Studies On Sesbania Mosaic Virus Asssembly And Structure And Function Of A Survival Protein (SurE) From Salmonella Typhimurium

Pappachan, Anju

05 1900

X-ray crystallography is a powerful method for determining the three-dimensional structures of biological macromolecules at atomic resolution. Crystallography can reliably provide the answer to many structure related questions, from global folds to atomic details of bonding. Crystallographic techniques find wide applications in understanding macromolecular assembly, enzyme mechanism, mode of activation of enzymes, substrate-specificity, ligand-binding properties, domain movement etc. The knowledge of accurate molecular structures is also a prerequisite for rational drug design and for structure based functional studies to aid the development of effective therapeutic agents. The current thesis can be broadly divided into two major parts. The first four chapters deal with assembly studies that have been carried out on Sesbania mosaic virus and the next two chapters describe the structure and function of a stationary phase survival protein, SurE from Salmonella typhimurium. In both studies X-ray crystallographic techniques have been used extensively for the structural studies. Viruses are obligate parasites with a proteinaceous capsid enclosing the genetic material. For genetic economy, several copies of capsid proteins self assemble to form complex virus capsids. Due to their intricate symmetric structures, viruses are considered as minute marvels of molecular architecture and study of virus structures serve as a paradigm for solutions to problems concerning macromolecular assembly and function in general. Crystallography provides a means of visualizing intact virus particles as well as their isolated constituent proteins and enzymes at near-atomic resolution, and is thus an extraordinarily powerful tool for understanding the function of these biological systems. Protein-protein interactions, protein-nucleic acid interactions, metal-ion mediated interactions, interactions between capsid proteins and auxillary or scaffolding proteins and particle maturation or post processing of capsid protein subunits are various elements that play a role in capsid assembly. Many structural and sequential motifs have been proposed as important conformational switches of capsid assembly. A functional analysis of these motifs by way of mutations in the capsid protein and structural studies of these mutants can provide further insight into capsid assembly pathways. Interaction between capsid protein subunits can determine the size and robustness of the capsid. Analysis of protein-protein interactions can help in understanding the principles of self-assembly. Arresting capsid assembly by disrupting intersubunit interactions and trapping the assembly intermediates will be helpful to delineate the changes that happen in capsid protein during the course of assembly and understand assembly pathways. Sesbania mosaic virus (SeMV) is a plant virus with a positive sense single-stranded RNA genome and belongs to the Sobemovirus genus. The protein and nucleic acids of SeMV can be separated and reassembled in vitro. Also, expression of the coat protein (CP) gene of SeMV in E. coli leads to the formation of virus like particles (VLPs). Therefore, SeMV is an excellent model system to study the assembly pathways that lead to the formation of complex virus shells. Earlier structural and functional studies on the native virus and the recombinant capsid protein and its various mutants have revealed the following: SeMV is a T=3 virus with chemically identical A-, B- and C-subunits occupying quasi equivalent positions in the icosahedral asymmetric unit of the virus particle. The A-type subunits form pentamers at the five-fold, and the B- and C- type subunits form hexamers at the icosahedral three-fold axes. The amino terminus of the polypeptide is ordered from residue 72 in the A- and B- subunits whereas it is ordered from residue 44 in the C-subunit. The disordered segment in all the subunits has an arginine rich motif (N-ARM). The segment ordered only in C-subunits has a -annulus structure that promotes intersubunit interactions at the quasi six-fold and a -segment (A). The virus is stabilized by protein-protein, protein–RNA and Ca2+ mediated protein-protein interactions. Virus like particles (VLPs) formed by the expression of full length CP encapsidate 23 S E. coli rRNA and CP mRNA. Expression of a deletion mutant lacking the N-terminal 65 residues (rCP∆N65) which results in the removal of the N-ARM, the -annulus and the A leads to the formation of stable T=1 particles. The -annulus, which was earlier believed to be an important molecular switch controlling the assembly of T=3 VLPs was found to be dispensable. The N-ARM, though important for RNA encapsidation, was not essential for capsid assembly . Depletion of Ca2+ ions led to slight swelling of virus particles and significantly reduced stability. Extensive studies on the VLPs suggested that the assembly is most likely initiated by the dimers of the capsid protein. Following a brief account of the historical highlights in the field of structural virology, a review of current literature on the available crystal structures of viruses and various assembly studies on viruses that have been carried out with emphasis on role of nucleic acid mediated interactions, protein-protein interactions and role of specific residues and ion-mediated interactions in assembly are presented in Chapter I of the thesis. A separate section in this chapter deals with the disassembly experiments that have led to the formation of smaller oligomers of spherical viruses. This chapter also gives an account of the earlier work that has been carried out on SeMV, which is the model system of study for the present thesis. Chapter II describes in detail the structural studies