Spontaneous Aggregation of the Insulin-Derived Steric Zipper Peptide VEALYL Results in Different Aggregation Forms with Common Features

Recently, several short peptides have been shown to self-assemble into amyloid fibrils with generic cross-β spines, so-called steric zippers, suggesting common underlying structural features and aggregation mechanisms. Understanding these mechanisms is a prerequisite for designing fibril-binding compounds and inhibitors of fibril formation. The hexapeptide VEALYL, corresponding to the residues B12-17 of full-length insulin, has been identified as one of these short segments. Here, we analyzed the structures of multiple, morphologically different (fibrillar, microcrystal-like, oligomeric) [¹³C,¹⁵N]VEALYL samples by solid-state nuclear magnetic resonance complemented with results from molecular dynamics simulations. By performing NHHC/CHHC experiments, we could determine that the β-strands within a given sheet of the amyloid-like fibrils formed by the insulin hexapeptide VEALYL are stacked in an antiparallel manner, whereas the sheet-to-sheet packing arrangement was found to be parallel. Experimentally observed secondary chemical shifts for all aggregate forms, as well as ∅ and ψ backbone torsion angles calculated with TALOS, are indicative of β-strand conformation, consistent with the published crystal structure (PDB ID: 2OMQ). Thus, we could demonstrate that the structural features of all the observed VEALYL aggregates are in agreement with the previously observed homosteric zipper spine packing in the crystalline state, suggesting that several distinct aggregate morphologies share the same molecular architecture.     

Dual transformation of homonuclear solid-state NMR spectra—an option to decrease measuring time

Long measurement times due to low sensitivity are a prime concern in solid-state NMR and limit the application of multidimensional experiments severely. One possibility to address this problem could be post-experimental suppression of noise and a reduction of the number of increments needed for higher dimensional data sets. This can be achieved by a hybrid approach based on the combination of separately Fourier transformed and covariance processed datasets. The method is applied to synthetic sets as well as to experimental two-dimensional homonuclear solid-state NMR spectra of peptide samples. It is demonstrated that a reduction in experiment time by a factor of 4 can be achieved for the case of a ¹³C-¹³C correlation spectrum on the nonapeptide bradykinin.     

Structural constraints on the transmembrane and juxtamembrane regions of the phospholamban pentamer in membrane bilayers: Gln29 and Leu52

The Ca²⁺-ATPase of cardiac muscle cells transports Ca²⁺ ions against a concentration gradient into the sarcoplasmic reticulum and is regulated by phospholamban, a 52-residue integral membrane protein. It is known that phospholamban inhibits the Ca²⁺ pump during muscle contraction and that inhibition is removed by phosphorylation of the protein during muscle relaxation. Phospholamban forms a pentameric complex with a central pore. The solid-state magic angle spinning (MAS) NMR measurements presented here address the structure of the phospholamban pentamer in the region of Gln22-Gln29. Rotational echo double resonance (REDOR) NMR measurements show that the side chain amide groups of Gln29 are in close proximity, consistent with a hydrogen-bonded network within the central pore. ¹³C MAS NMR measurements are also presented on phospholamban that is 1-¹³C-labeled at Leu52, the last residue of the protein. pH titration of the C-terminal carboxyl group suggests that it forms a ring of negative charge on the lumenal side of the sarcoplasmic reticulum membrane. The structural constraints on the phospholamban pentamer described in this study are discussed in the context of a multifaceted mechanism for Ca²⁺ regulation that may involve phospholamban as both an inhibitor of the Ca²⁺ ATPase and as an ion channel.     

