A form of apolipoprotein a-I is found specifically in relapses of focal segmental glomerulosclerosis following transplantation

Recurrence of idiopathic focal segmental glomerulosclerosis (FSGS) following kidney transplantation occurs in a large percentage of patients. Accurate prediction of recurrence and elucidation of its pathogenesis are major therapeutic goals. To detect differential proteins related to FSGS recurrence, proteomic analysis was performed on plasma and urine samples from 35 transplanted idiopathic FSGS patients, divided into relapsing and nonrelapsing. Several proteins were detected increased in urine of relapsing FSGS patients, including a high molecular weight form of apolipoprotein A-I, named ApoA-Ib, found exclusively in relapsing patients. This finding was verified by Western blot individually in the 35 patients and validated in an independent group of 40 patients with relapsing or nonrelapsing FSGS, plus two additional groups: FSGS-unrelated patients showing different proteinuria levels (n = 30), and familial FSGS transplanted patients (n = 14). In the total of 119 patients studied, the ApoA-Ib form was detected in 13 of the 14 relapsing FSGS patients, and in one of the 61 nonrelapsing patients. Only one of the 30 patients with FSGS-unrelated proteinuria tested positive for ApoA-Ib, and was not detected in familial patients. Urinary ApoA-Ib is associated with relapses in idiopathic FSGS and warrants additional investigation to determine its usefulness as biomarker of relapse following transplantation.

Adaptations of the beta-adrenoceptor-adenylyl cyclase system in rat skeletal muscle to endurance physical training

beta-Adrenergic mechanisms may be important in the adaptation of skeletal muscle to endurance training. beta-Adrenergic signal transduction was examined in the gastrocnemius muscle of rats submitted to a progressive, 12-week treadmill running program and compared with sedentary controls. beta-Adrenoceptor density was significantly lower in exercised rats than in controls. The affinity constant for [125I]-(-) iodocyanopindolol binding was not different among the various groups. Adenosine cyclic monophosphate formation was significantly decreased in trained animals when isoproterenol plus guanosine triphosphate or forskolin plus Mn2+ were used to stimulate adenylyl cyclase. Immunoblot analyses revealed that the amount of the alpha-subunit of stimulatory guanine nucleotide-binding protein (Gs,alpha), both the small and the large isoforms, also decreased with physical exercise. Thus, the present report shows that endurance training results in alterations in beta-adrenergic receptor density, adenylyl cyclase activity and Gs protein level in rat gastrocnemius muscle.

Three-dimensional structure of acidic fibroblast growth factor in solution: effects of binding to a heparin functional analog

Acidic and basic fibroblast growth factors (aFGF and bFGF; FGFs) are paradigms of a group of nine closely related proteins known as the fibroblast growth factor family. FGFs induce mitosis in most mesoderm- and neuroectoderm-derived cells, and appear to be involved in diseases caused by anomalous cell proliferation. In vitro assays show that binding to heparin-like glycosaminoglycans is required to elicit the mitogenic activity of these proteins. It has been shown that myo-inositol hexasulfate (MIHS) emulates heparin in the mitogenesis assays of aFGF, and a low-resolution three-dimensional structure in solution of this protein bound to MIHS has been reported. Here we describe the 1H-NMR three-dimensional structure in solution of the free aFGF. Comparison of this structure with that of the protein bound to MIHS, upgraded to a level of refinement equivalent to that of the free protein, shows that MIHS binding causes some slight conformational changes with an increase in the definition of the structure. In addition, amide exchange H/2H rates of the most protected protons, and exchange data of the intermediate and fast-exchanging ones show that the free protein is less stable (< or = 2 kcal/mol) and more flexible in terms of local unfolding equilibria, respectively, than the MIHS-bound one. Thus, MIHS binding to aFGF causes a decrease of its flexibility, which translates into an enhancement of the definition of its three-dimensional structure. The increase of aFGF rigidity affects regions that include those involved in recognizing the cell membrane receptor. Thus, our data suggest that enhancement of structural definition may play a key role in the modulation of the affinity of aFGF by its receptor, and, consequently, of its specific mitogenic activity.

