Chain length of cationic alpha-helical peptide sufficient for gene delivery into cells.

To define the minimal peptide length needed for gene delivery into mammalian cells, we synthesized several peptides with shortened chain lengths from the amino-termini of the original amphiphilic peptides (4(6), Ac-LARL-LARL-LARL-LRAL-LRAL-LRAL-NH( 2,) and Hel 11-7, KLLK-LLLK-LWKK-LLKL-LK), which have been known to have gene transfer abilities into cells. Each synthetic peptide was studied for its ability to bind and aggregate with plasmid DNA and the structural change of the peptide caused by binding with the DNA to establish a relative in vitro gene transfection efficiency in COS-7 cells. As a result, the deletion of eight amino acid residues of 4(6) had little influence on their ability, whereas that of 12 amino acid residues remarkably reduced the abilities to make aggregates and transfer the DNA into the cell. In the case of the Hel 11-7 series peptides, deletion of amino acid residues caused a considerable reduction in abilities to bind and form aggregates with DNA and to transfer the DNA into cell in due order. In summary, 16 and 17 amino acid residues were sufficient to form aggregates with the DNA and transfer the DNA into the cells in the deletion series of 4(6) and Hel 11-7, respectively. Furthermore, it was indicated that reduction of membrane perturbation activity of the peptide-DNA complex due to deletion of the peptide chain length caused suppression of the transfection efficiency even if the complex was incorporated into the cells. Transfer of the complex to cytosol mediated by membrane perturbation activity of the peptide is an important step for efficient protein expression from its cDNA. The results of this study will make it easy to design and synthesize a functional gene carrier molecule such as a carbohydrate-modified peptide used in targeted gene delivery.     

NMR solution structure and position of transportan in neutral phospholipid bicelles

Transportan is a chimeric cell-penetrating peptide constructed from the peptides galanin and mastoparan, which has the ability to internalize living cells carrying a hydrophilic load. In this study, we have determined the NMR solution structure and investigated the position of transportan in neutral bicelles. The structure revealed a well-defined alpha-helix in the C-terminal mastoparan part of the peptide and a weaker tendency to form an alpha-helix in the N-terminal domain. The position of the peptide in relation to the membrane, as studied by adding paramagnetic probes, shows that the peptide lies parallel to, and in the head-group region of the membrane surface. This result is supported by amide proton secondary chemical shifts.     

Optimization of hydrophobic domains in peptides that undergo transformation from alpha-helix to beta-fibril

Recent studies on peptide fibrillogenesis by the de novo method as well as amyloidogenic proteins including prion proteins and Alzheimer's beta-peptides have provided insights into the conformational changes, such as alpha-helix to beta-structure, involved in folding and misfolding processes. We have found that an exposed hydrophobic nucleation domain at N-terminal causes a structural transition of a peptide from alpha-helix to beta-fibril. It became clear that N-terminal acyl groups of particular lengths in a 2alpha-helix peptide caused the peptide to undergo an alpha-to-beta transition. The peptide with the octanoyl group (C8-2alpha) showed the highest rate of transformation. The study of the designed peptides revealed that these alpha-to-beta transitions were closely related to the initial alpha-helix conformation and its stability. Engineering peptides that undergo alpha-to-beta transitions are attractive not only to the study of pathogenic proteins such as prion proteins, but also to the control of self-assembly of peptides, which will lead to the development of peptidyl self-assembling materials.     

Correlation between fusogenicity of synthetic modified peptides corresponding to the NH2-terminal extremity of simian immunodeficiency virus gp32 and their mode of insertion into the lipid bilayer: an infrared spectroscopy study.

The amino-terminal extremity of the simian immunodeficiency virus (SIV) transmembrane protein (gp32) has been shown to play a pivotal role in cell-virus fusion and syncytium formation. We provide here evidence of a correlation between the structure and orientation of the modified SIV fusion peptide after insertion into the lipid membrane and its fusogenic activity. The sequence of the wild-type SIV peptide has been modified in such a way that the calculated angles of insertion correspond to an oblique, parallel, or normal orientation with respect to the lipid-water interface. Fourier transform infrared spectroscopy was used to gain experimental informations about the structures and orientations, of the membrane-inserted peptides with respect to the lipid acyl chains. The peptides adopt mainly a beta-sheet conformation in the absence of lipids. After interaction with large unilamellar liposomes, this beta sheet is partly converted into alpha helix. The ability of the modified peptides to promote lipid mixing was assessed by a fluorescence energy transfer assay. The data provide evidence that alpha-helix formation is not sufficient to induce lipid mixing and that the fusogenic activity of the peptide depends on its orientation in the lipid bilayer.     