on the β-annulus deletion mutant of SeMV. A unique feature of several T = 3 icosahedral viruses is the presence of a structure called the β-annulus formed by extensive hydrogen bonding between protein subunits related by icosahedral three-fold axis of symmetry. This unique structure has been suggested as a molecular switch that determines the T = 3 capsid assembly. In order to examine the importance of the β-annulus, a deletion mutant of Sesbania mosaic virus coat protein in which residues 48–59 involved in the formation of the β-annulus were deleted retaining the rest of the residues in the amino terminal segment (rCP (Δ48–59)) was constructed. When expressed in Escherichia coli, the mutant protein assembled into virus like particles of size close to that of the wild type virus particles. The purified capsids were crystallized and their three dimensional structure was determined at 3.6Å resolution by X-ray crystallography. The mutant capsid structure closely resembled that of the native virus particles. However, surprisingly, the structure revealed that the assembly of the particles has proceeded without the formation of the β-annulus. Therefore, the β-annulus is not essential for T = 3 capsid assembly as speculated earlier and may be formed as a consequence of the particle assembly. This is the first structural demonstration that the virus particle morphology with and without the β-annulus could be closely similar. Chapter III begins with a detailed description of the interfacial residue mutations that have been carried out in SeMV with the aim of disrupting assembly and trapping an assembly intermediate. These mutations were performed in rCP as well as rCP∆N65 gene. Among these, a single point mutation of a Trp 170 to a charged residue (either Glu or Lys) arrested virus assembly and resulted in stable dimers of the capsid protein. The chapter also gives an account of the biophysical characterization of these mutants. rCP∆N65 dimer mutants showed a characteristic 230 nm peak in CD spectral studies which may be due to the interactions of a stretch of aromatic residues in the capsid protein. The isolated dimers were more susceptible to trypsin cleavage compared to the assembled capsids due to the exposed basic amino terminus. Thermal melting studies showed that the isolated dimer mutants were much less stable when compared to the assembled capsids, probably due to the loss of intersubunit interactions and Ca2+ mediated interactions. The structure of one of the isolated dimer mutant- rCP∆N65W170K was solved to a resolution of 2.65Å. Chapter IV describes the crystal structure analysis of the rCP∆N65W170K mutant dimer and compares its structure with the dimers of native virus, T=3 and T=1 VLPs. A number of structural changes occur especially in the loop and interfacial regions during the course of assembly. The dimer in solution was “more relaxed” than the dimer that initiates assembly. Ca2+ ion is not bound and consequently the C-terminal residues are disordered. The FG loop, which interacts with RNA, was found to be flexible and adopts a different conformation in the unassembled dimer. The present thesis also deals with the structural and functional studies of a phosphatase, SurE, the stationary phase survival protein from Salmonella typhimurium. Chapter V provides a general introduction on Salmonella, which is a mesophilic food borne pathogen, its general features, classification and stress responses. This chapter also gives an account of stationary phase in bacteria and stress responses. A brief description about phosphatases and their classification is also presented in this chapter. Following this, a review of the current literature on the structural, biochemical and functional role of stress related proteins and phylogenetic and enzymatic studies of various homologues of SurE are described in detail. Chapter VI deals with the detailed crystal structure analysis of SurE, the first stationary phase survival protein from a mesophilic organism. SurE, of Salmonella typhimurium forms part of a stress survival operon regulated by the stationary phase RNA polymerase alternative sigma factor. SurE is known to improve bacterial viability during stress conditions. It functions as a phosphatase specific to nucleoside monophosphates. Here we report the X-ray crystal structure of SurE from Salmonella typhimurium (St SurE). The protein crystallized in two forms- orthorhombic F222 and monoclinic C2. The two structures were determined to resolutions of 1.7Å and 2.7Å, respectively. The protein exists as a domain swapped dimer. The residue Asp 230 is involved in several interactions that are probably crucial for domain swapping. A divalent metal ion is found at the active site of the enzyme, which is consistent with the divalent metal-ion dependent activity of the enzyme. Interactions of the conserved DD motif present at the N-terminus with the phosphate and the Mg2+ present in the active site suggest that these residues play an important role in enzyme activity. The divalent metal ion specificity and the kinetic constants of SurE were determined using the generic phosphatase substrate- para- Nitro Phenyl Phosphate. The enzyme was inactive in the absence of divalent cations and was most active in the presence of Mg2+. Thermal denaturation studies showed that St SurE is much less stable compared to its homologues and an attempt was made to understand the molecular basis of the lower thermal stability based on solvation free energy. The thesis concludes with a brief summary of the entire work that have been presented and future prospects. The various crystallographic, biochemical and biophysical techniques employed in the investigations are described under the section experimental techniques in Appendix I and the NCS matrices used in the structure solution of the β-annulus deletion mutant are listed in Appendix II.

