The biological activity of Humanin analogs correlates with structure stabilities in solution

A single mutation has resulted in large differences in neuroprotective activity of a 24 amino acid Humanin (HN). A mutation of Ser7Ala (S7A-HN) resulted in loss of activity, while a mutation of Ser14Gly (S14G-HN) resulted in about 1000-fold increase. The mechanism of the effects conferred by these mutations have been totally unclear, although our recent structure analysis suggested a possibility of the effect of mutation on the structure stability. Here, we have studied the effects of buffer and temperature on the structure of these three HN peptides. These peptides showed a similar disordered structure at 10 °C in 10 mM phosphate, pH 6.0. They were also similar in phosphate-buffered saline (PBS) as long as the temperature was kept low at 10 °C. However, a large difference was observed in both phosphate buffer and PBS between the peptides, when the temperature was raised to a physiological temperature of 37 °C. While S14G-HN showed small changes in both solutions at 37 °C, the less active HN and inactive S7A-HN showed much larger changes under the identical conditions. In addition, it appeared that structure change at 37 °C was faster for S7A-HN than HN. These results show that the structure stability at 37 °C increases in the order of S7A-HN, HN and S14G-HN, in correlation with their neuroprotective activities.     

Conformational structure of bombesin as studied by vibrational and circular dichroism spectroscopy

Raman and Fourier transform infrared (FTIR) spectroscopies and circular dichroism (CD) have been applied to investigate the secondary structure of bombesin in the solid state and in phosphate buffer solution (pH 3.8). At concentrations around 10⁻⁵ M, circular dichroism reveals that bombesin exists as an irregular or disordered conformation. However, the secondary structure of the peptide appears to be a mixture of disordered structure and intermolecular β-sheets in 0.01 M sodium phosphate buffer when the peptide concentrations are higher than around 6.5 mM. The tendency of bombesin to form aggregated β-sheet species seems to be originated mainly in the sequence of the residues 7–14, as supported by the Raman spectra and β-sheet propensities (P_β) of the amino-acid residues. It is the hydrophobic force of this amino-acid sequence, and not a salt bridge effect, that is the factor responsible for the formation of peptide aggregates.     

The structure analysis of Humanin analog, AGA-(C8R)HNG17, by circular dichroism and sedimentation equilibrium: comparison with the parent molecule

A 24-amino acid peptide, Humanin (HN), is a novel peptide that protects neuronal cells in vitro and in vivo from Alzheimer's disease-related toxicities. We have shown before that the structures of HN and a 1000-fold more active analog, HNG, with a Ser14Gly mutation are largely disordered. During additional mutational analysis, a shorter 17-amino acid form, AGA-(C8R)HNG17, was accidentally discovered to have a 100-fold higher activity than HNG. Here we have characterized the structural properties of the AGA-(C8R)HNG17 analog by circular dichroism (CD) and sedimentation equilibrium analysis. First, the structure in water was characterized, since these peptides have been dissolved in water prior to biological analysis. The AGA-(C8R)HNG17 peptide exhibited extensive beta-sheet structure in water, completely different from the aqueous HN and HNG structures. The beta-sheet structure was converted to a disordered structure upon dilution into phosphate-buffered saline (PBS) at low peptide concentration (e.g., below 0.2mg/ml), which was similar to the structure of HN and HNG, observed under similar conditions. Sedimentation equilibrium analysis showed that the AGA-(C8R)HNG17 analog was essentially monomeric in PBS, while HNG showed extensive aggregation. Such aggregation of HNG was observed when the peptide was added to the serum-containing cell culture media. Thus, the mutations introduced into the AGA-(C8R)HNG17 analog generated a peptide different from the parent HNG and HN peptides in the self-association properties and hence the solubility, which most likely contributed to the increased biological activity of the AGA-(C8R)HNG17 analog.     

