Investigation of the local expression of the relaxin system in canine mammary tumours.

While mammary tumours are the main reasons of death in bitches, early detection of tumours and metastases is crucial for survival of affected dogs. Invasiveness and angiogenesis, which are important processes of tumour growth and spreading, require connective tissue remodelling. This process is dominantly mediated by matrix metalloproteinases (MMP), which are well known to be positively regulated by relaxin (RLX) in various tissues, including human breast cancer. So far, the presence of RLX and its receptor RXFP-1 as well as their linkage with MMP in canine mammary tumours (CMT) is completely unknown. In the first part of the present study, concentrations of RLX, oestradiol and progesterone from plasma samples of bitches with CMT were compared with clinical and survival data to investigate the predictive value of these hormones. In the second part, the expressions of RLX, RXFP-1 and MMP-2, -9 and -13 were examined by real-time reverse transcriptase polymerase chain reaction (RT-PCR) in 31 CMT samples. Finally, relationships of systemic plasma RLX or locally expressed RLX with expression of MMP in CMT were analyzed for the first time. Comparison of hormone concentrations in 93 bitches in terms of benign or malignant nature of the CMT, lung metastases, recidivation and 12-month survival discovered no significances. The expressions of RLX, RXFP-1 and MMP were independent from plasma RLX, but expressions of local RLX and RXFP-1 showed a strong correlation (p = 0.00004, r = 0.671) as well as RXFP-1 and MMP-2 (p = 0.009, r = 0.463), indicating a possible significant role of the locally produced RLX in CMT pathogenesis as an inducer of connective tissue remodelling.

Study of the conformational transition of A beta(1-42) using D-amino acid replacement analogues.

A critical event in Alzheimer's disease is the transition of Abeta peptides from their soluble forms into disease-associated beta-sheet-rich conformers. Structural analysis of a complete D-amino acid replacement set of Abeta(1-42) enabled us to localize in the full-length 42-mer peptide the region responsible for the conformational switch into a beta-sheet structure. Although NMR spectroscopy of trifluoroethanol-stabilized monomeric Abeta(1-42) delineated two separated helical domains, only the destabilization of helix I, comprising residues 11-24, caused a transition to a beta-sheet structure. This conformational alpha-to-beta switch was directly accompanied by an aggregation process leading to the formation of amyloid fibrils.

Role of helix formation for the retention of peptides in reversed-phase high-performance liquid chromatography.

In order to get insight into the role of helix formation for retention in reversed-phase HPLC, we have studied the isocratic retention behavior of amphipathic and non-amphipathic potentially helical model peptides. Plots of the logarithmic capacity factor in absence of organic solvent (ln k0) versus l/T were used to derive the enthalpy, deltaH0, the free energy, deltaG0, the entropy of interaction, deltaS0, and the heat capacity change, deltaCp. Retention of all peptides was accompanied by negative deltaCp revealing that hydrophobic interactions play a large role independent of peptide sequence and secondary structure. deltaH0 was negative for the amphipathic analogs and was attributed mainly to helix formation of these peptides upon interaction with the stationary phase. In contrast, deltaH0 was considerably less exothermic or even endothermic for the non-amphipathic analogs. The differences in helix formation between the individual analogs were quantified on the basis of thermodynamic data of helix formation previously derived for peptides in a hydrophobic environment. Correlation of the helicity with the free energy of stationary phase interaction revealed that helix formation accounts for approximately 40-70% of deltaG0, and is hence in addition to the hydrophobic effect a major driving force of retention.

Peptide leucine arginine, a potent immunomodulatory peptide isolated and structurally characterized from the skin of the Northern Leopard frog, Rana pipiens.

