Exploring the structurial diversity and engineering potential of thermophilic periplasmic binding proteins

Cuneo, Matthew Joseph

02 May 2007

The periplasmic binding protein (PBP) superfamily is found throughout the genosphere of both prokaryotic and eukaryotic organisms. PBPs function as receptors in bacterial solute transport and chemotaxis systems; however the same fold is also used in transcriptional regulators, enzymes, and eukaryotic neurotransmitter receptors. This versatility has been exploited for structure-based computational protein design experiments where PBPs have been engineered to bind novel ligands and serve as biosensors for the detection of small-molecule ligands relevant to biomedical or defense-related interests. In order to further understand functional adaptation from a structural biology perspective, and to provide a set of robust starting points for engineering novel biosensors by structure-based design, I have characterized the ligand-binding properties and solved the structure of nine PBPs from various thermophilic bacteria. Analysis of these structures reveals a variety of mechanisms by which diverse function can be encoded in a common fold. It is observed that re-modeling of secondary structure elements (such as insertions, deletions, and loop movements), and re-decoration of amino acid side-chains are common diversification mechanisms in PBPs. Furthermore, the relationship between hinge-bending motion and ligand binding is critical to understanding the function of natural or engineered adaptations in PBPs. Three of these proteins were solved in both the presence and absence of ligand which allowed for the first time the observation and analysis of ligand-induced structural rearrangements in thermophilic PBPs. This work revealed that the magnitude and transduction of local and global ligand-induced motions are diverse throughout the PBP superfamily. Through the analysis of the open-to-closed transition, and the identification of natural structural adaptations in thermophilic members of the PBP superfamily, I reveal strategies which can be applied to computational protein design to significantly improve current strategies. / Dissertation

periplasmic binding protein (PBP)

ligand-binding properties

thermophilic bacteria

computational biology

Structural Studies of Binding Proteins: Investigations of Flexibility, Specificity and Stability

Magnusson, Ulrika

January 2003

<p>Binding proteins are present both in gram-negative and gram-positive bacteria. They are the recognition components of the ABC transport systems that transport different nutrients into the cell, and are in some cases also involved in chemotaxis. In gram-negative bacteria, they are present in the periplasm between the inner and the porous outer membrane. Here, these highly specific proteins can bind to a certain ligand such as ions, sugars and amino acids. The protein-ligand complex can then interact with permeases bound to the inner membrane that transport the nutrient into the cell. Gram-positive bacteria lack an outer membrane and the binding protein must therefore be anchored to the cell membrane.</p><p>In this thesis different aspects of three members of the super-family of the periplasmic binding proteins have been studied. In the case of the allose-binding protein (ALBP) from <i>E. coli</i> we focused on the movement of the protein when ligand is bound and released. This protein was also compared with the ribose-binding protein (RBP) which belongs to the same structural cluster and from which both open and closed structures are available. The leucine-binding protein (LBP) from <i>E. coli</i> was studied with regards to the structural basis of its specificity for different ligands as well as its conformational changes. The leucine-isoleucine-valine protein has 80% sequence identity with LBP but still exhibits a different preference for ligands. The structure of the maltose-binding protein (MBP) was obtained from a gram-positive thermoacidophile, <i>A. acidocaldarius. </i>Here, our goal was to study acid-stability of proteins. Since little is known about this and structures of the mesophilic counterpart in <i>E. coli</i> are available, as well as structures from two hyperthermophiles, we had an opportunity to study differences in their structural properties that could explain their differing stabilities.</p>

Molecular biology

Periplasmic binding protein

X-ray crystallography

conformational change

acidophile

protein specificity

protein structure

Molekylärbiologi

Molecular biology

Molekylärbiologi

Structural Studies of Binding Proteins: Investigations of Flexibility, Specificity and Stability

Magnusson, Ulrika

January 2003

Binding proteins are present both in gram-negative and gram-positive bacteria. They are the recognition components of the ABC transport systems that transport different nutrients into the cell, and are in some cases also involved in chemotaxis. In gram-negative bacteria, they are present in the periplasm between the inner and the porous outer membrane. Here, these highly specific proteins can bind to a certain ligand such as ions, sugars and amino acids. The protein-ligand complex can then interact with permeases bound to the inner membrane that transport the nutrient into the cell. Gram-positive bacteria lack an outer membrane and the binding protein must therefore be anchored to the cell membrane. In this thesis different aspects of three members of the super-family of the periplasmic binding proteins have been studied. In the case of the allose-binding protein (ALBP) from E. coli we focused on the movement of the protein when ligand is bound and released. This protein was also compared with the ribose-binding protein (RBP) which belongs to the same structural cluster and from which both open and closed structures are available. The leucine-binding protein (LBP) from E. coli was studied with regards to the structural basis of its specificity for different ligands as well as its conformational changes. The leucine-isoleucine-valine protein has 80% sequence identity with LBP but still exhibits a different preference for ligands. The structure of the maltose-binding protein (MBP) was obtained from a gram-positive thermoacidophile, A. acidocaldarius. Here, our goal was to study acid-stability of proteins. Since little is known about this and structures of the mesophilic counterpart in E. coli are available, as well as structures from two hyperthermophiles, we had an opportunity to study differences in their structural properties that could explain their differing stabilities.

