Structure-Function Relationships of Pi Class Glutathione Transferase Studied by Protein Engineering

Hegazy, Usama M.

January 2006

The glutathione transferases (GSTs) represent a superfamily of dimeric proteins involved in cellular detoxication by catalyzing the nucleophilic addition of the reduced glutathione (GSH) to the hydrophobic electrophiles. The present work focuses on the functional role of the conserved structures of GSTP1-1. The lock-and-key motif is a highly conserved hydrophobic interaction in the subunit interface of Pi, Mu, and Alpha class GSTs. The key residue (Tyr50 in hGSTP1-1) of one subunit is wedged into a hydrophobic pocket of the neighboring subunit. The heterodimer GSTP1/Y50A was constructed from the fully active wild-type GSTP1-1 and the nearly inactive Y50A in order to study how an essentially inactive subunit influences the activity of the neighboring subunit. The results illuminate the vital role of the lock-and-key motif in modulating the GSH binding and the rate of catalysis. Additionally, the two active sites of the dimeric enzyme work synergistically. An observed water network, in hGSTP1-1 structures, connects the two active sites, thereby offering a mechanism for communication between the two active sites. Cys48 and Tyr50 were targeted by mutations and chemical modifications for understanding how the α2 loop residues modulate GSH binding and catalysis. The replacement of Tyr50 with different unnatural amino acids showed that the nature of the key residue side-chain influences the interaction with the lock structure and, consequently, the catalytic activity. The KMGSH, GSH affinity and protein stability can be modulated by fitting key residue into the lock cavity of the neighbor subunit and, consequently, restriction of the flexibility of the α2 loop. Optimization of the interaction between the key residue and the lock-cavity increases kcat. Also, the crystal structure of the Cys-free variant was determined. The result indicated that Cys48 restricts the flexibility of the α2 loop by interacting with surrounding residues and, consequently, contributes to GSH binding and protein stability.

Biochemistry

Glutathione transferase

targeted chemical modification

lock-and-key motif

cooperativity

stucture-function relationship

protein engineering

unnatural amino acid

site-specific mutation

Biokemi

The birth and growth of the protein folding nucleus : Studies of protein folding focused on critical contacts, topology and ionic interactions

Hedberg, Linda

January 2008

Proteins are among the most complex molecules in the cell and they play a major role in life itself. The complexity is not restricted to just structure and function, but also embraces the protein folding reaction. Within the field of protein folding, the focus of this thesis is on the features of the folding transition state in terms of growing contacts, common nucleation motifs and the contribution of charged residues to stability and folding kinetics. During the resent decade, the importance of a certain residue in structure formation has been deduced from Φ-value analysis. As a complement to Φ-value analysis, I present how scatter in a Hammond plot is related to site-specific information of contact formation, Φ´(βTS), and this new formalism was experimentally tested on the protein L23. The results show that the contacts with highest Φ growth at the barrier top were distributed like a second layer outside the folding nucleus. This contact layer is the critical interactions needed to be formed to overcome the entropic barrier. Furthermore, the nature of the folding nucleus has been shown to be very similar among proteins with homologous structures and, in the split β-α-β family the proteins favour a two-strand-helix motif. Here I show that the two-strand-helix motif is also present in the ribosomal protein S6 from A. aeolicus even though the nucleation and core composition of this protein differ from other related structure-homologues. In contrast to nucleation and contact growth, which are events driven by the hydrophobic effect, my most recent work is focused on electrostatic effects. By pH titration and protein engineering the charge content of S6 from T. thermophilus was altered and the results show that the charged groups at the protein surface might not be crucial for protein stability but, indeed, have impact on folding kinetics. Furthermore, by site-specific removal of all acidic groups the entire pH dependence of protein stability was depleted.

protein folding

protein stability

two-state folding

chevron plot

transition-state movements

Hammond behaviour

topology

electrostatic interactions

pH dependence

mass-action

protein engineering

pKa

Biochemistry

Biokemi

Folding of the Ribosomal protein S6 : The role of sequence connectivity, overlapping foldons, and parallel pathways

