Design And Access To Disallowed And Unusual Conformers Of Peptides In Crystals And In Solution : Structural Consequences Of The Imidate And Thioimidate Isosteres For The Peptide Bond

Reddy, N Damodara

12 1900

This thesis entitled “Design and Access to Disallowed and Unusual Conformers of Peptides in Crystals and in Solution: Structural Consequences of the Imidate and Thioimidate Isosteres for the Peptide bond” is divided into eight chapters. Imidate Modification The range of disallowed dihedral angles for residues in peptides is governed by their local steric and electrostatic clashes. Rare tolerances of violations in these angles are attributed to distortions in both local and global bond characteristics of the peptides. Discerning the origins of such disallowed angles and the consequent distortions in body of the peptides is essential, for a complete understanding of the protein fold, to improve the crystal database for validation of rare but acceptable residue conformations and for validation and improvement of theoretical models that evaluate the interactions that define the Ramachandran space. Unlike for the ordered secondary structures such as β-sheets α-helices and β-turns currently there are no models for residues constrained in disallowed folds. We reasoned that residues may be stabilized in disallowed folds in peptides if a neighbouring group and The range of disallowed dihedral angles ( , ψ) for residues in peptides is governed by their hence its local unfavorable clashes can be selectively modified to a motif that favors such space Steric clashes of the type H•••Xi±n involving the backbone amide hydrogen (H) contribute to ~60% of disallowed ,ψspace. Conversion of an amide to an imidate (A→I) will remove the corresponding H and hence the steric clashes related to it in peptides. Importantly, this will introduce an H-bond acceptor N (of imidate) in place of an H-bond donor NH (of amide), which will allow formation of unusual H-bonding interactions between the imidate N and the neighbouring Hs and hence constrain residues in otherwise inaccessible dihedral angles. The conversion of A→I is challenging owing to difficulties in selective synthesis, stability and purification of the imidate motif. We address all these concerns by the selective conversion of a backbone amide in peptides to the relatively stable cyclic 5,6-dihydro-4H-1,3-oxazine imidate isostere, by an intra¬molecular nucleophilic cyclo-O-alkylation reaction. Chapter 1:SectionB: Autocyclo-O-Alkylation of N-(3-Bromopropyl)amides into 2-Alkyl-5,6-Dihydro-4H-1,3-Oxazinehydrobromides We are describing the reactivity of N-(3-bromopropyl)amides that are precursors for 2-peptide-5,6-dihydro-4H-1,3-oxazine. The starting materials, 3-bromopropylamides, were synthesized in good yields by coupling the corresponding carboxylic acids and anhydrides with 3-bromopropylaminehydrobromide using standard mixed anhydride peptide coupling protocol. N-(3-bromopropyl)-acylamides are unstable during the isolation. Time-dependent 1H NMR of all the acetamides revealed that they underwent clean auto-cyclization to form the corresponding 2-alkyl-5,6-dihydro-4H-1,3-oxazine hydrobromides following first order rate. The salts were easily isolated in high purity by trituration of the mixtures with ether. The t1/2 of autocycliation of decreased upon increase in electron density on the R-carbon. Notably, the tert-butyl substituent cyclized significantly faster than acetamide which have enolizable hydrogens at the R-carbon. Thus, the cyclization rate is affected predominantly by the inductive effect of the R-carbon substituents. The formamide remained stable and unchanged due to the poor electron-donating ability of hydrogen. Chapter 1: Section C: Intramolecular Hydrogen Bond Assistance Improves Autocyclization in N-(3-Bromopropyl)amides The autocyclisation do not go to 100% completion. This is because the released hydrobromic acid quenches the nucleophilicity of amide carbonyl oxygen. In order to scavenge hydro bromic acid, we used 1 equivalent of DIEA base is acting only acid scavenger which conformed by unaffecting the reaction rate upon increasing equivalents of DIEA. We found that autocyclisation of N-(3-bromopropyl)amides rates in peptides involved in intramolecular backbone H-bonding interactions improve the autocyclization rates significantly than unstructured (random coil) peptides. Even with in the ordered structures the rate depends on the proximity of H-bonding distances as well as the H-bond acceptor strength. Half-life of autocyclisation in various peptide secondary structures are determined from time variant 1H NMR studies performed at 60 