Protein

Sesbania Mosaic Virus

Salmonella Typhimurium

Survival Protein E (SurE)

Phosphatases

Viruses - Proteins

Virus Crystallography

Virus Mutation

β-annulus

Molecular Biology

Structural Studies on SeMV Chimeras and TSV : Insights into Capsid Assembly

Gulati, Ashutosh

January 2015

Assembly of virus capsid protein (CP) into icosahedrally symmetric particles is an intriguing and elegant process. In most cases of virus assembly, a large number of identical protein subunits self-assemble to generate a shell that protects the viral genome. Studies on virus assembly have resulted in a new scientific technique that uses these proteinaceous shells as nano-particles for a variety of biological applications. The current thesis deals with understanding the factors that govern the assembly of the Sesbania mosaic virus (SeMV) and a pleomorphic virus, Tobacco streak virus (TSV). CP of SeMV, a T=3 plant virus, consists of a disordered N-terminal R-domain and an ordered S-domain. The importance of the R-domain in the assembly was probed by replacement with polypeptides such as the B-domain of Staphylococcus aureus protein A and polypeptides P10 and P8 of SeMV. These chimera assembled into T=3 or larger virus like particles (VLPs). Addition of divalent cations resulted in the formation of heterogeneous nucleoprotein complexes that disappeared upon treatment with EDTA/RNAse. One of the chimeras (N∆65-B) purified in a dimeric form by affinity chromatography assembled into T=1 VLPs during crystallization. The three dimensional structure of these VLPs showed that they were devoid of divalent ions and the B-domain was disordered. These studies demonstrate the importance of N-terminal residues, metal ions in virus assembly and robustness of the assembly process. Also, the B-domain was functional in N∆65-B VLPs, suggesting possible biotechnological applications. Tobacco streak virus (TSV) is a polymorphic virus and a major plant pathogen. TSV capsids encapsidate the tri-partite ss-RNA genome of the virus in three spheroidal particles of diameters 27, 30 and 33 nm, respectively. CPs of ilarviruses are also involved in genome activation. The labile nature of ilarviruses has posed difficulties in their structure determination. This thesis describes the first crystal structure of truncated TSV-CP. The core of TSV CP conforms to the canonical β-barrel jelly roll tertiary structure found in other viral coat proteins. Dimers of CP with swapped C-terminal arms (C-arm) were observed in the two crystal structures determined. The C-arm was found to be flexible and responsible for the polymorphic and pleomorphic nature of TSV capsids. Mutations in the hinge region of the C-arm that reduce the flexibility resulted in the formation of more uniform particles. TSV CP was also found to be structurally similar to that of Alfalfa mosaic virus (AMV) accounting for similar mechanism of genome activation in alfamo and ilar viruses.

