Combinatorial syntheses of sugar derivatives

There has been an exponential growth in interest of the functional roles of carbohydrates and cell surface glycoconjugates in the past 10 years. The importance of glycoconjugates as mediators of biosignals has stimulated investigation into simple and versatile methods for their synthesis. The synthesis of carbohydrates and glycoconjugates by combinatorial chemistry has gained considerable interest.     

13C nmr spectra of some serjanic acid derivatives

Full assignments have been made for the ¹³C NMR signals of methyl serjanate, methyl acetyl serjanate, methyl-3-keto serjanate and methyl acetyl-11-keto serjanate. These data are useful for structural determination without previous chemical degradation of the saponins obtained from members of the Phytolaccaceae.     

31P nmr spin-lattice relaxation studies of deoxyoligonucleotides

Temperature-dependent conformational transitions of deoxyoligonucleotides have been monitored by measuring ³¹P chemical shifts, spin-lattice relaxation times (T₁), and ³¹P-{H} nuclear Overhauser enhancements (NOEs). The measured NOE ranged from 30 to 80%, compared to the theoretical maximum of 124% for a dipolar relaxation mediated by rapid isotropic rotation. The observed 3′-5′ phosphate diester ³¹P T₁ showed a similar temperature dependence over the range 2–75°C for both double- and single-stranded oligonucleotides, and for dinucleotides. The results show that dipole–dipole interactions dominate the internucleotide phosphate relaxation rate in oligonucleotides. The same is true of terminal phosphate groups at low temperature; but at higher temperature another process, possibly due to contamination by paramagnetic ions, becomes dominant. The rotational correlation time τ_R calculated from the dipole–dipole relaxation rate of the internucleotide phosphate in d(pA)₂ at 16°C is τ_R = 5.0 × 10^?10 sec, implying a Stokes radius for isotropic rotation of 7.6 Å. The T₁ and NOE values for the double-helical octanucleotide d(pA)₃pGpC(pT)₃ are consistent with dominance of dipole–dipole relaxation and isotropic rotation of a sphere of radius 14 Å, a reasonable dimension for the double helix. Activation energies for the rotation of dinucleotides range from 4 to 6 kcal/mol, close to the value of 4 kcal/mol expected for isotropic rotation. In order to test the possible effect of internal motion of correlation time τ_G on the results, we considered a model in which the nucleotide chain rotates about the P-O bonds. Comparison of the calculation with our experimental results shows that internal motion with τ_G ? 10^?9 sec, as found from other studies to be present for large nucleic acids, would not influence out T₁ and NOE values enough to be distinguished from isotropic rotation. However, we can conclude that τ_G cannot be as fast as 10^?10 sec, even for dinucleotides.     

High-resolution nmr studies of A- and G-containing oligonucleotides

We report the temperature dependence of the H2 and H8 purine ring proton resonances of oligoriboadenylates up to chain length 11, with or without a single guanosine residue at the 5′-end, second position, or 3′-end. The results suggest the following generalizations: (1) Stacking of the bases in a right-handed single-stranded helix is more extensive in the interior of the chain than at the chain ends. (2) The tendency of the terminal base to unstack is greater at the 5′-end than at the 3′-terminus. (3) G stacks more weakly than A, as evidenced by weak stacking of 3′-terminal G. Anomalies were also observed in the unstacking profile of G at the second position in the chain, indicating a conformational anomaly such as looping out of G, thereby allowing adjacent A's to stack together, or adoption by G of some other alternative structure. (4) The results imply that the environment at a given base is influenced by effects of longer range than nearest- or next-nearest-neighbor. Increasing ion condensation as chain length increases may be responsible for the slow approach of oligomer behavior to the properties of the high polymer.     

Electrochemical and ligand binding studies of a de novo heme protein

Heme proteins can perform a variety of electrochemical functions. While natural heme proteins carry out particular functions selected by biological evolution, artificial heme proteins, in principle, can be tailored to suit specified technological applications. Here we describe initial characterization of the electrochemical properties of a de novo heme protein, S824C. Protein S824C is a four-helix bundle derived from a library of sequences that was designed by binary patterning of polar and nonpolar amino acids. Protein S824C was immobilized on a gold electrode and the formal potential of heme-protein complex was studied as a function of pH and ionic strength. The binding of exogenous N-donor ligands to heme/S824C was monitored by measuring shifts in the potential that occurred upon addition of various concentrations of imidazole or pyridine derivatives. The response of heme/S824C to these ligands was then compared to the response of isolated heme (without protein) to the same ligands. The observed shifts in potential depended on both the concentration and the structure of the added ligand. Small changes in structure of the ligand (e.g. pyridine versus 2-amino pyridine) produced significant shifts in the potential of the heme-protein. The observed shifts correlate to the differential binding of the N-donor molecules to the oxidized and reduced states of the heme. Further, it was observed that the electrochemical response of the buried heme in heme/S824C differed significantly from that of isolated heme. These studies demonstrate that the structure of the de novo protein modulates the binding of N-donor ligands to heme.     

