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2. Increasing cell biomass in Saccharomyces cerevisiae increases recombinant protein yield: the use of a respiratory strain as a microbial cell factory

Author

Hedfalk Kristina, Larsson Christer, Gustafsson Lena, Wagner Renaud, Logez Christel, Bonander Nicklas, Ferndahl Cecilia, Darby Richard AJ, and Bill Roslyn M

Subjects
Microbiology, QR1-502
Abstract

Abstract Background Recombinant protein production is universally employed as a solution to obtain the milligram to gram quantities of a given protein required for applications as diverse as structural genomics and biopharmaceutical manufacture. Yeast is a well-established recombinant host cell for these purposes. In this study we wanted to investigate whether our respiratory Saccharomyces cerevisiae strain, TM6*, could be used to enhance the productivity of recombinant proteins over that obtained from corresponding wild type, respiro-fermentative strains when cultured under the same laboratory conditions. Results Here we demonstrate at least a doubling in productivity over wild-type strains for three recombinant membrane proteins and one recombinant soluble protein produced in TM6* cells. In all cases, this was attributed to the improved biomass properties of the strain. The yield profile across the growth curve was also more stable than in a wild-type strain, and was not further improved by lowering culture temperatures. This has the added benefit that improved yields can be attained rapidly at the yeast's optimal growth conditions. Importantly, improved productivity could not be reproduced in wild-type strains by culturing them under glucose fed-batch conditions: despite having achieved very similar biomass yields to those achieved by TM6* cultures, the total volumetric yields were not concomitantly increased. Furthermore, the productivity of TM6* was unaffected by growing cultures in the presence of ethanol. These findings support the unique properties of TM6* as a microbial cell factory. Conclusions The accumulation of biomass in yeast cell factories is not necessarily correlated with a proportional increase in the functional yield of the recombinant protein being produced. The respiratory S. cerevisiae strain reported here is therefore a useful addition to the matrix of production hosts currently available as its improved biomass properties do lead to increased volumetric yields without the need to resort to complex control or cultivation schemes. This is anticipated to be of particular value in the production of challenging targets such as membrane proteins.

Published
2010
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3. Altering the ribosomal subunit ratio in yeast maximizes recombinant protein yield

Author

Poyner David R, Brogna Saverio, Wen Jikai, Bora Nagamani, Grgic Ljuban, Darby Richard AJ, Bonander Nicklas, O'Neill Michael AA, and Bill Roslyn M

Subjects
Microbiology, QR1-502
Abstract

Abstract Background The production of high yields of recombinant proteins is an enduring bottleneck in the post-genomic sciences that has yet to be addressed in a truly rational manner. Typically eukaryotic protein production experiments have relied on varying expression construct cassettes such as promoters and tags, or culture process parameters such as pH, temperature and aeration to enhance yields. These approaches require repeated rounds of trial-and-error optimization and cannot provide a mechanistic insight into the biology of recombinant protein production. We published an early transcriptome analysis that identified genes implicated in successful membrane protein production experiments in yeast. While there has been a subsequent explosion in such analyses in a range of production organisms, no one has yet exploited the genes identified. The aim of this study was to use the results of our previous comparative transcriptome analysis to engineer improved yeast strains and thereby gain an understanding of the mechanisms involved in high-yielding protein production hosts. Results We show that tuning BMS1 transcript levels in a doxycycline-dependent manner resulted in optimized yields of functional membrane and soluble protein targets. Online flow microcalorimetry demonstrated that there had been a substantial metabolic change to cells cultured under high-yielding conditions, and in particular that high yielding cells were more metabolically efficient. Polysome profiling showed that the key molecular event contributing to this metabolically efficient, high-yielding phenotype is a perturbation of the ratio of 60S to 40S ribosomal subunits from approximately 1:1 to 2:1, and correspondingly of 25S:18S ratios from 2:1 to 3:1. This result is consistent with the role of the gene product of BMS1 in ribosome biogenesis. Conclusion This work demonstrates the power of a rational approach to recombinant protein production by using the results of transcriptome analysis to engineer improved strains, thereby revealing the underlying biological events involved.

