Charles M. Deber

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 (R2 = 0.8), and with hairpin helicity (R2 = 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.

Basis for Selectivity of Cationic Antimicrobial Peptides for Bacterial Versus Mammalian Membranes

Novel cationic antimicrobial peptides typified by structures such as KKKKKKAAXAAWAAXAA-NH2, where X = Phe/Trp, and several of their analogues display high activity against a variety of bacteria but exhibit no hemolytic activity even at high dose levels in mammalian erythrocytes. To elucidate their mechanism of action and source of selectivity for bacterial membranes, phospholipid mixtures mimicking the compositions of natural bacterial membranes (containing anionic lipids) and mammalian membranes (containing zwitterionic lipids + cholesterol) were challenged with the peptides. We found that peptides readily inserted into bacterial lipid mixtures, although no insertion was detected in model “mammalian” membranes. The depth of peptide insertion into model bacterial membranes was estimated by Trp fluorescence quenching using doxyl groups variably positioned along the phospholipid acyl chains. Peptide antimicrobial activity generally increased with increasing depth of peptide insertion. The overall results, in conjunction with molecular modeling, support an initial electrostatic interaction step in which bacterial membranes attract and bind peptide dimers onto the bacterial surface, followed by the “sinking” of the hydrophobic core segment to a peptide sequence-dependent depth of ∼2.5–8 Å into the membrane, largely parallel to the membrane surface. Antimicrobial activity was likely enhanced by the fact that the peptide sequences contain AXXXA sequence motifs, which promote their dimerization, and possibly higher oligomerization, as assessed by SDS-polyacrylamide gel analysis and fluorescence resonance energy transfer experiments. The high selectivity of these peptides for nonmammalian membranes, combined with their activity toward a wide spectrum of Gram-negative and Gram-positive bacteria and yeast, while retaining water solubility, represent significant advantages of this class of peptides.

A measure of helical propensity for amino acids in membrane environments

The frequent occurrence of β-sheet promoting residues such as Ile, Val, and Thr in the α-helical transmembrane segments of most integral membrane proteins suggests that the helical propensities of these residues are altered in the hydrophobic environment of the lipid bilayer. Systematic studies of peptides by circular dichroism models spectroscopy in various micellar/vesicular media allow the establishment of a ranking order of helical propensity for uncharged amino acids in the membrane environment. In contrast to their conformational preferences in water, the helical proclivity of amino acids in membranes is shown to be governed by their side chain hydrophobicity, and by the hydropathy of the local peptide segments in which the residues reside.

The structure of “unstructured” regions in peptides and proteins: Role of the polyproline II helix in protein folding and recognition*

Classical descriptions of the three‐dimensional shapes of proteins usually invoke three main structures: α‐helix, β‐sheet, and β‐turn. More recently, the polyproline II (PPII) structure has been implicated in diverse biological activities including signal transduction, transcription, cell motility, and immune response. Concurrently, evidence is accumulating that PPII structure has a significant role in the unfolded states of proteins. In this article, we connect the structural properties of PPII helices to their roles in protein recognition and protein unfolded states. The properties unique to the PPII conformation are linked to the exploitation of this structure for the molecular recognition of proteins, using peptide ligands of the Src homology 3 (SH3) domain as an example. The evidence supporting a role for PPII conformation in protein‐unfolded states is also presented in the context of the forces that may stabilize the PPII conformation in unfolded polypeptides.

Cationic Hydrophobic Peptides with Antimicrobial Activity

ABSTRACT The MICs of cationic, hydrophobic peptides of the prototypic sequence KKAAAXAAAAAXAAWAAXAAAKKKK-amide (where X is one of the 20 commonly occurring amino acids) are in a low micromolar range for a panel of gram-negative and gram-positive bacteria, with no or low hemolytic activity against human and rabbit erythrocytes. The peptides are active only when the average segmental hydrophobicity of the 19-residue core is above an experimentally determined threshold value (where X is Phe, Trp, Leu, Ile, Met, Val, Cys, or Ala). Antimicrobial activity could be increased by using peptides that were truncated from the prototype length to 11 core residues, with X being Phe and with 6 Lys residues grouped at the N terminus. We propose a mechanism for the interaction between these peptides and bacterial membranes similar to the “carpet model,” wherein the Lys residues interact with the anionic phospholipid head groups in the bacterial membrane surface and the hydrophobic core portion of the peptide is then able to interact with the lipid bilayer, causing disruption of the bacterial membrane.

Roles of Hydrophobicity and Charge Distribution of Cationic Antimicrobial Peptides in Peptide-Membrane Interactions

Background: Cationic antimicrobial peptides offer an alternative to conventional antibiotics, as they physically disrupt bacterial membranes, causing cell death. Results: Peptides designed with high hydrophobicity display strong self-association that is minimized by distribution of positive charges at both peptide termini. Conclusion: Balancing peptide hydrophobicity and charge distribution promotes efficient antimicrobial activity. Significance: Routes to optimization of peptide sequences are valuable for devising therapeutic strategies. Cationic antimicrobial peptides (CAPs) occur as important innate immunity agents in many organisms, including humans, and offer a viable alternative to conventional antibiotics, as they physically disrupt the bacterial membranes, leading to membrane lysis and eventually cell death. In this work, we studied the biophysical and microbiological characteristics of designed CAPs varying in hydrophobicity levels and charge distributions by a variety of biophysical and biochemical approaches, including in-tandem atomic force microscopy, attenuated total reflection-FTIR, CD spectroscopy, and SDS-PAGE. Peptide structural properties were correlated with their membrane-disruptive abilities and antimicrobial activities. In bacterial lipid model membranes, a time-dependent increase in aggregated β-strand-type structure in CAPs with relatively high hydrophobicity (such as KKKKKKALFALWLAFLA-NH2) was essentially absent in CAPs with lower hydrophobicity (such as KKKKKKAAFAAWAAFAA-NH2). Redistribution of positive charges by placing three Lys residues at both termini while maintaining identical sequences minimized self-aggregation above the dimer level. Peptides containing four Leu residues were destructive to mammalian model membranes, whereas those with corresponding Ala residues were not. This finding was mirrored in hemolysis studies in human erythrocytes, where Ala-only peptides displayed virtually no hemolysis up to 320 μm, but the four-Leu peptides induced 40–80% hemolysis at the same concentration range. All peptides studied displayed strong antimicrobial activity against Pseudomonas aeruginosa (minimum inhibitory concentrations of 4–32 μm). The overall findings suggest optimum routes to balancing peptide hydrophobicity and charge distribution that allow efficient penetration and disruption of the bacterial membranes without damage to mammalian (host) membranes.