Solid-state NMR as a method to reveal structure and membrane-interaction of amyloidogenic proteins and peptides

It is important to understand the Amyloid fibril formation in view of numerous medical and biochemical aspects. Structural determination of amyloid fibril has been extensively studied using electron microscopy. Subsequently, solid state NMR spectroscopy has been realized to be the most important means to determine not only microscopic molecular structure but also macroscopic molecular packing. Molecular structure of amyloid fibril was first predicted to be parallel β-sheet structure, and subsequently, was further refined for Aβ(1-40) to be cross β-sheet with double layered in register parallel β-sheet structure by using solid state NMR spectroscopy. On the other hand, anti-parallel β-sheet structure has been reported to short fragments of Aβ-amyloid and other amyloid forming peptides. Kinetic study of amyloid fibril formation has been studied using a variety of methods, and two-step autocatalytic reaction mechanism used to explain fibril formation. Recently, stable intermediates or proto-fibrils have been observed by electron microscope (EM) images. Some of the intermediates have the same microscopic structure as the matured fibril and subsequently change to matured fibrils. Another important study on amyloid fibril formation is determination of the interaction with lipid membranes, since amyloid peptide are cleaved from amyloid precursor proteins in the membrane interface, and it is reported that amyloid lipid interaction is related to the cytotoxicity. Finally it is discussed how amyloid fibril formation can be inhibited. Firstly, properly designed compounds are reported to have inhibition ability of amyloid fibril formation by interacting with amyloid peptide. Secondly, it is revealed that site directed mutation can inhibit amyloid fibril formation. These inhibitors were developed by knowing the fibril structure determined by solid state NMR.     

Two serine residues distinctly regulate the rescue function of Humanin,an inhibiting factor of Alzheimer's disease-related neurotoxicity: functional potentiation by isomerization and dimerization

The 24-residue peptide Humanin (HN), containing two Ser residues at positions 7 and 14, protects neuronal cells from insults of various Alzheimer's disease (AD) genes and A beta. It was not known why the rescue function of (S14G)HN is more potent than HN by two to three orders of magnitude. Investigating the possibility that the post-translational modification of Ser14 might play a role, we found that HN with D-Ser at position 14 exerts neuroprotection more potently than HN by two to three orders of magnitude, whereas D-Ser7 substitution does not affect the rescue function of HN. On the other hand, S7A substitution nullified the HN function. Multiple series of experiments indicated that Ser7 is necessary for self-dimerization of HN, which is essential for neuroprotection by this factor. These findings indicate that the rescue function of HN is quantitatively modulated by d-isomerization of Ser14 and Ser7-relevant dimerization, allowing for the construction of a very potent HN derivative that was fully neuroprotective at 10 pM against 25 microM A beta1-43. This study provides important clues to the understanding of the neuroprotective mechanism of HN, as well as to the development of novel AD therapeutics.     

Unusual binding mode of scorpion toxin BmKTX onto potassium channels relies on its distribution of acidic residues

Besides classical scorpion toxin–potassium channel binding modes, novel modes remain unknown. Here, we report a novel binding mode of native toxin BmKTX towards Kv1.3 channel. The combined experimental and computational data indicated that BmKTX-D33H analog used the classical anti-parallel β-sheet domain as the channel-interacting interface together with the conserved channel pore-blocking Lys²⁶. However, the wild-type BmKTX was found to use Arg²³ rather than Lys²⁶ as the new pore-blocking residue, and mainly adopt the turn motif between the α-helix and antiparallel β-sheet domains to recognize K_v1.3 channel. Together, these findings not only reveal that scorpion toxin–potassium channel interaction modes are more diverse than thought, but also highlight the functional role of toxin acidic residues in mediating diverse toxin–potassium channel binding modes.     

Diverse effects on the native β-sheet of the human prion protein due to disease-associated mutations

Prion diseases are fatal neurodegenerative disorders that involve the conversion of the normal cellular form of the prion protein (PrP(C)) to a misfolded pathogenic form (PrP(Sc)). There are many genetic mutations of PrP associated with human prion diseases. Three of these point mutations are located at the first strand of the native β-sheet in human PrP: G131V, S132I, and A133V. To understand the underlying structural and dynamic effects of these disease-causing mutations on the human PrP, we performed molecular dynamics of wild-type and mutated human PrP. The results indicate that the mutations induced different effects but they were all related to misfolding of the native β-sheet: G131V caused the elongation of the native β-sheet, A133V disrupted the native β-sheet, and S132I converted the native β-sheet to an α-sheet. The observed changes were due to the reorientation of side chain-side chain interactions upon introducing the mutations. In addition, all mutations impaired a structurally conserved water site at the native β-sheet. Our work suggests various misfolding pathways for human PrP in response to mutation.     