Molecular biology

Periplasmic binding protein

X-ray crystallography

conformational change

acidophile

protein specificity

protein structure

Molekylärbiologi

Molecular biology

Molekylärbiologi

Thermodynamic Characterization Of Wild Type And Mutants Of The E.coli Periplasmic Binding Proteins LBP, LIVBP, MBP And RBP

Prajapati, Ravindra Singh

12 1900

Native states of globular proteins typically show stabilization in the range of 5 to 15 kcal/mol with respect to their unfolded states. There has been a considerable progress in the area of protein stability and folding in recent years, but increasing protein stability through rationally designed mutations has remained a challenging task. Current ability to predict protein structure from the amino acid sequence is also limited due to the lack of quantitative understanding of various factors that defines the single lowest energy fold or native state. The most important factors, which are considered primarily responsible for the structure and stability of the biological active form of proteins, are hydrophobic interactions, hydrogen bonding and electrostatic interactions such as salt bridges as well as packing interactions. Several studies have been carried out to decipher the importance of each these factors in protein stability and structure via rationally designed mutant proteins. The limited success of previous studies emphasizes the need for comprehensive studies on various aspect of protein stability. An integrated approach involving thermodynamic and structural analysis of a protein is very useful in understanding this particular phenomenon. This approach is very useful in relating the thermodynamic stability with the structure of a protein. A survey of the current literature on thermodynamic stability of protein indicates that the majority of the model proteins which have been used for understanding the determinants of protein stability are small, monomeric, single domain globular proteins like RNase A, Lysozyme and Myoglobin. On the other hand large proteins often show complex unfolding transition profiles that are rarely reversible. The major part of this thesis is focused on studying potential stabilizing/destabilizing interactions in small and large globular proteins. These interactions have been identified and characterized by exploring the effects of various rationally designed mutations on protein stability. Spectroscopic, molecular biological and calorimetric techniques were employed to understand the relationships between protein sequence, structure and stability. The experimental systems used are Leucine binding proteins, Leucine isoleucine valine binding protein (LIVBP), Maltose binding protein (MBP), Ribose binding protein (RBP) and Thioredoxin (Trx). The last section of the thesis discusses thermodynamic properties of molten globule states of the periplasmic protein LBP, LIVBP, MBP and RBP. The amino acid Pro is unique among all the twenty naturally occurring amino acids. In the case of proline, the Cδ of the side chain is covalently linked with the main chain nitrogen atom in a five membered ring. Therefore, Pro lacks amide hydrogen and it is not able to form a main chain hydrogen bond with a carbonyl oxygen. Hence Pro is typically not found in the hydrogen bonded, interior region of α-helix. There have been several studies which showed that introduction of the Pro residue into the interior of an α-helix is destabilizing. Although, it is not common to find Pro residue in the interiors of an α-helix, it has been reported that it occurs with appreciable frequency (14%). The thermodynamic effects of replacements of Pro residue in helix interiors of MBP were investigated in Chapter 2 of this thesis. Unlike many other small proteins, MBP contains 21 Pro residues distributed throughout the structure. It contains three residues in the interiors of α-helices, at positions 48, 133 and 159. These Pro residues were replaced with an alanine and serine amino acids using site directed mutagenesis. Stabilities of all the mutant and wild type proteins have been studied via isothermal chemical denaturation at pH 7.4 and thermal denaturation as a function of pH ranging from pH 6.5 to 10.4. It has been observed that replacement of a proline residue in the middle of an α-helix does not always stabilize a protein. It can be stabilizing if the carbonyl oxygen of residue (i-3) or (i-4) is well positioned to form a hydrogen bond with the ith (mutated) residue and the position of mutation is not buried or conserved in the protein. Partially exposed position have the ability to form main chain hydrogen bonds and Ala seems to be a better choice to substitute Pro than Ser. Unlike other amino acids, the pyrolidine ring of Pro residue imposes rigid constraints on the rotation about the N---Cα bond in the peptide backbone. This causes conformational restriction of the φ dihedral angle of Pro to -63±15º in polypeptides. Therefore, introduction of a rigid Pro