Role of helix nucleation in the kinetics of binding of mastoparan X to phospholipid bilayers

Many antimicrobial peptides undergo a coil-to-helix transition upon binding to membranes. While this conformational transition is critical for function, little is known about the underlying mechanistic details. Here, we explore the membrane-mediated folding mechanism of an antimicrobial peptide, mastoparan X. Using stopped-flow fluorescence techniques in conjunction with a fluorescence resonance energy transfer (FRET) pair, p-cyanophenylalanine (donor) and tryptophan (acceptor), we were able to probe, albeit in an indirect manner, the membrane-mediated folding kinetics of this peptide. Our results show that the association of mastoparan X with model lipid vesicles proceeds with biphasic kinetics. The first step shows a large change in the FRET signal, indicating that the helix forms early in the time course of the interaction, while the second step where a further increase in tryptophan fluorescence is observed presumably reflects deeper insertion of the peptide into the bilayer. Additional kinetic studies on a double mutant of mastoparan X, designed to form a nucleation site for alpha-helix formation through coordination with a metal ion (e.g., Zn2+ or Ni2+), indicate that while the coil-to-helix transition occurs in the first step, it follows the rate-determining docking of the peptide onto the membrane surface. Taken together, these results indicate that the initial association of the peptide with the membrane occurs in a nonhelical conformation, which rapidly converts to a helical state within the anisotropic environment of the bilayer surface.     

Properties and structures of the influenza and HIV fusion peptides on lipid membranes: implications for a role in fusion

The fusion peptides of HIV and influenza virus are crucial for viral entry into a host cell. We report the membrane-perturbing and structural properties of fusion peptides from the HA fusion protein of influenza virus and the gp41 fusion protein of HIV. Our goals were to determine: 1), how fusion peptides alter structure within the bilayers of fusogenic and nonfusogenic lipid vesicles and 2), how fusion peptide structure is related to the ability to promote fusion. Fluorescent probes revealed that neither peptide had a significant effect on bilayer packing at the water-membrane interface, but both increased acyl chain order in both fusogenic and nonfusogenic vesicles. Both also reduced free volume within the bilayer as indicated by partitioning of a lipophilic fluorophore into membranes. These membrane ordering effects were smaller for the gp41 peptide than for the HA peptide at low peptide/lipid ratio, suggesting that the two peptides assume different structures on membranes. The influenza peptide was predominantly helical, and the gp41 peptide was predominantly antiparallel beta-sheet when membrane bound, however, the depths of penetration of Trps of both peptides into neutral membranes were similar and independent of membrane composition. We previously demonstrated: 1), the abilities of both peptides to promote fusion but not initial intermediate formation during PEG-mediated fusion and 2), the ability of hexadecane to compete with this effect of the fusion peptides. Taken together, our current and past results suggest a hypothesis for a common mechanism by which these two viral fusion peptides promote fusion.     

Required structure of cationic peptide for oligonucleotide-binding and -delivering into cells.

Improvement of the methods for oligonucleotide delivery into cells is necessary for the development of antisense therapy. In the present work, a new strategy for oligonucleotide delivery into cells was tested using cationic peptides as a vector. At first, to understand what structure of the peptide is required for binding with an oligonucleotide, several kinds of alpha-helical and non-alpha-helical peptides containing cationic amino acids were employed. As a result, the amphiphilic alpha-helix peptides were best for binding with the oligonucleotide, and the long chain length and large hydrophobic region in the amphiphilic structure of the peptide were necessary for the binding and forming of aggregates with the oligonucleotide. In the case of non-alpha-helical peptides, no significant binding ability was observed even if their chain lengths and number of cationic amino acid residues were equal to those of the alpha-helical peptides. The remarkable ability of oligonucleotide delivery into COS-7 cells was observed in the alpha-helical peptides with a long chain length and large hydrophobic region in the amphiphilic structure, but was not observed in the non-alpha-helical peptides. It is considered that such alpha-helical peptides could form optimum aggregates with the ODN for uptake into cells. Based on these results, the alpha-helical peptide with a long chain length and large hydrophobic region is applicable as a vector for the delivery of oligonucleotides into cells.     

Location and dynamics of tryptophan in transmembrane alpha-helix peptides: a fluorescence and circular dichroism study