On the basis of histamine release from rat peritoneal mast cells, an octadecapeptide was isolated from the skin extract of the Northern Leopard frog (Rana pipiens). This peptide was purified to homogeneity using reversed-phase high performance liquid chromatography and found to have the following primary structure by Edman degradation and pyridylethylation: LVRGCWTKSYPPKPCFVR, in which Cys(5) and Cys(15) are disulfide bridged. The peptide was named peptide leucine-arginine (pLR), reflecting the N- and C-terminal residues. Molecular modeling predicted that pLR possessed a rigid tertiary loop structure with flexible end regions. pLR was synthesized and elicited rapid, noncytolytic histamine release that had a 2-fold greater potency when compared with one of the most active histamine-liberating peptides, namely melittin. pLR was able to permeabilize negatively charged unilamellar lipid vesicles but not neutral vesicles, a finding that was consistent with its nonhemolytic action. pLR inhibited the early development of granulocyte macrophage colonies from bone marrow stem cells but did not induce apoptosis of the end stage granulocytes, i.e. mature neutrophils. pLR therefore displays biological activity with both granulopoietic progenitor cells and mast cells and thus represents a novel bioactive peptide from frog skin.

A role for a helical connector between two receptor binding sites of a long-chain peptide hormone.

The conformational freedom of single-chain peptide hormones, such as the 41-amino acid hormone corticotropin releasing factor (CRF), is a major obstacle to the determination of their biologically relevant conformation, and thus hampers insights into the mechanism of ligand-receptor interaction. Since N- and C-terminal truncations of CRF lead to loss of biological activity, it has been thought that almost the entire peptide is essential for receptor activation. Here we show the existence of two segregated receptor binding sites at the N and C termini of CRF, connection of which is essential for receptor binding and activation. Connection of the two binding sites by highly flexible epsilon-aminocaproic acid residues resulted in CRF analogues that remained full, although weak agonists (EC(50): 100-300 nM) independent of linker length. Connection of the two sites by an appropriate helical peptide led to a very potent analogue, which adopted, in contrast to CRF itself, a stable, monomer conformation in aqueous solution. Analogues in which the two sites were connected by helical linkers of different lengths were potent agonists; their significantly different biopotencies (EC(50): 0.6-50 nM), however, suggest the relative orientation between the two binding sites rather than the maintenance of a distinct distance between them to be essential for a high potency.

A new class of hexahelical insect proteins revealed as putative carriers of small hydrophobic ligands.

BACKGROUND: THP12 is an abundant and extraordinarily hydrophilic hemolymph protein from the mealworm Tenebrio molitor and belongs to a group of small insect proteins with four highly conserved cysteine residues. Despite their sequence homology to odorant-binding proteins and pheromone-binding proteins, the function of these proteins is unclear. RESULTS: The first three-dimensional structure of THP12 has been determined by multidimensional NMR spectroscopy. The protein has a nonbundle helical structure consisting of six alpha helices. The arrangement of the alpha helices has a 'baseball glove' shape. In addition to the hydrophobic core, electrostatic interactions make contributions to the overall stability of the protein. NMR binding studies demonstrated the binding of small hydrophobic ligands to the single hydrophobic groove in THP12. Comparing the structure of THP12 with the predicted secondary structure of homologs reveals a common fold for this new class of insect proteins. A search with the program DALI revealed extensive similarity between the three-dimensional structure of THP12 and the N-terminal domain (residues 1-95) of recoverin, a member of the family of calcium-binding EF-hand proteins. CONCLUSIONS: Although the biological function of this new class of proteins is as yet undetermined, a general role as alpha-helical carrier proteins for small hydrophobic ligands, such as fatty acids or pheromones, is proposed on the basis of NMR-shift perturbation spectroscopy.

Structural characterization of the entire 1.3S subunit of transcarboxylase from Propionibacterium shermanii.

Transcarboxylase (TC) from Propionibacterium shermanii, a biotin-dependent enzyme, catalyzes the transfer of a carboxyl group from methylmalonyl-CoA to pyruvate in two partial reactions. Within the multisubunit enzyme complex, the 1.3S subunit functions as the carboxyl group carrier. The 1.3S is a 123-amino acid polypeptide (12.6 kDa), to which biotin is covalently attached at Lys 89. We have expressed 1.3S in Escherichia coli with uniform 15N labeling. The backbone structure and dynamics of the protein have been characterized in aqueous solution by three-dimensional heteronuclear nuclear magnetic resonance (NMR) spectroscopy. The secondary structure elements in the protein were identified based on NOE information, secondary chemical shifts, homonuclear 3J(HNHalpha) coupling constants, and amide proton exchange data. The protein contains a predominantly disordered N-terminal half, while the C-terminal half is folded into a compact domain comprising eight beta-strands connected by short loops and turns. The topology of the C-terminal domain is consistent with the fold found in both carboxyl carrier and lipoyl domains, to which this domain has approximately 26-30% sequence similarity.

