A deficiency of functional dystrophin protein in muscle cells causes muscular dystrophy (MD). More than 50% of missense mutations that trigger the disease occur in the N-terminal actin binding domain (N-ABD or ABD1). We examined the effect of four diseasecausing mutations-L54R, A168D, A171P, and Y231N-on the structural and biophysical properties of isolated N-ABD. Our results indicate that N-ABD is a monomeric, well-folded α-helical protein in solution, as is evident from its α-helical circular dichroism spectrum, blue shift of the native state tryptophan fluorescence, well-dispersed amide crosspeaks in 2D NMR 15 N-1 H HSQC fingerprint region, and rotational correlation time calculated from NMR longitudinal ðT 1 Þ and transverse ðT 2 Þ relaxation experiments. Compared to WT, three mutants-L54R, A168D, and A171P-show a decreased α-helicity and do not show a cooperative sigmoidal melt with temperature, indicating that these mutations exist in a wide range of conformations or in a "molten globule" state. In contrast, Y231N has an α-helical content similar to WT and shows a cooperative sigmoidal temperature melt but with a decreased stability. All four mutants experience serious misfolding and aggregation. FT-IR, circular dichroism, increase in thioflavin T fluorescence, and the congo red spectral shift and birefringence show that these aggregates contain intermolecular cross-β structure similar to that found in amyloid diseases. These results indicate that disease-causing mutants affect N-ABD structure by decreasing its thermodynamic stability and increasing its misfolding, thereby decreasing the net functional dystrophin concentration.actin binding domain | Becker muscular dystrophy | calponin homology domain | Duchenne muscular dystrophy | protein aggregation
In Gram-positive bacteria, T-box riboswitches control gene expression to maintain the cellular pools of aminoacylated tRNAs essential for protein biosynthesis. Co-transcriptional binding of an uncharged tRNA to the riboswitch stabilizes an antiterminator, allowing transcription read-through, whereas an aminoacylated tRNA does not. Recent structural studies have resolved two contact points between tRNA and Stem-I in the 5′ half of the T-box riboswitch, but little is known about the mechanism empowering transcriptional control by a small, distal aminoacyl modification. Using single-molecule fluorescence microscopy, we have probed the kinetic and structural underpinnings of tRNA binding to a glycyl T-box riboswitch. We observe a two-step mechanism where fast, dynamic recruitment of tRNA by Stem-I is followed by ultra-stable anchoring by the downstream antiterminator, but only without aminoacylation. Our results support a hierarchical sensing mechanism wherein dynamic global binding of the tRNA body is followed by localized readout of its aminoacylation status by snap-lock-based trapping.
Proteins aggregate in response to various stresses including changes in solvent conditions. Addition of alcohols has been recently shown to induce aggregation of disease-related as well as non-disease-related proteins. Here we probed the biophysical mechanisms underlying alcoholinduced protein aggregation, in particular the role of partial protein unfolding in aggregation. We have studied aggregation mechanisms due to benzyl alcohol which is used in numerous biochemical and biotechnological applications. We chose cytochrome c as a model protein, for the reason that various optical and structural probes are available to monitor its global and partial unfolding reactions. Benzyl alcohol induced the aggregation of cytochrome c in isothermal conditions and decreased the temperature at which the protein aggregates. However, benzyl alcohol did not perturb the overall native conformation of cytochrome c. Instead, it caused partial unfolding of a local protein region around the methionine residue at position 80. Site-specific optical probes, two-dimensional NMR titrations, and hydrogen exchange all support this conclusion. The protein aggregation temperature varied linearly with the melting temperature of the Met80 region. Stabilizing the Met80 region by heme iron reduction drastically decreased protein aggregation, which confirmed that the local unfolding of this region causes protein aggregation. These results indicate that a possible mechanism by which alcohols induce protein aggregation is through partial rather than complete unfolding of native proteins.