Heterologous expression and solution structure of defensin from lentil Lens culinaris

A new defensin Lc-def, isolated from germinated seeds of the lentil Lens culinaris, has molecular mass 5440.4 Da and consists of 47 amino acid residues. Lc-def and its ¹⁵N-labeled analog were overexpressed in Escherichia coli. Antimicrobial activity of the recombinant protein was examined, and its spatial structure, dynamics, and interaction with lipid vesicles were studied by NMR spectroscopy. It was shown that Lc-def is active against fungi, but does not inhibit the growth of Gram-positive and Gram-negative bacteria. The peptide is monomeric in aqueous solution and contains one α-helix and triple-stranded β-sheet, which form cysteine-stabilized αβ motif (CSαβ) previously found in other plant defensins. The sterically neighboring loop1 and loop3 protrude from the defensin core and demonstrate significant mobility on the μs–ms timescale. Lc-def does not bind to the zwitterionic lipid (POPC) vesicles but interacts with the partially anionic (POPC/DOPG, 7:3) membranes under low-salt conditions. The Lc-def antifungal activity might be mediated through electrostatic interaction with anionic lipid components of fungal membranes.     

Atg7 Activates an Autophagy-Essential Ubiquitin-like Protein Atg8 through Multi-Step Recognition

Atg8 is a unique ubiquitin-like protein that is covalently conjugated with a phosphatidylethanolamine through reactions similar to ubiquitination and plays essential roles in autophagy. Atg7 is the E1 enzyme for Atg8, and it activates the C-terminal Gly116 of Atg8 using ATP. Here, we report the crystal structure of Atg8 bound to the C-terminal domain of Atg7 in an unprecedented mode. Atg8 neither contacts with the central β-sheet nor binds to the catalytic site of Atg7, both of which were observed in previously reported Atg7–Atg8 structures. Instead, Atg8 binds to the C-terminal α-helix and crossover loop, thereby changing the autoinhibited conformation of the crossover loop observed in the free Atg7 structure into a short helix and a disordered loop. Mutational analyses suggested that this interaction mode is important for the activation reaction. We propose that Atg7 recognizes Atg8 through multiple steps, which would be necessary to induce a conformational change in Atg7 that is optimal for the activation reaction.     

Unusual structural transition of antimicrobial VP1 peptide

VP1 peptide, an active domain of m-calpain enzyme with antimicrobial activity is found to undergo an unusual conformational transition in trifluoroethanol (TFE) solvent. The nature of, and time dependent variations in, circular dichroism associated with the amide I vibrations, suggest that VP1 undergoes self-aggregation forming anti-parallel β-sheet structure in TFE. Transmission electron micrograph (TEM) images revealed that β-sheet aggregates formed by VP1 possess fibril-like assemblies.     

Interaction of amphipathic polypeptides with phospholipids: characterization of conformations and the CD of oriented beta-sheets

The effects of interaction with phospholipids on the conformation of the alternating copolymer, poly(Leu-Lys), and the random copolymer poly(Leu⁵⁰, Lys⁵⁰) have been investigated by CD and ir spectroscopy. Poly(Leu-Lys) undergoes a partial unordered → β-sheet transition in solution in the presence of lysolecithin. On addition of lysolecithin plus cholate, an unordered → α -helix transition is observed. In films deposited from these solutions, poly(Leu-Lys) adopts the anti-parallel β-sheet conformation, as in aqueous solutions at moderate ionic strength. Polarized ir spectra showed that the plane of the β-sheet in such films deviates from the plane of the film by no more than 14°. The random copolymer, poly(Leu⁵⁰, Lys⁵⁰), is α-helical in the presence of lysolecithin and lysolecithin plus cholate, regardless of whether the sample is a solution or a film. CD measurements on the poly(Leu-Lys) films provide information about the component of the CD tensor for light propagating normal to the plane of the β-sheet. These measurements show (1) a negative n → π* CD band (214 nm maximum) with higher intensity than the average CD for isotropic solution; and (2) a positive band in the π → π* region (195 nm maximum), which is weaker than that in the isotropic spectrum.     