Haglund, Ellinor

January 2009

To investigate how protein folding is affected by sequence connectivity five topological variants of the ribosomal protein S6 were constructed through circular permutation.  In these constructs, the chain connectivity (i.e. the order of secondary-structure elements) is changed without changing the native-state topology.  The effects of the permutations on the folding process were then characterised by φ-value analysis, which estimates the extent of contact formations in the transition-state ensemble.  The results show that the folding nuclei of the wild-type and permutant proteins comprises a common motif of one α-helix docking against two β-sheets, i.e. the minimal structure for folding.  However, this motif is recruited in different parts of the S6 structure depending on the permutation, either in the α1 or α2 half of the protein.  This minimal structure is not unique for S6 but can also be seen in other proteins.  As an effect of the dual nucleation possibilities, the transition-state changes describe a competition between two parallel pathways, which both include the central β-stand 1.  This strand constitutes thus a structural overlap between the two competing nuclei.  As similar overlap between competing nuclei is also seen in other proteins, I hypothesise that the coupling of several small nuclei into extended ‘super nuclei’ represents a general principle for propagating folding cooperativity across large structural distances.  Moreover, I demonstrate by NMR analysis that the existence of multiple folding nuclei renders the H/D-exchange kinetics independent of the folding pathway. / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper IV: Manuscript

protein folding

protein stability

two-state folding

S6

chevron plot

transition state

parallell pathways

foldon

two-channel landscape

protein engineering

H/D-exchange

Biochemistry

Biokemi

Optimization of Recombination Methods and Expanding the Utility of Penicillin G Acylase

Loo, Bernard Liat Wen

02 November 2007

Protein engineering can be performed by combinatorial techniques (directed evolution) and data-driven methods using machine-learning algorithms. The main characteristic of directed evolution (DE) is the application of an effective and efficient screen or selection on a diverse mutant library. As it is important to have a diverse mutant library for the success of DE, we compared the performance of DNA-shuffling and recombination PCR on fluorescent proteins using sequence information as well as statistical methods. We found that the diversity of the libraries DNA-shuffling and recombination PCR generates were dependent on type of skew primers used and sensitive to nucleotide identity levels between genes. DNA-shuffling and recombination PCR produced libraries with different crossover tendencies, suggesting that the two protocols could be used in combination to produce better libraries. Data-driven protein engineering uses sequence, structure and function data along with analyzed empirical activity information to guide library design. Boolean Learning Support Vector Machines (BLSVM) to identify interacting residues in fluorescent proteins and the gene templates were modified to preserve interactions post recombination. By site-directed mutagenesis, recombination and expression experiments, we validated that BLSVM can be used to identify interacting residues and increase the fraction of active proteins in the library. As an extension to the above experiments, DE was applied on monomeric Red Fluorescent Proteins to improve its spectral characteristics and structure-guided protein engineering was performed on penicillin G acylase (PGA), an industrially relevant catalyst, to change its substrate specificity.

Recombination protocols

Red fluorescent proteins

Penicillin g acylase

Substrate specificity

Support vector machines

Boolean learning

Protein engineering

Molecular evolution

Genetic engineering

Biotechnology

Delivery of thermostabilized chondroitinase ABC enhances axonal sprouting and functional recovery after spinal cord injury

