The Unfolded State of the C-Terminal Domain of L9 Expands at Low but Not at Elevated Temperatures.

The temperature dependence of the overall dimensions of the denatured state ensemble (DSE) of proteins remains unclear. Some studies indicate compaction of the DSE at high temperatures, whereas others argue that dimensions do not decrease. The degree of compaction or expansion in the cold-denatured state has been less studied. To investigate the temperature dependence of unfolded state dimensions, small angle x-ray scattering measurements were performed in native buffer in the absence of denaturant for a designed point mutant of the C-terminal domain of L9, a small cooperatively folded α-ß protein, at 14 different temperatures over the range of 5-60°C. The I98A mutation destabilizes the domain such that both the DSE and the folded state are populated at 25°C in the absence of denaturant or extreme pH. Thermal unfolding as well as cold unfolding can thus be observed in the absence of denaturant, allowing a direct comparison of these regimes for the same protein using the same technique. The temperature of maximal stability, Ts, is 30°C. There is no detectable change in Rg of the unfolded state as the temperature is increased above Ts, but a clear expansion is detected as the temperature is decreased below Ts. The Rg of the DSE populated in buffer was found to be 27.8 ± 1.7 Å at 5°C, 21.8 ± 1.9 Å at 30°C, and 21.7 ± 2.0 Å at 60°C. In contrast, no significant temperature dependence was observed for the value of Rg measured in 6 M guanidine hydrochloride. The small angle x-ray scattering data reported here indicate clear differences between the cold- and thermal-unfolded states and show that there is no significant compaction at elevated temperatures.

Uncontacted tire explosion causing trauma to bilateral lower extremities: A case report.

It is uncommon for tire explosion related injuries on the lower extremity. The bilateral lower extremities were injured by tire explosion when the patient was seated in a bus. She sustained an open fracture with partial bone loss in the right calcaneus (a comminuted fracture in the right ankle joint) and a closed comminuted fracture in the left tibia and fibula. This damage was caused by uncontacted tire explosion, thanks to a thick floor between the exploded tire and the patient's feet. This type of injury on lower extremity caused by uncontacted tire explosion was uncommon.

Experiments and simulations show how long-range contacts can form in expanded unfolded proteins with negligible secondary structure.

The sizes of unfolded proteins under highly denaturing conditions scale as N(0.59) with chain length. This suggests that denaturing conditions mimic good solvents, whereby the preference for favorable chain-solvent interactions causes intrachain interactions to be repulsive, on average. Beyond this generic inference, the broader implications of N(0.59) scaling for quantitative descriptions of denatured state ensembles (DSEs) remain unresolved. Of particular interest is the degree to which N(0.59) scaling can simultaneously accommodate intrachain attractions and detectable long-range contacts. Here we present data showing that the DSE of the N-terminal domain of the L9 (NTL9) ribosomal protein in 8.3 M urea lacks detectable secondary structure and forms expanded conformations in accord with the expected N(0.59) scaling behavior. Paramagnetic relaxation enhancements, however, indicate the presence of detectable long-range contacts in the denatured-state ensemble of NTL9. To explain these observations we used atomistic thermal unfolding simulations to identify ensembles whose properties are consistent with all of the experimental observations, thus serving as useful proxies for the DSE of NTL9 in 8.3 M urea. Analysis of these ensembles shows that residual attractions are present under mimics of good solvent conditions, and for NTL9 they result from low-likelihood, medium/long-range contacts between hydrophobic residues. Our analysis provides a quantitative framework for the simultaneous observation of N(0.59) scaling and low-likelihood long-range contacts for the DSE of NTL9. We propose that such low-likelihood intramolecular hydrophobic clusters might be a generic feature of DSEs that play a gatekeeping role to protect against aggregation during protein folding.

A structural basis for the regulation of an H-NOX-associated cyclic-di-GMP synthase/phosphodiesterase enzyme by nitric oxide-bound H-NOX.