Published
2009
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4. Transcriptome analysis of a respiratory Saccharomyces cerevisiae strain suggests the expression of its phenotype is glucose insensitive and predominantly controlled by Hap4, Cat8 and Mig1

Author

Bonander Nicklas, Ferndahl Cecilia, Mostad Petter, Wilks Martin DB, Chang Celia, Showe Louise, Gustafsson Lena, Larsson Christer, and Bill Roslyn M

Subjects
Biotechnology, TP248.13-248.65, Genetics, QH426-470
Abstract

Abstract Background We previously described the first respiratory Saccharomyces cerevisiae strain, KOY.TM6*P, by integrating the gene encoding a chimeric hexose transporter, Tm6*, into the genome of an hxt null yeast. Subsequently we transferred this respiratory phenotype in the presence of up to 50 g/L glucose to a yeast strain, V5 hxt1-7Δ, in which only HXT1-7 had been deleted. In this study, we compared the transcriptome of the resultant strain, V5.TM6*P, with that of its wild-type parent, V5, at different glucose concentrations. Results cDNA array analyses revealed that alterations in gene expression that occur when transitioning from a respiro-fermentative (V5) to a respiratory (V5.TM6*P) strain, are very similar to those in cells undergoing a diauxic shift. We also undertook an analysis of transcription factor binding sites in our dataset by examining previously-published biological data for Hap4 (in complex with Hap2, 3, 5), Cat8 and Mig1, and used this in combination with verified binding consensus sequences to identify genes likely to be regulated by one or more of these. Of the induced genes in our dataset, 77% had binding sites for the Hap complex, with 72% having at least two. In addition, 13% were found to have a binding site for Cat8 and 21% had a binding site for Mig1. Unexpectedly, both the up- and down-regulation of many of the genes in our dataset had a clear glucose dependence in the parent V5 strain that was not present in V5.TM6*P. This indicates that the relief of glucose repression is already operable at much higher glucose concentrations than is widely accepted and suggests that glucose sensing might occur inside the cell. Conclusion Our dataset gives a remarkably complete view of the involvement of genes in the TCA cycle, glyoxylate cycle and respiratory chain in the expression of the phenotype of V5.TM6*P. Furthermore, 88% of the transcriptional response of the induced genes in our dataset can be related to the potential activities of just three proteins: Hap4, Cat8 and Mig1. Overall, our data support genetic remodelling in V5.TM6*P consistent with a respiratory metabolism which is insensitive to external glucose concentrations.

Published
2008
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10. Constitutively-stressed yeast strains are high-yielding for recombinant Fps1:implications for the translational regulation of an aquaporin

Author

Cartwright, Stephanie P., Darby, Richard A.J., Sarkar, Debasmita, Bonander, Nicklas, Gross, Stephane R., Ashe, Mark P., Bill, Roslyn M., Cartwright, Stephanie P., Darby, Richard A.J., Sarkar, Debasmita, Bonander, Nicklas, Gross, Stephane R., Ashe, Mark P., and Bill, Roslyn M.

Abstract

Background: We previously selected four strains of Saccharomyces cerevisiae for their ability to produce the aquaporin Fps1 in sufficient yield for further study. Yields from the yeast strains spt3Δ, srb5Δ, gcn5Δ and yTHCBMS1 (supplemented with 0.5 μg/mL doxycycline) that had been transformed with an expression plasmid containing 249 base pairs of 5′ untranslated region (UTR) in addition to the primary FPS1 open reading frame (ORF) were 10–80 times higher than yields from wild-type cells expressing the same plasmid. One of the strains increased recombinant yields of the G protein-coupled receptor adenosine receptor 2a (A2aR) and soluble green fluorescent protein (GFP). The specific molecular mechanisms underpinning a high-yielding Fps1 phenotype remained incompletely described. Results: Polysome profiling experiments were used to analyze the translational state of spt3Δ, srb5Δ, gcn5Δ and yTHCBMS1 (supplemented with 0.5 μg/mL doxycycline); all but gcn5Δ were found to exhibit a clear block in translation initiation. Four additional strains with known initiation blocks (rpl31aΔ, rpl22aΔ, ssf1Δ and nop1Δ) also improved the yield of recombinant Fps1 compared to wild-type. Expression of the eukaryotic transcriptional activator GCN4 was increased in spt3Δ, srb5Δ, gcn5Δ and yTHCBMS1 (supplemented with 0.5 μg/mL doxycycline); these four strains also exhibited constitutive phosphorylation of the eukaryotic initiation factor, eIF2α. Both responses are indicative of a constitutively-stressed phenotype. Investigation of the 5′UTR of FPS1 in the expression construct revealed two untranslated ORFs (uORF1 and uORF2) upstream of the primary ORF. Deletion of either uORF1 or uORF1 and uORF2 further improved recombinant yields in our four strains; the highest yields of the uORF deletions were obtained from wild-type cells. Frame-shifting the stop codon of the native uORF (uORF2) so that it extended into the FPS1 ORF did not substantially alter Fps1 yields in spt3Δ or wild-type cells, s