Backbone structure and dynamics of a hemolymph protein from the mealworm beetle Tenebrio molitor.

Pheromones play a vital role in the survival of insects and are used for chemical communication between members of the same species by their olfactory system. The selection and transportation of these lipophilic messengers by carrier proteins through the hydrophilic sensillum lymph in the antennae toward their membrane receptors remains the initial step for the signal transduction pathway. A moderately abundant 12.4 kDa hydrophilic protein present in hemolymph from the mealworm beetle Tenebrio molitor is approximately 38% identical to a family of insect pheromone-binding proteins. The backbone structure and dynamics of the 108-residue protein have been characterized using three-dimensional 1H-15N NMR spectroscopy, combined with 15N relaxation and 1H/D exchange measurements. The secondary structure, derived from characteristic patterns of dipolar connectivities between backbone protons, secondary chemical shifts, and homonuclear three-bond JHNH alpha coupling constants, consists of a predominantly disordered N-terminus from residues 1 to 10 and six alpha-helices connected by four 4-7 residue loops and one beta-hairpin structure. The up-and-down arrangement of alpha-helices is stabilized by two disulfide bonds and hydrophobic interactions between amphipathic helices. The backbone dynamics were characterized by the overall correlation time, order parameters, and effective correlation times for internal motions. Overall, a good correlation between secondary structure and backbone dynamics was found. The 15N relaxation parameters T1 and T2 and steady-state NOE values of the six alpha-helices could satisfactorily fit the Lipari-Szabo model. In agreement with their generalized order parameters (> 0.88), residues in helical regions exhibited restricted motions on a picosecond time scale. The stability of this highly helical protein was confirmed by thermal denaturation studies.

Hydrophobically induced conformation in ovine corticotropin-releasing hormone.

Multiple peptide synthesis has been applied for the simultaneous synthesis of systematic replacement sets of model peptides which varied in length from 18 to 36 residues and ovine corticotropin-releasing hormone (oCRH), a 41-residue receptor-binding peptide. The peptides were utilized to analyze the capability of the stationary phase during RP-HPLC to induce secondary structure in long-chain linear peptides. Double D-amino acid replacement studies demonstrate that nonamphipathic helical domains can be recognized, even in the presence of highly amphipathic domains. On the other hand, systematic alteration of hydrophobicity at each residue along the sequence by methionine and methionine sulfoxide replacements results in characteristic pattern of HPLC retention-time differences, which is shown to provide a useful method to probe hydrophobic surface regions in helical peptides. Both amino acid replacement strategies were successfully applied to characterize the hydrophobically induced structure of oCRH. Although an alpha-helix is formed from residues 6 to 32, the N-terminal residues 1-5 and the C-terminal region 33-41 do not show any regular structure. The helical domain from residues 12 to 20 is highly amphipathic.

Conformation of a water-soluble beta-sheet model peptide. A circular dichroism and Fourier-transform infrared spectroscopic study of double D-amino acid replacements.