Lee, Hyun-Jung

10 November 2009

Chondroitin sulfate proteoglycans (CSPGs) are one major class of axon growth inhibitors that are upregulated and accumulated around the lesion site after spinal cord injury (SCI), and result in regenerative failure. To overcome CSPG-mediated inhibition, digestion of CSPGs with chondroitinase ABC (chABC) has been explored and it has shown promising results. chABC digests glycosaminoglycan chains on CSPGs and can thereby enhance axonal regeneration and promote functional recovery when delivered at the site of injury. However, chABC has a crucial limitation; it is thermally unstable and loses its enzymatic activity rapidly at 37 ºC. Therefore, it necessitates the use of repeated injections or local infusions with a pump for days to weeks to provide fresh chABC to retain its enzymatic activity. Maintaining these infusion systems is invasive and clinically problematic. In this dissertation, three studies are reported that demonstrate our strategy to overcome current limitations of using chABC and develop a delivery system for facilitating chABC treatment after SCI: First, we enhanced the thermostability of chABC by adding trehalose, a protein stabilizer, and developed a system for its sustained local delivery in vivo. Enzymatic activity was assayed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and dimethylmethylene blue (DMMB), and conformational change of the enzyme was measured via circular dichroism (CD) with and without trehalose. When stabilized with trehalose, chABC remained enzymatically active at 37 ºC for up to 4 weeks in vitro. We developed a lipid microtube-agarose hydrogel delivery system for a sustained release and showed that chABC released from the delivery system is still functionally active and slowly released over 2 weeks in vitro. Second, the hydrogel-microtube system was used to locally deliver chABC over two weeks at the lesion site following a dorsal over hemisection injury at T10. The scaffold consisting of hydrogel and chABC loaded lipid microtubes was implanted at the top of the lesion site immediately following injury. To determine effectiveness of topical delivery of thermostabilized chABC, animal groups treated with single injection or gel scaffold implantation of chABC and penicillinase (P'ase) were included as controls. Two weeks after surgery, the functionality of released chABC and the cellular responses were examined by immunohistological analysis with 3B3, CS-56, GFAP and Wisteria floribunda agglutinin (WFA). The results demonstrated that thermostabilized chABC was successfully delivered slowly and locally without the need for an indwelling catheter by using the hydrogel-microtube delivery system in vivo. The results demonstrated that released chABC from the gel scaffold effectively digested CSPGs, and therefore, there were significant differences in CSPG digestion at the lesion site between groups treated with chABC loaded microtube-hydrogel scaffolds and controls. Third, a long term in vivo study (45 days) was conducted to examine axonal sprouting/regeneration and functional recovery with both a single treatment each of microtube loaded chABC or Neurotrophin-3 (NT-3), and a combination of them by using the hydrogel-microtube delivery system. Over the long term study period, the treated animals showed significant improvement in locomotor function and more sprouting of cholera toxin B subunit (CTB)-positive ascending dorsal column fibers and 5-HT serotonergic fibers around the lesion site. We demonstrated that this significant improvement of chABC thermostability facilitates the development of a minimally invasive method for sustained, local delivery of chABC that is potentially a useful and effective approach for treating SCI. In addition to that, we demonstrated that combinatorial therapy with chABC and neurotrophic factors could provide a synergistic effect on axonal regrowth and functional recovery after SCI.

Lipid microtube

Hydrogel

Regeneration

Chondroitin sulfate proteoglycan

Spinal cord injury

Chondroitinase ABC

Chondroitin sulfates

Protein engineering

Spinal cord Wounds and injuries

Spinal cord Regeneration

Protein structural changes and tyrosyl radical-mediated electron transfer reactions in ribonucleotide reductase and model compounds

Offenbacher, Adam R.

18 January 2011

Tyrosyl radicals can facilitate proton-coupled electron transfer (PCET) reactions that are linked to catalysis in many biological systems. One such protein system is ribonucleotide reductase (RNR). This enzyme is responsible for the conversion of ribonucleotides to deoxyribonucleotides. The beta2 subunit of class Ia RNRs contains a diiron cluster and a stable tyrosyl radical (Y122*). Reduction of ribonucleotides is dependent on reversible, long-distance PCET reactions involving Y122* located 35 Å from the active site. Protein conformational dynamics are postulated to precede diiron cluster assembly and PCET reactions in RNR. Using UV resonance Raman spectroscopy, we identified structural changes to histidine, tyrosine, and tryptophan residues with metal cluster assembly in beta2. With a reaction-induced infrared spectroscopic technique, local amide bond structural changes, which are associated with the reduction of Y122*, were observed. Moreover, infrared spectroscopy of tyrosine-containing pentapeptide model compounds supported the hypothesis that local amide bonds are perturbed with tyrosyl radical formation. These findings demonstrate the importance of the amino acid primary sequence and amide bonds on tyrosyl radical redox changes. We also investigated the function of a unique tyrosine-histidine cross-link, which is found in the active site of cytochrome c oxidase (CcO). Spectrophotometric titrations of model compounds that mimic the cross-link were consistent with a proton transfer role in CcO. Infrared spectroscopic data support the formation of tyrosyl radicals in these model compounds. Collectively, the effect of the local structure and the corresponding protein dynamics involved in tyrosyl radical-mediated PCET reactions are illustrated in this work.