Published
2017

11. Optimising yeast as a host for recombinant protein production (review)

Author

Bonander, Nicklas and Bill, Roslyn M.

Abstract

Having access to suitably stable, functional recombinant protein samples underpins diverse academic and industrial research efforts to understand the workings of the cell in health and disease. Synthesising a protein in recombinant host cells typically allows the isolation of the pure protein in quantities much higher than those found in the protein's native source. Yeast is a popular host as it is a eukaryote with similar synthetic machinery to the native human source cells of many proteins of interest, while also being quick, easy, and cheap to grow and process. Even in these cells the production of some proteins can be plagued by low functional yields. We have identified molecular mechanisms and culture parameters underpinning high yields and have consolidated our findings to engineer improved yeast cell factories. In this chapter, we provide an overview of the opportunities available to improve yeast as a host system for recombinant protein production.

Published
2012

12. Relieving the first bottleneck in the drug discovery pipeline:using array technologies to rationalize membrane protein production

Author

Bonander, Nicklas and Bill, Roslyn M.

Abstract

The slow down in the drug discovery pipeline is, in part, owing to a lack of structural and functional information available for new drug targets. Membrane proteins, the targets of well over 50% of marketed pharmaceuticals, present a particular challenge. As they are not naturally abundant, they must be produced recombinantly for the structural biology that is a prerequisite to structure-based drug design. Unfortunately, however, obtaining high yields of functional, recombinant membrane proteins remains a major bottleneck in contemporary bioscience. While repeated rounds of trial-and-error optimization have not (and cannot) reveal mechanistic details of the biology of recombinant protein production, examination of the host response has provided new insights. To this end, we published an early transcriptome analysis that identified genes implicated in high-yielding yeast cell factories, which has enabled the engineering of improved production strains. These advances offer hope that the bottleneck of membrane protein production can be relieved rationally.

Published
2009

14. Production, purification and characterization of recombinant, full-length human claudin-1

Author

Bonander, Nicklas, Jamshad, Mohammed, Oberthür, Dominik, Clare, Michelle, Barwell, James, Hu, Ke, Farquhar, Michelle J., Stamataki, Zania, Harris, Helen J., Dierks, Karsten, Dafforn, Timothy R., Betzel, Christian, McKeating, Jane A., Bill, Roslyn M., Bonander, Nicklas, Jamshad, Mohammed, Oberthür, Dominik, Clare, Michelle, Barwell, James, Hu, Ke, Farquhar, Michelle J., Stamataki, Zania, Harris, Helen J., Dierks, Karsten, Dafforn, Timothy R., Betzel, Christian, McKeating, Jane A., and Bill, Roslyn M.

