood, David W

Abstract

This project focuses on the development of highly effective non-chromatographic methods for purifying recombinant proteins and enzymes. This report covers work at Ohio State University, which focuses on the further optimization of the purification technology in the PI s new laboratory. A key aspect of the technology involves the use of a self-cleaving protein module, which can be used to make any purification tag self-cleaving. By combining this module with a variety of purification tags, we have generated a number of simple, inexpensive and highly effective methods for protein purification. We have applied these methods to the production of several proteins, including organophosphohydrolase (OPH), which can be used to degrade nerve agents and environmentally persistent insecticides. We have further demonstrated these methods in high cell-density fermentation at laboratory scale, and have provided evidence of their effectiveness. Our most recent work has been on the optimization of the fermentation process itself, as well as a more biochemical optimization of the expression system. Overall, the ARO support on this project has yielded two patent applications, seven peer-reviewed papers and one book chapter. In addition to these, three manuscripts are in late stages of preparation., The original document contains color images.

Published

2012

5. Rational stabilization of the C-LytA affinity tag by protein engineering

Author

Hernandez-Rocamora, V.M., Maestro García-Donas, María Beatriz, Molla-Morales, A., Sanz, J.M., Hernandez-Rocamora, V.M., Maestro García-Donas, María Beatriz, Molla-Morales, A., and Sanz, J.M.

Abstract

The C-LytA protein constitutes the choline-binding module of the LytA amidase from Streptococcus pneumoniae. Owing to its affinity for choline and analogs, it is regularly used as an affinity tag for the purification of proteins in a single chromatographic step. In an attempt to build a robust variant against thermal denaturation, we have engineered several salt bridges on the protein surface. All the stabilizing mutations were pooled in a single variant, C-LytAm7, which contained seven changes: Y25K, F27K, M33E, N51K, S52K, T85K and T108K. The mutant displays a 7°C thermal stabilization compared with the wild-type form, together with a complete reversibility upon heating and a higher kinetic stability. Moreover, the accumulation of intermediates in the unfolding of C-LytA is virtually abolished for C-LytAm7. The differences in stability become more evident when the proteins are bound to a DEAE-cellulose affinity column, as most of wild-type C-LytA is denatured at ∼65°C, whereas C-LytAm7 may stand temperatures up to 90°C. Finally, the change in the isoelectric point of C-LytAm7 enhances its solubility at acidic pHs. Therefore, C-LytAm7 behaves as an improved affinity tag and supports the engineering of surface salt bridges as an effective approach for protein stabilization., Ministerio de Educación y Ciencia (MEC), Fundación SALVAT-Inquifarma, Depto. de Bioquímica y Biología Molecular, Fac. de Ciencias Biológicas, TRUE, pub

Published

2008

6. Rational stabilization of the C-LytA affinity tag by protein engineering

Author

Ministerio de Educación y Ciencia (España), Fundació Salvat-Inquifarma, Hernández-Rocamora, V. M. [0000-0003-2517-5707], Maestro, Beatriz [0000-0001-5317-650X], Mollá-Morales, Almudena [0000-0001-9465-0490], Sanz, Jesús M. [0000-0002-4421-9376]], Hernández-Rocamora, V. M., Maestro, Beatriz, Mollá-Morales, Almudena, Sanz, Jesús M., Ministerio de Educación y Ciencia (España), Fundació Salvat-Inquifarma, Hernández-Rocamora, V. M. [0000-0003-2517-5707], Maestro, Beatriz [0000-0001-5317-650X], Mollá-Morales, Almudena [0000-0001-9465-0490], Sanz, Jesús M. [0000-0002-4421-9376]], Hernández-Rocamora, V. M., Maestro, Beatriz, Mollá-Morales, Almudena, and Sanz, Jesús M.

Abstract

The C-LytA protein constitutes the choline-binding module of the LytA amidase from Streptococcus pneumoniae. Due to its affinity for choline and analogs, it is regularly used as an affinity tag for the purification of proteins in a single chromatographic step. In an attempt to build a robust variant against thermal denaturation, we have engineered several salt bridges on the protein surface. All the stabilizing mutations were pooled in a single variant, C-LytAm7, which contained seven changes: Y25K, F27K, M33E, N51K, S52K, T85K and T108K. The mutant displays a 7 ºC thermal stabilization compared to the wild-type form, together with a complete reversibility upon heating and a higher kinetic stability. Moreover, the accumulation of intermediates in the unfolding of C-LytA is virtually abolished for C-LytAm7. The differences in stability become more evident when the proteins are bound to a DEAE-cellulose affinity column, as most of wild-type C-LytA is denatured at around 65 ºC, whereas C-LytAm7 may stand temperatures up to 90 ºC. Finally, the change in the isoelectric point of C-LytAm7 enhances its solubility at acidic pHs. Therefore, C LytAm7 behaves as an improved affinity tag and supports the engineering of surface salt bridges as an effective approach for protein stabilization.

Published

2008