NMR crystallography: The effect of deuteration on high resolution C solid state NMR spectra of a 7-TM protein

The effect of deuteration on the ¹³C linewidths of U-¹³C, ¹⁵N 2D crystalline bacteriorhodopsin (bR) from Halobacterium salinarium, a 248-amino acid protein with seven-transmembrane (7TM) spanning regions, has been studied in purple membranes as a prelude to potential structural studies. Spectral doubling of resonances was observed for receptor expressed in ²H medium (for both 50:50% 1H:2H, and a more highly deuterated form) with the resonances being of similar intensities and separated by < 0.3 ppm in the methyl spectral regions in which they were readily distinguished. Line-widths of the methyl side chains were not significantly altered when the protein was expressed in highly deuterated medium compared to growth in fully protonated medium (spectral line widths were about 0.5 ppm on average for receptor expressed both in the fully protonated and highly deuterated media from the Cδ, Cγ₁, and Cγ₂ Ile ¹³C signals observed in the direct, 21-39 ppm, and indirect, 9-17 ppm, dimensions). The measured ¹³C NMR line-widths observed for both protonated and deuterated form of the receptor are sufficiently narrow, indicating that this crystalline protein morphology is suitable for structural studies. ¹H decoupling comparison of the protonated and deuterated bR imply that deuteration may be advantageous for samples in which low power ¹H decoupling is required.     

Light Activation of Rhodopsin: Insights from Molecular Dynamics Simulations Guided by Solid-State NMR Distance Restraints

Structural restraints provided by solid-state NMR measurements of the metarhodopsin II intermediate are combined with molecular dynamics simulations to help visualize structural changes in the light activation of rhodopsin. Since the timescale for the formation of the metarhodopsin II intermediate (> 1 ms) is beyond that readily accessible by molecular dynamics, we use NMR distance restraints derived from ¹³C dipolar recoupling measurements to guide the simulations. The simulations yield a working model for how photoisomerization of the 11-cis retinylidene chromophore bound within the interior of rhodopsin is coupled to transmembrane helix motion and receptor activation. The mechanism of activation that emerges is that multiple switches on the extracellular (or intradiscal) side of rhodopsin trigger structural changes that converge to disrupt the ionic lock between helices H3 and H6 on the intracellular side of the receptor.     

Veratridine binding to a transmembrane helix of sodium channel Nav1.4 determined by solid-state NMR

The multi-step ligand action to a target protein is an important aspect when understanding mechanisms of ligand binding and discovering new drugs. However, structurally capturing such complex mechanisms is challenging. This is particularly true for interactions between large membrane proteins and small molecules. One such large membrane of interest is Na_v1.4, a eukaryotic voltage-gated sodium channel. Domain 4 segment 6 (D4S6) of Na_v1.4 is a transmembrane α-helical segment playing a key role in channel gating regulation, and is targeted by a neurotoxin, veratridine (VTD). VTD has been suggested to exhibit a two-step action to activate Na_v1.4. Here, we determine the NMR structure of a selectively ¹³C-labeled peptide corresponding to D4S6 and its VTD binding site in lipid bilayers determined by using magic-angle spinning solid-state NMR. By ¹³C NMR, we obtain NMR structural constraints as ¹³C chemical shifts and the ¹H-²H dipolar couplings between the peptide and deuterated lipids. The peptide backbone structure and its location with respect to the membrane are determined under the obtained NMR structural constraints aided by replica exchange molecular dynamics simulations with an implicit membrane/solvent system. Further, by measuring the ¹H-²H dipolar couplings to monitor the peptide-lipid interaction, we identify a VTD binding site on D4S6. When superimposed to a crystal structure of a bacterial sodium channel Na_vRh, the determined binding site is the only surface exposed to the protein exterior and localizes beside the second-step binding site reported in the past. Based on these results, we propose that VTD initially binds to these newly-determined residues on D4S6 from the membrane hydrophobic domain, which induces the first-step channel opening followed by the second-step blocking of channel inactivation of Na_v1.4. Our findings provide new detailed insights of the VTD action mechanism, which could be useful in designing new drugs targeting D4S6.     