mM peptide concentration in CDCl3 at 32 oC. Chapter 2: Section A: Synthesis and Isolation of 5,6 Dihydro-4H-1,3-Oxazine Containing Peptidomimetics We have introduced 5,6-Dihydro-4H-1,3-oxazine as the imidate isostere at C-terminus of a number of peptides through NaH (base) mediated intramolecular cyclo-O-alkylation of N-(3-bromopropyl)amides. The amide to imidate (A→I) modification reaction is faster (1-5.5 h), Exhibiting no electronic and structural effects under these conditions. The side product NaBr can be easily separated by filtration through celite. No side products were observed and there is no need of further purification to get pure 1,3-oxazines in quantitative yields in all the peptidomimetics. Using this synthetic protocol we have synthesised a variety of 1,3-oxazine containing peptide analogues including aliphatic, branched aliphatic, polar side chains and larger peptides. We show that the retention of configuration at Cαof peptides during the base mediated cyclo-O-alkylation reaction. that the C5i.structures are more populated at Aib due to operation of The Thorpe-Ingold effect. The strength of hydrogen bonding interaction in C5i structure is similar to those of the highly buried backbone hydrogen bonding interaction found in the middle of a model 310-helical peptide as indicated by DMSO titration experiments. Chapter 3: Section A: Consequences of "Disallowed" Conformations on Constrained β-Turn Peptides Here we are describe the consequence of disallowed conformations the on a C-terminus of a type-II β-turn. We choose stereochemically constrained Type-II β-turn Pro-Aib dipeptide analogue which is the ideal model to mirror the structural effects of introducing the A→I modification at the C-terminus. The imidate containing peptidomimetic crystallised in dichloromethane and hexane mixture. Analysis of crystal structure revealed that Aib NH is involved in 3-centered H-bonding interactions with the N of oxazine and N of proline. This constrains Aib in a conformation that is natively disallowed to it. The (, ) angles of Aib residue fall in the (180,0) region which is strictly disallowed for natural peptides due to steric clashes involving the back bone amide N-H. More importantly there are two C•••O interactions which are accomidated in the crystal structures. Both oxygen‟s were place in staggered orientation of the Pro oxygen (OPro) between the two β-CH3 groups of Aib, which is again strictly disallowed in natural peptides due to strong C•••Oi-1 hard sphere clashes. However no vdW space violations are observed between these atoms. Chapter 3: Section B: Conformational Effects of “Disallowed Aib on a 310-Helical peptide In order to investigate the origins and consequences of “disallowed” conformations on a folded helical peptide body, the conformationally stable peptide sequence Boc-Leu1-Aib2-Ala3-Leu4-Aib5-Ala6-Phe7-Aib8-OMe (310-helix-OMe)was chosen which is known to adopt 310-helix in crystal structure. Analyses of the ROESY spectra, DMSO titration experiments, and CD spectra of 310-helix-OMe and its Oxa analogue reveal that their solution conformations are identical to those of the crystal structure of 310-helix-OMeSix sequential i+3→i intramolecular backbone H-bonds stabilize the 310-helical peptide fold in both peptides in solvents of varying polarity. The N-terminal and central segments of the helical molecules are quite structurally rigid and are not deformed. The presence of the disallowed Aib*8 residue in Oxa analogue has a clear conformational effect mainly on the residue Phe7. It looks like the Phe7 amide H is involved in shielding, the Aib*8 amide H through a bifurcated hydrogen bonding interactions with the nitrogen of oxazine and carbonyl oxygen of Ala6 residue. Maximum structural distortion effect on the registers closest to the putative imidate bond. Our results show that “disallowed folds need not denature order in the peptide fold”. Chapter 4: Synthetic Methods for Introducing the A → I Modification anywhere along the Peptide Chain Here we describe the incorporation of imidate isostere in the middle of any peptide sequence. In Oxa selectivity is towards 5-exo-cyclo-O-alkylation in 1 : 4. In Thi it is towards 6-exo-cyclo-S-alkylation in 3 : 1 ratio. This is because of better nucleophile of sulphur (S). We saw that Thi is stable to peptide coupling, N-and C-terminus protection, deprotection conditions and can be easily incorporated in middle of peptide. Chapter 5: Section A: Cis-trans Isomerism in the X-Pro Peptide Bond In tertiary amides like X-Pro peptides having high propensity to access cis conformations due to similar environment in both cis and trans around the