Binding of alcohols to the peptide CO group of poly-L-proline in the I and II conformation. II. Binding constants from infrared measurements in solution

Trifluoroethanol, benzyl alcohol, and n-butanol bind to the peptide and acelyl CO groups of poly-O-acetyl-L -hydroxyproline in dichloromethane via hydrogen bonds. The binding aflinity decreases from trifhioroelhanol to n-buitanol. For the acelyl CO groups the binding does not depend on the conformation of the polymer but for the peptide CO groups the binding constants are larger by a factor of two to five time when it is in the helix II conformation (all peptide bonds trans) than when it assumes the helix I conformation (all peptide bonds cis). This preference is explained by the higher accessibility of the peptide CO groups in the II helix. The small additional energy which results from the preferential binding is sufficient, to induce a complete I → II transition because of the very high cooperativily of the system. The quantitative dependence of the equilibrium constant s for the propagation step of the transition on solvent composition (ratio of trifluoroethanol or benzyl alcohol to n-butanol) is derived from the binding data. It agrees satisfactorily with the empirical relation obtained from a best fit to transition curves of Ganseret al. The I ? II conversion of poly-L -proline is therefore an example of a conformational transition whose solvent dependence can be explained by a binding mechanism.     

Immobilization of yeast microbodies and the properties of immobilized microbody enzymes

Summary Yeast microbodies isolated from methanol-grown cells of Kloeckera sp. No. 2201 were immobilized by two types of entrapping techniques: photocrosslinking of liquid oligomers of suitable photosensitive resins and crosslinking of albumin molecules with glutaraldehyde. The apparent activities of catalase, alcohol oxidase, and D-amino acid oxidase in the gel-entrapped microbodies were 40–50, 70–80, and ca. 50% respectively as compared with those in the free microbodies. Alcohol oxidase in the immobilized microbodies, similarly to that in free ones, oxidized methanol, ethanol, n-propanol, n-butanol, n-amyl alcohol, and benzyl alcohol. Some properties of catalase and alcohol oxidase in the microbodies immobilized by the above-mentioned techniques were studied in comparison with those of the enzymes in the free microbodies.     

Conformational aspect of polypeptide structure. XLIV. Conformational transitions of poly(N-methyl-alanines) induced by trifluoroacetic acid

The synthesis of poly(N-methyl-L -alanine) and poly (N-methyl-DL -alanine) are described. The polymers were examined by 220 MHz high-resolution nuclear magnetic resonance (nmr) and circular dichroism (CD). The results demonstrate that poly(N-methyl-L -alanine) exists as an ordered helical structure with all the amide bonds in the trans configuration in appropriate solvents. As trifluoroacetic acid (TFA) is added to the solutions of the polymer in helix-supporting solvents, resonances corresponding to both trans and cis amide conformations of N-methyl, C-methyl, and α-CH are observed. The presence of both the trans and the cis peptide bonds in a polymer chain disrupts the ordered structures. Our conclusions from CD data are in agreement with the nmr results. Ultracentrifugation shows that degradation of the polymer chain does not occur during the TFA treatment.     

Removal of acid-labile protecting or anchoring groups in the presence of polyfluorinated alcohol: Application to solid-phase peptide synthesis

We describe herein a new method for cleaving from resin and removing acid-labile protecting groups in solid-phase peptide synthesis in the presence of a polyfluorinated alcohol (either trifluoroethanol, TFE, or hexafluoroisopropanol, HFIP). It was shown that 0.1 M HCl in hexafluoroisopropanol or trifluoroethanol removes the acid-labile protecting groups commonly used in Fmoc SPPS for the protection of amino acid side-chains, such as t-butyl ester and ether, Boc, trityl, and Pbf groups including the most acid-resistant p-hydroxymethylphenoxyacetyl group (HMPA), p-benzyloxy benzyl ester (Wang resin), Rink amide, and peptide amide linker (PAL). The addition of 5–10% of a hydrogen-bonding solvent was shown to considerably retard or even fully inhibit the reaction. However, nonhydrogen-bonding solvents, such as dichloromethane, do not slow down the reaction.     

