Enhanced proteolytic resistance of cationic antimicrobial peptides through lysine side chain analogs and cyclization.

While cationic antimicrobial peptides (CAPs) are compelling candidates for antimicrobial therapy, their clinical development is largely hampered by their rapid and non-specific enzymatic degradation in physiological fluids. We have earlier de novo designed and synthesized a novel category of CAPs typified by the sequence KKKKKK-AAFAAWAAFAA-NH2 (termed "6K-F17") that have remarkable membrane-penetrating power, are highly selective for bacterial rather than host membranes, and are non-cytotoxic. Here we pursue the design and validation of the Lys chain-shortened 6K-F17 analogs 6Dap-F17 (Dap = diaminopropionic acid), 6Dab-F17 (Dab = diaminobutyric acid), and 6Orn-F17 (Orn = ornithine). Intriguingly, although initially designed to specifically resist trypsin vs. their original Lys sites, all three derivatives of 6K-F17 showed markedly improved stability not only against trypsin, but also against the major proteolytic enzymes elastase and proteinase K at a 1:100 enzyme-to-peptide (E:P) ratio. When the least stable analog, 6Dap-F17, was then cyclized ('stapled') - with reduced main chain hydrophobicity to avoid erythrocyte hemolysis - the peptide became robust towards all three enzymes up to 60 min at a 1:100 E:P ratio, and retained strong presence even at an enhanced 1:1 E:P ratio, as determined by HPLC and mass spectrometry. These results suggest that the application of Lys chain-shortening, either alone or in combination with macrocyclization, may enhance metabolic stability of CAPs, and thus their clinical potential.

Structural effects of extracellular loop mutations in CFTR helical hairpins.

Missense mutations constitute 40% of 2000 cystic fibrosis-phenotypic mutations in the cystic fibrosis transmembrane conductance regulator (CFTR) database, yet the precise mechanism as to how a point mutation can render the entire 1480-residue CFTR protein dysfunctional is not well-understood. Here we investigate the structural effects of two CF-phenotypic mutations - glutamic acid to glycine at position 217 (E217G) and glutamine to arginine at position 220 (Q220R) - in the extracellular (ECL2) loop region of human CFTR using helical hairpin constructs derived from transmembrane (TM) helices 3 and 4 of the first membrane domain. We systematically replaced the wild type (WT) residues E217 and Q220 with the subset of missense mutations that could arise through a single nucleotide change in their respective codons. Circular dichroism spectra of E217G revealed that a significant increase in helicity vs. WT arises in the membrane-mimetic environment of sodium dodecylsulfate (SDS) micelles, while this mutant showed a similar gel shift to WT on SDS-PAGE gels. In contrast, the CF-mutant Q220R showed similar helicity but an increased gel shift vs. WT. These structural variations are compared with the maturation levels of the corresponding mutant full-length CFTRs, which we found are reduced to approx. 50% for E217G and 30% for Q220R vs. WT. The overall results with CFTR hairpins illustrate the range of impacts that single mutations can evoke in intramolecular protein-protein and/or protein-lipid interactions - and the levels to which corresponding mutations in full-length CFTR may be flagged by quality control mechanisms during biosynthesis.

A Modified Alderman-Grant Coil makes possible an efficient cross-coil probe for high field solid-state NMR of lossy biological samples.

The design, construction, and performance of a cross-coil double-resonance probe for solid-state NMR experiments on lossy biological samples at high magnetic fields are described. The outer coil is a Modified Alderman-Grant Coil (MAGC) tuned to the (1)H frequency. The inner coil consists of a multi-turn solenoid coil that produces a B(1) field orthogonal to that of the outer coil. This results in a compact nested cross-coil pair with the inner solenoid coil tuned to the low frequency detection channel. This design has several advantages over multiple-tuned solenoid coil probes, since RF heating from the (1)H channel is substantially reduced, it can be tuned for samples with a wide range of dielectric constants, and the simplified circuit design and high inductance inner coil provides excellent sensitivity. The utility of this probe is demonstrated on two electrically lossy samples of membrane proteins in phospholipid bilayers (bicelles) that are particularly difficult for conventional NMR probes. The 72-residue polypeptide embedding the transmembrane helices 3 and 4 of the Cystic Fibrosis Transmembrane Conductance Regulator (CFTR) (residues 194-241) requires a high salt concentration in order to be successfully reconstituted in phospholipid bicelles. A second application is to paramagnetic relaxation enhancement applied to the membrane-bound form of Pf1 coat protein in phospholipid bicelles where the resistance to sample heating enables high duty cycle solid-state NMR experiments to be performed.