Prion Fibrils of Ure2p Assembled under Physiological Conditions Contain Highly Ordered, Natively Folded Modules

The difference between the prion and the non-prion form of a protein is given solely by its three-dimensional structure, according to the prion hypothesis. It has been shown that solid-state NMR can unravel the atomic-resolution three-dimensional structure of prion fragments but, in the case of Ure2p, no highly resolved spectra are obtained from the isolated prion domain. Here, we demonstrate that the spectra of full-length fibrils of Ure2p interestingly lead to highly resolved solid-state NMR spectra. Prion fibrils formed under physiological conditions are therefore well-ordered objects on the molecular level. Comparing the full-length NMR spectra with the corresponding spectra of the prion and globular domains in isolation reveals that the globular part in particular shows almost perfect structural order. The NMR linewidths in these spectra are as narrow as the ones observed in crystals of the isolated globular domain. For the prion domain, the spectra reflect partial disorder, suggesting structural heterogeneity, both in isolation and in full-length Ure2p fibrils, although to different extents. The spectral quality is surprising in the light of existing structural models for Ure2p and in comparison to the corresponding spectra of the only other full-length prion fibrils (HET-s) investigated so far. This opens the exciting perspective of an atomic-resolution structure determination of the fibrillar form of a prion whose assembly is not accompanied by significant conformational changes and documents the structural diversity underlying prion propagation.     

Solid-state NMR and molecular dynamics simulations reveal the oligomeric ion-channels of TM2-GABAA stabilized by intermolecular hydrogen bonding

The second transmembrane (TM2) domain of GABA_A receptor forms the inner-lining surface of chloride ion-channel and plays important roles in the function of the receptor protein. In this study, we report the first structure of TM2 in lipid bilayers determined using solid-state NMR and MD simulations. The interatomic ¹³C-¹⁵N distances measured from REDOR magic angle spinning experiments on multilamellar vesicles, containing a TM2 peptide site specifically labeled with ¹³C′ and ¹⁵N isotopes, were used to determine the secondary structure of the peptide. The ¹⁵N chemical shift and ¹H-¹⁵N dipolar coupling parameters measured from PISEMA experiments on mechanically aligned phospholipid bilayers, containing a TM2 peptide site specifically labeled with ¹⁵N isotopes, under static conditions were used to determine the membrane orientation of the peptide. Our results reveal that the TM2 peptide forms an alpha helical conformation with a tilted transmembrane orientation, which is unstable as a monomer but stable as pentameric oligomers as indicated by MD simulations. Even though the peptide consists of a number of hydrophilic residues, the transmembrane folding of the peptide is stabilized by intermolecular hydrogen bondings between the side chains of Ser and Thr residues as revealed by MD simulations. The results also suggest that peptide-peptide interactions in the tilted transmembrane orientation overcome the hydrophobic mismatch between the peptide and bilayer thickness.     

Peptide antibiotics in action: Investigation of polypeptide chains in insoluble environments by rotational-echo double resonance

Rotational-echo double resonance (REDOR) is a solid-state NMR technique that has the capability of providing intra- and intermolecular distance and orientational restraints in non-crystallizable, poorly soluble heterogeneous molecular systems such as cell membranes and cell walls. In this review, we will present two applications of REDOR: the investigation of a magainin-related antimicrobial peptide in lipid bilayers and the study of a vancomycin-like glycopeptide in the cell walls of Staphylococcus aureus.     

Three-Dimensional Solid-State NMR Study of a Seven-Helical Integral Membrane Proton Pump—Structural Insights

Proteorhodopsin (PR) is a recently discovered ubiquitous eubacterial retinal-binding light-driven proton pump. Almost 1000 PR variants are widely distributed in species of marine and freshwater bacteria, suggesting PR's important photobiological role. PR is a typical seven-transmembrane α-helical membrane protein and as such poses a significant challenge to structural studies. Attempts to crystallize PR have not been successful, and its three-dimensional structure remains unknown. We show that PR reconstituted in lipids gives well-resolved magic-angle spinning NMR spectra of high signal-to-noise ratio. We report sequential assignment of ¹³C and ¹⁵N backbone and side-chain chemical shifts for 103 of 238 residues in PR, achieved by three-dimensional chemical shift correlation experiments performed on two samples with different patterns of reverse labeling. The chemical shift analysis gives a number of important structural insights not available from other studies: we have established protonation states of several carboxylic acids, identified the boundaries and distortions of transmembrane α-helices, and detected secondary structure elements in the loops. We confirmed that internal Asp227, which was proposed to form part of the Schiff base counterion, is ionized, while Glu142, which is located close to the extracellular surface, is neutral, in agreement with earlier predictions. We infer that, similar to bacteriorhodopsin's structure, PR has a proline kink in helix C, a non-proline kink in helix G, a short β-turn in the B-C loop, and a short α-helical segment in the E-F loop.     