Special Interaction of Anionic Phosphatidic Acid Promotes High Secondary Structure in Tetrameric Potassium Channel

Anionic phosphatidic acid (PA) has been shown to stabilize and bind stronger than phosphatidylglycerol via electrostatic and hydrogen bond interaction with the positively charged residues of potassium channel KcsA. However, the effects of these lipids on KcsA folding or secondary structure are not clear. In this study, the secondary structure analyses of KcsA potassium channel was carried out using circular dichroism spectroscopy. It was found that PA interaction leads to increases in α-helical and β-sheet content of KcsA protein. In PA, KcsA α-helical structure was further stabilized by classical membrane-active cosolvent trifluoroethanol followed by reduction in the β-sheet content indicating cooperative transformation from the β-sheet to an α-helical structure. The data further uncover the role of anionic PA in KcsA folding and provide mechanism by which strong hydrogen bonds/electrostatic interaction among PA headgroup and basic residues on lipid binding domains may induce high helical structure thereby altering the protein folding and increasing the stability of tetrameric assembly.     

Ubiquitously expressed hematological and neurological expressed 1 downregulates Akt-mediated GSK3β signaling, and its knockdown results in deregulated G2/M transition in prostate cells

As the molecular mechanism of β-catenin deregulation is not well understood, and stabilized β-catenin is known to translocate into the nucleus and activate genes for proliferation, a novel regulatory factor, hematological and neurological expressed 1 (HN1), for Akt-GSK3β-β-catenin axis is reported here. In our studies, HN1 gene structure was characterized. HN1 expression was found to be epidermal growth factor-responsive in PC-3 cells, and protein expression was also upregulated in PC-3 and LNCaP but not in DU145 cells. Additionally, HN1 was found to be downregulated by the specific AKT inhibitor wortmannin but not with PI3K or MAPK inhibitors, LY294002 and PD98059, respectively, in PC-3 and MCF-7 cells. Further, siRNA-mediated knockdown of HN1 resulted in considerable increase in Akt((S473)) and GSK3β((S9),(Y216)) phosphorylations; moreover, subsequent accumulation of β-catenin, increase in c-myc expression, and nuclear accumulation of cyclin D1 were observed in PC-3 cells. Knockdown of HN1 also resulted in prolongation of G(1) phase in cell cycle, increasing tetraploidy, presumably because of cells escaping from abnormal mitosis in PC-3 cells. Consistently, overexpression of HN1 reversed the cell-cycle-specific observations, resulted in accumulation of cells in G(2)/M, and reduced the proliferation rate, which were investigated using flow cytometry and methylthiazol tetrazolium assays. As activating mutations of β-catenin have been demonstrated in late-stage tumors, and β-catenin stabilization was correlated with poor prognosis in previous reports, epidermal growth factor-upregulated HN1 expression might have a role in deregulating the AKT-GSK3β((S9))-mediated signaling as a novel compensating mechanism.     

Structural Studies of Immunoglobulin-Binding Domains of Streptococcal Protein G

The solution and X-ray structures of the IgG-binding domains of streptococcal protein G are described and compared. Each domain comprises a core of 56 residues and exhibits extreme thermal stability (∼900C), despite the absence of any disulfide bridges. The structure has an unusual fold comprising a four-stranded β-sheet with a −1, +3x, −1 topology on top of which lies an α-helix. The central two strands, comprising the N- and C-termini, are parallel; the outer two strands, which are anti-parallel to the inner strands, are connected by the helix in a +3x crossover. This fold is also found in ubiquitin, a protein with no sequence similarity or functional relationship to the IgG-binding domains of protein G. The thermal stability of the domains can be accounted for by the unusual topology, coupled with an extensive hydrogen bonding network and a tightly packed and buried hydrophobic core. Possible sites of interaction with IgG are discussed in the light of the structure.     

