Structural Characterization and Interactions of the CFTR Regulatory Region

Baker, Jennifer May Reta

05 March 2010

The intrinsically disordered nonphosphorylated and phosphorylated R region of CFTR and its interactions with NBD1 and SLC26A3 STAS have been characterized at residue-specific resolution, primarily using NMR. Limited chemical shift dispersion indicates that the R region is intrinsically disordered in solution and that no global folding event occurs upon phosphorylation. Chemical shifts of backbone nuclei and sidechain carbons were assigned. SSP values indicate that phosphorylation acts as a structural switch, with a reduction in helical propensity in multiple nonphosphorylated R region segments. Free nonphosphorylated and phosphorylated R region were characterized using a variety of structural probes. Fast timescale motion indicates the presence of structural contacts in many R region segments. Hydrodynamic radii are intermediate to those expected for fully folded or denatured proteins, with the phosphorylated R region being slightly more compact. The nonphosphorylated R region was further characterized, including measurements of molecular dimensions, N-H bond vector orientation and inter-residue distances from 6 spin label sites. Using these parameters as input to the program ENSEMBLE enabled calculation of a representative pool of nonphosphorylated R region conformations, indicating the presence of transient contacts that could not be directly discerned from the input data. Examining labeled R region with the addition of unlabeled NBD1 provided evidence that multiple segments of nonphosphorylated R region bind and are released from NBD1 with varying affinities in a highly dynamic equilibrium. Phosphorylation relieves these interactions, with the exception of limited R region interactions near S768 when NBD1 is ATP-bound. Largely similar nonphosphorylated R region residues bind both ATP-bound ΔF508 and wild-type NBD1. Addition of unlabeled R region to labeled ATP-bound NBD1 caused spectral changes indicative of a direct interaction with more than one surface or conformational changes within NBD1 that are transmitted from one binding surface to other surface(s). Binding of unlabeled SLC26A3 STAS domain to labeled phosphorylated R region was also monitored and indicated that similar R region segments bind NBD1 and STAS, suggesting a direct competition between these two domains for binding. A model is proposed where the R region acts as a regulatory hub, integrating interactions with a variety of partners to regulate channel function.