Among peptide secondary structures beta-sheet domains have been much less intensively studied than alpha-helical conformations, mainly because of the lack of well characterized model peptides. In the present paper the secondary structure of a water-soluble de novo peptide consisting of 26 amino acids (DPKGDPKGVTVTVTVTVTGKGDPKPD-NH2) and the corresponding double D-amino acid replacement set have been studied by circular dichroism and Fourier-transform infrared spectroscopy. The model peptide was found to be unstructured in aqueous solution at peptide concentrations < 10(-3) mol/L but to adopt a predominantly beta-sheet structure in the presence of 15 mM sodium dodecyl sulfate or at apolar/water interfaces. Although the peptide is composed of amino acids with low helical propensity, it formed a single-stranded helical structure in aqueous trifluoroethanol. The D-amino acid replacement set was synthesized in order to study the conformational stability of the model peptide selectively in distinct regions. The data show that both the alpha-helix present in 50% trifluoroethanol as well as the beta-sheet domain formed in the presence of sodium dodecyl sulfate or at apolar/water interfaces, are located in the region between Val9 and Thr18. Pairwise substitution of adjacent amino acids by their corresponding D-amino acids provides a pronounced beta-sheet disturbance. These findings demonstrate that double D-amino acid replacements may be used to locate beta-sheet domains in peptides.

Assignment of the helical structure in neuropeptide Y by HPLC studies of methionine replacement analogues and 1H-NMR spectroscopy.

The HPLC retention behavior of three complete single methionine and methionine sulfoxide replacement sets of two 18-mer model peptides and neuropeptide Y (NPY) were investigated. All peptides were prepared by multiple solid-phase peptide synthesis. Plotting the retention time differences between methionine and methionine sulfoxide analogues vs the position of replacement shows that potentially alpha-helical peptides become helical on binding during reversed-phase high performance liquid chromatography. In the case of an amphipathic alpha-helix, the retention time differences change periodically with a 3-4 repeat pattern, which allow the location of amphipathic helical structures. Replacements in nonamphipathic alpha-helical domains cause local preferential binding areas and lead to sequence-dependent retention time profiles. Methionine replacement studies of NPY suggest an unstructured or extended conformation from Tyr1 to Ala12 connected to a well-defined amphipathic alpha-helix from Pro13 to Arg35. The assignment is confirmed by comparison of nuclear Overhauser effects based two-dimensional 1H-nmr spectroscopy and utilization of the C alpha H shift index method in 50% trifluoroethanol/50% water.

Temperature coefficients of amide proton NMR resonance frequencies in trifluoroethanol: a monitor of intramolecular hydrogen bonds in helical peptides.

2D 1H NMR spectroscopy of two alpha-helical peptides which differ in their amphipathicity has been used to investigate the relationships between amide-proton chemical shifts, amide-proton exchange rates, temperature, and trifluoroethanol (TFE) concentration. In 50% TFE, in which the peptides are maximally helical, the amide-proton chemical shift and temperature coefficient patterns are very similar to each other in each peptide. Temperature coefficients from -10 to -6 ppb/K, usually indicative of the lack of intramolecular hydrogen bonds, were observed even for hydrophobic amino acids in the center of the alpha-helices. However, slow hydrogen isotope exchange for residues from 4 to 16 in both 18-mer helices indicates intact intramolecular hydrogen bonds over most of the length of these peptides. Based on these anomalous observations, we suggest that the pattern of amide-proton shifts in alpha-helices in H20/TFE solvents is dominated by bifurcated intermolecular hydrogen-bond formation between the backbone carbonyl groups and TFE. The amide-proton chemical shift changes with increasing temperature may be interpreted by a disruption of intermolecular hydrogen bonds between carbonyl groups and the TFE in TFE/water rather than by the length of intramolecular hydrogen bonds in alpha-helices.

Peptide destabilization by two adjacent D-amino acids in single-stranded amphipathic alpha-helices.

We recently described the local destabilizing effect of systematic double D-amino acid replacements for characterization of amphipathic helices in peptides. The objective of this study was to determine the destabilizing effect of two adjacent D-amino acids incorporated into the center of a single-stranded amphipathic alpha-helix by hydrogen exchange and guanidine hydrochloride denaturation studies in trifluoroethanol (TFE)/water. Data from guanidine hydrochloride titration experiments in the presence of 30% TFE suggest that double D-amino acid replacements at the center of the helix destabilize the secondary structure by 4.5 kJ/mol. While the exchange rate for one backbone proton was found to vary by a factor of 10 at the replacement position, the remaining backbone protons are not markedly influenced by double D-amino acid replacement. These results confirm the hypothesis that the energy of -4.5 kJ/mol per residue is a major contribution to the stability of helical peptides in water and in solvent mixtures of TFE/water.

