Analysis of carotenoid isomerase activity in a prototypical carotenoid cleavage enzyme, apocarotenoid oxygenase (ACO).

Carotenoid cleavage enzymes (CCEs) constitute a group of evolutionarily related proteins that metabolize a variety of carotenoid and non-carotenoid substrates. Typically, these enzymes utilize a non-heme iron center to oxidatively cleave a carbon-carbon double bond of a carotenoid substrate. Some members also isomerize specific double bonds in their substrates to yield cis-apocarotenoid products. The apocarotenoid oxygenase from Synechocystis has been hypothesized to represent one such member of this latter category of CCEs. Here, we developed a novel expression and purification protocol that enabled production of soluble, native ACO in quantities sufficient for high resolution structural and spectroscopic investigation of its catalytic mechanism. High performance liquid chromatography and Raman spectroscopy revealed that ACO exclusively formed all-trans products. We also found that linear polyoxyethylene detergents previously used for ACO crystallization strongly inhibited the apocarotenoid oxygenase activity of the enzyme. We crystallized the native enzyme in the absence of apocarotenoid substrate and found electron density in the active site that was similar in appearance to the density previously attributed to a di-cis-apocarotenoid intermediate. Our results clearly demonstrated that ACO is in fact a non-isomerizing member of the CCE family. These results indicate that careful selection of detergent is critical for the success of structural studies aimed at elucidating structures of CCE-carotenoid/retinoid complexes.

Time-resolved events on the reaction pathway of transcript initiation by a single-subunit RNA polymerase: Raman crystallographic evidence.

The nucleotidyl transfer reaction leading to formation of the first phosphodiester bond has been followed in real time by Raman microscopy, as it proceeds in single crystals of the N4 phage virion RNA polymerase (RNAP). The reaction is initiated by soaking nucleoside triphosphate (NTP) substrates and divalent cations into the RNAP and promoter DNA complex crystal, where the phosphodiester bond formation is completed in about 40 min. This slow reaction allowed us to monitor the changes of the RNAP and DNA conformations as well as bindings of substrate and metal through Raman spectra taken every 5 min. Recently published snapshot X-ray crystal structures along the same reaction pathway assisted the spectroscopic assignments of changes in the enzyme and DNA, while isotopically labeled NTP substrates allowed differentiation of the Raman spectra of bases in substrates and DNA. We observed that substrates are bound at 2-7 min after soaking is commenced, the O-helix completes its conformational change, and binding of both divalent metals required for catalysis in the active site changes the conformation of the ribose triphosphate at position +1. These are followed by a slower decrease of NTP triphosphate groups due to phosphodiester bond formation that reaches completion at about 15 min and even slower complete release of the divalent metals at about 40 min. We have also shown that the O-helix movement can be driven by substrate binding only. The kinetics of the in crystallo nucleotidyl transfer reaction revealed in this study suggest that soaking the substrate and metal into the RNAP-DNA complex crystal for a few minutes generates novel and uncharacterized intermediates for future X-ray and spectroscopic analysis.

Structure-specific effects of protein topology on cross-beta assembly: studies of insulin fibrillation.

Systemic amyloidoses, an important class of protein misfolding diseases, are often due to fibrillation of disulfide-cross-linked globular proteins otherwise unrelated in sequence or structure. Although cross-beta assembly is regarded as a universal property of polypeptides, it is not understood how such amyloids accommodate diverse disulfide connectivities. Does amyloidogenicity depend on protein topology? A model is provided by insulin, a two-chain protein containing three disulfide bridges. The importance of chain topology is demonstrated by mini-proinsulin (MP), a single-chain analogue in which the C-terminus of the B chain (residue B30) is tethered to the N-terminus of the A chain (A1). The B30-A1 tether impedes the fiber-specific alpha --> beta transition, leading to slow formation of a structurally nonuniform amorphous precipitate. Conversely, fibrillation is robust to interchange of disulfide bridges. Whereas native insulin exhibits pairings [A6-A11, A7-B7, and A20-B19], metastable isomers with alternative pairings [A6-B7, A7-A11, A20-B19] or [A6-A7, A11-B7, A20-B1] readily undergo fibrillation with essentially identical alpha --> beta transitions. Respective pairing schemes are in each case retained. Isomeric fibrils and the amorphous MP precipitate are each able to seed the fibrillation of wild-type insulin, suggesting a structural correspondence between respective nuclei or modes of assembly. Together, our results demonstrate that effects of polypeptide topology on amyloidogenicity depend on structural context. Although the native structures and stabilities of single-chain insulin analogues are similar to those of wild-type insulin, the interchain tether constrains the extent of conformational distortion at elevated temperature, retards initial non-native aggregation, and is apparently incompatible with the mature structure of an insulin protofilament. We speculate that the general danger of fibrillation has imposed a constraint in protein evolution, selecting for topologies unfavorable to amyloid formation.