Biofilms are surface-attached communities of bacteria enclosed in a polysaccharide matrix. Bacteria in a biofilm are extremely resistant to antibiotics. Several recent reports have linked the signaling molecule nitric oxide (NO) with biofilm dispersal. We have previously reported that an H-NOX (heme-nitric oxide/oxygen binding) protein in the biofilm-dwelling bacterium Shewanella woodyi mediates NO-induced biofilm dispersal. In S. woodyi, H-NOX (SwH-NOX) is cocistronic with a gene encoding a dual-functioning diguanylate cyclase/phosphodiesterase enzyme, designated here as HaCE (H-NOX-associated cyclic-di-GMP processing enzyme). Enzymes such as these are responsible for regulating the intracellular concentrations of cyclic-di-GMP, a secondary signaling molecule essential to biofilm formation in bacteria. We have demonstrated that NO-bound SwH-NOX regulates both enzymatic activities of SwHaCE, resulting in decreased cellular cyclic-di-GMP levels and disruption of biofilm formation. Thus, H-NOX/HaCE represents a potential drug target for regulating biofilm formation. In this work, the SwH-NOX surface residues critical for the formation of a protein complex with SwHaCE are identified using nuclear magnetic resonance, fluorescence quenching, and cosedimentation. Enzyme assays confirm this protein-protein interface and its importance for H-NOX/HaCE function.

Denatured state ensembles with the same radii of gyration can form significantly different long-range contacts.

Defining the structural, dynamic, and energetic properties of the unfolded state of proteins is critical for an in-depth understanding of protein folding, protein thermodynamics, and protein aggregation. Here we analyze long-range contacts and compactness in two apparently fully unfolded ensembles of the same protein: the acid unfolded state of the C-terminal domain of ribosomal protein L9 in the absence of high concentrations of urea as well as the urea unfolded state at low pH. Small angle X-ray scattering reveals that the two states are expanded with values of Rg differing by <7%. Paramagnetic relaxation enhancement (PRE) nuclear magnetic resonance studies, however, reveal that the acid unfolded state samples conformations that facilitate contacts between residues that are distant in sequence while the urea unfolded state ensemble does not. The experimental PRE profiles for the acid unfolded state differ significantly from these predicted using an excluded volume limit ensemble, but these long-range contacts are largely eliminated by the addition of 8 M urea. The work shows that expanded unfolded states can sample very different distributions of long-range contacts yet still have similar radii of gyration. The implications for protein folding and for the characterization of unfolded states are discussed.

The denatured state ensemble contains significant local and long-range structure under native conditions: analysis of the N-terminal domain of ribosomal protein L9.

The denatured state ensemble (DSE) represents the starting state for protein folding and the reference state for protein stability studies. Residual structure in the DSE influences the kinetics of protein folding, the propensity to aggregate, and protein stability. The DSE that is most relevant for folding is the ensemble populated under native conditions, but the stability of proteins and the cooperativity of their folding normally prevent direct characterization of this ensemble. Indirect experiments have been used to infer residual structure in the DSE under nondenaturing conditions, but direct characterization is rare. The N-terminal domain of ribosomal protein L9 (NTL9) is a small mixed α-ß domain that folds cooperatively on the millisecond time scale. A destabilized double mutant of NTL9, V3A/I4A-NTL9, populates the DSE in the absence of denaturant and is in slow exchange with the native state on the nuclear magnetic resonance time scale. The DSE populated in buffer was compared to the urea-induced DSE. Analysis of (1)H and (13)C chemical shifts reveals residual secondary structure in the DSE in buffer, which is stabilized by both local and long-range interactions. (15)N R2 relaxation rates deviate from random coil models, suggesting hydrophobic clustering in the DSE. Paramagnetic relaxation enhancement experiments show that there are transient long-range contacts in the DSE in buffer. In contrast, the urea-induced DSE has significantly less residual secondary structure and markedly fewer long-range contacts; however, the urea-induced DSE deviates from a random coil.

Cooperative cold denaturation: the case of the C-terminal domain of ribosomal protein L9.