Raman studies of the C-H and C-D stretching regions in stearic acid and some specifically deuterated derivatives

Raman spectra of polycrystalline stearic acid-d₀, stearic acid-d₃₅, 16:16-d₂-18:18:18-d₃-stearic acid, 18:18:18-d₃-stearic acid, 17:17-d₂-stearic acid, 17-d₁-stearic acid, 16:16-d₂-stearic acid, 12:12-d₂-stearic acid and 12-d₁-stearic acid have been obtained for the region containing the C-D and C-H stretching vibrations. Assignments of the methyl, methyl-d₃, methylene, methylene-d₂ and methylene-d₁ stretching vibrations are discussed.     

Asymmetric syntheses of pipecolic acid and derivatives

Summary Results in the field of asymmetric synthesis of pipecolic acid derivatives are reviewed. Three sections describe the asymmetric syntheses of the title compounds (i) from the chiral pool (-amino acids or carbohydrates) (ii) using a chiral auxiliary either derived from terpenes,-amino acids, tartaric acid, an amine or-amino alcohols (iii) by means of asymmetric catalysis.     

Nonlinear optical studies of heme protein dynamics: implications for proteins as hybrid states of matter

Protein structure is fundamentally related to function. However, static structures alone are insufficient to understand how a protein works. Dynamics play an equally important role. Given that proteins are highly associated aperiodic systems, it may be expected that protein dynamics would follow glass-like dynamics. However, protein functions occur on time scales orders of magnitude faster than the time scales typically associated with glassy systems. It is becoming clear that the reaction forces driving functions do not sample entirely the large number of configurations available to a protein but are highly directed along an optimized pathway. Could there be any correlation between specific topological features in protein structures and dynamics that leads to strongly correlated atomic displacements in the dynamical response to a perturbation? This review will try to provide an answer by focusing upon recent nonlinear optical studies with the aim of directly observing functionally important protein motions over the entire dynamic range of the protein response function. The specific system chosen is photoinduced dynamics of ligand dissociation at the active site in heme proteins, with myoglobin serving as the simplest model system. The energetics and nuclear motions from the very earliest events involved in bond breaking on the femtosecond time scale all the way out to ligand escape and bimolecular rebinding on the microsecond and millisecond time scale have been mapped out. The picture that is emerging is that the system consists of strongly coupled motions from the very instant the bond breaks at the active site that cascade into low frequency collective modes specific to the protein structure. It is this coupling that imparts the ability of a protein to function on time scales more commensurate with liquids while simultaneously conserving structural integrity akin to solids.     

Hydrophobic modulation of heme properties in heme protein maquettes

We have investigated the properties of the two hemes bound to histidine in the H10 positions of the uniquely structured apo form of the heme binding four-helix bundle protein maquette [H10H24-L6I,L13F](2), here called [I(6)F(13)H(24)](2) for the amino acids at positions 6 (I), 13 (F) and 24 (H), respectively. The primary structure of each alpha-helix, alpha-SH, in [I(6)F(13)H(24)](2) is Ac-CGGGEI(6)WKL.H(10)EEF(13)LKK.FEELLKL.H(24)EERLKK.L-CONH(2). In our nomenclature, [I(6)F(13)H(24)] represents the disulfide-bridged di-alpha-helical homodimer of this sequence, i.e., (alpha-SS-alpha), and [I(6)F(13)H(24)](2) represents the dimeric four helix bundle composed of two di-alpha-helical subunits, i.e., (alpha-SS-alpha)(2). We replaced the histidines at positions H24 in [I(6)F(13)H(24)](2) with hydrophobic amino acids incompetent for heme ligation. These maquette variants, [I(6)F(13)I(24)](2), [I(6)F(13)A(24)](2), and [I(6)F(13)F(24)](2), are distinguished from the tetraheme binding parent peptide, [I(6)F(13)H(24)](2), by a reduction in the heme:four-helix bundle stoichiometry from 4:1 to 2:1. Iterative redesign has identified phenylalanine as the optimal amino acid replacement for H24 in the context of apo state conformational specificity. Furthermore, the novel second generation diheme [I(6)F(13)F(24)](2) maquette was related to the first generation diheme [H10A24](2) prototype, [L(6)L(13)A(24)](2) in the present nomenclature, via a sequential path in sequence space to evaluate the effects of conservative hydrophobic amino acid changes on heme properties. Each of the disulfide-linked dipeptides studied was highly helical (>77% as determined from circular dichroism spectroscopy), self-associates in solution to form a dimer (as determined by size exclusion chromatography), is thermodynamically stable (-DeltaG(H)2(O) >18 kcal/mol), and possesses conformational specificity that NMR data indicate can vary from multistructured to single structured. Each peptide binds one heme with a dissociation constant, K(d1) value, tighter than 65 nM forming a series of monoheme maquettes. Addition of a second equivalent of heme results in heme binding with a K(d2) in the range of 35-800 nM forming the diheme maquette state. Single conservative amino acid changes between peptide sequences are responsible for up to 10-fold changes in K(d) values. The equilibrium reduction midpoint potential (E(m7.5)) determined in the monoheme state ranges from -156 to -210 mV vs SHE and in the diheme state ranges from -144 to -288 mV. An observed heme-heme electrostatic interaction (>70 mV) in the diheme state indicates a syn global topology of the di-alpha-helical monomers. The heme affinity and electrochemistry of the three H24 variants studied identify the tight binding sites (K(d1) and K(d2) values <200 nM) having the lower reduction midpoint potentials (E(m7.5) values of -155 and -260 mV) with the H10 bound hemes in the parent tetraheme state of [H10H24-L6I,L13F](2), here called [I(6)F(13)H(24)](2). The results of this study illustrate that conservative hydrophobic amino acid changes near the heme binding site can modulate the E(m) by up to +/-50 mV and the K(d) by an order of magnitude. Furthermore, the effects of multiple single amino acid changes on E(m) and K(d) do not appear to be additive.     