Raman spectroscopic characterization of secondary structure in natively unfolded proteins: alpha-synuclein.

The application of Raman spectroscopy to characterize natively unfolded proteins has been underdeveloped, even though it has significant technical advantages. We propose that a simple three-component band fitting of the amide I region can assist in the conformational characterization of the ensemble of structures present in natively unfolded proteins. The Raman spectra of alpha-synuclein, a prototypical natively unfolded protein, were obtained in the presence and absence of methanol, sodium dodecyl sulfate (SDS), and hexafluoro-2-propanol (HFIP). Consistent with previous CD studies, the secondary structure becomes largely alpha-helical in HFIP and SDS and predominantly beta-sheet in 25% methanol in water. In SDS, an increase in alpha-helical conformation is indicated by the predominant Raman amide I marker band at 1654 cm(-1) and the typical double minimum in the CD spectrum. In 25% HFIP the amide I Raman marker band appears at 1653 cm(-1) with a peak width at half-height of approximately 33 cm(-1), and in 25% methanol the amide I Raman band shifts to 1667 cm(-1) with a peak width at half-height of approximately 26 cm(-1). These well-characterized structural states provide the unequivocal assignment of amide I marker bands in the Raman spectrum of alpha-synuclein and by extrapolation to other natively unfolded proteins. The Raman spectrum of monomeric alpha-synuclein in aqueous solution suggests that the peptide bonds are distributed in both the alpha-helical and extended beta-regions of Ramachandran space. A higher frequency feature of the alpha-synuclein Raman amide I band resembles the Raman amide I band of ionized polyglutamate and polylysine, peptides which adopt a polyproline II helical conformation. Thus, a three-component band fitting is used to characterize the Raman amide I band of alpha-synuclein, phosvitin, alpha-casein, beta-casein, and the non-A beta component (NAC) of Alzheimer's plaque. These analyses demonstrate the ability of Raman spectroscopy to characterize the ensemble of secondary structures present in natively unfolded proteins.

Transcarboxylase: one of nature's early nanomachines.

The enzyme transcarboxylase (TC) catalyzes an unusual reaction; TC transfers a carboxylate group from methylmalonyl-CoA to pyruvate to form oxaloacetate and propionyl-CoA. Remarkably, to perform this task in Propionii bacteria Nature has created a large assembly made up of 30 polypeptides that totals 1.2 million daltons. In this nanomachine the catalytic machinery is repeated 6-12 times over using ordered arrays of replicated subunits. The latter are sites of the half reactions. On the so-called 12S subunit a biotin cofactor accepts carboxylate, - CO2- , from methylmalonyl-CoA. The carboxylated-biotin then translocates to a second subunit, the 5S, to deliver the carboxylate to pyruvate. We have not yet characterized the intact nanomachine, however, using a battery of biophysical techniques, we have been able to derive novel,and sometimes unexpected, structural and mechanistic insights into the 12S and 5S subunits. Similar insights have been obtained for the small 1.3S subunit that acts as the biotin carrier linking the 12S and 5S forms. Interestingly, some of these insights gained for the 12S and 5S subunits carry over to related mammalian enzymes such as human propionyl-CoA carboxylase and human pyruvate carboxylase, respectively, to provide a rationale for their malfunction in disease-related mutations.

Insulin assembly damps conformational fluctuations: Raman analysis of amide I linewidths in native states and fibrils.

The crystal structure of insulin has been investigated in a variety of dimeric and hexameric assemblies. Interest in dynamics has been stimulated by conformational variability among crystal forms and evidence suggesting that the functional monomer undergoes a conformational change on receptor binding. Here, we employ Raman spectroscopy and Raman microscopy to investigate well-defined oligomeric species: monomeric and dimeric analogs in solution, native T(6) and R(6) hexamers in solution and corresponding polycrystalline samples. Remarkably, linewidths of Raman bands associated with the polypeptide backbone (amide I) exhibit progressive narrowing with successive self-assembly. Whereas dimerization damps fluctuations at an intermolecular beta-sheet, deconvolution of the amide I band indicates that formation of hexamers stabilizes both helical and non-helical elements. Although the structure of a monomer in solution resembles a crystallographic protomer, its encagement in a native assembly damps main-chain fluctuations. Further narrowing of a beta-sheet-specific amide I band is observed on reorganization of insulin in a cross-beta fibril. Enhanced flexibility of the native insulin monomer is in accord with molecular dynamics simulations. Such conformational fluctuations may initiate formation of an amyloidogenic nucleus and enable induced fit on receptor binding.