Cof X. X-Pro peptide bonds, constrained in s-cis conformations are prevalently found in the turn regions of peptides with the residue „X‟ in the i+1position and Pro at the i+2position of the β¬turn. These types of turns are termed as the type VI β-turns. For better understanding of the molecular recognition at specific cis X-Pro peptide bonds in biological events, the structure and dynamics of various constrained cis X-Pro peptide bond analogues with varying steric and electronic perturbations have been studied. Many models have been developed for stabilizing cis conformer by perturbation of molecular recognition surface of proline by employing steric and electronic interaction. In biological functions proline molecular recognition surface and cis X-Pro peptide bond more important. There is need of novel method for stabilizing X-Pro peptide bond in cis conformer without modifying the pyrolidine ring in proline. Chapter 5: Section B: Biasing the cis/trans Equilibrium in X Pro Peptides using Reverse ni → ni-1 * Interactions Here we present our findings that peptidomimetics containing the 5,6-dihydro-4H-1,3¬oxazine (Oxa) and 5,6-dihydro-4H-1,3-thiazine (Thi) functional groups at the C-terminus of Pro selectively and remotely stabilize the s-cis rotamers of the preceding pyrrolyl (Xaa-Pro) 3° amide bonds, while conserving these recognition elements. The cis/trans equilibrium of Xaa-Pro peptide bonds is shifted significantly in favor of the satirically disfavored cis isomers in these peptidomimetics (upto ~90%). We also provide evidence for the influence of an unusual n→ πi-1 * interaction in the cis, and the n)(n repulsion in the trans, conformers of these molecules to beat the origin of such the origin of such cis stabilization. Chapter 6: Steric Interactions in the cis Piv-Pro Peptide Bond The inaccessibility of cis Piv-Pro rotamer in any peptide is believed to be because the steric clashes between substituents on CX and CPro are unavoidable in this conformer. Here we access the cisPiv-Pro conformer in crystal structure of Piv-Pro-Aib-OMe and that it is sufficiently flexible to undergo bond distortions and avoid all steric clashes between substituents on CPiv and CPro . It is however the unavoidable distortions in the dihedral angle of the Prothe cisPiv-Proconformer. The cisPiv -Pro conformer is indeed accessible, if such distortions are accommodated in the peptide. Chapter 7: Steric and Electronic Interactions in the cis Isomer of Piv-Pro Peptide Bond in Solution We have studied the electronic and steric interactions and the conformational equilibrium in two sets of homologous peptides, X-Pro-Aib-OMe (which contain Aib) and X-Pro-NH-Me, where X is acetyl, propionyl, isobutyryl and pivaloyl, in solvents of varying polarities consisting of carbontetrachloride, chloroform or dimethylsulfoxide, by means of their 1H and 13C-NMR, and FT-IR spectra. Formation of n * interactions between the carbonyls that flank the Aib residue, influences the alleviation of steric interactions that are believed to preclude access to the cis conformer of the Piv-Pro peptide bond. The cis Piv-Pro conformer is observable in the Aib containing peptides, at ambient conditions by FT-IR and at temperatures as low as 273 K by NMR. We estimate that the steric interactions contribute < 0.5 kcal/mol to the conformational free energy of X-Pro peptide bond isomerism, irrespective of the steric bulk on the acyl (X) group. The relative strengths of intramolecular hydrogen bonding interactions involving the X-Pro peptide motif in different conformers of these peptides influence their relative conformational stabilities. Chapter 8: Remote Effect of Oxa and Thi Functional Groups on cis-trans Isomerism at X-Pro Peptide Bonds The C5a interaction at Pro residue occurs in the transition states for the intramolecular acid catalysis of cis → trans isomerization in peptidyl prolyl isomerases (PPIs) and enables the decrease in transition energy barrier for the isomerization process. We show that the NPro….HAib interactions in C5a structures can be remotely effected in order to control in equilibrium constant values of the cis/trans isomerism (Kc/t) in X-Pro¬Aib-Oxa and Thi containing peptides. By this method we observed improvement in Kc/t values from 0.18 in esters to 0.56 in Thi and 0.66 in Oxa containing peptides. Analyses of the ROESY spectra, DMSO titration experiments, variable temperature experiments and FT-IR spectra of R-CO-Pro-Aib-Oxa (R = Me, Et, iPr) and its Thi analogues reveals that both interactions (C5a and C5i) are persistent in cis and trans conformers of this peptidomimetics. (for structural formula pl. see the abstract.)

