pH dependent unfolding characteristics of DLC8 dimer: Residue level details from NMR.

Environment dependence of folding and unfolding of a protein is central to its function. In the same vein, knowledge of pH dependence of stability and folding/unfolding is crucial for many biophysical equilibrium and kinetic studies designed to understand protein folding mechanisms. In the present study we investigated the guanidine induced unfolding transition of dynein light chain protein (DLC8), a cargo adaptor of the dynein complex in the pH range 7-10. It is observed that while the protein remains a dimer in the entire pH range, its stability is somewhat reduced at alkaline pH. Global unfolding features monitored using fluorescence spectroscopy revealed that the unfolding transition of DLC8 at pH 7 is best described by a three-state model, whereas, that at pH 10 is best described by a two-state model. Chemical shift perturbations due to pH change provided insights into the corresponding residue level structural perturbations in the DLC8 dimer. Likewise, backbone (15)N relaxation measurements threw light on the corresponding motional changes in the dimeric protein. These observations have been rationalized on the basis of expected changes with increasing pH in the protonation states of the titratable residues on the structure of the protein. These, in turn provide an explanation for the change from three-state to two-state guanidine induced unfolding transition as the pH is increased from 7 to 10. All these results exemplify and highlight the role of environment vis-à-vis the sequence and structure of a given protein in dictating its folding/unfolding characteristics.

Residue-wise conformational stability of DLC8 dimer from native-state hydrogen exchange.

Dynein light chain (DLC8) is the smallest subunit of the dynein motor complex, which is known to act as a cargo adaptor in intracellular trafficking. The protein exists as a pure dimer at physiological pH and a completely folded monomer below pH 4. Here, we have determined the energy landscape of the dimeric protein using a combination of optical techniques and native-state hydrogen exchange of amide groups, the former giving the global features and the latter yielding the residue level details. The data indicated the presence of intermediates along the equilibrium unfolding transition. The hydrogen exchange data suggested that the molecule has differential stability in its various segments. We deduce from the free energy data that the antiparallel beta-sheets (beta4 and beta5) that form the hydrophobic core of the protein and the alpha2 helix, all of which are highly protected with regard to hydrogen exchange, contribute significantly to the initial step of the protein folding mechanism. Denaturant-dependent hydrogen exchange indicated further that some amides exchange via local fluctuations, whereas there are others which exchange via global unfolding events. Implications of these to cargo adaptability of the dimer are discussed.

NMR investigations on residue level unfolding thermodynamics in DLC8 dimer by temperature dependent native state hydrogen exchange.

Understanding protein stability at residue level detail in the native state ensemble of a protein is crucial to understanding its biological function. At the same time, deriving thermodynamic parameters using conventional spectroscopic and calorimetric techniques remains a major challenge for some proteins due to protein aggregation and irreversibility of denaturation at higher temperature values. In this regard, we describe here the NMR investigations on the conformational stabilities and related thermodynamic parameters such as local unfolding enthalpies, heat capacities and transition midpoints in DLC8 dimer, by using temperature dependent native state hydrogen exchange; this protein aggregates at high (>65 degrees C) temperatures. The stability (free energy) of the native state was found to vary substantially with temperature at every residue. Significant differences were found in the thermodynamic parameters at individual residue sites indicating that the local environments in the protein structure would respond differently to external perturbations; this reflects on plasticity differences in different regions of the protein. Further, comparison of this data with similar data obtained from GdnHCl dependent native state hydrogen exchange indicated many similarities at residue level, suggesting that local unfolding transitions may be similar in both the cases. This has implications for the folding/unfolding mechanisms of the protein.

NMR characterization of structural and dynamics perturbations due to a single point mutation in Drosophila DLC8 dimer: functional implications.

Dynein light chain protein (DLC8), the smallest subunit of the dynein motor complex, acts as a cargo adaptor. The protein exists as a dimer under physiological conditions, and cargo binding occurs at the dimer interface. Dimer stability and relay of perturbations through the dimer interface can thus be anticipated to play crucial roles in the variety of functions the protein performs. Recent investigations point out that DLC8 also gets phosphorylated at Ser 88, which is located at the extreme C-terminal end. In this background, we investigate here by NMR the effects of a small perturbation by way of a single point mutation, S88A, on the structure, dynamics, and cargo binding efficacy of the DLC8 dimer. We observe that the perturbation travels far away along the sequence from the site of the mutation. This relay has been explained at the atomic level by looking into the packing of the side chains in the crystal structure of the protein. It follows that the interface is highly adaptable, which may account for the versatility of the dimer's cargo binding ability. Binding studies with a peptide indicate that the mutation compromises binding efficacy. These observations show how remote residues that may not be directly bound to a target can still affect the affinity of the protein to the target. Furthermore, the S88A mutational perturbations seen here in Drosophila DLC8 are dramatically different from those of the same mutation in human DLC8 (also known as DLC1) ( Song, C. , et al., ( 2008) J. Biol. Chem, 283, 4004- 4013. ) which differs from Drosophila DLC8 at only five locations. All of these observations put together highlight the sensitivity of dynein light chain protein to small perturbations, and this would have great functional implications.