Effect of endurance physical training on rat liver adenylyl cyclase system

The adaptive response to endurance exercise of the catecholamine- and glucagon-sensitive adenylyl cyclase system was studied in rat liver plasma membranes. Endurance exercise enhanced adenylyl cyclase system activation by cellular agonists (glucagon, isoproterenol), by stimulators of the enzyme catalytic subunit (forskolin, Mn2+), and by Gs-protein activators (GppNHp, fluoride). In addition, endurance exercise increased the levels of G50, Gi alpha, and G beta subunits. These results show that the adenylyl cyclase system becomes sensitized in response to physical training.

Adenylyl cyclase system is affected differently by endurance physical training in heart and adipose tissue

Adaptive changes in the beta-adrenergic adenylyl cyclase (AC) system in response to endurance training were studied in heart and adipose tissue. Training was performed by making male Wistar rats run on a motor-driven treadmill. The changes following exercise training were opposite in the two tissue studied. The density of beta-adrenergic receptors in left ventricular membranes of trained rats showed a marked decrease. Comparison of AC activities in cardiac membranes prepared from trained and sedentary rats revealed a depressing effect of endurance training on: 1. the beta-adrenergic stimulatory pathway and the inhibition of AC via receptor; 2. the Gs component and the Gs-adenylyl cyclase coupling, as shown by the response of adenylyl cyclase to GppNHp and NaF; and 3. the enzyme catalytic activity in the presence of Mn2+ or forskolin. The levels of Gsalpha subunits in the left ventricle, as measured in terms of ADP-ribosylated and immunologically reactive proteins, were decreased by endurance exercise, whereas immunodetectable levels of Gialpha2 increased in the membranes of trained myocardium. In contrast to the diminished sensitivity that characterizes the behavior of the cardiac beta-adrenergic-AC system, endurance physical training increased sensitivity of this signal transduction system in adipose tissue. Thus, the density of beta-ARs as well as AC activity and the beta-adrenergic stimulatory pathway were increased in adipose membranes of trained rats compared with the corresponding sedentary controls. In addition, the levels of Gsalpha subunits were higher in the adipose plasma membranes of trained rats. However, immunodetectable levels of Gi1alpha and Gi3alpha increased with training, whereas the amount of Gi2alpha decreased in membranes of trained rats. In conclusion, the present study shows that chronic exercise is associated with a tissue-specific adaptation of the beta-adrenergic AC system.

Conformational investigation of designed short linear peptides able to fold into beta-hairpin structures in aqueous solution

BACKGROUND

Formation of secondary structure plays an important role in the early stages of protein folding. The conformational analysis of designed peptides has proved to be very useful for identifying the interactions responsible for the formation and stability of alpha-helices. However, very little is known about the factors leading to the formation of beta-hairpins. In order to get a good beta-hairpin-forming model peptide, two peptides were designed on the basis of beta-sheet propensities and individual statistical probabilities in the turn sites, together with solubility criteria. The conformational properties of the two peptides were analyzed by two-dimensional NMR methods.

RESULTS

Long-range cross-correlations observed in NOE and ROE spectra, together with other NMR evidence, show that peptide IYSNPDGTWT forms a highly populated beta-hairpin in aqueous solution with a type I beta-turn plus a G1 beta-bulge conformation in the chain-bend region. The analogous peptide with a Pro5 substituted by Ser forms, in addition to the previous conformation, a second beta-hairpin with a standard type I beta-turn conformation, and the two forms are in fast dynamic equilibrium with one another. The effect of pH demonstrates the existence of a stabilizing interaction between the Asn and Asp sidechains. The populations of beta-hairpin conformations increase in the presence of trifluoroethanol (a structure-enhancing solvent). On the other hand, some residual structure persists at a high denaturant concentration (8 M urea).

CONCLUSIONS

This work highlights the importance of the beta-turn residue composition in determining the particular type of beta-hairpin adopted by a peptide, though a role of interstrand sidechain interactions in the stabilization of the formed beta-hairpin is not discarded. The fact that trifluoroethanol can stabilize alpha-helices or beta-hairpins depending on the intrinsic properties of the peptide sequence is again shown. An additional example of the presence of residual structure under denaturing conditions is also presented.