Sesbania Mosaic Virus Chimeras

Tobacco Streak Virus Coat Protein

Chimeric SeMV

Plant Virus Assembly

Sobemovirus

Bromoviridae

SeMV Chimeras

Molecular Biophysics

X-ray Diffraction Studies On The Coat Protein Mutants Of Sesbania Mosaic Virus

Sangita, V

05 1900

No description available.

Viruses - Proteins

X-ray Diffraction

Sesbania Mosaic Virus (SeMV)

T=3 capsids

T=I capsid

Capsid Architecture

Capsid Structure

Molecular Biology

Structural Studies on the Role of Hinge involved in Domain Swapping in Salmonella Typhimurium Stationary Phase Survival Protein (SurE) and Sesbania Mosaic Virus Coat Protein

Yamuna Kalyani, M

January 2014

A unique mechanism of protein oligomerization is domain swapping. It is a feature found in some proteins wherein a dimer or a higher oligomer is formed by the exchange of identical structural segments between protomers. Domain swapping is thought to have played a key role in the evolution of stable oligomeric proteins and in oligomerization of amyloid proteins. This thesis deals with studies to understand the significance of hinges involved in domain swapping for protein oligomerization and function. The stationary phase survival protein SurE from Salmonella typhimurium (StSurE) and Sesbania mosaic virus (SeMV) coat protein have been used as models for studies on domain swapping. This thesis has been divided into eight chapters. Chapter 1 provides a brief introduction to domain swapping, while Chapters 2 to 6 describes the studies carried out on StSurE protein, Chapter 7 deals with studies on SeMV coat protein. The final Chapter 8 provides brief descriptions of various experimental techniques employed during these investigations. Chapter 1 deals with a brief introduction to domain swapping in proteins. Examples where different domains are exchanged are cited. Then it describes physiological relevance of domain swapping in proteins and probable factors which promote swapping. Finally it also discusses the uncertainties that are inevitable in protein structure prediction and design. Chapter 2 describes the structure of Salmonella typhimurium SurE (StSurE; Pappachan et al., 2008) determined at a higher resolution. The chapter also deals with the sequence and structure based comparison of StSurE with other known SurE homolog structures. A comparative analysis of the relative conservation of N- and C-terminal halves of SurE protomer and variations observed in the quaternary structures of SurE homologs are presented. Then a brief introduction is provided on function of StSurE. The conserved active site of StSurE that might be important for its phosphatase activity is described. A plausible mechanism for the phosphatase activity as proposed by Pappachan et al. (2008) is presented. Crystal structures of StSurE bound with AMP, pNPP and pNP that was determined with the view of better understanding the mechanism of enzyme function is presented. These structures provide structural evidence for the mechanism proposed by Pappachan et al. (2008). Finally a substrate entry channel inferred from these structures is discussed. SurE from Salmonella typhimurium (StSurE) was selected for studies on domain swapping as there is at least one homologous structure (Pyrobaculum aerophilum - PaSurE) in which swapping of the C-terminal helices appears to have been avoided without leading to the loss of oligomeric structure or function. It was of interest to examine if an unswapped dimer of StSurE resembling PaSurE dimer could be constructed by mutagenesis. To achieve this objective, a crucial hydrogen bond in the hinge involved in C-terminal helix swapping was abolished by mutagenesis. These mutants were constructed with the intention of increasing the flexibility of the hinge which might bring the C-terminal helices closer to the respective protomer as in PaSurE. Chapter 3 presents a comparative analysis of the hinges involved in C-terminal helix swapping in PaSurE and StSurE. Based on the comparison of structure and sequence, crucial residues important for C-terminal helix swapping in StSurE were identified as D230 and H234. The chapter describes the construction of mutants obtained by substituting D230 and H234 by alanine and their biophysical characterization. Finally it describes structural studies carried out on these mutants. The mutation H234A and D230A/H234A resulted in highly distorted dimers, although helix swapping was not avoided. Comparative analysis of the X-ray crystal structures of native StSurE and mutants H234A and D230A/H234A reveal large structural changes in the mutants relative to