disordered proteins

CFTR

0487

The Structure, Evolution, and Assembly Mechanism of the Bacteriophage Tail Tube

Pell, Lisa

01 September 2010

Large multi-component structures play an essential role in many crucial cellular processes. The morphogenetic pathway of the long, non-contractile tail of bacteriophage λ provides a superb paradigm for studying the assembly of macromolecular complexes. This thesis describes the structural and functional characterization of two λ tail proteins, gpU and gpV, with the aim of improving our understanding of phage tail assembly and evolution, while also providing a starting point to answering some of the fundamental questions surrounding the assembly and function of other supramolecular structures. Tail Terminator Proteins (TrPs) play an essential role in regulating the length of phage tails, and serve as the interaction surface for phage heads. To provide insight into the mechanisms by which TrPs exert their functions, I have determined the X-ray crystal structure of gpU, the TrP from phage λ, in its biologically relevant hexameric state. The gpU hexamer displays several flexible loops that are involved in head and tail binding. By comparing the hexameric crystal structure of gpU to its previously determined NMR solution structure I was able to identify large structural rearrangements in the protein, which are likely induced upon oligomerization. In addition, I have shown that the hexameric structure of gpU is very similar to the structure of a putative TrP from a contractile phage tail even though they display no detectable sequence similarity. This finding implies that the TrPs of non-contractile tailed phages are evolutionarily related to those of contractile-tailed phages. To determine the mechanism by which tail tubes self-assemble prior to termination, I have determined the NMR solution structure of the N-terminal domain of gpV (gpVN), the protein comprising the major portion of the phage λ tail tube. I found that approximately 30% of gpVN is disordered in solution and that some of these disordered regions are biologically important. Intriguingly, my gpVN structure is very similar to a previously solved tail tube protein from a contractile-tailed phage, once again suggesting an evolutionary connection between these two distinct tail types. A remarkable structural similarity is also seen to the hexameric structure of Hcp1, a component of the bacterial type VI secretion system. This finding, coupled with other similarities between phage and type VI secretion proteins support an evolutionary relationship between these systems. Using Hcp1 as a model, I proposed a mechanism for the oligomerization and polymerization of gpV involving several disorder-to-order transitions. Further supporting the importance of unstructured regions, I have shown that the unstructured linker between the N- and C-terminal domains of gpV is crucial for protein function and that a complete truncation of the C-terminal domain (gpVC) results in a 100-fold decrease in activity compared to full-length gpV (gpVFL). To provide insight into the role of gpVC, I determined its NMR solution structure and showed that it possesses an Ig-like fold, however the function of gpVC remains unknown. Interestingly, the gpVC structure revealed the location of two residues that when mutated were previously shown to either abrogate (G222D) or restore (G222D/P227L) function of gpVFL. In addition to being inactive, I demonstrated that the G222D mutation also exerts a temperature dependent dominant negative phenotype. My preliminary NMR data suggests that G222D causes gpVC to partially unfold and that this destabilized form of the domain interacts with gpVN in a region that is likely involved in both oligomerization and hexamer-hexamer interactions. To further our understanding of how these mutations exert their effect, I determined the NMR solution structure of gpVC-P227L. My structure reveals that the β7-β8 region of gpVC-P227L is altered compared to gpVC-WT and suggests that the conformational changes in gpVC-P227L may protect the domain from protein-folding defects induced by the G222D mutation.

Structure

Virus

0487

Structural and Functional Characterization of Leukocyte-type Core 2 {beta}1,6-N-acetylglucosaminyltransferase

Pak, John

18 January 2012

Leukocyte type core 2 {beta}1,6-N-acetylglucosaminyltransferase (C2GnT-L) is a key enzyme in the biosynthesis of branched O-glycans. It is an inverting, metal ion-independent glycosyltransferase that catalyzes the formation of the core 2 O-glycan (Gal{beta}1,3[GlcNAc{beta}1,6]GalNAc-O-Ser/Thr) from its donor and acceptor substrates, UDP-GlcNAc and the core 1 O-glycan (Gal{beta}1,3GalNAc-O-Ser/Thr), respectively. The primary objective of the work described in this thesis is to shed light on the structure, catalytic mechanism and substrate specificity of C2GnT-L. Since glycosyltransferases are membrane bound glycoproteins that possess disulphide bonds, the first challenge was to produce sufficient quantities of C2GnT-L for biochemical and structural characterization. To this end, C2GnT-L and various active site mutants were expressed and purified from stably transformed mammalian cell lines. The x-ray crystal structure of wild-type C2GnT-L was solved, in both its apo and acceptor substrate complexed forms. The structures, along with revealing the structural basis for acceptor substrate specificity, showed that C2GnT-L belongs to the GT-A glycosyltransferase fold type. This was a surprising result given that, to this day, C2GnT-L is the only GT-A glycosyltransferase that does not possess a DXD motif and does not require a divalent metal ion for catalysis. The mechanism of the metal ion-independent C2GnT-L activity, within the context of the metal ion-dependent GT-A fold, was probed further using site directed mutagenesis in conjuncition with x-ray crystallography, enzyme assays, and frontal affinity chromatography. It was found that positively charged side chains in C2GnT-L functionally replace the divalent metal ion found in other GT-A glycosyltransferases, providing evidence for a convergence of metal ion-independent activity between GT-A and GT-B glycosyltransferase fold types.