Interactions responsible for the pH dependence of the beta-hairpin conformational population formed by a designed linear peptide

In a previous work [Blanco, F.J., Jiménez, M.A., Herranz, J., Rico, M., Santoro, J. & Nieto, J. L. (1993) J. Am. Chem. Soc. 115, 5887-5888] we showed that a short, designed linear peptide, YQNPDGSQA (peptide 1), can form a monomeric beta hairpin in aqueous solution. The pH dependence of the beta-hairpin conformation formed by the designed peptide and a series of related peptides has been examined in this work using 1H-NMR methods. Three pH-dependent interactions have been identified: a local interaction, unimportant structurally, between the C-terminal carboxylate group and the side-chain amide group of Q8; an electrostatic interaction between the main-chain N-terminus and C-terminus; and a hydrogen bond involving the side-chain amide protons of N3 and the side-chain carboxylate group of D5. The latter two interactions are particularly relevant as they increase the population of the beta-hairpin conformation. We also observe in the mutant peptide A9H that the interaction between Y1 and H9 (of the type proposed to exist in proteins) does not contribute to beta-hairpin stabilisation in our peptide system. Peptide 1 is, therefore, a very suitable model to examine the different interactions that contribute to beta-hairpin stability.

1H-NMR assignment and solution structure of human acidic fibroblast growth factor activated by inositol hexasulfate

A major fragment of human acidic fibroblast growth factor of 132 amino acid residues is shown to be as active and stable as the 139 residue molecule initially described, and commonly used in physiological studies. It is shown that inositol hexasulfate is a good substitute for heparin in both activating and protecting acidic fibroblast growth factor. The complex between the shortened form of the protein and inositol hexasulfate was used to determine the structure of activated acidic fibroblast growth factor in solution. The 1H-NMR spectrum of the complex was totally assigned, and a low-resolution, three-dimensional structure of the protein computed. The global fold of the activated acidic fibroblast growth factor is similar to that proposed for a crystallized variant of the protein obtained by genetic engineering whose activity is not dependent on heparin. The inositol hexasulfate binds to the protein through the positively charged groups of Lys126, Lys127, Arg133 and Lys142 side-chains. The computed three-dimensional structure suggests that inositol hexasulfate may stabilize and activate the protein by conferring rigidity to the hairpin involving beta-strands 10 and 11.

NMR solution structure of the isolated N-terminal fragment of protein-G B1 domain. Evidence of trifluoroethanol induced native-like beta-hairpin formation

The solution structure of the isolated N-terminal fragment of streptococcal protein-G B1 domain has been investigated in H2O and TFE/H2O solution by CD and NMR to gain insight into the possible role that native beta-hairpin secondary structure elements may have in early protein folding steps. The fragment also has been studied under denaturing conditions (6 M urea), and the resulting NMR chemical shifts were used as a reference for the disordered state. On the basis of CD and NMR data, it is concluded that in aqueous solution the fragment is basically flexible, with two local low populated chain bends involving residues 8-9 and 14-15, respectively, in close agreement with secondary structure predictions, a structure that is different from the final folded state of that segment of the protein. The changes in the CD spectrum, the presence of several medium-range NOEs plus two long-range NOEs, and the sign of the H alpha conformational shifts reveal that the addition of TFE facilitates the formation of a set of transient beta-hairpins involving essentially the same residues that form the native beta-hairpin found in the final three-dimensional structure of the B1 domain. The stabilization of native-like structures by TFE is known to occur for helices, but, to our knowledge, this is the first time the stabilization of a native-like beta-hairpin structure by TFE is reported. Since long-range tertiary interactions are absent in the isolated fragment, our results support the idea that, in addition to helices, beta-hairpins may play an active role in directing the protein folding process.

Helix formation by the phospholipase A2 38-59 fragment: influence of chain shortening and dimerization monitored by nmr chemical shifts

The solution structure of a peptide fragment corresponding to the 38-59 region of porcine phospholipase A2 has been investigated using CD, nmr chemical shifts, and nuclear overhauser effects (NOEs). This isolated fragment of phospholipase forms an alpha-helix spanning residues 38-55, very similar to the one found in the native protein, except for residues 56-58, which were helical in the crystal but found random in solution. Addition of triflouroethanol (TFE) merely increased helix population but it did not redefine helix limits. To investigate how the folding information, in particular that concerning eventual helix start and stop signals, was coded in this particular amino acid sequence, the helices formed by synthetic peptides reproducing sections of this phospholipase 38-59 fragment, namely 40-59, 42-59, 38-50, and 45-57, were characterized using NOEs and helix populations quantitatively evaluated on different peptide chain segments using nmr chemical shifts in two solvents (H2O and 30% TFE/H2O). A set of nmr spectra was also recorded and assigned under denaturing conditions (6M urea) to obtain reliable values for the chemical shifts of each peptide in the random state. Based on chemical shift data, it was concluded that the helix formed by the phospholipase 38-59 fragment was not abruptly, but progressively, destabilized all along its length by successive elimination of residues at the N end, while the removal of residues at the C end affected helix stability more locally and to a lesser extent. These results are consistent with the idea that there are not single residues responsible for helix initiation or helix stability, and they also evidence an asymmetry for contributions to helix stability by residues located at the two chain ends. The restriction of molecular mobility caused by linking with a disulphide bridge at Cys 51 two identical 38-59 peptide chains did not increase helix stability. The helix formed by the covalently formed homodimer was very similar in length and population to that formed by the monomer.

