The Rational Investigation of Anti-Cancer Peptide Specificity using the Knob-Socket Model

Patel, Shivarni

01 January 2017

Cancer has been a pervasive and deadly problem for many years. No treatments have been developed that effectively destroy cancer cells while also keeping healthy cells safe. In this work, the knob-socket construct is used to analyze two systems involved in cancer pathways, the PDZ domain and the Bcl-BH3 complex. Application of the knob-socket model in mapping the packing surface topology (PST) allows a direct analysis of the residue groups important for peptide specificity and affinity in both of these systems. PDZ domains are regulatory proteins that bind the C-terminus of peptides involved in the signaling pathway of cancer progression. The domain includes five -strands, two -helices, and six coils/turns. In this study, the PST of all eight solved crystal structures of T-cell lymphoma invasion and metastasis 1 (Tiam1) PDZ domains are mapped to reveal details of ligand-domain binding pockets and packing interactions. Four main interactions were identified in the comparison of the PST maps and a consensus sequence was calculated using knob-socket interaction data. In the case of the Bcl-BH3 complex, binding of these two proteins prevents an unhealthy cell from undergoing apoptosis. In the knob-socket mapped protein-ligand interactions, the helical ligand consists of 8 to 10 residues that specifically interact with four helices on the binding protein: the N-terminus of Helix2, the main bodies of Helix3 and Helix4 and the C-terminus of Helix5. Among all of the interactions that were analyzed, there were three amino acids from the ligand, glycine, leucine, and isoleucine, that always packed into the hydrophobic groove that is key for ligand recognition. By using knob-socket analysis to map quaternary packing structure, it was possible to identify the quaternary-level protein interactions that define ligand specificity and binding strength. From this analysis, possible protein mimetics can be developed that could be used as cancer treatments.

Biochemistry

Bcl-2 Domain

Knob-Socket Model

PDZ Domain

Protein Folding

Chemistry

Pharmacy and Pharmaceutical Sciences

The Role of Phosducin-like Protein and the Cytosolic Chaperonin CCT in G beta gamma dimer Assembly

Hu, Ting

17 November 2005

Phosducin-like protein (PhLP), a G protein beta gamma subunit dimer binder and G protein signaling regulator, was suggested to regulate the activity of cytosolic chaperonin CCT by their high affinity interaction. In the present study, the three-dimensional structure of PhLP:CCT complex has been solved by cryoelectron microscopy. PhLP was found to bind only one of the chaperonin rings with both N- and C-terminal domains. It spans the central folding cavity of CCT and interacts with two opposite sides of the top apical region, inducing the constraining of the entry of the folding cavity. These findings support a putative role of PhLP as a co-chaperone similar to prefoldin. Docking studies with the atomic model of PhLP generated from several known structures of the homologous phosducin (Pdc) together with the immuno-EM studies have provided more details of the complex structure and predicted some regions of PhLP and the subunits of CCT involved in the interaction. Taking advantage of the fact that Pdc is highly homologous to PhLP but lack of binding to CCT, the regions of PhLP involved in the interaction with CCT were determined by testing various PhLP/Pdc chimeric proteins in the CCT binding assay. In the other part of this dissertation, the physiological role of PhLP in G protein signaling was investigated. Cellular expression of PhLP was blocked using RNA interference targeting PhLP. Together with overexpression of PhLP variants and kinetic studies of G protein beta gamma dimer formation, PhLP was determined to be a positive mediator of G protein signaling and essential for G protein beta gamma dimer expression and dimer formation. Phosphorylation of PhLP at serines 18—20 by protein kinase CK2 was required for G protein beta gamma dimer formation, while a high-affinity interaction of PhLP with CCT appeared unnecessary. Interestingly, G protein beta subunit was found to interact with CCT by co-immunoprecipitation and PhLP over-expression increased the binding of G protein beta subunit to CCT. These results suggest that PhLP and CCT act as co-chaperones in the folding and assembly of the G protein beta gamma subunit dimer by forming a ternary PhLP-Gbeta-CCT complex that is a necessary intermediate in the assembly process.

phosducin-like protein (PhLP)

electron microscopy

chaperonin

CK2 phosphorylation

G protein

protein folding

Biochemistry

Chemistry

The Unavoidable Threat of Aggregation: Implications for Folding and Function of a β-Rich Protein

Ferrolino, Mylene Hazelle Anne

01 May 2013

Protein aggregation has been implicated in several catastrophic diseases (neurodegeneration, diabetes, ALS) and its complexity has also become a major obstacle in large-scale production of protein-based therapeutics. Despite the generic behavior of proteins to aggregate, only a few globular proteins have known aggregation mechanisms. At present, there have been no clear connections between a protein folding, function and aggregation. We have tackled the challenge of understanding the links between a protein's natural tendency to fold and function with its propensity to misfold and aggregate. Using a predominantly beta-sheet protein whose in vitro folding has been explored in detail: cellular retinoic acid-binding protein I (CRABP 1), as a model, we investigated sequence determinants for folding and aggregation. In addition, we characterized the aggregation-prone intermediate under native conditions. Our studies revealed similar contiguous aggregation cores in in vitro and in vivo aggregates of CRABP 1 validating the importance of sequence information under extremely different conditions. Hydrophobic stretches that comprise the interface in aggregates include residues surrounding the ligand binding portal and residues at the C-terminal strands of CRABP 1. Folding studies reveal that docking of the N and C terminals happen in the early stages of barrel closure of CRABP 1 emphasizing the role of folding in preventing exposure of risky aggregation-prone sequences. We further examined the intermediate that initiates aggregation under native conditions. We found that inherent structural fluctuations in the native protein, relevant to ligand binding of CRABP 1, expose aggregation-prone sequences. Binding of the ligand, retinoic acid decreases the aggregation of CRABP 1 illustrating the contribution functional interactions in avoiding aggregation. Our study implies that because of the evolutionary requirement for proteins to fold and function, aggregation becomes an unavoidable risk.