Connexin43 interacts with βarrestin: a pre-requisite for osteoblast survival induced by parathyroid hormone

Parathyroid hormone (PTH) promotes osteoblast survival through a mechanism that depends on cAMP-mediated signaling downstream of the G protein-coupled receptor PTHR1. We present evidence herein that PTH-induced survival signaling is impaired in cells lacking connexin43 (Cx43). Thus, expression of functional Cx43 dominant negative proteins or Cx43 knock-down abolished the expression of cAMP-target genes and anti-apoptosis induced by PTH in osteoblastic cells. In contrast, cells lacking Cx43 were still responsive to the stable cAMP analog dibutyril-cAMP. PTH survival signaling was rescued by transfecting wild type Cx43 or a truncated dominant negative mutant of βarrestin, a PTHR1-interacting molecule that limits cAMP signaling. On the other hand, Cx43 mutants lacking the cytoplasmic domain (Cx43(Δ245)) or unable to be phosphorylated at serine 368 (Cx43(S368A)), a residue crucial for Cx43 trafficking and function, failed to restore the anti-apoptotic effect of PTH in Cx43-deficient cells. In addition, overexpression of wild type βarrestin abrogated PTH survival signaling in Cx43-expressing cells. Moreover, βarrestin physically associated in vivo to wild type Cx43 and to a lesser extent to Cx43(S368A) ; and this association and the phosphorylation of Cx43 in serine 368 were reduced by PTH. Furthermore, induction of Cx43(S368) phosphorylation or overexpression of wild type Cx43, but not Cx43(Δ245) or Cx43(S368A) , reduced the interaction between βarrestin and the PTHR1. These studies demonstrate that βarrestin is a novel Cx43-interacting protein and suggest that, by sequestering βarrestin, Cx43 facilitates cAMP signaling, thereby exerting a permissive role on osteoblast survival induced by PTH.     

Crystal structure of serine dehydrogenase from Escherichia coli: important role of the C-terminal region for closed-complex formation

Serine dehydrogenase from Escherichia coli is a homotetrameric enzyme belonging to the short-chain dehydrogenase/reductase (SDR) family. This enzyme catalyses the NADP(+)-dependent oxidation of serine to 2-aminomalonate semialdehyde. The enzyme shows a stereospecificity for β-(3S)-hydroxy acid as a substrate; however, no stereospecificity was observed at the α-carbon. The structures of the ligand-free SerDH and SerDH-NADP(+)-phosphate complex were determined at 1.9 and 2.7 ? resolutions, respectively. The overall structure, including the catalytic tetrad of Asn106, Ser134, Tyr147 and Lys151, shows obvious relationships with other members of the SDR family. The structure of the substrate-binding loop and that of the C-terminal region were disordered in the ligand-free enzyme, whereas these structures were clearly defined in the SerDH-NADP(+) complex as a closed form. Interestingly, the C-terminal region was protruded from the main body and it formed an anti-parallel β-sheet with another C-terminal region on the subunit that is diagonally opposite to that in the tetramer. It is revealed that the C-terminal region possesses the important roles in substrate binding through the stabilization of the substrate-binding loop in the closed form complex. The roles of the C-terminal region along with those of the residues involved in substrate recognition were studied by site-directed mutagenesis.     

Association with nitric oxide synthase on insulin secretory granules regulates glucokinase protein levels

Glucokinase (GCK) association with insulin-secretory granules is controlled by interaction with nitric oxide synthase (NOS) and is reversed by GCK S-nitrosylation. Nonetheless, the function of GCK sequestration on secretory granules is unknown. Here we report that the S-nitrosylation blocking V367M mutation prevents GCK accumulation on secretory granules by inhibiting association with NOS. Expression of this mutant is reduced compared with a second S-nitrosylation blocking GCK mutant (C371S) that accumulates to secretory granules and is expressed at levels greater than wild type. Even so, the rate of degradation for wild type and mutant GCK proteins were not significantly different from one another, and neither mutation disrupted the ability of GCK to be ubiquitinated. Furthermore, gene silencing of NOS reduced endogenous GCK content but did not affect β-actin content. Treatment of GCK(C371S) expressing cells with short interfering RNA specific for NOS also blocked accumulation of this protein to secretory granules and reduced expression levels to that of GCK(V367M). Conversely, cotransfection of catalytically inactive NOS increased GCK-mCherry levels. Expression of GCK(C371S) in βTC3 cells enhanced glucose metabolism compared with untransfected cells and cells expressing wild type GCK, even though this mutant has slightly reduced enzymatic activity in vitro. Finally, molecular dynamics simulations revealed that V367M induces conformational changes in GCK that are similar to S-nitrosylated GCK, thereby suggesting a mechanism for V367M-inhibition of NOS association. Our findings suggest that sequestration of GCK on secretory granules regulates cellular GCK protein content, and thus cellular GCK activity, by acting as a storage pool for GCK proteins.     