Differential native state ruggedness of the two Ca2+-binding domains in a Ca2+ sensor protein.

Characterization of near-native excited states of a protein provides insights into various biological functions such as co-operativity, protein-ligand, and protein-protein interactions. In the present study, we investigated the ruggedness of the native state of EhCaBP using nonlinear temperature dependence of backbone amide-proton chemical shifts. EhCaBP is a two-domain EF-hand calcium sensor protein consisting of two EF-hands in each domain and binds four Ca2+ ions. It has been observed that approximately 30% of the residues in the protein access alternative conformations. Theoretical modeling suggested that these low-energy excited states are within 2-3 kcal/mol from the native state. Further, it is interesting to note that the residues accessing alternative conformations are more dominated in the C-terminal domain compared with its N-terminal counterpart suggesting that the former is more rugged in its native state. These distinct characteristics of N- and C-terminal domains of a calcium sensor protein belonging to the super family of calmodulin would have implications for domain dependent Ca2+ signaling pathways.

pH driven conformational dynamics and dimer-to-monomer transition in DLC8.

Dynein light chain protein, a part of the cytoplasmic motor assembly, is a homodimer at physiological pH and dissociates below pH 4.5 to a monomer. The dimer binds to a variety of cargo, whereas the monomer does not bind any of the target proteins. We report here the pH induced stepwise structural and motional changes in the protein, as derived from line broadening and 15N transverse relaxation measurements. At pH 7 and below until 5, partial protonation and consequent interconversion between molecules carrying protonated and neutral histidines, causes conformational dynamics in the dimeric protein and this increases with decreasing pH. Enhanced dynamics in turn leads to partial loosening of the structure. This would have implications for different efficacies of binding by target proteins due to small variations in pH in different parts of the cell, and hence for cargo trafficking from one part to another. Below pH 5, enhanced charge repulsions, partial loss of hydrophobic interactions, and destabilization of H-bonds across the dimer interface cause further loosening of the dimeric structure, leading eventually to the dissociation of the dimer.

Residual structure and dynamics in DMSO-d6 denatured dynein light chain protein.

Structural and motional features in the denatured state of a protein dictate the early folding events starting from that state and these features vary depending upon the nature of the denaturant used. Here, we have attempted to decipher the early events in the folding of Dynein Light Chain protein (DLC8), starting from DMSO-d6 denatured state. Multinuclear NMR experiments were used to obtain the full spectral assignment. The HSQC spectrum shows the presence of two sets of peaks for the residues Met 1, Ser 2, Arg 4, Ala 11, Met 17, Thr 26, Lys 44, Tyr 50, Asn 51, Trp 54, His 55, Val 58, Gly 59, Ser 64, Tyr 65, His 68, Phe 86, Lys 87 indicating the presence of slow conformational transition in the heterogeneous ensemble. Analysis of residual structural propensities with secondary (13)C chemical shifts, (3)J(H(N)(-)H(α)) coupling constants and (1)H-(1)H NOE revealed the presence of local preferences which encompass both native and non-native like structures. The spectral density calculations, as obtained from measured R(1), R(2) and (1)H-(15)N steady state NOE values provide insights into the backbone dynamics on the milli to picosecond timescale. The segment Ser 14 - His 55 exhibits slow motions on the milli- to microsecond timescale arising from conformational exchange. The presence of native like structural preference, as well as conformational exchange classifies the above segment as the nucleation site of folding. Based on the observations, we propose here, the probable hierarchy of folding of DLC8 on dilution of denaturant: the two helices are formed first followed by the formation of ß2 and ß5.

Hierarchy of local structural and dynamics perturbations due to subdenaturing urea in the native state ensemble of DLC8 dimer.

Local structural and dynamic modulations due to small environmental perturbations reflect the adaptability of the protein to different interactors. We have investigated here the preferential local perturbations in Dynein light chain protein (DLC8), a cargo adapter, by sub-denaturing urea concentrations. Equilibrium unfolding experiments by optical spectroscopic methods indicated a two state like unfolding of DLC8 dimer, with the transition mid-point occurring around 8.6M urea. NMR studies identified the ß3 and ß4 strands, N-, C- terminal regions, loops connecting ß1 to α1, α1 to α2 and ß3 to ß4 as the soft targets of urea perturbation and thus indicated potential unfolding initiation sites. Native-state hydrogen exchange studies suggested the unfolding to traverse from the edges towards the centre of the secondary structural elements. At 6M urea the whole protein chain acts like a cooperative unit. These observations are expected to have important implications for the protein's multiple functions.

Structure-function-folding relationships and native energy landscape of dynein light chain protein: nuclear magnetic resonance insights.