beta protein

CRABP 1

protein aggregation

protein folding

Cell and Developmental Biology

Molecular Biology

Components of a Protein Machine: Allosteric Domain Assembly and a Disordered C-terminus Enable the Chaperone Functions of Hsp70

Smock, Robert G

01 September 2011

Hsp70 molecular chaperones protect proteins from aggregation, assist in their native structure formation, and regulate stress responses in the cell. A mechanistic understanding of Hsp70 function will be necessary to explain its physiological roles and guide the therapeutic modulation of various disease states. To this end, several fundamental features of the Hsp70 structure-function relationship are investigated. The central component of Hsp70 chaperone function is its capacity for allosteric signaling between structural domains and tunable binding of misfolded protein substrates. In order to identify a cooperative network of sites that mediates interdomain allostery within Hsp70, a mutational correlation analysis is performed using genetic data. Evolutionarily correlations that describe an allosteric network are validated by examining roles for implicated sites in cellular fitness and molecular function. In a second component of the Hsp70 molecular mechanism, a novel function is discovered for the disordered C-terminal tail. This region of the protein enhances the refolding efficiency of substrate proteins independently of interdomain allostery and is required in the cell upon depletion of compensatory chaperones, suggesting a previously undescribed mode of chaperone action. Finally, experiments are initiated to assess the dynamic assembly of Hsp70 domains in various allosteric states and how domain orientations may be guided through interaction with partner co-chaperone proteins.

Allostery

DnaK

Hsp70

Intrinsic disorder

Molecular chaperone

Protein folding

Cell Biology

The study of structural and mechanistic features of Hsp70/CHIP-driven protein quality control

Paththamperuma Arachchige Don, Jeral Chathura Madushanka P.

January 2023

No description available.

Biochemistry

Biophysics

Chemistry

Protein quality control

Chaperones

Hsp70

CHIP

Ubiquitination

Protein folding

Probing the biophysical interactions between autolysin proteins and polystyrene surfaces

Wadduwage, Radha Paramee

08 December 2023

Biofilms formed on medical devices pose significant challenges, compromising device efficiency and serving as sources of infection. Staphylococcus epidermidis, an opportunistic pathogen, relies on the autolysin protein, notably its R2ab and amidase domains, to attach to polystyrene surfaces and initiate biofilm formation. Despite their pivotal role, the structural intricacies of these proteins’ interactions with surfaces remain elusive. In this dissertation, the multifaceted aspects of protein interactions with polystyrene surfaces and the implications of these interactions for biofilm control are studied. Over the course of this study, it is found how the R2ab and amidase domains influence biofilm formation on polystyrene surfaces. Pretreatment of polystyrene plates with these domains effectively inhibits biofilm growth, underscoring their strong affinity for polystyrene surfaces. Furthermore, these domains demonstrate a remarkable propensity for interactions with polystyrene nanoparticles (PSNPs). The insights gained from this study offer promising avenues for the development of novel biofilm eradication strategies, with the potential to enhance the longevity and effectiveness of medical devices. Shifting to a broader context of nanotechnology, the influence of nanoparticle size on protein adsorption and unfolding stabilities is studied using two distinct proteins, R2ab and GB3. Isothermal titration calorimetry reveals tighter binding to smaller PSNPs for both proteins, with enthalpy as the driving force. Structural changes in the adsorbed proteins are detected through fluorescence spectroscopy and circular dichroism, indicating a propensity for protein unfolding upon adsorption. Importantly, this unfolding effect is less pronounced with larger PSNPs, which has implications for protein binding on macroscopic surfaces. The significance of side-on interactions between neighboring proteins is underscored in this work, since they appear to stabilize proteins bound to surfaces with low curvature, an observation with critical implications for the protein corona formed around nanoparticles and its potential to preserve the structure of surface-adsorbed proteins in vivo. This dissertation also investigates the molecular-level interaction between R2ab and PSNPs of varying sizes. By utilizing lysine methylation in mass spectrometry and hydrogen-deuterium exchange (HDX) NMR spectroscopy, this work investigates how changes in methylation patterns and hydrogen-deuterium exchange rates in specific regions of R2ab reflect conformational changes upon binding to PSNPs. In conclusion, this dissertation comprehensively explores protein-surface interactions and reveals several important and surprising features of the proteins that drive biofilm formation.

protein interactions

nanoparticles

biofilms

biophysics

protein folding

protein dynamics

Staphylococcus

polystyrene

Autolysin

Folding of the Prion Protein

Apetri, Constantin Adrian

31 March 2004

No description available.

Biophysics, Medical

protein folding

prion diseases

prion protein

folding intermediate

salt effect

kinetics

stopped flow

The Doublesex transcription factor: Structural and functional studies of a sex-determining factor

Bayrer, James Robert

January 2006

No description available.

Chemistry, Biochemistry

doublesex

dsx

UBA

ubiquitin

dimer

dimerization

protein folding

sex determination

Kinetics of Aβ Peptide Deposition: Toward <i>In Vivo</i> Imaging of Alzheimer’s Disease Amyloid

Marshall, Jeffrey Richard

21 May 2002

No description available.

Alzheimer's Disease

amyloidosis

protein folding disorders

diagnostic imaging

peptide structure activity

Elucidating Allosteric Mechanisms of the AAA+ ClpATPases Using Molecular Dynamics Simulations

Wang, Huan, Ph.D.

16 October 2015

No description available.

Physical Chemistry

protein quality control

AAA unfolding chaperone

protein folding

molecular dynamics