Characterization of the sodium binding sites in microcrystalline ATP by Na-solid-state NMR and ab initio calculations

Stepwise conformational transition of disodium adenosine 5′-triphosphate (Na₂ATP) crystals as a function of relative humidity (r.H.), was examined by means of high resolution ²³Na, ³¹P solid state NMR spectroscopy and quantum mechanics calculations. ²³Na-MQMAS solid state NMR spectra of hydrated disodium salts of adenosine 5,5′-triphosphate were measured to characterize the individual sodium sites. Quadrupolar coupling constants (C_Q), and the asymmetry parameters of the electric field gradient tensors (η) of sodium-23 determined by quantum mechanical calculations (gaussian03) using larger clusters than in previous studies were compared to the experimental ²³Na-MQMAS spectra.     

Partial site-specific assignment of a uniformly C, N enriched membrane protein, light-harvesting complex 1 (LH1), by solid state NMR

Partial site-specific assignments are reported for the solid state NMR spectra of light-harvesting complex 1, a 160 kDa integral membrane protein. The assignments were derived from 600 MHz ¹⁵N-¹³CO-¹³Cα and ¹⁵N-¹³Cα-¹³CX correlation spectra, using uniformly ¹³C, ¹⁵N enriched hydrated material, in an intact and precipitated form. Sequential assignments were verified using characteristic ¹⁵N-¹³Cα-¹³Cβ side chain chemical shifts observed in 3D experiments. Tertiary contacts found in 2D DARR spectra of the selectively ¹³C enriched sample provided further confirmatory evidence for the assignments. The assignments include the region of the Histidine ligands binding the Bacteriochlorophyll chromophore. The chemical shifts of Cα and Cβ resonances indicated the presence of typical α-helical secondary structure, consistent with previous studies.     

Retinal dynamics during light activation of rhodopsin revealed by solid-state NMR spectroscopy

Rhodopsin is a canonical member of class A of the G protein-coupled receptors (GPCRs) that are implicated in many of the drug interventions in humans and are of great pharmaceutical interest. The molecular mechanism of rhodopsin activation remains unknown as atomistic structural information for the active metarhodopsin II state is currently lacking. Solid-state ²H NMR constitutes a powerful approach to study atomic-level dynamics of membrane proteins. In the present application, we describe how information is obtained about interactions of the retinal cofactor with rhodopsin that change with light activation of the photoreceptor. The retinal methyl groups play an important role in rhodopsin function by directing conformational changes upon transition into the active state. Site-specific ²H labels have been introduced into the methyl groups of retinal and solid-state ²H NMR methods applied to obtain order parameters and correlation times that quantify the mobility of the cofactor in the inactive dark state, as well as the cryotrapped metarhodopsin I and metarhodopsin II states. Analysis of the angular-dependent ²H NMR line shapes for selectively deuterated methyl groups of rhodopsin in aligned membranes enables determination of the average ligand conformation within the binding pocket. The relaxation data suggest that the β-ionone ring is not expelled from its hydrophobic pocket in the transition from the pre-activated metarhodopsin I to the active metarhodopsin II state. Rather, the major structural changes of the retinal cofactor occur already at the metarhodopsin I state in the activation process. The metarhodopsin I to metarhodopsin II transition involves mainly conformational changes of the protein within the membrane lipid bilayer rather than the ligand. The dynamics of the retinylidene methyl groups upon isomerization are explained by an activation mechanism involving cooperative rearrangements of extracellular loop E2 together with transmembrane helices H5 and H6. These activating movements are triggered by steric clashes of the isomerized all-trans retinal with the β4 strand of the E2 loop and the side chains of Glu¹²² and Trp²⁶⁵ within the binding pocket. The solid-state ²H NMR data are discussed with regard to the pathway of the energy flow in the receptor activation mechanism.     