Cold denaturation is a general property of globular proteins, but it is difficult to directly characterize because the transition temperature of protein cold denaturation, T(c), is often below the freezing point of water. As a result, studies of protein cold denaturation are often facilitated by addition of denaturants, using destabilizing pHs or extremes of pressure, or reverse micelle encapsulation, and there are few studies of cold-induced unfolding under near native conditions. The thermal and denaturant-induced unfolding of single-domain proteins is usually cooperative, but the cooperativity of cold denaturation is controversial. The issue is of both fundamental and practical importance because cold unfolding may reveal information about otherwise inaccessible partially unfolded states and because many therapeutic proteins need to be stabilized against cold unfolding. It is thus desirable to obtain more information about the process under nonperturbing conditions. The ability to access cold denaturation in native buffer is also very useful for characterizing protein thermodynamics, especially when other methods are not applicable. In this work, we study a point mutant of the C-terminal domain of ribosomal protein L9 (CTL9), which has a T(c) above 0 °C. The mutant was designed to allow the study of cold denaturation under near native conditions. The cold denaturation process of I98A CTL9 was characterized by nuclear magnetic resonance, circular dichroism, and Fourier transform infrared spectroscopy. The results are consistent with apparently cooperative, two-state cold unfolding. Small-angle X-ray scattering studies show that the unfolded state expands as the temperature is lowered.

Biophysical and functional analyses suggest that adenovirus E4-ORF3 protein requires higher-order multimerization to function against promyelocytic leukemia protein nuclear bodies.

The early region 4 open reading frame 3 protein (E4-ORF3; UniProt ID P04489) is the most highly conserved of all adenovirus-encoded gene products at the amino acid level. A conserved attribute of the E4-ORF3 proteins of different human adenoviruses is the ability to disrupt PML nuclear bodies from their normally punctate appearance into heterogeneous filamentous structures. This E4-ORF3 activity correlates with the inhibition of PML-mediated antiviral activity. The mechanism of E4-ORF3-mediated reorganization of PML nuclear bodies is unknown. Biophysical analysis of the purified WT E4-ORF3 protein revealed an ordered secondary/tertiary structure and the ability to form heterogeneous higher-order multimers in solution. Importantly, a nonfunctional E4-ORF3 mutant protein, L103A, forms a stable dimer with WT secondary structure content. Because the L103A mutant is incapable of PML reorganization, this result suggests that higher-order multimerization of E4-ORF3 may be required for the activity of the protein. In support of this hypothesis, we demonstrate that the E4-ORF3 L103A mutant protein acts as a dominant-negative effector when coexpressed with the WT E4-ORF3 in mammalian cells. It prevents WT E4-ORF3-mediated PML track formation presumably by binding to the WT protein and inhibiting the formation of higher-order multimers. In vitro protein binding studies support this conclusion as demonstrated by copurification of coexpressed WT and L103A proteins in Escherichia coli and coimmunoprecipitation of WT·L103A E4-ORF3 complexes in mammalian cells. These results provide new insight into the properties of the Ad E4-ORF3 protein and suggest that higher-order protein multimerization is essential for E4-ORF3 activity.

Chemotherapy effectively suppresses interleukin-20, receptor activator of nuclear factor kappa-B ligand, and osteoprotegerin levels in patients with lung adenocarcinoma and bone metastasis.

BACKGROUND: Bone metastasis (BM) is common in patients with lung cancer. Osteolysis is caused by increased osteoclast activity. Interleukin-20 (IL-20) and receptor activator of nuclear factor kappa-B ligand (RANKL) are crucial for osteoclast formation. Osteoprotegerin (OPG) inhibits a receptor activator of RANKL/RANK signaling. The aims of this study were to analyze the serum levels of IL-20, OPG, and RANKL in patients with and without BM and to observe the effect of chemotherapy on these cytokines. PATIENTS AND METHODS: A total 54 cases of pathologically confirmed lung adenocarcinoma (ADC) and 18 healthy individuals (Control) were enrolled in this study. Eligible patients were divided into three groups (18 patients per group): ADC without BM (ADC), ADC with BM (ADC + BM), and ADC with BM treated with chemotherapy (ADC + BM + Chemo). Serum IL-20, RANKL, and OPG levels were analyzed by enzyme-linked immunosorbent assay. RESULTS: Serum IL-20, RANKL, and OPG levels in ADC + BM patients were significantly elevated compared with that in the Control or ADC groups (both P < 0.001). The serum cytokine levels were significantly lower following chemotherapy compared with that in patients who did not receive chemotherapy (P < 0.001). CONCLUSIONS: Serum IL-20, RANKL, and OPG levels increase in patients with lung cancer and BMs. Chemotherapy suppresses the elevation of these cytokines.