Cytochrome c oxidase

Escherichia coli

UV resonance Raman spectroscopy

FT-IR spectroscopy

Infrared spectroscopy

Proton-coupled electron transfer

Oxidation-reduction reaction

Protein engineering

Tyrosine

Engineering the human vitamin D receptor to bind a novel small molecule: investigating the structure-function relationship between human vitamin d receptor and various ligands

Ousley, Amanda

12 April 2011

The human vitamin D receptor (hVDR) is a member of the nuclear receptor superfamily, involved in calcium and phosphate homeostasis; hence implicated in a number of diseases, such as Rickets and Osteoporosis. This receptor binds 1α,25-dihydroxyvitamin D3 (also referred to as 1,25(OH)2D3) and other known ligands, such as lithocholic acid. Specific interactions between the receptor and ligand are crucial for the function and activation of this receptor, as implied by the single point mutation, H305Q, causing symptoms of Type II Rickets. In this work, further understanding of the significant and essential interactions between the ligand and the receptor were deciphered, through a combination of rational and random mutagenesis. A hVDR mutant, H305F, was engineered with increased sensitivity towards lithocholic acid, with an EC50 value of 10 µM and 40 + 14 fold activation in mammalian cell assays, while maintaining wild-type activity with 1,25(OH)2D3. Furthermore, via random mutagenesis, a hVDR mutant, H305F/H397Y, was discovered to bind a novel small molecule, cholecalciferol, a precursor in the 1α,25-dihydroxyvitamin D3 biosynthetic pathway, which does not activate wild-type hVDR. This variant, H305F/H397Y, binds and activates in response to cholecalciferol concentrations as low as 100 nM, with an EC50 value of 300 nM and 70 + 11 fold activation in mammalian cell assays.

Lithocholic acid

Cholecalciferol

Human vitamin D receptor

Nuclear receptors

Vitamin D in the body

Protein engineering

Ligand binding (Biochemistry)

Receptor complexes (Biochemistry)

Mutagenesis

Engineering the pregnane X receptor and estrogen receptor alpha to bind novel small molecules using negative chemical complementation

Shaffer, Hally A.

05 April 2011

Nuclear receptors are ligand-activated transcription factors that play significant roles in various biological processes within the body, such as cell development, hormone metabolism, reproduction, and cardiac function. As transcription factors, nuclear receptors are involved in many diseases, such as diabetes, cancer, and arthritis, resulting in approximately 10-15% of the pharmaceutical drugs presently on the market being targeted toward nuclear receptors. Structurally, nuclear receptors consist of a DNA-binding domain (DBD), responsible for binding specific sequences of DNA called response elements, fused to a ligand-binding domain (LBD) through a hinge region. The LBD binds a small molecule ligand. Upon ligand binding, the LBD changes to an active conformation leading to the recruitment of coactivator (CoAC) proteins and initiation of transcription. As a result of their involvement in disease, there is an emphasis on engineering nuclear receptors for applications in gene therapy, drug discovery and metabolic engineering.