Cardiac beta-adrenoceptors, G-proteins and adenylate cyclase regulation during myocardial hypertrophy

The role of the beta-adrenoceptor-G-protein-adenylate cyclase system in the pathogenesis of cardiac hypertrophy was studied. We have used a minipig model of pressure-overload cardiac hypertrophy secondary to aortic banding. Four groups of five animals were used: minipigs made hypertrophic were evaluated 2 months (CH2 group) and 9 months (CH9 group) later and compared to controls (C2 and C9 groups, respectively). A decrease in beta-adrenergic receptor density and an increase in antagonist affinity were shown in left ventricular membranes of hypertrophied animals compared with controls. In both groups, CH2 and CH9, an increase in EC50 for isoproterenol-stimulated adenylate cyclase activity, an increase in forskolin-stimulated adenylate cyclase activity and a diminished inhibition by carbachol of isoproterenol-stimulated adenylate cyclase were observed. In contrast, fluoride-stimulated adenylate cyclase activity was markedly increased only in the end stage of hypertrophy. alpha s-cholera toxin-catalysed ADP-ribosylation is increased in early hypertrophy and then decreases with late hypertrophy and a similar pattern is observed with alpha o pertussis toxin-catalysed ADP-ribosylation, whereas alpha i-ADP-ribosylation remains unchanged. Tissue content of Gs-, Gi- and Go-proteins, as assessed by specific antibodies, was found unchanged in CH9 and CH2 groups when compared with that in C9 and C2 control groups, respectively. Modifications in Gs functional activity in later hypertrophic stages, expressed as alterations in cholera toxin ADP-ribosylation and adenylate cyclase fluoride responsiveness, may be important in the pathogenesis of decompensation from compensated hypertrophy to cardiac failure.

High-resolution three-dimensional structure of ribonuclease A in solution by nuclear magnetic resonance spectroscopy

High-resolution three-dimensional structures of bovine pancreatic ribonuclease A in aqueous solution have been determined by nuclear magnetic resonance (NMR) spectroscopy combined with restrained molecular dynamics calculations. The structures are based on: (1) 464 interproton distance constraints with accurate upper and lower limits, determined from build-up rates of nuclear Overhauser effects (NOE) by using the complete relaxation matrix; (2) 999 more approximate upper limits for interproton distances; and (3) 42 dihedral angle constraints (37 for phi and 5 for chi 1). A total of 16 structures were calculated, which show a root-mean-square (r.m.s.) deviation of 0.66 A for the backbone atoms and 1.68 A for all heavy-atoms. The converged structures are highly similar to those found in the crystal state. r.m.s. deviation of backbone atom positions in the crystal as compared to those in the average solution structure is 0.92 A. Observed differences are concentrated in loop regions and in the neighborhood of His119 and His48 side-chains. Dynamic aspects, such as H/D amide proton exchange and side-chain mobility have been examined.

CD and 1H-NMR studies on the conformational properties of peptide fragments from the C-terminal domain of thermolysin

The propensity of the peptide fragments 233-248, 245-260, 258-276, 279-298 and 299-316 from the thermolysin C-terminal domain to form non-random structures has been examined by CD and two-dimensional NMR spectroscopy. The conformational properties of these fragments have been studied in aqueous solution and in the mixed solvent trifluoroethanol/H2O (3:7 by vol.). Small but detectable populations of helical structures (up to 10-20%) in aqueous solution have been found for the fragments 233-248, 279-298 and 299-316. These populations are remarkably enhanced (50-70%) in the more hydrophobic mixed solvent, where the fragment 258-276 also forms a comparable helical population. These four fragments are helical in the native crystal structure and the spanning of the corresponding helices in the isolated peptides in solution matches very closely the ones in the native structure. In contrast, the fragment 245-260, an omega-loop in the crystal, remains unstructured in both solvents. Medium-range NOE between protons in sidechains indicate the adoption of preferred sidechain conformations accompanying helix formation. Results are in agreement with the framework model of folding, in which native elements of secondary structure are formed first and folding follows from the collapse of these structural elements.