Conformational studies of polymers and copolymers of L-aspartate esters. I. Preparation and solution studies

An alcoholysis method is described for the modification of high molecular weight poly(β-benzyl L -asparatate); by this method the benzyl groups in the polypeptide have been replaced by methyl, ethyl, isopropyl, n-propyl, and phenethyl groups to give a series of copolymers of each of the corresponding aspartate esters with benzyl L -aspartate. By repeating the reactions, replacement of better than 99% has been achieved in some cases to give in effect the homopolymer. Optical rotatory dispersion studies show that of all the systems studied only poly(β-methyl L -aspartate) has the left-handed helix sense, the others are right-handed. It is shown further that the helix sense is not an intrinsic property of the nature of the aspartate side chain. Raising the temperature of chloroform solutions of the right-handed form of the copolymers of benzyl L -aspartate and ethyl L -aspartate results in a transition to the left-handed helix, the temperature of the transition being dependent on the composition of the copolymer. Also poly(β-n-propyl L -aspartate) undergoes a transition from the right- to the left-handed helix form at 59°C. These results suggest a general pattern of behavior of poly(aspartate esters) and that with suitable conditions of solvent and temperature they may be in either the right- or left-handed helical form.     

Amide I band of IR spectrum and structure of collagen and related polypeptides

The infrared amide I band of collagens (rat and cod skin) and related compounds (polyproline, polyglycine, and polytripeptides) was studied. Assignment of amide I-band components for polyproline II and polytripeptides (Gly-Pro-Pro)_n and (Gly-Pro-Gly)_n in the solid state and water solution was made. Three amide I components observed in the polypeptide spectra were attributed to three different peptide CO groups in each triplet. On the basis of this assignment, the interpretation of the amide I multicomponent structure in collagen and isomorphous oligo- and polypeptides was attempted. The ordering of intra- and intermolecular hydrogen bonds involving peptide CO groups in collagen and related compounds was discussed.     

Cyclic retro-inverso dipeptides with two aromatic side chains. I. Synthesis.

A series of cyclic retro-inverso dipeptides--2-[(4-hydroxy)benzyl]-5-benzyl-4,6(1H,2H,3H,5H)-pyrimidinedi one (c[mPhe-gTyr]), 2-benzyl-5-[(4-hydroxy)benzyl]-4,6(1H,2H,3H,5H)-pyrimidinedione (c[mTyr-gPhe]), and 2-benzyl-5-amino-5-[(4-hydroxy)benzyl]-4,6(1H,2H,3H,5H)-pyrimidinedione (c[(alpha-amino)mTyr-gPhe])--were synthesized in order to define the minimum structural requirements for binding affinity with opiate receptors and biological activity. Although the first two compounds lack a free amine proposed to be necessary for receptor recognition, the c[mPhe-gTyr] and c[mTyr-gPhe] analogues serve as model molecules in conformational studies of the target analogue, c[(alpha-amino)mTyr-gPhe]. The cis- and trans-c[(alpha-amino)mTyr-gPhe] contain all the functional groups such as the amine and phenolic groups in the tyrosine, and the aromatic group in the phenylalanine, necessary for opiate activity. In addition, the c[(alpha-amino)mTyr-gPhe] analogues possess similar geometries to the Tyr-Pro part of morphiceptin (Tyr-Pro-Phe-Pro-NH2) whose high mu-receptor activity is attributed to conformations with the Tyr-Pro amide bond in a cis conformation because the peptide bonds assume a cis conformation. However, both analogues are inactive in the guinea pig ileum and the mouse vas deferens assays. This may result from wrong orientation of the benzyl group of the gPhe residue with respect to the (alpha-amino)mTyr residue. Conformational studies of these molecules using 1H-nmr spectroscopy and molecular mechanics calculations will be reported in the following paper. Results of conformational analysis should provide information about backbone-side-chain interactions in the retro-inverso peptide chains since all the fundamental structural elements of the retro-inverso peptides are included in these model systems even though the peptide bonds must assume a cis conformation.     