Nuclear receptors

Chemical complementation

Negative chemical complementation

Yeast-two hybrid selection

Pregnane X receptor

Estrogen receptor

Pregnane

Protein engineering

Nuclear receptors (Biochemistry)

Transcription factors

Yeast Genetics

Engineering of staphylococcal surfaces for biotechnological applications

Wernérus, Henrik

January 2002

<p>The engineering of bacterial surfaces has in recent yearsattracted a lot of attention with applications in manydifferent areas of bioscience. Here we describe the use of twodifferent surface display systems for the gram-positivebacteria Staphylococcus carnosus and Staphylococcus xylosus invarious biotechnological applications.</p><p>Environmental microbiology currently attracts a lot ofattention since genetically engineered plants and bacteriamight be used as bioadsorbents for sequestration of toxicmetals. Bacterial surface display of metal-binding peptidesmight enable recycling of the biomass by desorption ofaccumulated heavymetals. In an attempt to recruitstaphylococcal display systems for bioremediation purposes,polyhistidyl peptides were successfullly displayed on thesurface of recombinant S. carnosus and S. xylosus cells.Whole-cell Ni2+-binding assays demonstrated that therecombinant cells had gained metal-binding capacity compared towild-type cells.</p><p>Tailor-made, metal-binding staphylococci was created using apreviously constructed phage-display combinatorial proteinlibrary based on a fungal cellulose-binding domain (CBD)derived from the cellobiohydrolase Cel7A of Trichoderma reseii.Novel metal-binding CBDs were generated through a phagemediated selection procedure. Selected CBD variants, now devoidof cellulose binding, were randomly selected and sequenceanalysis of selected variants revealed a marked preference forhistidine residues at the randomized positions. Surface displayof these novel CBD variants resulted in recombinantstaphylococci with increased metal-binding capacity compared tocontrol strains, indicating that this could become a generalstrategy to engineer bacteria for improved binding to specificmetal ions.</p><p>Directed immobilization of cells with surface displayedheterologous proteins have widespread use in modernbiotechnology. Among other things they could provide aconvenient way of generating biofilters, biocatalysts orwhole-cell diagnostic devices. It was therefore investigatedwhether directed immobilization of recombinant staphylococci oncotton fibers could be achieved by functional display of afungal cellulose-binding domain (CBD). Recombinant S. carnosuscells with surface anchored CBDs from Trichoderma reseii Cel6Awere found to efficiently bind to cotton fibers creating almosta monolayer on the fibrous support. The co-expression of thisCBD together with previously described metal-binding proteinson the surface of our staphylococci would create means fordeveloping effective bioadsorbents for remediationpurposes.</p><p>The original plasmid vector, designed for heterologoussurface display on recombinant S. carnosus cells has exhibitedproblems related to structural instability, possibly due to thepresence of a phage f1 origin of replication in the vectorsequence. This would be a problem if using the vector systemfor library display applications. Therefore, novel surfacedisplay vectors, lacking the phage ori were constructed andevaluated by enzymatic and flow cytometric whole-cell assays.One such novel vector, pSCXm, exhibited dramatically increasedplasmid stability with the retained high surface density ofexpressed heterologous proteins characteristic for the originalS. carnosus display vector, thus making it potentially moresuitable for library display applications.</p><p>The successful engineering of our staphylococcal displaysystem encouraged us to further evaluate the potential to usethe staphylococcal system for display of combinatorial proteinlibraries and subsequent affinity based selections using flowcytometric cell sorting. A model system of recombinant S.carnosus cells with surface displayed engineered protein Adomains was constructed. It was demonstrated that target cellscould be sorted essentially quantitatively from a moderateexcess of background cells in a single sorting-step.Furthermore, the possibility of using staphylococcal surfacedisplay and flow cytometric cell sorting also for specificenrichment of very rare target cells by multiple rounds ofcell-sorting and in between amplification was demonstrated.</p><p><b>Key words:</b>affibody, albumin binding protein, bacterialsurface display, cell immobilization, bioremediation,combinatorial protein engineering, flow cytometry,Gram-positive, metal binding, staphylococcal protein A,Staphylococcus carnosus, Staphylococcus xylosus, whole-celldevices</p>

