Justin L. Lorieau

The complete influenza hemagglutinin fusion domain adopts a tight helical hairpin arrangement at the lipid:water interface

All but five of the N-terminal 23 residues of the HA2 domain of the influenza virus glycoprotein hemagglutinin (HA) are strictly conserved across all 16 serotypes of HA genes. The structure and function of this HA2 fusion peptide (HAfp) continues to be the focus of extensive biophysical, computational, and functional analysis, but most of these analyses are of peptides that do not include the strictly conserved residues Trp21-Tyr22-Gly23. The heteronuclear triple resonance NMR study reported here of full length HAfp of sero subtype H1, solubilized in dodecylphosphatidyl choline, reveals a remarkably tight helical hairpin structure, with its N-terminal α-helix (Gly1-Gly12) packed tightly against its second α-helix (Trp14-Gly23), with six of the seven conserved Gly residues at the interhelical interface. The seventh conserved Gly residue in position 13 adopts a positive ϕ angle, enabling the hairpin turn that links the two helices. The structure is stabilized by multiple interhelical CαH to C = O hydrogen bonds, characterized by strong interhelical HN-Hα and Hα-Hα NOE contacts. Many of the previously identified mutations that make HA2 nonfusogenic are also incompatible with the tight antiparallel hairpin arrangement of the HAfp helices.15N relaxation analysis indicates the structure to be highly ordered on the nanosecond time scale, and NOE analysis indicates HAfp is located at the water-lipid interface, with its hydrophobic surface facing the lipid environment, and the Gly-rich side of the helix-helix interface exposed to solvent.

Conformational dynamics of an intact virus: Order parameters for the coat protein of Pf1 bacteriophage

This study has examined the atomic-level dynamics of the protein in the capsid of filamentous phage Pf1. This capsid consists of ≈7,300 small subunits of only 46 aa in a helical array around a highly extended, circular single-stranded DNA molecule of 7,349 nt. Measurements were made of site-specific, solid-state NMR order parameters, 〈S〉, the values which are dimensionless quantities between 0 (mobile) and 1 (static) that characterize the amplitudes of molecular bond angular motions that are faster than microseconds. It was found that the protein subunit backbone is very static, and of particular interest, it appears to be static at residues glycine 15 and glutamine 16 where it had been previously thought to be mobile. In contrast to the backbone, several side chains display large-amplitude angular motions. Side chains on the virion exterior that interact with solvent are highly mobile, but surprisingly, the side chains of residues arginine 44 and lysine 45 near the DNA deep in the interior of the virion are also highly mobile. The large-amplitude dynamic motion of these positively charged side chains in their interactions with the DNA were not previously expected. The results reveal a highly dynamic aspect of a DNA–protein interface within a virus.

pH-triggered, activated-state conformations of the influenza hemagglutinin fusion peptide revealed by NMR

The highly conserved first 23 residues of the influenza hemagglutinin HA2 subunit constitute the fusion domain, which plays a pivotal role in fusing viral and host-cell membranes. At neutral pH, this peptide adopts a tight helical hairpin wedge structure, stabilized by aliphatic hydrogen bonding and charge–dipole interactions. We demonstrate that at low pH, where the fusion process is triggered, the native peptide transiently visits activated states that are very similar to those sampled by a G8A mutant. This mutant retains a small fraction of helical hairpin conformation, in rapid equilibrium with at least two open structures. The exchange rate between the closed and open conformations of the wild-type fusion peptide is ∼40 kHz, with a total open-state population of ∼20%. Transitions to these activated states are likely to play a crucial role in formation of the fusion pore, an essential structure required in the final stage of membrane fusion.

Liquid crystalline phase of G-tetrad DNA for NMR study of detergent-solubilized proteins.

The liquid crystalline phase consisting of the potassium salt of the dinucleotide d(GpG) is compatible with detergents commonly used for solubilizing membrane proteins, including dodecylphosphocholine, the lysolipid 1-palmitoyl-2-hydroxy-sn-glycero-3-phosphocholine, and small bicelles consisting of dihexanoyl phosphatidylcholine and dimyristoyl phosphatidylcholine. The chiral nematic liquid crystalline phase of d(GpG) consists of long columns of stacked G-tetrad structures and carry a net negative charge. For water-soluble systems, the protein alignment induced by d(GpG) is very similar to that observed for liquid crystalline Pf1 bacteriophage, but of opposite sign. Alignment of the detergent-solubilized fusion domain of hemagglutinin is demonstrated to be homogeneous and stable, resulting in high quality NMR spectra suitable for the measurement of residual dipolar couplings.

Whole-body rocking motion of a fusion peptide in lipid bilayers from size-dispersed 15N NMR relaxation.

Biological membranes present a highly fluid environment, and integration of proteins within such membranes is itself highly dynamic: proteins diffuse laterally within the plane of the membrane and rotationally about the normal vector of this plane. We demonstrate that whole-body motions of proteins within a lipid bilayer can be determined from NMR 15N relaxation rates collected for different-sized bicelles. The importance of membrane integration and interaction is particularly acute for proteins and peptides that function on the membrane itself, as is the case for pore-forming and fusion-inducing proteins. For the influenza hemagglutinin fusion peptide, which lies on the surface of membranes and catalyzes the fusion of membranes and vesicles, we found large-amplitude, rigid-body wobbling motions on the nanosecond time scale relative to the lipid bilayer. This behavior complements prior analyses where data were commonly interpreted in terms of a static oblique angle of insertion for the fusion peptide with respect to the membrane. Quantitative disentanglement of the relative motions of two interacting objects by systematic variation of the size of one is applicable to a wide range of systems beyond protein–membrane interactions.

