Site-Specific Structural Variations Accompanying Tubular Assembly of the HIV-1 Capsid Protein

The 231-residue capsid (CA) protein of human immunodeficiency virus type 1 (HIV-1) spontaneously self-assembles into tubes with a hexagonal lattice that is believed to mimic the surface lattice of conical capsid cores within intact virions. We report the results of solid-state nuclear magnetic resonance (NMR) measurements on HIV-1 CA tubes that provide new information regarding changes in molecular structure that accompany CA self-assembly, local dynamics within CA tubes, and possible mechanisms for the generation of lattice curvature. This information is contained in site-specific assignments of signals in two- and three-dimensional solid-state NMR spectra, conformation-dependent ¹⁵N and ¹³C NMR chemical shifts, detection of highly dynamic residues under solution NMR conditions, measurements of local variations in transverse spin relaxation rates of amide ¹H nuclei, and quantitative measurements of site-specific ¹⁵N–¹⁵N dipole–dipole couplings. Our data show that most of the CA sequence is conformationally ordered and relatively rigid in tubular assemblies and that structures of the N-terminal domain (NTD) and the C-terminal domain (CTD) observed in solution are largely retained. However, specific segments, including the N-terminal β-hairpin, the cyclophilin A binding loop, the inter-domain linker, segments involved in intermolecular NTD–CTD interactions, and the C-terminal tail, have substantial static or dynamical disorder in tubular assemblies. Other segments, including the 3₁₀-helical segment in CTD, undergo clear conformational changes. Structural variations associated with curvature of the CA lattice appear to be localized in the inter-domain linker and intermolecular NTD–CTD interface, while structural variations within NTD hexamers, around local 3-fold symmetry axes, and in CTD–CTD dimerization interfaces are less significant.     

Structural studies of a synthetic peptide derived from the carboxyl-terminal domain of RNA polymerase II

The conformation of the repeating heptapeptide unit of the carboxyl-terminal domain of RNA Polymerase II, Y¹S²P³T⁴S⁵P⁶S⁷ has been examined using nuclear magnetic resonance spectroscopy and circular dichroism. Nuclear Overhauser effects and CD spectra for the synthetic 56-residue peptide H₂N-(S²P³T⁴S⁵P⁶S⁷Y^l)₈-COOH in water indicate that the peptide is largely unordered. A small population of folded molecules is observed to contain β-turns located at Ser²-Pro³-Thr⁴-Ser⁵ (SPTS) and Ser⁵-Pro⁶-Ser⁷-Tyr¹ (SPSY). CD and NMR results in 90% TFE also indicate an equilibrium population of structures, but the fraction of turns is higher. Similarities of nuclear Overhauser effects in water and in 90% TFE suggest that the structures in TFE are biologically relevant. Based on these observations, the average structure of a single conformer of the heptapeptide repeat in 90% TFE was obtained by a distance geometry-simulated annealing method, using distance restraints extracted from nuclear Overhauser data. NMR spectra of the 56-mer show signals corresponding to only one repeat indicating that each repeat is in an identical environment. Thus it is possible to obtain an average structure of the heptapeptide repeat from NOE data on the 56-mer. Twenty-seven final structures were calculated and the root mean square deviations between the 27 structure and the mean coordinates was 1.52 Å for the backbone and 2.2 Å for all nonhydrogen atoms. The heptapeptide repeat consists of two overlapping β-turns which are potentially stabilized by hydrogen bonds. The hydroxyl side chains of Ser², Ser⁵, Thr⁴, and Ser⁷ all appear to be equally exposed for potential phosphorylation. The tyrosyl side chain of each repeat is folded inwards to the backbone and can potentially hydrogen bond to the carbonyl oxygen of the tyrosine in the preceding repeat. Iteration of the average structure of the heptapeptide repeat results in a model of the carboxyl-terminal domain with a regular but unusual secondary structure consisting of a series of staggered β-turns. © 1995 Wiley-Liss, Inc.     