Peptides

Peptide Bonds

Imidate Isosteres

Thioimidate Isoteres

Peptides - Disallowed Conformations

Amide-Imidate Modification

Amides - Autocyclization

Peptide Bonds - Isomerism

Peptidomimetics

beta-Turn Peptides

Cis-trans Isomerism

cis Piv-Pro Peptide Bond

Piv-Pro Peptide Bond

Biochemistry

Die parallele beta-Helix der Pektat-Lyase aus Bacillus subtilis : Stabilität, Faltungsmechanismus und Faltungsmutanten

Walter, Monika

January 2002

Die Pektat-Lyasen gehören zu einer Proteinfamilie, die meistens von pflanzenpathogenen Mikroorganismen sekretiert werden. Die Enzyme katalysieren den Abbau von Polygalakturonsäure, einem Hauptbestandteil in <br /> pflanzlichen Mittellamellen und Primärzellwänden. Der Abbau der alpha-1,4-verbrückten Galakturonsäurereste erfogt durch eine beta-Eliminierungsreaktion, dabei entsteht ein Produkt mit einer ungesättigten C4-C5 Bindung am nicht reduzierenden Ende, das durch spektroskopische Messungen beobachtet werden kann. Für die enzymatische Reaktion der Pektat-Lyasen ist Calcium nötig und das pH-Optimum der Reaktion liegt bei pH 8.5. Alle bis jetzt bekannten Strukturen der Pektat- und Pektin-Lyasen haben das gleiche Strukturmotiv - eine rechtsgängige parallele beta-Helix. Die Struktur der Pektat-Lyase aus Bacillus subtilis (BsPel) ist im Komplex mit Calcium gelöst worden. BsPel ist ein monomeres Protein mit einer ungefähren Molekularmasse von 43 kDa, das keine Disulfidbrücken enthält. Dies erlaubte sowohl eine effiziente rekombinante Expression des Wildtypproteins, als auch von destabilisierten Mutanten im Cytoplasma von E. coli. Parallele beta-Helices sind relativ große, jedoch verhältnismäßig einfach aufgebaute Proteine. Um detailliertere Informationen über die kritischen Schritte bei der in vitro-Faltung von parallelen beta-Helices zu erhalten, sollte in der vorliegenden Arbeit versucht werden, den Faltungsmechanismus dieses Proteins näher zu charakterisieren. Dabei sollte vor allem die Frage geklärt werden, welche Wechselwirkungen für die Stabilität dieses Proteins einerseits und für die Stabilität von essentiellen Faltungsintermediaten andererseits besonders wichtig sind.<BR><br>Rückfaltung von BsPel, ausgehend vom guanidiniumchlorid-denaturierten Zustand, war bei kleinen Proteinkonzentrationen und niedrigen Temperaturen vollständig möglich. GdmCl-induzierte Faltungsübergänge waren aber nicht reversibel und zeigten eine apparente Hysterese. Kinetische Messungen des Fluoreszenz- und CD-Signals im fernen UV ergaben eine extreme Denaturierungsmittelabhängigkeit der Rückfaltungsrate im Bereich des Übergangmittelpunktes. Der extreme Abfall der Rückfaltungsraten mit steigender Denaturierungsmittelkonzentration kann als kooperative <br /> Entfaltung eines essentiellen Faltungsintermediats verstanden werden. Dieses Faltungsintermediat ist temperaturlabil und kann durch den Zusatz Glycerin im Renaturierungspuffer stabilisiert werden, wobei sich die Hysterese verringert, jedoch nicht vollständig aufgehoben wird. Durch reverse Doppelsprungexperimente konnten zwei transiente Faltungsintermediate nachgewiesen werden, die auf zwei parallelen Faltungswegen liegen und beide zum nativen Zustand weiterreagieren können. Fluoreszenzemissionsspektren der beiden Intermediate zeigten, daß beide schon nativähnliche Struktur aufweisen. Kinetische Daten von Prolin-Doppelsprungexperimenten zeigten, daß Prolinisomerisierung den geschwindigkeitsbestimmenden Schritt in der Reaktivierung des denaturierten Enzyms darstellt. Desweiteren konnte durch Prolin-Doppelsprungexperimenten an Mutanten mit Substitutionen im Prolinrest 281 gezeigt werden, daß die langsame Renaturierung von BsPel nicht durch die Isomerisierung der einzigen cis-Peptidbindung an Prolin 281 verursacht wird, sondern durch die Isomerisierung mehrerer trans-Proline. Die beiden beobachteten transienten Faltungsintermediate sind somit wahrscheinlich zwei Populationen von Faltungsintermediaten mit nicht-nativen X-Pro-Peptidbindungen, wobei sich die Populationen durch mindestens eine nicht-native X-Pro-Peptidbindung unterscheiden.