glycosyltransferase

crystallography

C2GnT

0487

Characterization of the Role of Elg1-RFC in Suppression of Genome Instability

Davidson, Marta

14 February 2011

Sliding clamps and their cognate clamp loaders facilitate DNA synthesis, DNA repair, and sister chromatid cohesion in eukaryotes. ELG1 (enhanced level of genome instability) encodes a member of the fourth clamp-loader-like complex identified to date, and is important in the maintenance of genome integrity. Like all clamp loaders, Elg1 is a replication factor C (RFC) homologue. I examined the roles of the unique and conserved regions of S.cerevisiae Elg1 in resistance to exogenous DNA damage and suppression of spontaneous DNA damage. The conserved RFC region of Elg1 mediates association with chromatin function. The unique C- terminus of Elg1 mediates oligomerization with Rfc2-5, a core complex present in all clamp loaders, and is essential for Elg1 function. Finally, the N-terminus of Elg1 promotes its nuclear localization and contributes to the maintenance of genome stability. The Elg1-RFC complex most likely functions in collaboration with the sliding clamp PCNA. Combining mutations in ELG1 and PCNA results in endogenous DNA damage, which activates a noncanonical DNA damage response that results in upregulation of dNTP production. Increased dNTP pools allow significant DNA synthesis to occur at hydroxyurea (HU) concentrations that prevent replication in wild type cells. However, consistent with the recognized correlation between dNTP levels and spontaneous mutation, the double mutant exhibits a significant increase in mutation frequency. These phenotypes are also detectable in the single mutants although to a lesser extent. Together, these findings suggest that spontaneous mutagenesis stimulated by endogenous DNA damage may be a general feature of the DNA damage response.

Biochemistry

Molecular Biology

0487

Biomimetic Aminoacylation: Investigating Detection of Acylation and the Effect of α-Amino Protection

Andrusiak, Tara

15 December 2009

Direct synthesis of aminoacyl-tRNA occurs using α-N-tBoc-protected aminoacyl phosphates and lanthanum salts. Deprotection of aminoacyl tRNA is essential prior to translation; however, the conditions of tBoc deprotection causes tRNA degradation. It was found that α-N-pentenoyl-protected aminoacyl phosphates, deprotected under mild conditions, are effectively used in lanthanum-mediated acylation of tRNA analogs. This provides an alternative route for aminoacyl-tRNA synthesis that maintains tRNA structure. Also, it was determined that α-N-deprotection of aminoacyl phosphates prior to aminoacylation still produces aminoacylated tRNA analogs. This establishes that acyl phosphates activate amino acids without inducing self-condensation, presumably due to electrostatic repulsion. Direct quantification of lanthanum-mediated tRNA aminoacylation was additionally undertaken utilizing a radiolabelled tRNA assay. From this, it was shown that lanthanum-mediated acylation does not promote deacylation and degradation of tRNA. These results have provided insight into lanthanum-mediated acylation of tRNA, ultimately allowing for use of the reagent in ribosomal translation.

aminoacylation

tRNA

0487

Characterization of the Mobility of FcγRIIa in Primary Human Macrophages

Farkash, Yoav

26 July 2010

Fcγ receptor-mediated phagocytosis is an active process requiring receptor clustering as a signal initiation event. The mechanisms controlling Fcγ receptor clustering are unknown, as are the parameters governing the receptor lateral mobility in the plasma membrane. This work investigated the lateral mobility of Fcγ receptor IIa in resting primary human macrophages using single-molecule tracking methodology. In the absence of ligands, the receptor was found to exist mostly as a monomeric species. Detailed receptor dynamics revealed the existence of two receptor populations: one that was mobile, the other confined. The actin cytoskeleton was shown to be important for receptor confinement but did not affect receptor diffusion. Such findings are important in understanding the mechanisms for receptor clustering and signal initiation in phagocytosis.