Conformation and Trimer Association of the Transmembrane Domain of the Parainfluenza Virus Fusion Protein in Lipid Bilayers from Solid-State NMR: Insights into the Sequence Determinants of Trimer Structure and Fusion Activity

Enveloped viruses enter cells by using their fusion proteins to merge the virus lipid envelope and the cell membrane. While crystal structures of the water-soluble ectodomains of many viral fusion proteins have been determined, the structure and assembly of the C-terminal transmembrane domain (TMD) remains poorly understood. Here we use solid-state NMR to determine the backbone conformation and oligomeric structure of the TMD of the parainfluenza virus 5 fusion protein. ¹³C chemical shifts indicate that the central leucine-rich segment of the TMD is α-helical in POPC/cholesterol membranes and POPE membranes, while the Ile- and Val-rich termini shift to the β-strand conformation in the POPE membrane. Importantly, lipid mixing assays indicate that the TMD is more fusogenic in the POPE membrane than in the POPC/cholesterol membrane, indicating that the β-strand conformation is important for fusion by inducing membrane curvature. Incorporation of para-fluorinated Phe at three positions of the α-helical core allowed us to measure interhelical distances using ¹⁹F spin diffusion NMR. The data indicate that, at peptide:lipid molar ratios of ~ 1:15, the TMD forms a trimeric helical bundle with inter-helical distances of 8.2–8.4 Å for L493F and L504F and 10.5 Å for L500F. These data provide high-resolution evidence of trimer formation of a viral fusion protein TMD in phospholipid bilayers, and indicate that the parainfluenza virus 5 fusion protein TMD harbors two functions: the central α-helical core is the trimerization unit of the protein, while the two termini are responsible for inducing membrane curvature by transitioning to a β-sheet conformation.     

Solid-state NMR and functional studies on proteorhodopsin

Proteins of the proteorhodopsin (PR) family are found abundantly in many marine bacteria in the photic zone of the oceans. They are colour-tuned to their environment. The green absorbing species has been shown to act as a light-driven proton pump and thus could form a potential source of energy. The pK_a of the primary proton acceptor is close to the pH of seawater which could also indicate a regulatory role. Here, we review and summarize our own recent findings in the context of known data and present some new results. Proton transfer in vitro by PR is shown by a fluorescence assay which confirms a pH dependent vectoriality. Previously reported low diffracting 2D crystal preparations of PR are assessed for their use for solid-state NMR by two dimensional ¹³C-¹³C DARR spectra. ¹⁵N-¹H HETCOR MAS NMR experiments show bound water in the vicinity of the protonated Schiff base which could play a role in proton transfer. The effect of highly conserved H75 onto the properties of the chromophore has been investigated by single site mutations. They do show a pronounced effect onto the optical absorption maximum and the pK_a of the proton acceptor but have only a small effect onto the ¹⁵N chemical shifts of the protonated Schiff base.     

Structural analysis of pituitary adenylate cyclase-activating polypeptides bound to phospholipid membranes by magic angle spinning solid-state NMR

PACAP (pituitary adenylate cyclase-activating polypeptide) is a member of the VIP/secretin/glucagon family, which includes the ligands of class II G-protein coupled receptors. Since the recognition of PACAP by the receptor may involve the binding of PACAP to membranes, its membrane-bound structure should be important. We have carried out structural analysis of uniformly ¹³C,¹⁵N labeled PACAP27 and its C-terminal truncated form PACAP(1-21)NH₂ (PACAP21) bound to membranes with high resolution solid-state NMR. Phosphatidylcholine bilayers and phosphatidylcholine/phosphatidylglycerol bilayers were used for PACAP27 and PACAP21, respectively. Most backbone signals were assigned for PACAP27 and PACAP21. TALOS analysis revealed that both peptides take on extended conformations on the membranes. Dilution of PACAP21 did not change the conformation of the major part. Selective polarization transfer experiment confirmed that PACAP27 is interacting with the membranes. It was concluded that the interaction of PACAP with the membrane surface causes their extended conformation. PACAP27 is reported to take an α-helical conformation in dodecylphosphocholine micelles and membrane-binding peptides usually take similar conformations in micelles and in membranes. Therefore, the property of PACAP27 changing its conformation in response to its environment is unique. Its conformational flexibility may be associated with its wide variety of functions.     