the native structure. However the crystal structures do not provide information on the changes in dynamics of the protein resulting from these mutations. To gain better insights into the dynamics involved in the native and mutants H234A and D230A/H234A, MD simulations were carried on using GROMACS 4.0.7. Chapter 4 deals with a brief description of the theory of molecular dynamics, followed by results of simulation studies carried out on monomeric and dimeric forms of StSurE and dimeric forms of its mutants H234A and D230A/H234A. The conformational changes and dynamics of different swapped segments are discussed. Crystal structures of H234A and D230A/H234A mutants reveal that they form highly distorted dimers with altered dimeric interfaces. Chapter 5 focuses on comparison of dimeric interfaces of the native StSurE and hinge mutants H234A and D230A/H234A. Based on the analysis, three sets of interactions were selected to investigate the importance of the interface formed by swapped segments in StSurE mutants H234A and D230A/H234A. One of the selected sites corresponds to a novel interaction involving tetramerization loop in the hinge mutants H234A and D230A/H234A resulting in a salt bridge between E112 – R179’ and E112’ – H180 (prime denotes residue from the other chain of the dimeric protein). This salt bridge seems to stabilize the distorted dimer. It is shown by structural studies that the loss of this salt bridge due to targeted mutation restores symmetry and dimeric organization of the mutants. Loss of a crucial hydrogen bond in the hinge region involved in C-terminal helix swapping in SurE not only leads to large structural changes but also alters the conformation of a loop near the active site. It is of interest to understand functional consequences of these structural changes. StSurE is a phosphatase, and its activity could be conveniently monitored using the synthetic substrate para nitrophenyl phosphate (pNPP) at pH 7 and 25 ºC. Chapter 6 deals with the functional studies carried out with various StSurE mutants. The studies suggest that there is a drastic loss in phosphatase activity in hinge mutants D230A, H234A and D230A/H234A, while in the salt bridge mutants the function seems to have been restored. Few of these mutants also exhibit positive cooperativity, which could probably be due to altered dynamics of domains. Sesbania mosaic virus (SeMV) is a plant virus, belonging to genus sobemovirus. SeMV is a T=3 icosahedral virus (532 symmetry) made up of 180 coat protein (CP) subunits enclosing a positive-sense RNA genome. The asymmetric unit of the icosahedral capsid is composed of chemically identical A, B and C subunits occupying quasi-equivalent environments. Residues 48 – 59 of the N-terminal arms of the C subunits interact at the nearby icosahedral three-fold axes through a network of hydrogen bonds to form a structure called the “β-annulus”. Residues 60 – 73 form the “βA-arm” that connects the N-terminal β-annulus to the rest of the protomer. Various studies on SeMV-CP suggest that different lengths of the N-terminal segments affect the assembly of virus. It might be possible to exploit this flexibility of the N-terminus in SeMV-CP to introduce swapping of this segment between two 2-fold related C subunits as is found in Rice yellow mottle virus (RYMV), another sobemovirus, with which SeMV shares significant sequence similarity. Chapter 7 focuses on attempts made to examine the mutational effects planned to introduce domain swapping. The strategy used for introducing swapping in SeMV-CP was based on the sequence of the βA-arm or the hinge involved in swapping of β-annulus in RYMV. TEM images of the mutant virus like particles obtained suggest that they are heterogeneous. These mutants could not be crystallized, probably due to the heterogeneity. However, the assembly of the expressed proteins to virus like particles was profoundly influenced by the mutations. Chapter 8 discusses various crystallographic, biophysical and biochemical techniques used during these investigations. Finally the thesis concludes with Conclusions and Future perspectives of the various studies reported in the thesis. In summary, I have addressed the importance of amino acid residues and interactions of hinges involved in domain swapping for the quaternary structure and function of proteins.

Protein Oligomerization

Domain Swapping

C-Terminal Helix Swapping

Protein X-ray Crystallography

Bacterial Protein Structure

Molecular Dynamics Simulations

Bacterial Proteins

H234A

Sesbania Mosaic Virus Coat Protein

Molecular Biophysics