Cell biology

Biochemistry

0487

Biochemical Investigation of the Bacteriophage Protein HK97 gp74

Moodley, Serisha

12 January 2011

Bacteriophages are viruses that infect and propagate within bacteria by making use of the host’s biosynthetic machinery. With a global population of 1031, phages pose a significant influence on microbial populations. Studies of bacteriophage proteins can elucidate the influence that bacteriophages play on the evolution of bacteria, as well as, providing the basis for the use of phage proteins as possible therapeutics and bioengineering solutions. This study aims to investigate the structural and functional role of the HK97 phage protein gp74. Sequence alignments indicate that gp74 is related to homing HNH endonucleases. Homing endonucleases are predominantly double-stranded DNases, suggesting that gp74 mediates integration of phage genes into the host genome or may target foreign phage DNA. DNA digestion experiments with gp74 reveals that gp74 mediates non-specific double-stranded cleavage of lambda phage DNA and single strand cleavage of plasmid DNA. Our initial work demonstrates that HK97 gp74 is an HNH endonuclease.

Bacteriophage

HK97 gp74

0487

Interactions of Cationic Antimicrobial Peptides with Bacterial Membranes and Biofilms

Yin, Lois Menglu

27 November 2012

Cationic antimicrobial peptides (CAPs) offer a viable alternative to conventional antibiotics as they physically disrupt the bacterial membranes, leading to cell lysis and death. However, colonized bacteria often form “biofilms” – characterized by the overproduction of exopolysaccharides - that restrict the penetration of antibiotics; successful antimicrobial agents must evade this exopolysaccharide ‘matrix’ to reach the bacterial membrane. Since the Pseudomonas aeruginosa biofilm alginate traps CAPs by forming peptide-alginate complexes, the aim of this thesis is to better understand the mechanisms of interaction of CAPs with bacterial membranes and biofilm alginate. Using a series of CAPs designed in our lab derived from the sequence KKKKKK-AAFAAWAAFAA-NH2, we found that hydrophobicity, charge distribution, and amino acid composition of CAPs play important roles in their membrane disruptive power, bioactivities, alginate-binding and alginate-diffusion abilities. These findings suggest routes to an optimal balance of factors in CAP design to allow both biofilm penetration and bacterial membrane destruction.

antimicrobial peptides

biofilms

0487

Characterization of the Mobility of FcγRIIa in Primary Human Macrophages

Farkash, Yoav

26 July 2010

Fcγ receptor-mediated phagocytosis is an active process requiring receptor clustering as a signal initiation event. The mechanisms controlling Fcγ receptor clustering are unknown, as are the parameters governing the receptor lateral mobility in the plasma membrane. This work investigated the lateral mobility of Fcγ receptor IIa in resting primary human macrophages using single-molecule tracking methodology. In the absence of ligands, the receptor was found to exist mostly as a monomeric species. Detailed receptor dynamics revealed the existence of two receptor populations: one that was mobile, the other confined. The actin cytoskeleton was shown to be important for receptor confinement but did not affect receptor diffusion. Such findings are important in understanding the mechanisms for receptor clustering and signal initiation in phagocytosis.

Cell biology

Biochemistry

0487

Biochemical Investigation of the Bacteriophage Protein HK97 gp74

Moodley, Serisha

12 January 2011

Bacteriophages are viruses that infect and propagate within bacteria by making use of the host’s biosynthetic machinery. With a global population of 1031, phages pose a significant influence on microbial populations. Studies of bacteriophage proteins can elucidate the influence that bacteriophages play on the evolution of bacteria, as well as, providing the basis for the use of phage proteins as possible therapeutics and bioengineering solutions. This study aims to investigate the structural and functional role of the HK97 phage protein gp74. Sequence alignments indicate that gp74 is related to homing HNH endonucleases. Homing endonucleases are predominantly double-stranded DNases, suggesting that gp74 mediates integration of phage genes into the host genome or may target foreign phage DNA. DNA digestion experiments with gp74 reveals that gp74 mediates non-specific double-stranded cleavage of lambda phage DNA and single strand cleavage of plasmid DNA. Our initial work demonstrates that HK97 gp74 is an HNH endonuclease.

Bacteriophage

HK97 gp74

0487