Characterization of a synthetic calmodulin-binding peptide derived from Bacillus anthracis adenylate cyclase

A 34-amino acid peptide corresponding to residues 532-565 of Bacillus anthracis adenylate cyclase (P532-565), a calmodulin (CaM)-activated enzyme, was synthesized by solid phase method. Although not homologous to any known CaM binding sequence, P532-565 exhibits molecular features characteristic of this class of peptides: a higher proportion of basic and hydrophobic residues, segregated onto the two faces of the alpha-helical structure. Fluorescence measurements and gel retardation analysis showed that P532-565 binds CaM in a Ca(2+)-dependent manner, with a binding energy that represents 80% of the binding energy of the adenylate cyclase-CaM complex. Circular dichroism analysis showed that P532-565 exists in solution as a mixture of random-coil and alpha-helical structures and that trifluoroethanol increases the relative proportion of alpha-helical population. Analysis of proton NMR spectrum in H2O allowed identification of the different amino acid spin systems and complete spectral assignment. The pattern of nuclear Overhauser effect connectivities, intense NN(i,i + 1) and medium range alpha N(i,i + 3) and alpha beta (i,i + 3) indicate the presence of an alpha-helix in the carboxylterminal end (between residues 551 and 563) in fast exchange with extended structures. These data, together with CaM-binding properties of Bordetella pertussis adenylate cyclase, show that despite rather divergent primary structures, the two bacterial enzymes possess similar structural organization of their binding sites for activator protein.

Periodic properties of proton conformational shifts in isolated protein helices. An experimental study

In this work, the helix-forming residues in fragments of several proteins (ribonuclease, thermolysin, tendamistat and angiogenin) were identified by NOE and the helix proton shifts were measured as delta changes associated with helix-population increments driven by trifluoroethanol addition. When estimated in this way, a regular pattern of helix conformational shifts was clearly seen in the delta delta versus sequence profiles of all the peptides studied. The helix periodicity of the H alpha and H beta resonances was especially clear, an observation that earlier statistical studies of protein delta values failed to predict. Amide protons showed the largest helix shifts, but with a less-sharply defined periodic character. Aromatic residues considerably distorted the periodicity of the helix amide shifts in some peptides, as evidenced by the delta shifts of a RNase A fragment 1-15 analog in which the two aromatic residues were replaced by Ala. The relationship between helix periodicity and peptide amphiphatic character is discussed.

The homologous angiogenin and ribonuclease N-terminal fragments fold into very similar helices when isolated

The solution structure of the N-terminal hexadecapeptide of human angiogenin, a protein of unknown tertiary structure, has been precisely delineated by the combined use of CD, NOE and secondary shift data. A helix that starts just after Ser 3 and ends at Asp 14 was stabilized in 30% trifluoroethanol. This helix is strikingly similar in origin and length to the one formed by its homologous, the S-peptide of Ribonuclease (conformationally reexamined here), despite their quite different sequences (only four conserved residues). These results support the idea that individual start and stop signals indeed govern the location and size of natural isolated helices.

Tendamistat (12-26) fragment. NMR characterization of isolated beta-turn folding intermediates

In order to determine whether regions of a protein that are turns in the native structure are able to maintain such a structure when isolated, we have studied the conformational properties of various peptide fragments corresponding to the 12-26-peptide region of the alpha-amylase inhibitor tendamistat, by NMR. Amide solvent accessibility, NOE spectroscopy (NOESY) and rotating-frame NOE spectroscopy (ROESY) data strongly support the conclusion that the 12-26 and 15-23 peptides adopt in aqueous solution, a set of turn-like structures located around the central region of their corresponding polypeptidic chains, the same region where a beta turn exists in the native protein. Such a set of structures are destabilized when one residue located within the native beta turn of the 15-23 peptide is modified Trp18----Ser. Our results indicate that the tendency to bend in a predetermined region of a protein chain seems to exist from the very beginning of the folding process and therefore it could drive the folding instead of being a consequence of the tertiary assembly of the protein.

