Derek Macmillan

Analysis and separation of residues important for the chemoattractant and antimicrobial activities of beta-defensin 3.

β-Defensins are important in mammalian immunity displaying both antimicrobial and chemoattractant activities. Three canonical disulfide intramolecular bonds are believed to be dispensable for antimicrobial activity but essential for chemoattractant ability. However, here we show that HBD3 (human β-defensin 3) alkylated with iodoactemide and devoid of any disulfide bonds is still a potent chemoattractant. Furthermore, when the canonical six cysteine residues are replaced with alanine, the peptide is no longer active as a chemoattractant. These findings are replicated by the murine ortholog Defb14. We restore the chemoattractant activity of Defb14 and HBD3 by introduction of a single cysteine in the fifth position (CysV) of the β-defensin six cysteine motif. In contrast, a peptide with a single cysteine at the first position (CysI) is inactive. Moreover, a range of overlapping linear fragments of Defb14 do not act as chemoattractants, suggesting that the chemotactic activity of this peptide is not dependent solely on an epitope surrounding CysV. Full-length peptides either with alkylated cysteine residues or with cysteine residues replaced with alanine are still strongly antimicrobial. Defb14 peptide fragments were also tested for antimicrobial activity, and peptides derived from the N-terminal region display potent antimicrobial activity. Thus, the chemoattractant and antimicrobial activities of β-defensins can be separated, and both of these functions are independent of intramolecular disulfide bonds. These findings are important for further understanding of the mechanism of action of defensins and for therapeutic design.

Development of an ion mobility quadrupole time of flight mass spectrometer.

We describe here a new ion mobility capable mass spectrometer which comprises a drift cell for mobility separation and a quadrapole time of flight mass spectrometer for mass analysis--the MoQTOF. A commercial QToF instrument (Micromass UK Ltd., Manchester, UK) has been modified by the inclusion of an additional chamber containing a drift cell and ancillary ion optics. The drift cell is 5.1 cm long made from a copper block and is mounted from a top hat flange in a chamber situated post source optics and prior to the quadapole analyzer. Details of this instrument are provided along with information about how it can be used to acquire mobilities of ions along with their mass to charge ratios. The MoQTOF is used to examine conformations of a series of antimicrobial peptides based on a beta-defensin template. In vivo, these cationic cystine-rich amphiphilic peptides are conformationally restrained by three or more disulfide bridges, although recent findings by several groups have cast doubt on the importance of canonical disulfide pairing to antimicrobial activities. By synthesizing a panel of variants to Defb14 (the murine orthologue of HBD3), we exploit ion mobility to distinguish conformational differences which arise due to disulfide formation and to the hydrophobicity of the peptide sequence. Our gas-phase results are interpreted in terms of the antimicrobial and chemotacic properties of beta-defensins, and this mass spectrometry based approach to discern structure may have a role in future design of novel antibiotics.

The Human Cathelicidin LL-37 Has Antiviral Activity against Respiratory Syncytial Virus

Respiratory syncytial virus is a leading cause of lower respiratory tract illness among infants, the elderly and immunocompromised individuals. Currently, there is no effective vaccine or disease modifying treatment available and novel interventions are urgently required. Cathelicidins are cationic host defence peptides expressed in the inflamed lung, with key roles in innate host defence against infection. We demonstrate that the human cathelicidin LL-37 has effective antiviral activity against RSV in vitro, retained by a truncated central peptide fragment. LL-37 prevented virus-induced cell death in epithelial cultures, significantly inhibited the production of new infectious particles and diminished the spread of infection, with antiviral effects directed both against the viral particles and the epithelial cells. LL-37 may represent an important targetable component of innate host defence against RSV infection. Prophylactic modulation of LL-37 expression and/or use of synthetic analogues post-infection may represent future novel strategies against RSV infection.

Peptide thioester synthesis through N-->S acyl-transfer: application to the synthesis of a beta-defensin.

Peptide thioesters readily prepared through N-->S acyl transfer of a specific C-terminal motif provide access to biologically active mini-proteins using native chemical ligation.

Small-Molecule Inhibition of c-MYC:MAX Leucine Zipper Formation Is Revealed by Ion Mobility Mass Spectrometry

The leucine zipper interaction between MAX and c-MYC has been studied using mass spectrometry and drift time ion mobility mass spectrometry (DT IM-MS) in addition to circular dichroism spectroscopy. Peptides comprising the leucine zipper sequence with (c-MYC-Zip residues 402-434) and without a postulated small-molecule binding region (c-MYC-ZipΔDT residues 406-434) have been synthesized, along with the corresponding MAX leucine zipper (MAX-Zip residues 74-102). c-MYC-Zip:MAX-Zip complexes are observed both in the absence and in the presence of the reported small-molecule inhibitor 10058-F4 for both forms of c-MYC-Zip. DT IM-MS, in combination with molecular dynamics (MD), shows that the c-MYC-Zip:MAX-Zip complex [M+5H](5+) exists in two conformations, one extended with a collision cross section (CCS) of 1164 ± 9.3 Å(2) and one compact with a CCS of 982 ± 6.6 Å(2); similar values are observed for the two forms of c-MYC-ZipΔDT:MAX-Zip. Candidate geometries for the complexes have been evaluated with MD simulations. The helical leucine zipper structure previously determined from NMR measurements (Lavigne, P.; et al. J. Mol. Biol. 1998, 281, 165), altered to include the DT region and subjected to a gas-phase minimization, yields a CCS of 1247 Å(2), which agrees with the extended conformation we observe experimentally. More extensive MD simulations provide compact complexes which are found to be highly disordered, with CCSs that correspond to the compact form from experiment. In the presence of the ligand, the leucine zipper conformation is completely inhibited and only the more disordered species is observed, providing a novel method to study the effect of interactions of disordered systems and subsequent inhibition of the formation of an ordered helical complex.