<BR><br>Der Austausch des Prolinrestes 281 gegen verschiedene Aminosäuren (Ala, Ile, Leu, Phe, Gly) führte zu einer starken Destabilisierung des nativen Proteins und daneben auch zu einer Reduktion in der Aktivität, da die Mutationsstelle in der Nähe der putativen Substratbindetasche liegt. Die Rückfaltungskinetiken der Prolinmutanten war bei 10&#176;C annähernd gleich zum Wildtyp und die geschwindigkeitsbestimmenden Schritte der Faltung waren durch die Mutation nicht verändert. Die durch die Mutation verursachte drastische Destabilisierung des nativen Zustands führte zu einem reversiblen Entfaltungsgleichgewicht bei pH 7 und 10&#176;C. GdmCl-induzierte Faltungsübergänge der Mutante P281A zeigten bei Messungen der Tryptophanfluoreszenzemission und der Aktivität einen kooperativen Phasenübergang mit einem Übergangsmittelpunkt bei 1.1 M GdmCl. Durch die Übereinstimmung der Faltungsübergänge bei beiden Messparametern konnten die Faltungsübergänge nach dem Zwei-Zustandsmodell ausgewertet werden. Dabei wurde eine freie Sabilisierungsenthalpie der Faltung für die Mutante von <nobr>-&nbsp;64.2&nbsp;&#177;&nbsp;0.4&nbsp;kJ/mol</nobr> und eine Kooperativität des Übergangs <br /> von <nobr>-&nbsp;58.2&nbsp;&#177;&nbsp;0.3&nbsp;kJ/(mol&#183;M)</nobr> bestimmt.<BR> <br /> <br>BsPel enthält, wie die meisten monomeren rechtsgängigen parallelen beta-Helix-Proteine, einen internen Stapel wasserstoffverbrückter Asparagin-Seitenketten. Die Mehrheit der erzeugten Mutanten mit Substitutionen im Zentrum der Asn-Leiter (N271X) waren als enzymatisch aktives Protein zugänglich. Die Auswirkung der Mutation auf die Stabilität und Rückfaltung wurde an den Proteinen BsPel-N271T und BsPel-N271A näher analysiert. Dabei führte die Unterbrechung des Asparaginstapels im Inneren der beta-Helix zu keiner drastischen Destabilisierung des nativen Proteins. Allerdings führten diese Mutationen zu einem temperatur-sensitiven Faltungsphänotyp und die Hysterese im Denaturierungsübergang wurde verstärkt. Offenbar wird durch die Unterbrechung des Asparaginstapel ein essentielles, thermolabiles Faltungsintermediat destabilisiert. Der Asparaginstapel wird somit bei der Faltung sehr früh ausgebildet und ist wahrscheinlich schon im Übergangszustand vorhanden. / Pectate lyases belong to a family of proteins secreted by plant pathogenic microbes. The enzymes cleave alpha-1,4 linked galacturonic acid by a beta-elimination that results in an unsaturated product, which can be quantified spectrophotometrically. Calcium is essential for the activity and the pH-optimum is near 8.5. All known structures of pectate and pectin lyases have the same structural motif - a right handed parallel beta-helix. The structure of pectate lyase from Bacillus subtilis (BsPel) has been solved in complex with calcium. It is a monomeric protein, with a molecular mass of about 43 kDa and without disulfide bonds. This allows its high-yield recombinant expression in the cytoplasm of Escherichia coli. Parallel beta-helices are relative large proteins, however with a simple folding topology. The objective of this work was to characterize the folding mechanism of BsPel. In particular we investigated the role of the interactions of certain residues in the parallel beta-helix for the stability of the native protein and the stability of essential folding intermediates.