Mechanism of inhibition of adenylate cyclase by phospholipase C-catalyzed hydrolysis of phosphatidylcholine. Involvement of a pertussis toxin-sensitive G protein and protein kinase C

The phospholipase C-mediated hydrolysis of phosphatidylcholine has been shown recently to be activated by a number of agonists. Muscarinic receptors, which trigger various signal transduction mechanisms including inhibition of adenylate cyclase through Gi, have been shown to be potent stimulants of this novel phospholipid degradative pathway. We demonstrate here, by exogenous addition of Bacillus cereus phosphatidylcholine-hydrolyzing phospholipase C, that phosphatidylcholine breakdown mimics the ability of carbachol to inhibit adenylate cyclase. This effect is sensitive to pertussis toxin and is entirely dependent on the presence of protein kinase C. This kinase is also required for the inhibition by carbachol of adenylate cyclase. These results suggest that the activation of phosphatidylcholine breakdown by phospholipase C may play an important role linking or favoring the coupling muscarinic receptors to Gi. Results presented here also show that phospholipase C-mediated hydrolysis of phosphoinositides by exogenous addition of Bacillus thuringiensis phosphoinositide-hydrolyzing phospholipase C does not affect adenylate cyclase, despite the fact that protein kinase C is translocated to an extent similar to that produced by the hydrolysis of phosphatidylcholine. According to the results shown here, both phospholipases also differ in their ability to down-regulate protein kinase C as well as to phosphorylate p80 and to transmodulate the binding of epidermal growth factor, two well established effects of protein kinase C in Swiss 3T3 fibroblasts. This emphasizes the complexity, from a functional point of view, of protein kinase C activation "in vivo."

Solution structure of the isolated ribonuclease C-terminal 112-124 fragment

The conformational properties of the ribonuclease C-terminal 112-124 fragment have been studied by CD and 1H- and 13C-NMR in an attempt to determine whether native secondary structure elements other than alpha-helices have stability enough to be detected when isolated in aqueous solution. Only sequential alpha N and intraresidue NOE cross-peaks are observed in the NOESY spectra, a fact which points towards an essentially extended polypeptidic chain. Observed spectral variations with temperature, pH and urea addition allowed the identification of two non-random regions within the chain. The first one is located within residues 119-121, the same region where a native salt bridge (H119...D121) exists in the native protein, and the stability of that structure is affected by the protonation state of carboxylate groups. The second one involves the S123 and V124 residues at the C-terminal end. No signs of the native 112-115 beta-turn were detected which suggests that, in contrast to alpha-helices, long range interactions may be needed to stabilize these secondary structure elements.

Characterization of low populated peptide helical structures in solution by means of NMR proton conformational shifts

A NOE independent NMR method is proposed to characterize unambiguously residues involved in low populated isolated peptide helices. The method is based on the comparison of amide and H alpha chemical shift changes originated upon the addition of stabilizing or denaturing agents with true helical conformational shifts that have been measured for the first time using an isolated model peptide helix, the one formed by Ac-(Leu-Lys-Lys-Leu)3-NHEt in aqueous solution.

Sequential 1H-NMR assignment and solution structure of bovine pancreatic ribonuclease A

Assignments for 1H-NMR resonances of most of the residues of bovine pancreatic ribonuclease (RNase A) have been obtained by sequence-specific methods. Identification and classification of spin systems have been carried out by two-dimensional phase-sensitive correlated spectroscopy (360 MHz) and single relayed coherence transfer spectroscopy. Sequence-specific assignments have been achieved by phase-sensitive two-dimensional nuclear Overhauser effect spectroscopy. To overcome the problem of spectral overlap use has been made of (a) an exhaustive analysis of partly exchanged RNase A (spectra in D2O), (b) a comparison with the subtilisin-modified enzyme (RNase S) and (c) small spectral perturbations caused by changes in pH and temperature. The secondary structure elements have been identified from the observed sequential, medium and long-range nuclear Overhauser effects together with data from amide-exchange rates. All information collected leads to the conclusion that the crystal and the solution structures are closely similar.