The detailed characterization of the structure, dynamics and folding process of a protein is crucial for understanding the biological functions it performs. Modern biophysical and nuclear magnetic resonance (NMR) techniques have provided a way to obtain accurate structural and thermodynamic information on various species populated on the energy landscape of a given protein. In this context, we review here the structure-function-folding relationship of an important protein, namely, dynein light chain protein (DLC8). DLC8, the smallest subunit of the dynein motor complex, acts as a cargo adaptor. The protein exists as a dimer under physiological conditions and dissociates into a pure monomer below pH 4. Cargo binding occurs at the dimer interface. Dimer stability and relay of perturbations through the dimer interface are anticipated to be playing crucial roles in the variety of functions the protein performs. NMR investigations have provided great insights into these aspects of DLC8 in recent years.

Hierarchy in guanidine unfolding of DLC8 dimer: regulatory functional implications.

Folding-unfolding caused by environmental changes play crucial regulatory roles in protein functions. To gain an insight into these for DLC8, a cargo adaptor in dynein motor complex, we investigated here the unfolding of homodimeric DLC8 by GdnHCl, a standard unfolding agent. Fluorescence spectroscopy revealed a three-state unfolding transition with midpoints at 1.5 and 4.0 M GdnHCl. The HSQC spectrum at 1.5 M GdnHCl displayed peaks belonging to a folded monomer. NMR chemical shift perturbations, line broadening effects and (15)N relaxation measurements at low GdnHCl concentrations identified a hierarchy in the unfolding process, with the dimer interface--the cargo binding site--being the most susceptible followed by the helices in the interior. Similar observations were made earlier for small pH perturbations and thus the early unfolding events appear to be intrinsic to the protein. These, by virtue of their location, influence target binding efficacies and thus have important regulatory implications.

Magnesium promotes structural integrity and conformational switching action of a calcium sensor protein.

Calcium binding proteins carry out various signal transduction processes upon binding to Ca2+. In general, these proteins perform their functions in a high background of Mg2+. Here, we report the role of Mg2+ on a calcium sensor protein from Entamoeba histolytica (EhCaBP), containing four Ca2+-binding sites. Mg2+-bound EhCaBP exists as a monomer with a conformation different from that of the holo- and apo-EhCaBP. NMR and biophysical data on EhCaBP demonstrate that Mg2+ stabilizes the closed conformation of the apo form. In the presence of Mg2+, the partially collapsed apo-EhCaBP gains stability and structural integrity. Mg2+ binds to only 3 out of 4 calcium binding sites in EhCaBP. The Ca2+ binding affinity and cooperativity of the conformational switching from the "closed" to the "open" state is significantly modulated by the presence of Mg2+. This fine-tuning of the Ca2+ concentration to switch its conformation is essential for CaBPs to carry out the signal transduction process efficiently.

Energetics of the native energy landscape of a two-domain calcium sensor protein: distinct folding features of the two domains.

The protein folding energy landscape allows a thorough understanding of the protein folding problem which in turn helps in understanding various aspects of biological functions. Characterizing the cooperative unfolding units and the intermediates along the folding funnel of a protein is a challenging task. In this paper, we investigated the native energy landscape of EhCaBP, a calcium sensor, belonging to the same EF-hand superfamily as calmodulin. EhCaBP is a two-domain EF-hand protein consisting of two EF-hands in each domain and binding to four Ca2+ cations. Native-state hydrogen exchange (HX) was used to assess the folding features of the landscape and also to throw light on the structure-folding function paradigm of calcium sensor proteins. HX measurements under the EX2 regime provided the thermodynamic information about the protein folding events under native conditions. HX studies revealed that the unfolding of EhCaBP is not a two-state process. Instead, it proceeds through cooperative units. The C-terminal domain exhibits less denaturant dependence than the N-terminal domain, suggesting that the former is dominated by local fluctuations. It is interesting to note that the N- and C-terminal domains of EhCaBP have distinct folding features. In fact, these observed differences can regulate the domain-dependent target recognition of two-domain Ca2+ sensor proteins.

NMR elucidation of early folding hierarchy in HIV-1 protease.

Folding studies on proteases by the conventional hydrogen exchange experiments are severely hampered because of interference from the autolytic reaction in the interpretation of the exchange data. We report here NMR identification of the hierarchy of early conformational transitions (folding propensities) in HIV-1 protease by systematic monitoring of the changes in the state of the protein as it is subjected to different degrees of denaturation by guanidine hydrochloride. Secondary chemical shifts, HN-Halpha coupling constants, 1H-15N nuclear Overhauser effects, and 15N transverse relaxation parameters have been used to report on the residual structural propensities, motional restrictions, conformational transitions, etc., and the data suggest that even under the strongest denaturing conditions (6 m guanidine) hydrophobic clusters as well as different native and non-native secondary structural elements are transiently formed. These constitute the folding nuclei, which include residues spanning the active site, the hinge region, and the dimerization domain. Interestingly, the proline residues influence the structural propensities, and the small amino acids, Gly and Ala, enhance the flexibility of the protein. On reducing the denaturing conditions, partially folded forms appear. The residues showing high folding propensities are contiguous along the sequence at many locations or are in close proximity on the native protein structure, suggesting a certain degree of local cooperativity in the conformational transitions. The dimerization domain, the flaps, and their hinges seem to exhibit the highest folding propensities. The data suggest that even the early folding events may involve many states near the surface of the folding funnel.