residue into an appropriate position in a protein sequence is expected to decrease the conformational entropy of the denatured state and consequently lead to protein stabilization. In Chapter 3 of this thesis, the thermodynamic effects of Pro introduction on protein stability has been investigated in LIVBP, MBP, RBP and Trx. Thirteen single and two double mutants have been generated in the above four proteins. Three of the MBP mutants were characterized by X-ray crystallography to confirm that no structural changes had occurred upon mutation. In the remaining cases, CD spectroscopy was used to show the absence of structural changes. Stability of all the mutant and wild type proteins was studied via isothermal chemical denaturation at neutral pH and thermal denaturation as a function of pH. The mutants did not show enhanced stability with respect to chemical denaturation at room temperature. However, six of the thirteen single mutants showed a small but significant increase in the free energy of thermal unfolding in the range of 0.3-2.4 kcal/mol, two mutants showed no change and five were destabilized. In five of the six cases, the stabilization was because of a reduced entropy of unfolding. Two double mutants were constructed. In both cases, the effects of the single mutations on the free energy of thermal unfolding were non-additive. In addition to the hydrogen bond, hydrophobic and electrostatic interactions, other interactions like cation-π and aromatic-aromatic interactions etc. are also considered to make important contributions to protein stability. The relevance of cation-π interaction in biological systems has been recognized in recent years. It has been reported that positively charged amino acids (Lys, Arg and His) are often located within 6 Å of the ring centroids of aromatic amino acids (Phe, Tyr and Trp). The importance of cation-π interaction in protein stability has been suggested by previous theoretical and experimental studies. We have attempted to determine the magnitude of cation-π interactions of Lys with aromatic amino acids in four different proteins (LIVBP, MBP, RBP and Trx) in Chapter 4 of the thesis. Cation-π pairs have been identified by using the program CaPTURE. We have found thirteen cation-π pairs in five different proteins (PDB ID’s 2liv, 1omp, 1anf, 1urp and 2trx). Five cation-π pairs were selected for the study. In each pair, Lys was replaced with Gln and Met. In a separate series of experiments, the aromatic amino acid in each cation-π pair was replaced by Leu. Stabilities of wild type (WT) and mutant proteins were characterized by similar methods, to those discussed in previous chapters. Gln and Aromatic → Leu mutants were consistently less stable than the corresponding Met mutants reflecting the non-isosteric nature of these substitutions. The strength of the cation-π interaction was assessed by the value of the change in the free energy of unfolding (ΔΔG0=ΔG0 (Met) - ΔG0(WT)). This ranged from +1.1 to –1.9 kcal/mol (average value – 0.4 kcal/mol) at 298 K and +0.7 to –2.6 kcal/mol (average value –1.1 kcal/mol) at the Tm of each WT. It therefore appears that the strength of cation-π interactions increases with temperature. In addition, the experimentally measured values are appreciably smaller in magnitude than the calculated values with an average difference |ΔG0expt -ΔG0calc|avg of 2.9 kcal/mol. At room temperature, the data indicate that cation-π interactions are at best weakly stabilizing and in some cases are clearly destabilizing. However at elevated temperatures, close to typical Tm’s, cation-π interactions are generally stabilizing. In Chapter 5, we have attempted to characterize molten globule states for the periplasmic proteins LBP, LIVBP, MBP and RBP. It was observed that all these proteins form molten globule states at acidic pH (3 - 3.4). All these molten globule states showed cooperative thermal transitions and bound with their ligand comparable to (LBP and LIVBP) or with lower (MBP and RBP) affinity than the corresponding native states. Trp, ANS fluorescence and near-UV CD spectra for ligand bound and free forms of molten globule states were found to be very similar. This shows that molten globule states of these proteins have the ability to bind to their corresponding ligand without conversion to the native state. All four molten globule states showed destabilization relative to the native state. ΔCp values indicate that these molten globule states contain approximately 29-67% of tertiary structure relative to the native state. All four proteins lack prosthetic groups and disulfide bonds. Therefore, it is likely that molten globule states of these proteins are stabilized via hydrophobic and hydrogen bonding interactions.

Proteins

Escherechia Coli

Leucine Binding Protein

Maltose Binding Protein

Ribose Binding Protein

Leucine Valine Binding Protein

Protein Folding

Protein Stability

Periplasmic Binding Protein

Thioredoxin (Trx)

Biochemistry