<br /> <br /> Refolding of BsPel was possible at low protein concentrations and low temperature. However, denaturation of BsPel was not freely reversible. De- and renaturation curves showed a large apparent hysteresis. Furthermore, the folding rate constant deduced from fluorescence and circulardichroism measurements showed a very strong dependence on denaturant concentrations near the midpoint of the renaturation transition. This can be explained with a cooperative unfolding of an essential folding intermediate. Upon stabilisation of the temperature-sensitive intermediate by addition of glycerol in the renaturation buffer, the hysteresis is reduced, but does not disappear. Reverse double mixing kinetic experiments have shown that two transient folding intermediates are on the folding pathway. These intermediates are on parallel pathways and both can fold to the native state. Fluorescence emission spectra have shown the native-like structure of both intermediates. Furthermore, data from proline double mixing kinetic experiments revealed that isomerization of peptidyl-prolyl bonds was responsible for the slow kinetics in the reactivation of the enzyme. However, the isomerization of the single cis-peptidyl-prolyl bond at Pro281 was not responsible for the slowest folding phase observed, but rather the isomerization of other trans-peptidyl-prolyl bonds. Thus, both transient folding intermediates observed probably represent two populations of folding intermediates with non-native X-Pro-peptide bonds. The difference of the two populations is at least one non-native X-Pro-peptide bond.<br /> <br /> Mutations of the proline 281 against various residues (Ala, Ile, Leu, Phe, Gly) resulted in a strong destabilization of the native protein. Also, the activity of the mutant proteins was strong reduced due to the position of the mutation site near the putative active center of the protein. At 10&#176;C the kinetic folding behavior of the proline mutants was not significant changed. However, the strong destabilization of the native state in the proline mutants resulted in a reversible folding equilibrium at pH 7 and 10&#176;C. The unfolding of the P281A mutant was reversible as determined by fluorescence emission and enzyme activity measurements. The coincidence of these detected transitions is consistent with a two-state equilibrium transition. At pH 7 and 10&#176;C the delta G&#176;(H₂O) for folding of P281A was <nobr>-&nbsp;64.2&nbsp;&#177;&nbsp;0.4&nbsp;kJ/mol,</nobr> with a midpoint of the transition at 1.1 M GdmCl and a cooperativity of <nobr>-&nbsp;58.2&nbsp;&#177;&nbsp;0.3&nbsp;kJ/(mol&#183;M).</nobr><br /> <br /> BsPel has an asparagine ladder in turn 2 of the parallel beta-helix with extensive network of side-chain hydrogen bonds between the Asn residues. Such an Asn-ladder is a conserved feature of many monomeric beta-helices crystallized so far. The middle Asn residue (271) was selected and exchanged for various residues. Most of the mutants were expressed at 25&#176;C as soluble and active proteins but with a significant reduction in yield. Mutants N271T and N271A were selected to study the stability and refolding of these proteins in comparison with the wild-type protein. The substitution in the Asn-ladder did not drastically destabilize the native protein, but caused a temperature-sensitive-folding (tsf) phenotype with an increased hysteresis in the de- and renaturation transition curves. In addition, the disruption of the Asn-ladder resulted in destabilization of an essential, thermosensitive folding intermediate. Thus, the Asn-ladder is formed very early during the folding, probably well before the transition state of folding.

Life sciences

Residual density validation and the structure of Labyrinthopeptin A2 / Residualdichtevalidierung und die Struktur von Labyrinthopeptin A2

Meindl, Katharina Anna Christina

30 October 2008

No description available.

540 Chemie

Mathematics and Computer Science

residual density analysis

jnk2RDA

fractal dimension

gross residual electrons

labyrinthopeptin A2

lantibiotic

<i>cis</i> peptide bonds

Residualdichteanalyse

jnk2RDA

fraktale Dimension

Bruttoresidualelektronen

Labyrinthopeptin A2

Lantibiotikum

<i>cis</i>-Peptidbindungen

35.06

35.11

35.25

35.62

35.76

SXL 300: Peptide

Polypeptide

Peptone {Biochemie}

SP 000: Strukturchemie