Using poly(vinyldodecylimidazolium bromide) for the in-situ product recovery of n-butanol

The mitigation of end-product inhibition during the biosynthesis of n-butanol is demonstrated for an in-situ product recovery (ISPR) system employing a poly(ionic liquid) (PIL) absorbent. The thermodynamic affinity of poly(vinyldodecylimidazolium bromide) [P(VC₁₂ImBr)] for n-butanol, acetone and ethanol versus water was measured at conditions experienced in a typical acetone-ethanol-butanol (ABE) fermentation. In addition to providing a high n-butanol partition coefficient (PC = 6.5) and selectivity (α_BuOH/water = 46), P(VC₁₂ImBr) is shown to be biocompatible with Saccharomyces cerevisiae and Clostridium acetobutylicum. Furthermore, the diffusivity of n-butanol in a hydrated PIL provides absorption rates that support ISPR applications. Using a 5 wt% PIL phase fraction relative to the aqueous phase mass, P(VC₁₂ImBr) improved the volumetric productivity of a batch ABE ISPR process by 31% relative to a control fermentation. The concentration of n-butanol in the P(VC₁₂ImBr) phase was sufficient to increase the alcohol concentration from 1.5 wt% in the fermentation medium to 25 wt% in the saturated PIL, thereby facilitating downstream n-butanol recovery.     

Far ultraviolet optical rotatory properties of poly-L-tryptophan. I

A block copolymer [γ-Et-DL -Glu]_m [L -Trp]_n was prepared using N-carboxy anhydrides (NCA) of L -tryptohan and γ-ethyl DL -glutamate. The block copolymer, dissolved in trifluoroethanol (TFE)–dichloroacetic acid (DCA) mixtures, exhibited a sharp change in the specific rotation at 546 mμ when the solvent composition reached 70–75% DCA content. Optical rotatory dispersion (ORD) and circular dichroism (CD) measurement were carried out in TFE solution in the spectral range 180–350 mμ. Indole side-chain chromophores were found to be optically active in the polymer. On the other hand, these groups exhibit very small optical activity in the model compound C₆H₃? CH₂? O? CO? (L -Trp)₂? O? CH₃. Indole groups therefore appear to be in a dissymmetric environment only in the polymer. From these data it was concluded that poly-L -Trp is in some type of helical conformation in TFE. Strong overlapping of CD bands from side-chain chromophores and peptides chromophores in the wavelength range 185–240 mμ does not allow definite conclusions to be drawn about the type of helical conformation which exists in poly-L -Trp in TFE solution.     

Proton transfer and polarizability of hydrogen bonds in proteins coupled with conformational changes. I. Infrared investigation of poly(glutamic acid) with various N Bases

The nature of hydrogen bonds formed between carboxylic acid residues and histidine residues in proteins is studied by ir spectroscopy. Poly(glutamic acid) [(Glu)_n] is investigated with various monomer N bases. The position of the proton transfer equilibrium OH…?N ? O^?…?H⁺N is determined considering the bands of the carboxylic group. It is shown that largely symmetrical double minimum energy surfaces are present in the OH…?N ? O^?…?H⁺N bonds when the pK_a of the protonated N base is two values larger than that of the carboxylic groups of (Glu)_n. Hence OH…?N ? O^?…?H⁺N bonds between glutamic and aspartic acid residues and histidine residues in proteins may be easily polarizable proton transfer hydrogen bonds. The polarizability of these bonds is one to two orders of magnitude larger than usual electron polarizabilities; therefore, these bonds strongly interact with their environment. It is demonstrated that water molecules shift these proton transfer equilibria in favor of the polar proton boundary structure. The access of water molecules to such bonds in proteins and therefore the position of this proton transfer equilibrium is dependent on conformation. The amide bands show that (Glu)_n is α-helical with all systems. The only exception is the (Glu)_n-n-propylamine system. When this system is hydrated (Glu)_n is α-helical, too. When it is dried, however, (Glu)_n forms antiparallel β-structure. This conformational transition, dependent on degree of hydration, is reversible. An excess of n-propylamine has the same effect on conformation as hydration.     