Shifting Native Chemical Ligation into Reverse through N→S Acyl Transfer.

Peptide thioester synthesis by N→S acyl transfer is being intensively explored by many research groups the world over. Reasons for this likely include the often straightforward method of precursor assembly using Fmoc-based chemistry and the fundamentally interesting acyl migration process. In this review we introduce recent advances in this exciting area and discuss, in more detail, our own efforts towards the synthesis of peptide thioesters through N→S acyl transfer in native peptide sequences. We have found that several peptide thioesters can be readily prepared and, what’s more, there appears to be ample opportunity for further development and discovery.

Chk2 Oligomerization Studied by Phosphopeptide Ligation IMPLICATIONS FOR REGULATION AND PHOSPHODEPENDENT INTERACTIONS

Chk2/CHEK2/hCds1 is a modular serine-threonine kinase involved in transducing DNA damage signals. Phosphorylation by ataxia telangiectasia-mutated kinase (ATM) promotes Chk2 self-association, autophosphorylation, and activation. Here we use expressed protein ligation to generate a Chk2 N-terminal regulatory region encompassing a fork-head-associated (FHA) domain, a stoichiometrically phosphorylated Thr-68 motif and intervening linker. Hydrodynamic analysis reveals that Thr-68 phosphorylation stabilizes weak FHA-FHA interactions that occur in the unphosphorylated species to form a high affinity dimer. Although clearly a prerequisite for Chk2 activation in vivo, we show that dimerization modulates potential phosphodependent interactions with effector proteins and substrates through either the pThr-68 site, or the canonical FHA phosphobinding surface with which it is tightly associated. We further show that the dimer-occluded pThr-68 motif is released by intra-dimer autophosphorylation of the FHA domain at the highly conserved Ser-140 position, a major pThr contact in all FHA-phosphopeptide complex structures, revealing a mechanism of Chk2 dimer dissociation following kinase domain activation.

Cysteine Promoted C‐Terminal Hydrazinolysis of Native Peptides and Proteins

Tagging the terminus: N→S acyl transfer in native peptides and proteins can be reliably intercepted with hydrazine. The method allows selective labeling and ligation, without recourse to the use of protein-splicing elements. NCL=native chemical ligation.

Synthesis of cyclic peptides through an intramolecular amide bond rearrangement

The amide linkage is generally considered to make amides the most stable carboxylic acid derivatives, and this is one feature that contributes to their attractiveness as building blocks in essential biological components such as proteins. However, we recently reported a sequencespecific N!S acyl shift in peptides and proteins where cysteine residues facilitate cleavage of the protein backbone, particularly when positioned adjacent to cysteine, glycine or histidine. When N!S acyl transfer proceeds in the presence of a thiol such as sodium 2-mercaptoethanesulfonate (MESNa), Cterminal thioester formation ensues (Scheme 1 A). The thioester products are key components for native chemical ligation (NCL), which is a powerful method for producing modified peptides and proteins. A feature of this thioesterforming reaction is that it is essentially unidirectional, presumably due to the high concentration of MESNa present and low pH. When two peptides (each containing a thioesterification site) are mixed, the cleaved species tend not recombine under normal reaction conditions. However, we investigated whether a transiently produced thioester from a seemingly unactivated peptide precursor could be intercepted by an N-terminal cysteine to form a new amide bond and result in a cyclic product through intramolecular NCL (Scheme 1 B). We were not aware of any analogous process in which retro-NCL and NCL occur simultaneously yet act in concert to provide access to cyclic peptides without the aid of an intein; however, we rationalized that a cyclic peptide bearing an internal Gly-Cys sequence could accumulate at the expense of a linear precursor with a terminal Gly-Cys-carboxyl motif. The products are of considerable interest because peptide cyclization is known to increase the therapeutic potential of many peptides by increasing their thermal and proteolytic stability as well as oral bioavailability. If successful, this route would provide an extremely straightforward way to cyclic peptides, as installation of an Nand C-terminal cysteine is all that would be required in order to initiate cyclization. We initially focussed our study on a synthetic peptide derived from the b-defensin family of cationic antimicrobial peptides, as we had previously identified defensin fragments that retained significant antimicrobial activity and considered that shorter analogues of the parent peptide might serve as useful scaffolds for the development of new antibacterial agents. Antimicrobial analysis of Defb14, the mouse orthologue of human b-defensin-3 (hBD-3), revealed potent antimicrobial activity in the N-terminal half of the peptide and within a short sequence comprising residues 6–17 (sequence: Ac-LRKFFARIRGGR-NH2 ; 1; minimal bactericidal concentration (MBC) = 0.9 mm), particularly against Gram-negative strains. An homoloScheme 1. A) N!S acyl shift provides access to thioesters. B) Thioesters formed in this way could be amenable to intramolecular NCL.

Optimisation of chemical protein cleavage for erythropoietin semi-synthesis using native chemical ligation

Selective protein cleavage at methionine residues is a useful method for the production of bacterially derived protein fragments containing an N-terminal cysteine residue required for native chemical ligation. Here we describe an optimised procedure for cyanogen bromide-mediated protein cleavage, and ligation of the resulting fragments to afford biologically active proteins.