affibody

albumin binding protein

Bacterial surface display

cell immobilisation

bioremediation

combinatorial protein engineering

flow cytometry

Gram-positive

metal-binding

staphylococcal protein A

Staphylococcus carnosus

Staphylococcus xylo

Protein engineering to explore and improve affinity ligands

Linhult, Martin

January 2003

<p>In order to produce predictable and robust systems forprotein purification and detection, well characterized, small,folded domains descending from bacterial receptors have beenused. These bacterial receptors, staphylococcal protein A (SPA)and streptococcal protein G (SPG), possess high affinity to IgGand / or HSA. They are composed of repetitive units in whicheach one binds the ligand independently. The domains foldindependently and are very stable. Since the domains also havewellknown three-dimensional structures and do not containcysteine residues, they are very suitable as frameworks forfurther protein engineering.</p><p>Streptococcal protein G (SPG) is a multidomain proteinpresent on the cell surface of<i>Streptococcus</i>. X-ray crystallography has been used todetermine the binding site of the Ig-binding domain. In thisthesis the region responsible for the HSA affinity of ABD3 hasbeen determined by directed mutagenesis followed by functionaland structural analysis. The analysis shows that the HSAbindinginvolves residues mainly in the second α-helix.</p><p>Most protein-based affinity chromatography media are verysensitive towards alkaline treatment, which is the preferredmethod for regeneration and removal of contaminants from thepurification devices in industrial applications. Here, aprotein engineering strategy has been used to improve thetolerance to alkaline conditions of different domains fromprotein G, ABD3 and C2. Amino acids known to be susceptibletowards high pH were substituted for less alkali susceptibleresidues. The new, engineered variants of C2 and ABD shownhigher stability towards alkaline pH. Also, very important forthe potential use as affinity ligands, these mutated variantsretained the secondary structure and the affinity to HSA andIgG, respectively. Moreover, dimerization was performed toinvestigate whether a higher binding capacity could be obtainedby multivalency. For ABD, binding studies showed that divalentligands coupled using non-directed chemistry demonstrated anincreased molar binding capacity compared to monovalentligands. In contrast, equal molar binding capacities wereobserved for both types of ligands when using a directed ligandcoupling chemistry involving the introduction and recruitmentof a unique C-terminal cysteine residue.</p><p>The staphylococcal protein A-derived domain Z is also a wellknown and thoroughly characterized fusion partner widely usedin affinity chromatography systems. This domain is consideredto be relatively tolerant towards alkaline conditions.Nevertheless, it is desirable to further improve the stabilityin order to enable an SPA-based affinity medium to withstandeven longer exposure to the harsh conditions associated withcleaning in place (CIP) procedures. For this purpose adifferent protein engineering strategy was employed. Smallchanges in stability due to the mutations would be difficult toassess. Hence, in order to enable detection of improvementsregarding the alkaline resistance of the Z domain, a by-passmutagenesis strategy was utilized, where a mutated structurallydestabilized variant, Z(F30A) was used as a surrogateframework. All eight asparagines in the domain were exchangedone-by-one. The residues were all shown to have differentimpact on the alkaline tolerance of the domain. By exchangingasparagine 23 for a threonine we were able to remarkablyincrease the stability of the Z(F30A)-domain towards alkalineconditions. Also, when grafting the N23T mutation to the Zscaffold we were able to detect an increased tolerance towardsalkaline treatment compared to the native Z molecule. In allcases, the most sensitive asparagines were found to be locatedin the loops region.</p><p>In summary, the work presented in this thesis shows theusefulness of protein engineering strategies, both to explorethe importance of different amino acids regarding stability andfunctionality and to improve the characteristics of aprotein.</p><p><b>Keywords:</b>binding, affinity, human serum albumin (HSA),albumin-binding domain (ABD), affinity chromatography,deamidation, protein A, stabilization, Z-domain, capacity,protein G, cleaning-in-place (CIP), protein engineering, C2receptor.</p>

binding

affinity

human serum albumin (HSA)

albumin-binding domain (ABD)

affinity chromatography

deamidation

protein A

stabilization

Z-domain

capacity

protein G

cleaning-in-place (CIP)

protein engineering

C2 receptor