Detergent binding explains anomalous SDS-PAGE migration of membrane proteins.

Migration on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) that does not correlate with formula molecular weights, termed "gel shifting," appears to be common for membrane proteins but has yet to be conclusively explained. In the present work, we investigate the anomalous gel mobility of helical membrane proteins using a library of wild-type and mutant helix-loop-helix ("hairpin") sequences derived from transmembrane segments 3 and 4 of the human cystic fibrosis transmembrane conductance regulator (CFTR), including disease-phenotypic residue substitutions. We find that these hairpins migrate at rates of -10% to +30% vs. their actual formula weights on SDS-PAGE and load detergent at ratios ranging from 3.4-10 g SDS/g protein. We additionally demonstrate that mutant gel shifts strongly correlate with changes in hairpin SDS loading capacity (R(2) = 0.8), and with hairpin helicity (R(2) = 0.9), indicating that gel shift behavior originates in altered detergent binding. In some cases, this differential solvation by SDS may result from replacing protein-detergent contacts with protein-protein contacts, implying that detergent binding and folding are intimately linked. The CF-phenotypic V232D mutant included in our library may thus disrupt CFTR function via altered protein-lipid interactions. The observed interdependence between hairpin migration, SDS aggregation number, and conformation additionally suggests that detergent binding may provide a rapid and economical screen for identifying membrane proteins with robust tertiary and/or quaternary structures.

Role of the extracellular loop in the folding of a CFTR transmembrane helical hairpin.

The folding of membrane-spanning domains into their native functional forms depends on interactions between transmembrane (TM) helices joined by covalent loops. However, the importance of these covalent linker regions in mediating the strength of helix-helix associations has not been systematically addressed. Here we examine the potential structural impact of cystic fibrosis-phenotypic mutations in the extracellular loop 2 (ECL2) on interactions between the TM3 and TM4 helices of the cystic fibrosis transmembrane conductance regulator (CFTR) in constructs containing CFTR residues 194-241. When the effects of replacements in ECL2 (including the CF-phenotypic mutants E217G and Q220R) were evaluated in a library of wild-type and mutant TM3-ECL2-TM4 hairpin constructs, we found that SDS-PAGE gel migration rates differed over a range of nearly 40% +/- the wild-type position and that decreased migration rates correlate with increasing hairpin alpha-helical content as measured by circular dichroism spectra in sodium dodecyl sulfate micelles. The decreased mobility of TM3/4 constructs by introduction of non-native residues is interpreted in terms of an elongation or "opening" of the helical hairpin and concomitant destabilization of membrane-based helix-helix interactions. Our results support a role for short loop regions in dictating the stability of membrane protein folds and highlight the interplay between membrane-embedded helix-helix interactions and loop conformation in influencing the structure of membrane proteins.

Expression and purification of two hydrophobic double-spanning membrane proteins derived from the cystic fibrosis transmembrane conductance regulator.

We describe a rapid method for the expression and purification of two hydrophobic protein constructs derived from the membrane domain of the cystic fibrosis transmembrane conductance regulator (CFTR), the protein associated with cystic fibrosis. The proteins have no sequence homology but are both predicted to contain two membrane-spanning segments. The protocol involves the expression of CFTR constructs as thioredoxin fusion proteins in Escherichia coli, followed by partial purification by affinity chromatography, removal of the thioredoxin moiety by proteolytic cleavage in the presence of detergent, and final purification by reversed-phase high-performance liquid chromatography. The method yields milligram amounts of purified constructs that spontaneously insert into detergent micelles in alpha-helical conformation. We predict that this protocol will be applicable to a variety of proteins of similar size and hydrophobicity.