Biomolecular recognition mechanisms studied by NMR spectroscopy and MD simulations

This thesis describes the use of solution Nuclear Magnetic Resonance (NMR) spectroscopy and Molecular Dynamics (MD) simulations to study the mechanism of biomolecular recognition with two model systems: i) lipid II-binding lantibiotics (lanthionine-containing antibiotics) and ii) the human immunodeficiency virus 1 (HIV-1) envelope protein (Env), gp120, and its receptor molecule, CD4. The first system concerns a group of unique antimicrobial peptides, which make use of an hitherto unknown mechanism of attacking bacteria by targeting the Achilles¹ heel of bacteria, the cell wall precursor, lipid II. In the light of antibiotic resistance, understanding of this recognition mechanism may lead to novel antibiotics. The second system focuses on the initiation step of the HIV-1 viral entry wherein the engagement of gp120 and CD4 switches on a cascade of conformational changes that are necessary for the membrane fusion between the virus and the host cell. The biological contexts of both systems are important to human health and numerous functional studies on both systems have been well documented. Yet, because of the underlying dynamics and the intricate assembly process of higher order complexes, a detailed structural description is currently lacking in both systems. We therefore applied advanced NMR and MD techniques to unravel the structure and dynamics of these complexes with the hope to facilitate the development of new antibiotics and vaccines for infectious diseases, such as AIDS. As biological functions are manifested by interactions at a molecular level, understanding of structural properties of these biomolecules may consolidate related biomedical research

The Knotted Protein UCH-L1 Exhibits Partially Unfolded Forms under Native Conditions that Share Common Structural Features with Its Kinetic Folding Intermediates.

The human ubiquitin C-terminal hydrolase, UCH-L1, is an abundant neuronal deubiquitinase that is associated with Parkinson's disease. It contains a complex Gordian knot topology formed by the polypeptide chain alone. Using a combination of fluorescence-based kinetic measurements, we show that UCH-L1 has two distinct kinetic folding intermediates that are transiently populated on parallel pathways between the denatured and native states. NMR hydrogen-deuterium exchange (HDX) experiments indicate the presence of partially unfolded forms (PUFs) of UCH-L1 under native conditions. HDX measurements as a function of urea concentration were used to establish the structure of the PUFs and pulse-labelled HDX NMR was used to show that the PUFs and the folding intermediates are likely the same species. In both cases, a similar stable core encompassing most of the central β-sheet is highly structured and α-helix 3, which is partially formed, packs against it. In contrast to the stable β-sheet core, the peripheral α-helices display significant local fluctuations leading to rapid exchange. The results also suggest that the main difference between the two kinetic intermediates is structure and packing of α-helices 3 and 7 and the degree of structure in β-strand 5. Together, the fluorescence and NMR results establish that UCH-L1 neither folds through a continuum of pathways nor by a single discrete pathway. Its folding is complex, the β-sheet core forms early and is present in both intermediate states, and the rate-limiting step which is likely to involve the threading of the chain to form the 52-knot occurs late on the folding pathway.This work was supported by the National Science Council (99-2911-I-007-034 and 104-2113-M-001-016), National Tsing Hua University and Academia Sinica, Taiwan. S.-T.D.H. was supported by a Career Development Award (CDA- 00025/2010-C) from the International Human Frontier Science Program. The NMR spectra were obtained at the NMR facility of the Department of Chemistry, University of Cambridge and at the Core Facility for Protein Structural Analysis, supported by the National Core Facility Program for Biotechnology, Taiwan.This is the author accepted manuscript. The final version is available from Elsevier via http://dx.doi.org/10.1016/j.jmb.2016.04.00

Tying up the Loose Ends : A Mathematically Knotted Protein

Knots have attracted scientists in mathematics, physics, biology, and engineering. Long flexible thin strings easily knot and tangle as experienced in our daily life. Similarly, long polymer chains inevitably tend to get trapped into knots. Little is known about their formation or function in proteins despite >1,000 knotted proteins identified in nature. However, these protein knots are not mathematical knots with their backbone polypeptide chains because of their open termini, and the presence of a "knot" depends on the algorithm used to create path closure. Furthermore, it is generally not possible to control the topology of the unfolded states of proteins, therefore making it challenging to characterize functional and physicochemical properties of knotting in any polymer. Covalently linking the amino and carboxyl termini of the deeply trefoil-knotted YibK from Pseudomonas aeruginosa allowed us to create the truly backbone knotted protein by enzymatic peptide ligation. Moreover, we produced and investigated backbone cyclized YibK without any knotted structure. Thus, we could directly probe the effect of the backbone knot and the decrease in conformational entropy on protein folding. The backbone cyclization did not perturb the native structure and its cofactor binding affinity, but it substantially increased the thermal stability and reduced the aggregation propensity. The enhanced stability of a backbone knotted YibK could be mainly originated from an increased ruggedness of its free energy landscape and the destabilization of the denatured state by backbone cyclization with little contribution from a knot structure. Despite the heterogeneity in the side-chain compositions, the chemically unfolded cyclized YibK exhibited several macroscopic physico-chemical attributes that agree with theoretical predictions derived from polymer physics.Peer reviewe