Comparison of conformation and antimicrobial activity of synthetic analogs of gramicidin S: Stereochemical consideration of the role of D-phenylalanine in the antibiotic.

In order to study the role of D -amino acid residues in keeping the stable β-sheet conformation and in the antimicrobial activity of gramicidin S (GS), the four analogs of GS containing D -Ala, L -Ala, Gly, and Aib (α-aminoisobutyric acid) in place of D -Phe were synthesized. D -Ala-and Gly-containing analogs showed antimicrobial activity, while those containing L -Ala and Aib showed no activity. Conformation of these analogs and their derivatives were studied by comparison of ORD and CD spectra and by slective methylation method. It is concluded that the biologically active analogs have β-sheet conformation while inactive analogs have a much different conformation from that of GS. This indicates that D -Ala-Pro and Gly-Pro sequences favor taking a β-bend form but L -Ala-Pro and Aib-Pro sequences do not because the presence of L -side methyl group on the α-carbon atom of L Ala and Aib residues destabilizes the β-bend form. This would explain why the inactive analogs which take a different conformation from that of the active ones result in the loss of activity.     

An improved capping unit for stabilizing the ends of associated β-strands

Understanding protein beta structures has been hindered by the challenge of designing small, well-folded β-sheet systems. A β-capping motif was previously designed to help solve this problem, but not without limitations, as the termini of this β-cap were not fully available for chain extension. Combining Coulombic side chain attractions with a Trp/Trp edge-to-face interaction we produced a new capping motif that provided greater β-sheet stability. This stability was maintained even in systems lacking a turn locus with a high propensity for chain direction reversal. The Coulombic cap was shown to improve β-sheet stability in a number of difficult systems, hence providing an additional tool for protein structure and folding studies.     

Energetics and protomer communication in the dynamical structure of S100A13 in free and protein-bound states

S100A13 is S100 family of EF-hand-containing calcium-binding protein involved in the secretion of some growth factors and pro-inflammatory cytokines lacking signal peptides. The involvement of S100A13 in cancer progression and inflammatory diseases has been reported. In this study, structures generated during atomistic molecular dynamics simulation were studied. Dynamical network analysis data revealed that native inter-protomer communication network driven principally by vdW interaction (~550 kj/mol) is altered (Receptor for advanced glycation end products (RAGE) C2- and Fibroblast growth factor (FGF)-1-bound S100A13) or completely abolished (interleukin-1 (IL1)-α- and C2A-p40Syt1-bound S100A13) in protein-bound S100A13 homodimer. Bulk water density (weighted atomic density) around exposed S100A13 homodimer surface explored tends to follow the dynamical network lead as S100A13 homodimer appeared densely solvated in C2A-p40Syt1- and IL1)-α-bound states but not in RAGE C2- and FGF-1-bound biosystems. Furthermore, projection of radius of gyration and root mean square deviation (from native structure) variables of the generated structures along the 3D-free energy surface showed anti-parallel β-sheet proximal to Ca²⁺-binding loops-I/II in most metastable complexes retrieved from energy minima state with strong indications for β-sheet network formation during protein binding. Interaction between S100A13 homodimer and ligand–proteins may be dictated by the strength of vdW and electrostatic interaction with possible involvement of bulk water desolvation in some complexes. All these results strongly suggest that disruption of multiprotein receptor complex can be achieved by designing specific compounds targeting a specific aspect of S100A13/protein interaction; such drugs may have clinical usefulness in blocking angiogenesis, reversing cell proliferation and attenuating inflammatory processes.