Abstract

The transmembrane domain proteins of the claudin superfamily are the major structural components of cellular tight junctions. One family member, claudin-1, also associates with tetraspanin CD81 as part of a receptor complex that is essential for hepatitis C virus (HCV) infection of the liver. To understand the molecular basis of claudin-1/CD81 association we previously produced and purified milligram quantities of functional, full-length CD81, which binds a soluble form of HCV E2 glycoprotein (sE2). Here we report the production, purification and characterization of claudin-1. Both yeast membrane-bound and detergent-extracted, purified claudin-1 were antigenic and recognized by specific antibodies. Analytical ultracentrifugation demonstrated that extraction with n-octyl-ß-d-glucopyranoside yielded monodispersed, dimeric pools of claudin-1 while extraction with profoldin-8 or n-decylphosphocholine yielded a dynamic mixture of claudin-1 oligomers. Neither form bound sE2 in line with literature expectations, while further functional analysis was hampered by the finding that incorporation of claudin-1 into proteoliposomes rendered them intractable to study. Dynamic light scattering demonstrated that claudin-1 oligomers associate with CD81 in vitro in a defined molar ratio of 1:2 and that complex formation was enhanced by the presence of cholesteryl hemisuccinate. Attempts to assay the complex biologically were limited by our finding that claudin-1 affects the properties of proteoliposomes. We conclude that recombinant, correctly-folded, full-length claudin-1 can be produced in yeast membranes, that it can be extracted in different oligomeric forms that do not bind sE2 and that a dynamic preparation can form a specific complex with CD81 in vitro in the absence of any other cellular components. These findings pave the way for the structural characterization of claudin-1 alone and in complex with CD81.

Published
2013

15. Understanding the yeast host cell response to recombinant membrane protein production

Author

Bawa, Zharain, Bland, Charlotte E., Bonander, Nicklas, Bora, Nagamani, Cartwright, Stephanie P., Clare, Michelle, Conner, Matthew T., Darby, Richard A.J., Dilworth, Marvin V, Holmes, William J., Jamshad, Mohammed, Routledge, Sarah J., Gross, Stephane R., Bill, Roslyn M., Bawa, Zharain, Bland, Charlotte E., Bonander, Nicklas, Bora, Nagamani, Cartwright, Stephanie P., Clare, Michelle, Conner, Matthew T., Darby, Richard A.J., Dilworth, Marvin V, Holmes, William J., Jamshad, Mohammed, Routledge, Sarah J., Gross, Stephane R., and Bill, Roslyn M.

Abstract

Membrane proteins are drug targets for a wide range of diseases. Having access to appropriate samples for further research underpins the pharmaceutical industry's strategy for developing new drugs. This is typically achieved by synthesizing a protein of interest in host cells that can be cultured on a large scale, allowing the isolation of the pure protein in quantities much higher than those found in the protein's native source. Yeast is a popular host as it is a eukaryote with similar synthetic machinery to that of the native human source cells of many proteins of interest, while also being quick, easy and cheap to grow and process. Even in these cells, the production of human membrane proteins can be plagued by low functional yields; we wish to understand why. We have identified molecular mechanisms and culture parameters underpinning high yields and have consolidated our findings to engineer improved yeast host strains. By relieving the bottlenecks to recombinant membrane protein production in yeast, we aim to contribute to the drug discovery pipeline, while providing insight into translational processes.

Published
2011

16. Increasing cell biomass in Saccharomyces cerevisiae increases recombinant protein yield:the use of a respiratory strain as a microbial cell factory

Author

Ferndahl, Cecilia, Bonander, Nicklas, Logez, Christel, Wagner, Renaud, Gustafsson, Lena, Larsson, Christer, Hedfalk, Kristina, Darby, Richard A.J., Bill, Roslyn M., Ferndahl, Cecilia, Bonander, Nicklas, Logez, Christel, Wagner, Renaud, Gustafsson, Lena, Larsson, Christer, Hedfalk, Kristina, Darby, Richard A.J., and Bill, Roslyn M.