15N nmr spectroscopy. I. Polysarcosine and related sequence polypeptides

The natural abundance ¹⁵N nmr spectra of linear polysarcosine (DP = 35) has been recorded in Me₂SO and H₂O solution. Because of cis/trans isomerization at the peptide bond, a broad signal with several splittings was observed. These splittings appear to reflect the influence of three peptide bonds on a single N atom. The ¹⁵N signals from the sequence polypeptides (β-Ala-Sar-Gly)_n and (β-Ala-Sar-D ,L -Ala)_n also show a cis/trans splitting, as well as chemical shifts which are dependent on the peptide sequence. The tertiary nitrogen of the sarcosyl residue has a T₁ relaxation time which is longer than the T₁ for secondary nitrogens of the other amino acids. The nuclear Overhauser effect is also discussed.     

Gas chromatographic–mass spectrometric identification and quantitation of benzyl alcohol in serum after derivatization with perfluorooctanoyl chloride: a new derivative

Benzyl alcohol is commonly used as an antibacterial agent in a variety of pharmaceutical formulations. Several fatalities in neonates have been linked to benzyl alcohol poisoning. Most methods for measuring benzyl alcohol concentrations in serum utilize direct extraction followed by high-performance liquid chromatography. We describe here a novel derivatization of benzyl alcohol using perfluorooctanoyl chloride after extraction from human serum for analysis by gas chromatography–mass spectrometry (GC–MS). The derivative was eluted at a significantly higher temperature respective to underivatized molecule and the method was free from interferences from more volatile components in serum and hemolyzed specimens. Another advantage of this derivatization technique is the conversion of low-molecular-mass benzyl alcohol (M_r 108) to a high-molecular-mass derivative (M_r 504). The positive identification of benzyl alcohol can be achieved by observing a distinct molecular ion at m/z 504 as well as the base peak at m/z 91. Quantitation of benzyl alcohol in human serum can easily be achieved by using 3,4-dimethylphenol as an internal standard. The within run and between run precisions (using serum standard of benzyl alcohol: 25 mg/l) were 2.7% (mean=24.1, S.D.=0.66 mg/l, n=8) and 4.2% (mean=24.3, S.D.=1.03 mg/l, n=8), respectively. The assay was linear for the serum benzyl alcohol concentrations of 2 mg/l to 200 mg/l and the detection limit was 0.1 mg/l. We observed no carry-over (memory effect) problem in our assay as when 2 μl ethyl acetate was injected into the GC–MS system after analyzing serum specimens containing 200 mg/l of benzyl alcohol, we observed no peak for either benzyl alcohol or the internal standard in the total ion chromatogram.     

Purification and Characterization of a DNA Topoisomerase I from Bifidobacterium breve

The monoacylation of (η⁶-1,2-benzenedimethanol)tricarbonylchromium (2) by vinyl acetate, palmitate and benzoate, alcoholysis of the corresponding diesters of 2 in n-butanol, and acylation of (η⁶-benzyl alcohol) tricarbonylchromium by (±)-vinyl 2-phenoxypropanoate and 2-phenylpropanoate were accomplished with lipase P (from P. fluorescens) and lipase CC (from C. cylindracea) to give optically active organometallic esters. Their configurations indicated that the stereoselectivity of each of these two lipases was in marked contrast. An active site model for them is proposed.     

Conformational studies of polymers and copolymers of L-aspartate ester. II. Infrared studies and the factors involved in the formation of the omega-helix

It has already been show that the helix senses of poly(β-benzyl L -aspartate) and poly(β-methyl L -aspartate) are left-handed, while the poly esters of n-propyl, isopropyl, n-butyl, and phenethyl L -asparate are all right-handed. The effect of changes in helix sense from the left-handed to the right-handed α-helical form on the infrared spectra of copolymers of benzyl L -aspartate with ethyl, n-butyl, isopropyl, n-propyl, and phenethyl L -aspartate have been studied. Those show that for the right-handed helical form the amide band frequencies fall within the range given by Elliott,⁷ while for the left-handed form the frequencies are higher. The frequency ranges for the two helix senses are given and have been used to show that poly (β-n-propyl L -aspartate) in chloroform solution undergoes a transition from the right-handed to the left-handed helix form on heating. Polarized infrared studies of the different copolymers show that the disposition of the side chain ester groups is different for the two forms. Although methyl L -aspartate forms a left-handed α-helix similar to benzyl L -aspartate, the introduction of methyl L -aspartate residues into poly (β-benzyl L -aspartate) prevents the formation of the ω-helix. The factors involved in the formation of this helix form are discussed.     