Triosephosphate Isomerase: 15N and 13C Chemical Shift Assignments and Conformational Change upon Ligand Binding by Magic-Angle Spinning Solid-State NMR Spectroscopy

Microcrystalline uniformly (13)C,(15)N-enriched yeast triosephosphate isomerase (TIM) is sequentially assigned by high-resolution solid-state NMR (SSNMR). Assignments are based on intraresidue and interresidue correlations, using dipolar polarization transfer methods, and guided by solution NMR assignments of the same protein. We obtained information on most of the active-site residues involved in chemistry, including some that were not reported in a previous solution NMR study, such as the side-chain carbons of His95. Chemical shift differences comparing the microcrystalline environment to the aqueous environment appear to be mainly due to crystal packing interactions. Site-specific perturbations of the enzymes chemical shifts upon ligand binding are studied by SSNMR for the first time. These changes monitor proteinwide conformational adjustment upon ligand binding, including many of the sites probed by solution NMR and X-ray studies. Changes in Gln119, Ala163, and Gly210 were observed in our SSNMR studies, but were not reported in solution NMR studies (chicken or yeast). These studies identify a number of new sites with particularly clear markers for ligand binding, paving the way for future studies of triosephosphate isomerase dynamics and mechanism.

Modulating alignment of membrane proteins in liquid-crystalline and oriented gel media by changing the size and charge of phospholipid bicelles

We demonstrate that alignment of a structured peptide or small protein solubilized in mixed phospholipid:detergent micelles or bicelles, when embedded in a compressed gel or liquid crystalline medium, can be altered by either changing the phospholipid aggregate shape, charge, or both together. For the hemagglutinin fusion peptide solubilized in bicelles, we show that bicelle shape and charge do not change its helical hairpin structure but impact its alignment relative to the alignment medium, both in charged compressed acrylamide gel and in liquid crystalline d(GpG). The method can be used to generate sets of residual dipolar couplings that correspond to orthogonal alignment tensors, and holds promise for high-resolution structural refinement and dynamic mapping of membrane proteins.

A Positively Charged Liquid Crystalline Medium for Measuring Residual Dipolar Couplings in Membrane Proteins by NMR

Residual Dipolar Couplings (RDCs) are integral to the refinement of membrane protein structures by NMR since they accurately define the orientation of helices and other structural units. Only a small set of liquid crystals used for RDC measurements are compatible with the detergents needed in membrane protein studies. The available detergent-compatible liquid crystals are negatively charged, thus offering effectively only one of five orthogonal components of the alignment Saupe matrix. In this communication, we present a robust liquid crystalline medium that is positively charged, pinacyanol acetate (PNA), for the determination of orthogonal sets of RDCs in membrane proteins. This new medium promises to enhance the accuracy of membrane protein structures and the measurement of dynamics based on RDCs.

Structure and Dynamics of Membrane Proteins and Membrane Associated Proteins with Native Bicelles from Eukaryotic Tissues

In vitro studies of protein structure, function, and dynamics typically preclude the complex range of molecular interactions found in living tissues. In vivo studies elucidate these complex relationships, yet they are typically incompatible with the extensive and controlled biophysical experiments available in vitro. We present an alternative approach by extracting membranes from eukaryotic tissues to produce native bicelles to capture the rich and complex molecular environment of in vivo studies while retaining the advantages of in vitro experiments. Native bicelles derived from chicken egg or mouse cerebrum tissues contain a rich composition of phosphatidylcholine (PC), phosphatidylethanolamine (PE), phosphatidylglycerol (PG), phosphatidylserine (PS), phosphatidylinositol (PI), phosphatidic acid (PA), lysolipids, cholesterol, ceramides (CM), and sphingomyelin (SM). The bicelles also contain source-specific lipids such as triacylglycerides (TAGs) and sulfatides from egg and brain tissues, respectively. With the influenza hemagglutinin fusion peptide (HAfp) and the C-terminal Src homology domain of lymphocyte-specific protein-tyrosine kinase (lck-cSH2), we show that membrane proteins and membrane associated proteins reconstituted in native bicelles produce high-resolution NMR data and probe native protein-lipid interactions.

Hybrid NMR: A Union of Solution- and Solid-State NMR

Hybrid NMR (hdNMR) is a powerful new tool that combines the strengths of solution- and solid-state NMR to measure dipolar, chemical shift, and quadrupolar tensors in aqueous solution. We introduce the theory of hdNMR and partially randomly oriented (PRO) crystalline hydrogel samples. PRO samples produce randomly oriented spectra with characteristic Pake patterns from the solid state, yet they maintain the high-resolution dispersion of solution NMR experiments. With new pulse sequences, we show how hdNMR can be used to measure with high precision the 1Hα-13Cα dipolar tensor and carboxylate chemical shift anisotropy tensor of aspartate. These measurements contain detailed information on the distribution of electron density, interatomic distances, and the orientation dependence of molecular motion.