Abstract

BACKGROUND: Recombinant protein production is universally employed as a solution to obtain the milligram to gram quantities of a given protein required for applications as diverse as structural genomics and biopharmaceutical manufacture. Yeast is a well-established recombinant host cell for these purposes. In this study we wanted to investigate whether our respiratory Saccharomyces cerevisiae strain, TM6*, could be used to enhance the productivity of recombinant proteins over that obtained from corresponding wild type, respiro-fermentative strains when cultured under the same laboratory conditions. RESULTS: Here we demonstrate at least a doubling in productivity over wild-type strains for three recombinant membrane proteins and one recombinant soluble protein produced in TM6* cells. In all cases, this was attributed to the improved biomass properties of the strain. The yield profile across the growth curve was also more stable than in a wild-type strain, and was not further improved by lowering culture temperatures. This has the added benefit that improved yields can be attained rapidly at the yeast's optimal growth conditions. Importantly, improved productivity could not be reproduced in wild-type strains by culturing them under glucose fed-batch conditions: despite having achieved very similar biomass yields to those achieved by TM6* cultures, the total volumetric yields were not concomitantly increased. Furthermore, the productivity of TM6* was unaffected by growing cultures in the presence of ethanol. These findings support the unique properties of TM6* as a microbial cell factory. CONCLUSIONS: The accumulation of biomass in yeast cell factories is not necessarily correlated with a proportional increase in the functional yield of the recombinant protein being produced. The respiratory S. cerevisiae strain reported here is therefore a useful addition to the matrix of production hosts currently available as its improved biomass properties do lead to increased volu

Published
2010

17. Altering the ribosomal subunit ratio in yeast maximizes recombinant protein yield

Author

Bonander, Nicklas, Darby, Richard A.J., Grgic, Ljuban, Bora, Nagamani, Wen, Jikai, Brogna, Saverio, Poyner, David R., O'Neill, Michael A. A., Bill, Roslyn M., Bonander, Nicklas, Darby, Richard A.J., Grgic, Ljuban, Bora, Nagamani, Wen, Jikai, Brogna, Saverio, Poyner, David R., O'Neill, Michael A. A., and Bill, Roslyn M.

Abstract

Background The production of high yields of recombinant proteins is an enduring bottleneck in the post-genomic sciences that has yet to be addressed in a truly rational manner. Typically eukaryotic protein production experiments have relied on varying expression construct cassettes such as promoters and tags, or culture process parameters such as pH, temperature and aeration to enhance yields. These approaches require repeated rounds of trial-and-error optimization and cannot provide a mechanistic insight into the biology of recombinant protein production. We published an early transcriptome analysis that identified genes implicated in successful membrane protein production experiments in yeast. While there has been a subsequent explosion in such analyses in a range of production organisms, no one has yet exploited the genes identified. The aim of this study was to use the results of our previous comparative transcriptome analysis to engineer improved yeast strains and thereby gain an understanding of the mechanisms involved in high-yielding protein production hosts. Results We show that tuning BMS1 transcript levels in a doxycycline-dependent manner resulted in optimized yields of functional membrane and soluble protein targets. Online flow microcalorimetry demonstrated that there had been a substantial metabolic change to cells cultured under high-yielding conditions, and in particular that high yielding cells were more metabolically efficient. Polysome profiling showed that the key molecular event contributing to this metabolically efficient, high-yielding phenotype is a perturbation of the ratio of 60S to 40S ribosomal subunits from approximately 1:1 to 2:1, and correspondingly of 25S:18S ratios from 2:1 to 3:1. This result is consistent with the role of the gene product of BMS1 in ribosome biogenesis. Conclusion This work demonstrates the power of a rational approach to recombinant protein production by using the results of transcriptome analysis to engineer im

Published
2009

18. Transcriptome analysis of a respiratory Saccharomyces cerevisiae strain suggests the expression of its phenotype is glucose insensitive and predominantly controlled by Hap4, Cat8 and Mig1

Author

Bonander, Nicklas, Ferndahl, Cecilia, Mostad, Petter, Wilks, Martin D.B., Chang, Celia, Showe, Louise, Gustafsson, Lena, Larsson, Christer, Bill, Roslyn M., Bonander, Nicklas, Ferndahl, Cecilia, Mostad, Petter, Wilks, Martin D.B., Chang, Celia, Showe, Louise, Gustafsson, Lena, Larsson, Christer, and Bill, Roslyn M.