1H-nmr studies of polyoxyethylene-bound homo-oligo-L-methionines

The use of ¹H-nmr spectroscopy is demonstrated to be a useful analytical method to characterize the structure of synthetic peptides attached to soluble, macromolecular polyoxyethylene (POE) supports in the liquid-phase method (LPM) of peptide synthesis. We report an extensive 360-MHz ¹H-nmr study of POE-bound homo-oligo-L -methionine peptides. A combination of high field and selective saturation or Redfield pulse methods allows resolution of individual backbone NH and α-CH resonances of dilute peptides in the presence of strong resonances from macromolecular POE and/or protonated solvents. The nmr spectra for the POE-bound peptides in CDCl₃ are qualitatively similar to those of the low-molecular-weight Boc-L -Met_n-OMe peptide esters. This corroborates other observations that POE has little effect on peptide stucture. The backbone α-CH region of peptides is overlapped by signals from the terminal oxyethylene group of POE, but the peptide side-chain and low-field backbone NH resonances are well resolved. In trifluoroethanol the Boc-(L -Met)_n-NH-POE heptamer and octamer adopt the right-handed α-helical structure, and the present nmr studies provide evidence for two strong intramolecular hydrogen bonds to stabilize the helices. In water, the N-deblocked derivatives, (L -Met)_n-NH-POE oligomers adopt β-sheet structure and manifest well-resolved nonequivalent NH resonances with 6–7 Hz ³J_NH-CH coupling constants.     

Effect of Carbohydrates and Starvation on Nitrogen Sparing Action of Methionine and Threonine in Rats

Formaldehyde dehydrogenase from Pseudomonas putida C-83 was found to contain 7 halfcystine residues per subunit monomer, as checked by the method of performic acid oxidation. Approximately 7 sulfhydryl groups per subunit monomer were titrated with 5,5′-dithiobis(2-nitrobenzoic acid) (DTNB) after denaturation with 8 m urea. In the native enzyme, modification of three sulfhydryl groups per subunit with p-chloromercuribenzoate (PCMB) led to the complete loss of enzyme actiyities for both formaldehyde and n-butanol. Hydrogen-peroxide competitively inhibited the enzyme activity for formaldehyde, while it was only slightly inhibitory to the activity for n-butanol. Both formaldehyde and hydrogen-peroxide protected one sulfhydryl group per subunit monomer from modification with PCMB. Moreover, hydrogen-peroxide was hardly reactive to the enzyme which was preincubated with formaldehyde.

From these observations, we conclude that one of three PCMB-reactive sulfhydryl groups is essential for the binding of formaldehyde, and hydrogen-peroxide modifies this sulfhydryl group.     

The influence of asymmetric carbon atoms of the side chains on the conformational properties of polypeptides: Comparison of diastereomeric homooligopeptides of L-isoleucine and D-alloisoleucine

The conventionally protected oligopeptides of the two homologous series Boc-(L -Ile)_n-OMe and Boc-(D -aIle)_n-OMe (n = 2–6) were synthesized in a standard stepwise fashion and their uv and CD spectra in 2,2,2-trifluoroethanol, and solid-state ir spectra were investigated. In addition, two oligomeric products derived from the NCAs of L -isoleucine and of D -allo-isoleucine and having a DP of 20 and 12, respectively, were studied in the solid state by x-ray and ir. No substantial differences between the properties of the diastereomeric oligomers in the solid state were noticed, a β-structure being very likely at least for the Boc-protected hexapeptides and the higher oligomers. In contrast, differences were observed between the spectroscopic properties of the diastereomeric oligopeptides, and especially of the hexapeptides, in trifluoroethanol solution. The different properties of the hexapeptides in solution were related to the existence, in the case of Boc-(L -Ile)₆-OMe, of soluble molecular aggregates in which the peptide chains assume the β-conformation. These results provide an additional example of the influence of the configuration of asymmetric carbon atoms of the side chains on the conformational properties of peptide molecules in solution.     