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 Similarity between the Prion Domain of HET-s and a Homologue Can Explain Amyloid Cross-Seeding in Spite of Limited Sequence Identity

We describe a distant homologue of the fungal HET-s prion, which is found in the fungus Fusarium graminearum. The domain FgHET-s(218-289), which corresponds to the prion domain in HET-s from Podospora anserina, forms amyloid fibrils in vitro and is able to efficiently cross-seed HET-s(218-289) prion formation. We structurally characterize FgHET-s(218-289), which displays 38% sequence identity with HET-s(218-289). Solid-state NMR and hydrogen/deuterium exchange detected by NMR show that the fold and a number of structural details are very similar for the prion domains of the two proteins. This structural similarity readily explains why cross-seeding occurs here in spite of the sequence divergence.     

NMR studies on fully hydrated membrane proteins, with emphasis on bacteriorhodopsin as a typical and prototype membrane protein

The 3D structures or dynamic feature of fully hydrated membrane proteins are very important at ambient temperature, in relation to understanding their biological activities, although their data, especially from the flexible portions such as surface regions, are unavailable from X-ray diffraction or cryoelectron microscope at low temperature. In contrast, high-resolution solid-state NMR spectroscopy has proved to be a very convenient alternative means to be able to reveal their dynamic structures. To clarify this problem, we describe here how we are able to reveal such structures and dynamic features, based on intrinsic probes from high-resolution solid-state NMR studies on bacteriorhodopsin (bR) as a typical membrane protein in 2D crystal, regenerated preparation in lipid bilayer and detergents. It turned out that their dynamic features are substantially altered upon their environments where bR is present. We further review NMR applications to study structure and dynamics of a variety of membrane proteins, including sensory rhodopsin, rhodopsin, photoreaction centers, diacylglycerol kinases, etc.     

The cytochromes P450 and b5 and their reductases—Promising targets for structural studies by advanced solid-state NMR spectroscopy

Members of the cytochrome P450 (cyt P450) superfamily of enzymes oxidize a wide array of endogenous and xenobiotic substances to prepare them for excretion. Most of the drugs in use today are metabolized in part by a small set of human cyt P450 isozymes. Consequently, cyt P450s have for a long time received a lot of attention in biochemical and pharmacological research. Cytochrome P450 receives electrons from cytochrome P450 reductase and in selected cases from cytochrome b₅ (cyt b₅). Numerous structural studies of cyt P450s, cyt b₅, and their reductases have given considerable insight into fundamental structure-function relationships. However, structural studies so far have had to rely on truncated variants of the enzymes to make conventional X-ray crystallographic and solution-state NMR techniques applicable. In spite of significant efforts it has not yet been possible to crystallize any of these proteins in their full-length membrane bound forms. The truncated parts of the enzymes are assumed to be α-helical membrane anchors that are essential for some key properties of cyt P450s. In the present contribution we set out with a basic overview on the current status of functional and structural studies. Our main aim is to demonstrate how advanced modern solid-state NMR spectroscopic techniques will be able to make substantial progress in cyt P450 research. Solid-state NMR spectroscopy has sufficiently matured over the last decade to be fully applicable to any membrane protein system. Recent years have seen a remarkable increase in studies on membrane protein structure using a host of solid-state NMR techniques. Solid-state NMR is the only technique available today for structural studies on full-length cyt P450 and full-length cyt b₅. We aim to give a detailed account of modern techniques as applicable to cyt P450 and cyt b₅, to show what has already been possible and what seems to be viable in the very near future.