Abstract

BACKGROUND: We previously described the first respiratory Saccharomyces cerevisiae strain, KOY.TM6*P, by integrating the gene encoding a chimeric hexose transporter, Tm6*, into the genome of an hxt null yeast. Subsequently we transferred this respiratory phenotype in the presence of up to 50 g/L glucose to a yeast strain, V5 hxt1-7Delta, in which only HXT1-7 had been deleted. In this study, we compared the transcriptome of the resultant strain, V5.TM6*P, with that of its wild-type parent, V5, at different glucose concentrations. RESULTS: cDNA array analyses revealed that alterations in gene expression that occur when transitioning from a respiro-fermentative (V5) to a respiratory (V5.TM6*P) strain, are very similar to those in cells undergoing a diauxic shift. We also undertook an analysis of transcription factor binding sites in our dataset by examining previously-published biological data for Hap4 (in complex with Hap2, 3, 5), Cat8 and Mig1, and used this in combination with verified binding consensus sequences to identify genes likely to be regulated by one or more of these. Of the induced genes in our dataset, 77% had binding sites for the Hap complex, with 72% having at least two. In addition, 13% were found to have a binding site for Cat8 and 21% had a binding site for Mig1. Unexpectedly, both the up- and down-regulation of many of the genes in our dataset had a clear glucose dependence in the parent V5 strain that was not present in V5.TM6*P. This indicates that the relief of glucose repression is already operable at much higher glucose concentrations than is widely accepted and suggests that glucose sensing might occur inside the cell. CONCLUSION: Our dataset gives a remarkably complete view of the involvement of genes in the TCA cycle, glyoxylate cycle and respiratory chain in the expression of the phenotype of V5.TM6*P. Furthermore, 88% of the transcriptional response of the induced genes in our dataset can be related to the potential activities of just th

Published
2008

19. Optimized in vitro and in vivo expression of proteorhodopsin: A seven-transmembrane proton pump

Author

Gourdon, Pontus Emanuel, Alfredsson, Anna, Pedersen, Anders, Mahnerberg, Erik, Nyblom, Maria, Widell, Mikael, Berntsson, Ronnie, Pinhassi, Jarone, Braiman, Marc, Hansson, Orjan, Bonander, Nicklas, Karlsson, Goran, Neutze, Richard, Gourdon, Pontus Emanuel, Alfredsson, Anna, Pedersen, Anders, Mahnerberg, Erik, Nyblom, Maria, Widell, Mikael, Berntsson, Ronnie, Pinhassi, Jarone, Braiman, Marc, Hansson, Orjan, Bonander, Nicklas, Karlsson, Goran, and Neutze, Richard

Published
2008

20. Production, Purification and Characterization of Recombinant, Full-Length Human Claudin-1

Author

Bonander, Nicklas, primary, Jamshad, Mohammed, additional, Oberthür, Dominik, additional, Clare, Michelle, additional, Barwell, James, additional, Hu, Ke, additional, Farquhar, Michelle J., additional, Stamataki, Zania, additional, Harris, Helen J., additional, Dierks, Karsten, additional, Dafforn, Timothy R., additional, Betzel, Christian, additional, McKeating, Jane A., additional, and Bill, Roslyn M., additional

Published
2013
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21. Metal co-ordination, protein-folding, and electron-transfer studies of wild-type and mutant azurin

Author

Bonander, Nicklas

Subjects
Azurin, E. coli, site-directed mutagenesis, exogenous ligand, blue copper, EPR, resonance Raman, crystal structure, copper, cobalt, nickel, electron transfer
Abstract

Azurin is a copper-containing protein that functions as an electron carrierin certain bacteria. Like other cupredoxins its three-dimensional structureis essentially that of a b-barrel. The interaction between the oxidizedcopper ion and the metal binding site of the protein results in a strongoptical absorption around 630 nm and a special combination of EPRparameters. The copper ion in azurin is co-ordinated by three strongligands (NNS) and two more weakly interacting groups (S and O).The properties of the metal binding site in azurin have been probed byreplacing the native copper ion for non-native cobalt and nickel ions, andthe resulting structures have by X-ray crystallography been determined. Themain difference compared to copper is a displacement of cobalt and nickeltoward the oxygen ligand. This makes these metal ions four co-ordinated.Spectroscopic and structural properties of the copper ion in azurin havealso been probed by binding small molecules to the metal. These moleculesinteract with the copper ion in 121X azurin mutants, but not in wild-typeazurin. The interaction of the mutants M121X (X = Gly, Ala, Val, Leu, andAsp) with oxygen- and nitrogen-containing ligands has been analyzed by EPRand optical spectroscopy, as well as by resonance Raman spectroscopy. TheX-ray structure of Ala121 and Ala121 + azide have been determined in orderto analyze the geometrical changes upon ligand binding. One end of theexogenous ligand azide interacts with the copper ion close to where thesulfur of Met121 is positioned in the wild-type structure. This structuredemonstrates that the exogenous ligand interaction can change theco-ordination of the copper ion from three to four strong ligands.The effect of removing the disulfide bond in azurin has been investigated.The major change upon replacing the cysteine residues in the disulfide bondfor alanine residues is a decreased folding stability. It is concluded thatthe disulfide contributes at least 20 kJmol-1 to the folding energy ofazurin.A possible function of aromatic amino acids in the electron transferreaction has been investigated by introducing an additional tryptophan inazurin. The tryptophan was engineered in a proposed electron transferpathway in van der Waals contact with the native tryptophan. Evidencesuggests that several aromatic amino acids stacked against each other mayinduce a more effective electron transfer between the donor and acceptorsite.