GTDC2 modifies O-mannosylated α-dystroglycan in the endoplasmic reticulum to generate N-acetyl glucosamine epitopes reactive with CTD110.6 antibody

Hypoglycosylation is a common characteristic of dystroglycanopathy, which is a group of congenital muscular dystrophies. More than ten genes have been implicated in α-dystroglycanopathies that are associated with the defect in the O-mannosylation pathway. One such gene is GTDC2, which was recently reported to encode O-mannose β-1,4-N-acetylglucosaminyltransferase. Here we show that GTDC2 generates CTD110.6 antibody-reactive N-acetylglucosamine (GlcNAc) epitopes on the O-mannosylated α-dystroglycan (α-DG). Using the antibody, we show that mutations of GTDC2 identified in Walker–Warburg syndrome and alanine-substitution of conserved residues between GTDC2 and EGF domain O-GlcNAc transferase resulted in decreased glycosylation. Moreover, GTDC2-modified GlcNAc epitopes are localized in the endoplasmic reticulum (ER). These data suggested that GTDC2 is a novel glycosyltransferase catalyzing GlcNAcylation of O-mannosylated α-DG in the ER. CTD110.6 antibody may be useful to detect a specific form of GlcNAcylated O-mannose and to analyze defective O-glycosylation in α-dystroglycanopathies.     

Polyacrylamide Gel Electrophoresis of Plasteins

A peptic hydrolysate of soybean protein was filtered with Sephadex G–25 and was separated approximately into four fractions (I, II, II, and IV in the order of mol. wt.). Fraction II (av. mol. wt: 1043) and III (av. mol. Wt.: 685) were more plastein-productive than others. When plastein produced from Fraction II with Nagarse was investigated by plate electrophoresis using 7.5% polyacrylamide-gel, the upper limit of the molecular weight was found to be about 25,000. A similar result was obtained also with Fraction III. The increase of molecular weight in the course of the plastein formation with the mixture (substrate) of Fractions II and III was shown that the final product lay mainly in a position between cytochrome c (mol. wt.: 11,700) and Nagarse (mol wt.: 27,600). In addition, the gel-electrophoretic experiments revealed that the most favorable condition for the plastein synthesis were pH 6.5 and 35% in substrate concentration.     

Contributions of the C-terminal domain to poly(A)-specific ribonuclease (PARN) stability and self-association

Poly(A)-specific ribonuclease (PARN) catalyzes the degradation of mRNA poly(A) tail to regulate translation efficiency and mRNA decay in higher eukaryotic cells. The full-length PARN is a multi-domain protein containing the catalytic nuclease domain, the R3H domain, the RRM domain and the C-terminal intrinsically unstructured domain (CTD). The roles of the three well-structured RNA-binding domains have been extensively studied, while little is known about CTD. In this research, the impact of CTD on PARN stability and aggregatory potency was studied by comparing the thermal inactivation and denaturation behaviors of full-length PARN with two N-terminal fragments lacking CTD. Our results showed that K⁺ induced additional regular secondary structures and enhanced PARN stability against heat-induced inactivation, unfolding and aggregation. CTD prevented PARN from thermal inactivation but promoted thermal aggregation to initiate at a temperature much lower than that required for inactivation and unfolding. Blue-shift of Trp fluorescence during thermal transitions suggested that heat treatment induced rearrangements of domain organizations. CTD amplified the stabilizing effect of K⁺, implying the roles of CTD was mainly achieved by electrostatic interactions. These results suggested that CTD might dynamically interact with the main body of the molecule and release of CTD promoted self-association via electrostatic interactions.     

Pushing, pulling and trapping--modes of motor protein supported protein translocation

Protein translocation across the cellular membranes is an ubiquitous and crucial activity of cells. This process is mediated by translocases that consist of a protein conducting channel and an associated motor protein. Motor proteins interact with protein substrates and utilize the free energy of ATP binding and hydrolysis for protein unfolding, translocation and unbinding. Since motor proteins are found either at the cis- or trans-side of the membrane, different mechanisms for translocation have been proposed. In the Power stroke model, cis-acting motors are thought to push, while trans-motors pull on the substrate protein during translocation. In the Brownian ratchet model, translocation occurs by diffusion of the unfolded polypeptide through the translocation pore while directionality is achieved by trapping and refolding. Recent insights in the structure and function of the molecular motors suggest that different mechanisms can be employed simultaneously.