Fungal volatiles emitted by members of the microbiome of desert plants are diverse and capable of promoting plant growth

Fungi represent a group of eukaryotic microorganisms that are an important part of the plant microbiome. They produce a vast array of metabolites, including fungal volatile organic compounds (fVOCs). However, the diversity and biological activities of fVOCs emitted by the mycobiota of plants native to arid and semi-arid environments remain under-explored. We characterized the chemical diversity of fVOCs produced by 22 representative members of the microbiome of agaves and cacti using SPME-GC–MS. We further tested the effects of pure compounds on the growth and development of Arabidopsis thaliana and host plants. Members of the Sordariomycetes (nine strains), Eurotiomycetes (three), Dothideomycetes (eight), Saccharomycetes (one) and Mucoromycetes (one) were included in our study. We identified 94 fungal organic volatiles classified into nine chemical classes. Terpenes showed the greatest chemical diversity, followed by alcohols and aliphatic compounds. We discovered that camphene and benzyl benzoate, together with the widely distributed and already tested benzyl alcohol, 2-phenylethyl alcohol and 3-methyl-1-butanol, improved plant growth and development of A. thaliana, Agave tequilana and Agave salmiana. Our studies on the fungal VOCs from desert plants underscore an untapped chemical diversity with promising biotechnological applications.     

Conformational properties of the sequential polyproline analogs poly(Pro-Aze-Pro) and poly(Aze-Pro-Aze)

The lack of the positive band at around 226 nm in the CD spectra of poly(prolyl-azetidine-2-carbonyl-proline) in trifluoroethanol and of poly(azetidine-2-carbonyl-prolyl-azetidine-2-carboxylic) acid in F₃EtOH and water, the hyperchromism of the absorption maximum at about 202 nm, and the extremely small intensity of the C^β-Pro, C^γ-Pro, and C^β-Aze signals for the cis peptide bonds in the ¹³C nmr spectrum of poly(Pro-Aze-Pro) in F₃EtOH indicate that both polyproline analogs exist as disordered chains in this solvent, the trans peptide group being maintained. The disordering of the chains is attributed to an increase in the accessible range of ψ due to the reduced dimensions of the square ring of L -azetidine-2-carboxylic acid residue relative to the pyrrolidine ring of proline and to strong interactions of the haloalcohol with the peptide groups of the chains.     

Formation of the collagen-like triple-helical structure in oligopeptides during elongation of the molecular chain

Oligotripeptides Z-(Gly-Pro-Pro)_n-OMe (n = 1,2,…,8), Z-Gly-Pro_Pro-Gly-Pro-Gly-OMe, Z-Gly-Pro-Pro-Gly-Pro-Gly-Gly-Pro-Pro-OMe, Z-Gly-Pro-Pro-(Gly-Pro-Gly)₂-Gly-Pro-Pro-OMe, and Z-(Gly-Pro-Ala)_n-OMe (n = 1,2,…,4) were synthesized step-by-step and then studied by means of x-ray diffraction, ir spectroscopy, the kinetics of hydrogen-deuterium exchange of peptide groups, and circular dichroism,. Different stages in the formation of a triple helix in Z-(Gly-Pro-Pro)_n-OMe were revealed during the chain elongation. In the solid state, at the first stage a conformation of the polyproline II-type is formed in the tripeptide and in the second stage a triple helical complex appears in the hexapeptide. Interpeptide hydrogen bonds in this complex are still of low order. At further stages an ordered set of interpeptide hydrogen bonds is gradually formed. It is shown that the degree of order of interpeptide H bonds depends on the length of the molecular chain, the amino acid composition, and residue sequence in the triplets.