A molten globule-to-ordered structure transition of Drosophila melanogaster crammer is required for its ability to inhibit cathepsin

Drosophila melanogaster crammer is a novel cathepsin inhibitor that is involved in LTM (long-term memory) formation. The mechanism by which the inhibitory activity is regulated remains unclear. In the present paper we have shown that the oligomeric state of crammer is pH dependent. At neutral pH, crammer is predominantly dimeric in vitro as a result of disulfide bond formation, and is monomeric at acidic pH. Our inhibition assay shows that monomeric crammer, not disulfide-bonded dimer, is a strong competitive inhibitor of cathepsin L. Crammer is a monomeric molten globule in acidic solution, a condition that is similar to the environment in the lysosome where crammer is probably located. Upon binding to cathepsin L, however, crammer undergoes a molten globule-to-ordered structural transition. Using high-resolution NMR spectroscopy, we have shown that a cysteine-to-serine point mutation at position 72 (C72S) renders crammer monomeric at pH 6.0 and that the structure of the C72S variant highly resembles that of wild-type crammer in complex with cathepsin L at pH 4.0. We have determined the first solution structure of propeptide-like protease inhibitor in its active form and examined in detail using a variety of spectroscopic methods the folding properties of crammer in order to delineate its biomolecular recognition of cathepsin

Local Cooperativity in an Amyloidogenic State of Human Lysozyme Observed at Atomic Resolution

The partial unfolding of human lysozyme underlies its conversion from the soluble state into amyloid fibrils observed in a fatal hereditary form of systemic amyloidosis. To understand the molecular origins of the disease, it is critical to characterize the structural and physicochemical properties of the amyloidogenic states of the protein. Here we provide a high-resolution view of the unfolding process at low pH for three different lysozyme variants, the wild-type protein and the mutants I56T and I59T, which show variable stabilities and propensities to aggregate in vitro. Using a range of biophysical techniques that includes differential scanning calorimetry and nuclear magnetic resonance spectroscopy, we demonstrate that thermal unfolding under amyloidogenic solution conditions involves a cooperative loss of native tertiary structure, followed by progressive unfolding of a compact, molten globule-like denatured state ensemble as the temperature is increased. The width of the temperature window over which the denatured ensemble progressively unfolds correlates with the relative amyloidogenicity and stability of these variants, and the region of lysozyme that unfolds first maps to that which forms the core of the amyloid fibrils formed under similar conditions. Together, these results present a coherent picture at atomic resolution of the initial events underlying amyloid formation by a globular protein

Folding dynamics and structural basis of the enzyme mechanism of ubiquitin C-terminal hydroylases

[[sponsorship]]生物化學研究所[[note]]出版中(accepted);有審查制度;具代表

Unraveling the Folding Mechanism of the Smallest Knotted Protein, MJ0366

Understanding the mechanism by which polypeptide chains thread themselves into topologically knotted structures has emerged to be a challenging subject not least because of the additional complexity associated with the spontaneous and efficient knotting and folding events. While recent theoretical calculations have made significant progress in establishing the atomistic folding pathways for a number of knotted proteins, experimental data on the folding stabilities and kinetic pathways of knotted proteins has been sparse. Using MJ0366 from <i>Methanocaldococcus jannaschii</i>, the smallest knotted protein known to date, as a model system, we set out to systematically investigate its folding equilibrium, kinetics, and internal dynamics under native and chemically denatured states. NMR hydrogen–deuterium exchange analysis indicates that the knotted region is the most stable structural element within the novel fold. Additionally, ¹⁵N spin relaxation analysis reveals the presence of residual structures in urea-denatured MJ0366. Despite the apparent two-state equilibrium unfolding behavior during chemical denaturation, the kinetic unfolding pathway of MJ0366 involves the dissociation of the homodimeric native state into a native-like monomeric intermediate followed by unfolding into a denatured state. Our results provide comprehensive structural information regarding the folding dynamics and kinetic pathways of MJ0366, whose small size is ideal for converging experimental and theoretical findings to better understand the underlying principles of the folding of knotted proteins