Conformational properties of the isolated 1-23 fragment of human hemoglobin alpha-chain

With the purpose of establishing whether, as a general rule, regions of a protein chain that are helical in the native structure maintain, at least partially, the same helical structure when isolated in solution, we have prepared the 1-23 fragment of human hemoglobin alpha-chain, and studied its conformational properties in aqueous solution by CD and 1H-NMR. From the analysis of CD and NMR spectral changes with temperature, salt and addition of trifluoroethanol (TFE) it can be concluded that the 1-23 peptide forms a measurable population (18% at 22 degrees C (pH 5.6) TFE/H2O, 30:70 (v/v)) of an alpha-helix structure that spans the same residues that are helical in the native protein (namely, 6 to 17). These results, taken together with similar ones obtained previously in the 1-19, 21-42 and 50-61 RNAase fragments, support the idea that no helices other than the native ones are actually formed in solution by protein fragments. This implies that the final helical structure of a protein is present from the very beginning of the folding process, and also that such elements of secondary structure can act as primary nucleation centers.

Nuclear Overhauser effects in aqueous solution as dynamic probes in short linear peptides

The possibility of obtaining interresidue NOEs from short linear peptides in aqueous solution has been investigated from an experimental point of view using peptides of various lengths (namely GGRA, LHRH and RNase S-peptide). It is shown that, provided that long (approximately 800 ms) NOESY mixing times are used, complete sets of sequential alpha N NOEs are obtainable. From the intensities and signs of the observed NOEs, the relative mobilities of different parts of the polypeptide chain can be determined.

1H-NMR assignment and folding of the isolated ribonuclease 21-42 fragment

We show in this paper that the isolated bovine ribonuclease 21-42 fragment is able to adopt in water solution a measurable population (14% at 22 degrees C, pH 5.4) of a native-like alpha-helical structure. Strong support for this conclusion is given by the analysis of CD data and 1H chemical shift variations with the temperature and the addition of stabilizing (trifluoroethanol) and denaturing (urea) agents. This results gives experimental support to the idea that native isolated secondary structure elements (at least alpha helices) are, as a rule, partially stable in solution and therefore they can act as independent protein-folding nucleation centers.

1H NMR and CD evidence of the folding of the isolated ribonuclease 50-61 fragment

In our search for potential folding intermediates we have prepared and characterized the fragment of RNase A corresponding to residues 50-61. Proton chemical shift variations with temperature, addition of stabilizing (TFE) or denaturing agents (urea) provide a strong experimental basis for concluding that in aqueous solution this RNase fragment forms an alpha-helix structure similar to that in the intact RNase A crystal. This conclusion lends strong support to the idea that elements of secondary structure (mainly alpha-helices) can be formed in the absence of tertiary interactions and act as nucleation centers in the protein folding process.

1H-n.m.r. study of the folding of ribonuclease 12-(beta-(3-pyridyl)-L-Ala) S-peptide (1-14)

The 1H-n.m.r. spectra (360 MHz) of 12-(beta-(3-pyridyl)-L-Ala) ribonuclease S-peptide (1-14), a tetradecapeptide incorporating (beta-3-pyridyl-L-Ala) instead of His at position 12, have been assigned. The shift vs. temperature dependence has been analyzed at three different pD's in terms of a two-state helix (3-13) in equilibrium coil equilibrium, and the corresponding values for the thermodynamic quantities delta H degrees and delta S degrees determined. Helix populations at 0 degrees C have been measured as a function of pD, showing their dependence on two apparent pKa's at approximately 3.3 and 5.5, with a maximum at pD approximately 4.2. All the obtained results show that the new peptide has very similar folding properties to those shown by S-peptide and particularly to those of C-peptide. The 3-13 helix formed is stabilized by two interactions: a salt-bridge Glu 2-...Arg 10+ and a partial stacking between the aromatic rings of residues Phe 8 and His 12. Calculations involving ring current shifts and potential energies validate the possible existence of this latter interaction, which must present a local geometry defined by chi 81 180 degrees, chi 82 100 degrees, chi 121-60 and chi 122 80.

Assignment and conformation of neurotensin in aqueous solution by 1H NMR

A complete assignment of exchangeable and unexchangeable proton resonances of neurotensin 1-13 in aqueous solution has been carried out with the help of its 1-8 and 8-13 fragments. To detect formation of a secondary structure, the effects of peptide fragmentation, temperature decrease, pH changes and addition of denaturing agents on the neurotensin 1H NMR spectrum were investigated. The small changes observed in all cases support the conclusion that neurotensin exists mainly as a flexible random coiled polypeptidic chain in aqueous solution in agreement with previous CD studies.