Distance metrics for heme protein electron tunneling

There is no doubt that distance is the principal parameter that sets the order of magnitude for electron-tunneling rates in proteins. However, there continue to be varying ways to measure electron-tunneling distances in proteins. This distance uncertainty blurs the issue of whether the intervening protein medium has been naturally selected to speed or slow any particular electron-tunneling reaction. For redox cofactors lacking metals, an edge of the cofactor can be defined that approximates the extent in space that includes most of the wavefunction associated with its tunneling electron. Beyond this edge, the wavefunction tails off much more dramatically in space. The conjugated porphyrin ring seems a reasonable edge for the metal-free pheophytins and bacteriopheophytins of photosynthesis. For a metal containing redox cofactor such as heme, an appropriate cofactor edge is more ambiguous. Electron-tunneling distance may be measured from the conjugated heme macrocycle edge or from the metal, which can be up to 4.8 A longer. In a typical protein medium, such a distance difference normally corresponds to a approximately 1000 fold decrease in tunneling rate. To address this ambiguity, we consider both natural heme protein electron transfer and light-activated electron transfer in ruthenated heme proteins. We find that the edge of the conjugated heme macrocycle provides a reliable and useful tunneling distance definition consistent with other biological electron-tunneling reactions. Furthermore, with this distance metric, heme axially- and edge-oriented electron transfers appear similar and equally well described by a simple square barrier tunneling model. This is in contrast to recent reports for metal-to-metal metrics that require exceptionally poor donor/acceptor couplings to explain heme axially-oriented electron transfers.     

New PEG2 type polyethylene glycol derivatives for protein modification

Although proteins with 2,4-bis (o-methoxypolyethylene glycol)-6-chloro-s-triazine (PEG2-Cl) as a divalent PEG modification have some advantages compared to proteins with the linear PEG modification, PEG2Cl cannot react with amino groups at neutral pH. Therefore, we have prepared new PEG2 derivatives that have an activated ester as the functional group. We confirmed that these derivatives are useful for the divalent modification of proteins, such as bSOD and rhG-CSF. © Rapid Science Ltd. 1998     

Monomeric ferric heme peptide derivatives: Model systems for hemoproteins

Electron paramagnetic resonance spectra of a number of ferric heme peptide derivatives, in aqueous-detergent and various aqueous-alcohol solvent mixtures, have been obtained using samples in the concentration range 0.1–1.0 mM. Some of these were clearly monomeric, homogeneous, mixed-ligand adducts, entirely suitable for use as model systems for hemoprotein specroscopic studies. As anticipated, the measured EPR parameters were largely independent of solvent environment. Surprisingly, micellar preparations of ferric heme undecapeptide in mildly alkaline solution showed no evidence for the formation of a hydroxide adduct, contrary to a previous report [S. Mazumdar, O. K. Medhi and S. Mitra, Inorg. Chem.30 700 (1991)].     