One-third of protein formulations are multi-dose. These require antimicrobial preservatives (APs); however, some APs have been shown to cause protein aggregation. Our previous work on a model protein cytochrome c indicated that partial protein unfolding, rather than complete unfolding, triggers aggregation. Here, we examined the relative strength of five commonly used APs on such unfolding and aggregation, and explored whether stabilizing the aggregation “hot-spot” reduces such aggregation. All APs induced protein aggregation in the order m-cresol > phenol > benzyl alcohol > phenoxyethanol > chlorobutanol. All these enhanced the partial protein unfolding that includes a local region which was predicted to be the aggregation “hot-spot”. The extent of destabilization correlated with the extent of aggregation. Further, we show that stabilizing the “hot-spot” reduces aggregation induced by all five APs. These results indicate that m-cresol causes the most protein aggregation, whereas chlorobutanol causes the least protein aggregation. The same protein region acts as the “hot-spot” for aggregation induced by different APs, implying that developing strategies to prevent protein aggregation induced by one AP will also work for others.
Nucleoside base modifications can alter the structures, dynamics, and metal ion binding properties of transfer RNA molecules and are important for accurate aminoacylation and for maintaining translational fidelity and efficiency. The unmodified anticodon stem-loop from Escherichia coli tRNA(Phe) forms a trinucleotide loop in solution, but Mg(2+) and dimethylallyl modification of A(37) N6 disrupt the loop conformation and increase the mobility of the loop and loop-proximal nucleotides. We have used NMR spectroscopy to investigate the binding and structural effects of multivalent cations on the unmodified and dimethylallyl-modified anticodon stem-loops from E. coli tRNA(Phe). The divalent cation binding sites were probed using Mn(2+) and Co(NH(3))(6)(3+). These ions bind along the major groove of the stem and associate with the anticodon loop on the major groove side in a nonspecific manner. Co(NH(3))(6)(3+) stabilizes the U-turn conformation of the loop in the dimethylallyl-modified molecule, and the chemical shift changes that accompany Co(NH(3))(6)(3+) binding are similar to those observed with the addition of Mg(2+). The base-phosphate and base-2'-OH hydrogen bonds that characterize the UNR U-turn motif lead to spectral signatures in the form of unusual (15)N and (1)H chemical shifts and reduced solvent exchange of the U(33) 2'-OH and N3H protons. The unmodified molecule also displays spectral features of the U-turn fold in the presence of Co(NH(3))(6)(3+), but the loop has additional conformations and is dynamic. The results indicate that charge neutralization by a polyvalent cation is sufficient to promote formation of the U-turn fold. However, base modification is necessary to destabilize competing alternative conformers even for a purine-rich loop sequence that is predicted to have strongly favorable base stacking energy.
The periodicity in nucleic acid duplex structures is shown to be correlated to the periodicity in residual dipolar couplings (RDCs) in the form of an "RDC wave". This "RDC wave" is characteristic of the alignment of the duplex in the magnetic field, and hence fitting of the data allows the duplex global orientation (, Phi) to be extracted. Further, because the "RDC wave" is fit as a data set of a corresponding secondary structure element, the degeneracy problem is greatly reduced. Consequently, with the global orientation (, Phi) determined, local bond vector conformations are defined. The fit is demonstrated in the examples of the imino RDCs of the negative regulator of splicing RNA fragment (NRS23) and for the C1'H1' RDCs of the Dickerson dodecamer.
Nucleoside base modifications can alter the structures and dynamics of RNA molecules and are important in tRNAs for maintaining translational fidelity and efficiency. The unmodified anticodon stem–loop from Escherichia coli tRNAPhe forms a trinucleotide loop in solution, but Mg2+ and dimethylallyl modification of A37 N6 destabilize the loop-proximal base pairs and increase the mobility of the loop nucleotides. The anticodon arm has three additional modifications, ψ32, ψ39, and A37 C2-thiomethyl. We have used NMR spectroscopy to investigate the structural and dynamical effects of ψ32 on the anticodon stem-loop from E.coli tRNAPhe. The ψ32 modification does not significantly alter the structure of the anticodon stem–loop relative to the unmodified parent molecule. The stem of the RNA molecule includes base pairs ψ32-A38 and U33–A37 and the base of ψ32 stacks between U33 and A31. The glycosidic bond of ψ32 is in the anti configuration and is paired with A38 in a Watson–Crick geometry, unlike residue 32 in most crystal structures of tRNA. The ψ32 modification increases the melting temperature of the stem by ∼3.5°C, although the ψ32 and U33 imino resonances are exchange broadened. The results suggest that ψ32 functions to preserve the stem integrity in the presence of additional loop modifications or after reorganization of the loop into a translationally functional conformation.
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