NH resonances of Ribonuclease S-peptide in aqueous solution. Low temperature n.m.r. study

A detailed study of the NH resonances of Ribonuclease-S-peptide (1-19 N-terminal fragment of Ribonuclease A) has been carried out in H2O, pH 3.0, in the temperature range 1-31 degrees, and ionic strength 0-1 M. Individual assignments of all NH amide signals have been achieved by means of extensive double resonance experiments. The folding of S-peptide at low temperature has been monitored by examination of the several NH resonance parameters: first, the nonlinearity of chemical shift vs. temperature plots; second, the selective broadening observed for signals assigned to residues 3-13; and third, the decrease of 3JHNCH coupling constants belonging to this region of the polypeptide chain. All these results are in agreement with the formation of a folded structure at low temperature, which is similar to the one found for the S-peptide in the RNase S crystal.

On the fundamental role of the Glu 2- ... Arg 10+ salt bridge in the folding of isolated ribonuclease A S-peptide

The fundamental role of the Glu 2- ... Arg 10+ salt bridge in the folding of isolated S-peptide (1-19 N-terminal fragment of Ribonuclease A) is demonstrated from the comparison of the helix contents, at 0 degrees C, of S-peptide and related peptides. Helix contents have been determined from the analysis of proton chemical shift vs. temperature curves. The observed data can be accounted for by assuming that two side-chain interactions contribute to stabilize the 3-13 helix of S-peptide, the salt bridges Glu 2- ... Arg 10+ and Glu 9-... His 12+, the former being more effective. The salt bridge Glu 9- ... Arg 10+ turns to a weaker interaction, a hydrogen bond Glu 2 (C delta = 0) ... Arg 10+, on protonation or esterification of the Glu 2 carboxylate.

Low-temperature 1H-NMR evidence of the folding of isolated ribonuclease S-peptide

The temperature (-7 degrees C to 45 degrees C, pH 5.4) and pH (0 degrees C) dependence of 1H chemical shifts of ribonuclease S-peptide (5 mM, 1 M NaCl) has been measured at 360 MHz. The observed variations evidence the formation of a partial helical structure, involving the fragment Thr-3-Met-13. Two salt-bridges stabilize the helix: those formed by Glu-9- ...His-12+ and Glu-2- ...Arg-10+. The structural features deduced from the 1H-NMR at low temperature for the isolated S-peptide are compatible with the structure shown by the same molecule in the ribonuclease S crystal.

1H n.m.r. parameters of the N-terminal 19-residue S-peptide of ribonuclease in aqueous solution

The 1H n.m.r. chemical shifts and the spin-spin coupling constants of the N-terminal 19-residue S-peptide of ribonuclease A have been measured in a 10 mM solution in D2O, pD 3.0, 27 degrees, at 300 MHz. The titration parameters for end groups Lys-1 and Ala-19 and side chains Lys-1, Glu-2, Lys-7, Glu-9, Arg-10, His-12 and Asp-14 have been determined at 90 MHz. An assignment of observed signals to individual residue protons based upon characteristic shifts, spectral analysis, double resonance, titration shifts and comparison with the spectrum of C-peptide (N-terminal 13-residue) is proposed. Differences in the observed chemical shifts, pKa's and titration shifts with reference to those proposed as "random coil" parameters are not large enough to assume the existence of a significant population of secondary structure in the conditions studied. The H alpha chemical shifts differences can be accounted for by the Phe-8 phenyl ring current for an extended peptide backbone conformation and appropriate values for the torsion angles chi 1 Phe-8 and chi 2 Phe-8.

[Hypervitaminosis D. Review of fifteen cases]

Fifteen cases of hypervitaminosis D in childhood are reviewed. In all of them, vitamin D was given following medical prescription. In four occasions, excessive dosage of vitamine D impaired the evolution of a previous nephropathy. The clinical, analytical, radiological and histological findings as well as the therapeutical aspects are commented. Hypercalcemia, hypercalciuria, polyuria with hypostenuria, renal failure, bone lesions and nephrocalcinosis are the most prominent features of the picture. Occasionally, arterial hypertension and glycosuria were found. Prednisone, thyrocalcitonine and phosphates were used as therapeutical means. In spite of nephrocalcinosis and renal failure generally present at diagnosis, the clinical course was rather good.