Published
1997

28. Transcriptome analysis of a respiratory Saccharomycescerevisiae strain suggests the expression of its phenotype is glucose insensitive and predominantly controlled by Hap4, Cat8 and Mig1.

Author

Bonander, Nicklas, Ferndahl, Cecilia, Mostad, Petter, Wilks, Martin D. B., Chang, Celia, Showe, Louise, Gustafsson, Lena, Larsson, Christer, and Bill, Roslyn M.

Subjects
SACCHAROMYCES cerevisiae, GENE expression, PHENOTYPES, GLUCOSE, MICROBIAL proteins
Abstract

Background: We previously described the first respiratory Saccharomyces cerevisiae strain, KOY.TM6*P, by integrating the gene encoding a chimeric hexose transporter, Tm6*, into the genome of an hxt null yeast. Subsequently we transferred this respiratory phenotype in the presence of up to 50 g/L glucose to a yeast strain, V5 hxt1-7?, in which only HXT1-7 had been deleted. In this study, we compared the transcriptome of the resultant strain, V5.TM6*P, with that of its wild-type parent, V5, at different glucose concentrations. Results: cDNA array analyses revealed that alterations in gene expression that occur when transitioning from a respiro-fermentative (V5) to a respiratory (V5.TM6*P) strain, are very similar to those in cells undergoing a diauxic shift. We also undertook an analysis of transcription factor binding sites in our dataset by examining previously-published biological data for Hap4 (in complex with Hap2, 3, 5), Cat8 and Mig1, and used this in combination with verified binding consensus sequences to identify genes likely to be regulated by one or more of these. Of the induced genes in our dataset, 77% had binding sites for the Hap complex, with 72% having at least two. In addition, 13% were found to have a binding site for Cat8 and 21% had a binding site for Mig1. Unexpectedly, both the up- and down-regulation of many of the genes in our dataset had a clear glucose dependence in the parent V5 strain that was not present in V5.TM6*P. This indicates that the relief of glucose repression is already operable at much higher glucose concentrations than is widely accepted and suggests that glucose sensing might occur inside the cell. Conclusion: Our dataset gives a remarkably complete view of the involvement of genes in the TCA cycle, glyoxylate cycle and respiratory chain in the expression of the phenotype of V5.TM6*P. Furthermore, 88% of the transcriptional response of the induced genes in our dataset can be related to the potential activities of just three proteins: Hap4, Cat8 and Mig1. Overall, our data support genetic remodelling in V5.TM6*P consistent with a respiratory metabolism which is insensitive to external glucose concentrations. [ABSTRACT FROM AUTHOR]

Published
2008
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30. NMR assignment of HI1723 from Haemophilus influenzae--a sequence homologue from the iron sulfur cluster assembly (IscA) family.

Author

Yeh DC, Liu F, Bonander N, Eisenstein E, and Orban J

Subjects
Cluster Analysis, Escherichia coli chemistry, Haemophilus influenzae genetics, Nitrogen Isotopes chemistry, Recombinant Proteins chemistry, Bacterial Proteins chemistry, Carbon Isotopes chemistry, Iron-Sulfur Proteins chemistry, Magnetic Resonance Spectroscopy
Published
2004
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