Structure effects of double D-amino acid replacements: a nuclear magnetic resonance and circular dichroism study using amphipathic model helices.

D-Amino acid replacements and the determination of resulting structural changes are a useful tool to recognize amphipathic helices in biologically active peptides such as neuropeptide Y and corticotropin-releasing factor. In this paper the secondary structures of one amphipathic alpha-helical peptide and its double D-amino acid analog have been determined by means of 1H NMR and CD spectroscopies under equivalent conditions. The chemical shifts (NH and C alpha H) and the analysis of nuclear Overhauser effects show a split of the continuous helix for the all-L peptide into two helices at the position of double D-amino acid replacement. Hydrogen exchange rates correlate with water accessibilities in the hydrophobic/hydrophilic face and confirm the amphipathic helical structure in the all-L peptide as well as in its double D-amino acid analog. A significantly accelerated hydrogen isotope exchange rate is observed for the D-Ala9 backbone proton, implying an increased flexibility at that position. These results show that the incorporation of an adjacent pair of D-amino acids only causes a local change in structure and flexibility, which makes the double D replacement interesting as a tool for specific helix-disturbing modifications to search for helical conformations in biologically active peptides.

Recognition of alpha-helical peptide structures using high-performance liquid chromatographic retention data for D-amino acid analogues: influence of peptide amphipathicity and of stationary phase hydrophobicity.

The reversed-phase HPLC behaviour of double D-amino acid replacement sets of amphipathic and non-amphipathic helix-forming peptides consisting exclusively of leucine, lysine and alanine residues was studied on different polymer-encapsulated silica-based stationary phases. Plotting the retention times versus the position of D-amino acid substitution gives a characteristic pattern showing decreased retention times in the helical region. The retention time profile obtained using an amphipathic alpha-helix is caused by disturbance of the preferred binding domain of the stationary phase-bound peptide. However, the effect is similar but less pronounced using a non-amphipathic helical peptide that is unable to interact by a preferred binding site. The results demonstrate that reversed-phase HPLC data for peptide analogues provide an indication event of a non-amphipathic helical structure in peptides.

Location of an amphipathic alpha-helix in peptides using reversed-phase HPLC retention behavior of D-amino acid analogs.

The reversed-phase HPLC retention behavior of D-amino acid replacement sets of an amphipathic model peptide, neuropeptide Y, and corticotropin releasing factor has been studied. The results demonstrate that D-amino acid substitutions destabilized the amphipathic alpha-helix, leading to a decrease of fractional helicity as determined by circular dichroism. The effect is enhanced by substitution of two adjacent D-amino acids and correlates well with a decrease of hydrophobic interaction during reversed-phase HPLC, caused by disturbance of the preferred binding domain of the stationary phase-bound peptide. In contrast, D-amino acid substitutions in nonamphipathic or disordered regions of peptides do not influence the retention time to the same extent. Thus, the "retention profile" that results from plotting the retention time vs the position of the double D-amino acid replacements provides an indication of the presence and location of an amphipathic alpha-helical secondary structure in peptides.

Determination of peptide hydrophobicity parameters by reversed-phase high-performance liquid chromatography.

The log kw values of fourteen potential fibrinogen receptor antagonist peptides (RGDX) determined by reversed-phase HPLC were correlated to hydrophobic parameters of the amino acid side-chain log P in position X of the tetrapeptides. Comparing the polymer columns with LiChrosorb RP-8, the correlation coefficient using a polyethylene column is higher (0.94) than that for RP-8 (0.88), which demonstrates the importance of a homogeneous hydrophobic surface and makes this method very suitable for the determination of the overall hydrophobicity of shorter peptides. The hydrophobicity parameters log kw of the RGDX peptides (-1.15 to 2.19) were used to investigate the influence of molecular parameters of X on the potency of RGDX in inhibiting platelet aggregation. The results confirm the importance of hydrophobicity for the contribution of X to the biological activity of RGDX.