TM Finder: a prediction program for transmembrane protein segments using a combination of hydrophobicity and nonpolar phase helicity scales.

Based on the principle of dual prediction by segment hydrophobicity and nonpolar phase helicity, in concert with imposed threshold values of these two parameters, we developed the automated prediction program TM Finder that can successfully locate most transmembrane (TM) segments in proteins. The program uses the results of experiments on a series of host‐guest TM segment mimic peptides of prototypic sequence KK AAAXAAAAAXAAWAAXAAAKKKK‐amide (where X = each of the 20 commonly occurring amino acids) through which an HPLC‐derived hydropathy scale, a hydrophobicity threshold for spontaneous membrane insertion, and a nonpolar phase helical propensity scale were determined. Using these scales, the optimized prediction algorithm of TM Finder defines TM segments by first searching for competent core segments using the combination of hydrophobicity and helicity scales, and then performs a gap‐joining operation, which minimizes prediction bias caused by local hydrophilic residues and/or the choice of window size. In addition, the hydrophobicity threshold requirement enables TM Finder to distinguish reliably between membrane proteins and globular proteins, thereby adding an important dimension to the program. A full web version of the TM Finder program can be accessed at http://www.bioinformatics‐canada.org/TM/.

Interhelical hydrogen bonds in the CFTR membrane domain.

Critical mutations in the membrane-spanning domains of proteins cause many human diseases. We report the expression in Escherichia coli of helix-loop-helix segments of the cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel domain in milligram quantities. Analysis of gel migration patterns of these constructs, in conjunction with circular dichroism spectroscopy, demonstrate that a neutral-to-charged, CF-phenotypic point mutation of a hydrophobic residue (V232D) in the CFTR transmembrane (TM) helix 4 induces a hydrogen bond with neighboring wild type Gln 207 in TM helix 3. As an electrostatic crosslink within a hydrocarbon phase, such a hydrogen bond could alter the normal assembly and alignment of CFTR TM helices and/or impede their movement in response to substrate transport. Our results imply that membrane proteins may be vulnerable to loss of function through formation of membrane-buried interhelical hydrogen bonds by partnering of proximal polar side chains.

Central nervous system myelin: structure, function, and pathology

Multiple sclerosis (MS) and a number of related distinctive diseases are characterized by the active degradation of central nervous system (CNS) myelin, an axonal sheath comprised essentially of proteins and lipids. These demyelinating diseases appear to arise from complex interactions of genetic, immunological, infective, and biochemical mechanisms. While circumstances of MS etiology remain hypothetical, one persistent theme involves recognition by the immune system of myelin-specific antigens derived from myelin basic protein (MBP), the most abundant extrinsic myelin membrane protein, and/or another equally susceptible myelin protein or lipid component. Knowledge of the biochemical and physical—chemical properties of myelin proteins and lipids, particularly their composition, organization, structure, and accessibility with respect to the compacted myelin multilayers, thus becomes central to the understanding of how and why these antigens become selected during the development of MS. This review focuses on current understanding of the molecular basis underlying demyelinating disease as it may relate to the impact of the various protein and lipid components on myelin morphology; the precise molecular architecture of this membrane as dictated by protein—lipid and lipid—lipid interactions; and the relationship, if any, between the protein/lipid components and the destruction of myelin in pathological situations.

Sequence Context Strongly Modulates Association of Polar Residues in Transmembrane Helices

Polar residues are capable of mediating the association of membrane-embedded helices through the formation of side-chain/side-chain inter-helical hydrogen bonds. However, the extent to which native van der Waals packing of the residues surrounding the polar locus can enhance, or interfere with, the interaction of polar residues has not yet been studied. We examined the propensities of four polar residues (aspartic acid, asparagine, glutamic acid, and glutamine) to promote self-association of transmembrane (TM) domains in several biologically derived sequence environments, including (i). four naturally occurring TM domains that contain a Glu or Gln residue (Tnf5/CD40 ligand, C79a/Ig-alpha, C79b/Ig-beta, and Fut3/alpha-fucosyltransferase); and (ii). variants of bacteriophage M13 major coat protein TM segment with Asp and Asn at interfacial and non-interfacial positions. Self-association was quantified by the TOXCAT assay, which measures TM helix self-oligomerization in the Escherichia coli inner membrane. While an appropriately placed polar residue was found in several cases to significantly stabilize TM helix-helix interactions through the formation of an interhelical hydrogen bond, in other cases the strongly polar residues did not enhance the association of the two helices. Overall, these results suggest that an innate structural mechanism may operate to control non-specific association of membrane-embedded polar residues.