A simple protocol for the production of highly deuterated proteins for biophysical studies

Highly deuterated protein samples expand the biophysics and biological tool kit by providing, among other qualities, contrast matching in neutron diffraction experiments and reduction of dipolar spin interactions from normally protonated proteins in magnetic resonance studies, impacting both electron paramagnetic resonance and NMR spectroscopy. In NMR applications, deuteration is often combined with other isotopic labeling patterns to expand the range of conventional NMR spectroscopy research in both solution and solid-state conditions. However, preparation of deuterated proteins is challenging. We present here a simple, effective, and user-friendly protocol to produce highly deuterated proteins in Escherichia coli cells. The protocol utilizes the common shaker flask growth method and the well-known pET system (which provides expression control via the T7 promotor) for large-scale recombinant protein expression. One liter expression typically yields 5 to 50 mg of highly deuterated protein. Our data demonstrate that the optimized procedure produces a comparable quantity of protein in deuterium (²H₂O) oxide M9 medium compared with that in ¹H₂O M9 medium. The protocol will enable a broader utilization of deuterated proteins in a number of biophysical techniques.     

A general synthesis of specifically deuterated nucleotides for studies of DNA and RNA

An efficient procedure is described for the preparation of ribonucleotides and deoxyribonucleotides with deuterium incorporated at the 1', 4', or 5' position. Three intermediates-[1-2H]-D-ribose, [4-2H]-D-ribose, and [5-2H(2)]-D-ribose-were prepared by chemical synthesis and subsequently converted to ribonucleotides and deoxyribonucleotides via enzymatic reactions. Milligram quantities of the desired products were obtained with an average deuterium content of 96+/-1%.     

Synthesis and nmr conformational studies of polyoxyethylene-bound, alpha-deuterated glutamate oligopeptides

The syntheses of three series of glutamate oligopeptides attached to a macromolecular solubilizing polyoxyethylene (POE) group Boc-[Glu(OMe)]_n-OPOE, Ac-[Glu(OMe)]_n-OPOE, pGlu-[Glu(OMe)]_n?1-OPOE (n ? 1–7) and their various analogs specifically deuterated at individual α-CH positions using the liquid-phase method of peptide synthesis are described. It was shown that stepwise synthesis using the symmetrical anhydride gave homo-oligopeptides that are analytically pure. Fragment condensation methods using DCC-HOBt yield POE-peptides with POE-HOBt impurities but the peptide synthesis may be carried stoichiometrically with smaller quantities of amino acid derivatives. 360 MHz ¹H-nmr conformational studies of these homo-oligopeptides in DMSO-d₆ are presented. The α-deuterated peptides are shown to allow unequivocal homoligopeptide backbone NH assignments.     

On the subtransitions of deuterated derivatives of 1,2-dipalmitoyl-sn-glycero-3-phosphocholine

By means of Fourier transform infrared spectroscopy the subtransition temperature of 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) and the derivatives in which either or both of the acyl chains were deuterated were determined. It was found that, while the temperatures of the gel to liquid-crystal and the pre-transitions decrease with increasing deuteration, the temperature of the subtransition is independent of the degree of deuteration.     

Efficient syntheses of chiral myo-inositol derivatives—key intermediates in glycosylphosphatidylinositol (GPI) syntheses

A facile and effective method was developed for large-scale syntheses of myo-inositol derivatives with the 1,2,6-O-positions differentiated from each other and from other positions as well. The syntheses started from methyl α-d-glucopyranoside, and the key steps are Ferrier rearrangement and a series of other regioselective and stereoselective reactions. The target compounds are key intermediates in the synthesis of GPIs.     

Plesiomonas shigelloides hugZ encodes an iron-regulated heme binding protein required for heme iron utilization

Plesiomonas shigelloides is an intestinal pathogen that uses heme as an iron source. The P. shigelloides heme utilization system consists of 10 genes, 7 of which permit heme transport and 3 of which are associated with utilization of heme as an iron source once it is inside the cell. The goal of this study was to examine hugZ, 1 of the 3 genes associated with utilization of heme iron. DPH8, a hugZ mutant, failed to grow to full cell density in media containing heme as the iron source, indicating that hugZ is required for heme iron utilization. Western blots using antibodies against Vibrio cholerae HutZ to detect the P. shigelloides HugZ indicated that hugZ encodes an iron-regulated cytoplasmic protein, which is absent in DPH8. A heme affinity bead assay performed on soluble protein fractions from P. shigelloides DPH8/pHUG24.5 (pHUG24.5 encodes hugZ) indicated that HugZ binds heme. Heme utilization was restored in DPH8 by hox1, which encodes the alpha-heme oxygenase from Synechocystis sp. strain PCC6803. However, HugZ did not exhibit alpha-heme oxygenase activity in an assay that detects the conversion of heme to the bilin functional group present in phycobiliproteins. These results do not rule out that HugZ exhibits another type of heme oxygenase activity not detected in the assay.