Amphiphilic and hydrophobic peptides play a key role in many biological processes. We have developed a reference system for evaluating the insertion of such peptides bearing Trp fluorescent reporter groups into membrane mimetic systems. This system involves a set of six 25-amino acid synthetic peptides that are models of transmembrane alpha-helices. They are Lys-flanked polyLeu sequences, each containing a single Trp residue at a different position (P i, with i=3, 5, 7, 9, 11 and 13). These peptides were inserted into micelles of a non-ionic detergent, dodecylmaltoside (DM). We analyzed this system by use of circular dichroism and steady-state and time-resolved fluorescence in combination with Trp quenching with two brominated DM analogs. We found significant variations in the Trp emission maximum according to its position in each peptide (from 327 to 313 nm). This is consistent with the radial insertion of the peptides within DM micelles. We observed characteristic patterns of fluorescence quenching of these peptides in mixed micelles of DM, with either 7,8-dibromododecylmaltoside (BrDM) or 10,11-dibromoundecanoylmaltoside (BrUM), that reflect differences in the accessibility of the Trp residue to the bromine atoms located on the detergent acyl chain. In the isotropic reference solvent, methanol, the alpha-helix content was high and identical (approximately 76%) for all peptides. In DM micelles, the alpha-helix content for P9 to P13 was similar to that in methanol, but slightly lower for P3 to P7. The fluorescence intensity decays were heterogeneous and depended upon the position of the Trp. The Trp dynamics of each peptide are described by sub-nanosecond and nanosecond rotational motions that were significantly lower than those observed in methanol. These results, which precisely describe structural, dynamic and microenvironment parameters of peptide Trp in micelles according to its depth, should be useful for describing the interactions of peptides of biological interest with micelles.     

Low molecular weight disulfide cross-linking peptides as nonviral gene delivery carriers

Cross-linking peptides have been developed by inserting multiple Cys residues into a 20 amino acid condensing peptide that polymerizes through disulfide bond formation when bound to DNA resulting in small, highly stable DNA condensates that mediate efficient in vitro gene transfer [McKenzie et al. (2000) J. Biol. Chem. 275, 9970-9977]. In the present study, a minimal peptide of four Lys and two terminal Cys residues was found to substitute for Cys-Trp-(Lys)(17)-Cys, resulting in DNA condensates with similar particle size and gene expression in HepG2 cells. Substitution of His for Lys residues resulted in an optimal peptide of Cys-His-(Lys)(6)-His-Cys that, in addition to the attributes described above, also provided buffering capacity to enhance in vitro gene expression in the absence of chloroquine. The reported structure-activity relationships systematically explore peptides with combinations of Lys, Cys, and His residues resulting in low molecular weight peptides with improved gene transfer properties.     

Apoptosis induced in neuronal cells by C-terminal amyloid beta-fragments is correlated with their aggregation properties in phospholipid membranes

A number of findings suggest that lipophilic monomeric Abeta peptides can interact with the cellular lipid membranes. These interactions can affect the membrane integrity and result in the initiation of apoptotic cell death. The secondary structure of C-terminal Abeta peptides (29-40) and the longer (29-42) variant have been investigated in solution by circular dichroism measurements. The secondary structure of lipid bound Abeta (29-40) and (29-42) peptides prepared at different lipid/peptide ratio's, was investigated by ATR-FTIR spectroscopy. Finally, the changes in secondary structure (i.e. the transition of alpha-helix to beta-sheet) of the lipid bound peptides were correlated with the induction of neurotoxic and apoptotic effects in neuronal cells. The data suggest that the C-terminal fragments of the Abeta peptide induce a significant apoptotic cell death, as demonstrated by caspase-3 measurements and DNA laddering, with consistently a stronger effect of the longer Abeta (29-42) variant. Moreover, the induction of apoptotic death induced by these peptides can be correlated with the secondary structure of the lipid bound amyloid beta peptides. Based on these observations, it is proposed that membrane bound aggregated Abeta peptides (produced locally as the result of gamma-secretase cleavage) can accumulate and aggregate in the membrane. These membrane bound beta-sheet aggregated amyloid peptides induce neuronal apoptotic cell death.     

Inhibition of peptide amyloid formation by cationic peptides with homologous sequences

We have studied the model peptides that undergo self-initiated structural transition from alpha-helix to beta-sheet and self-assembling into amyloid fibrils. We here constructed an inhibition system of amyloid formation utilizing homologous recognition and assembly of peptides with increased solubility. Among 20 peptides with homologous sequences examined here, cationic peptides showed the stronger inhibition ability against the amyloid formation of a model peptide.     

Synthesis and biological activity of N epsilon-acyl derivatives of a Saccharomyces cerevisiae mating pheromone

We report a general method for acylation of the N epsilon-amino group of the lysyl residue in peptides. The procedure involves acylation using p-nitrophenyl esters and 1-hydroxybenzotriazole in organic solvents to yield a series of fatty acyl mating pheromones of Saccharomyces cerevisiae. The fatty acyl group does not influence coupling of peptide fragments. Biological activities of the synthesized alpha-factor mating pheromones derivatized with acetyl, butyryl, caprylyl and lauryl groups are nearly equivalent to the activity of unacylated alpha-factor. The N epsilon-stearyl-alpha-factor is biologically inactive. The procedures reported in this communication can be used to increase hydrophobicity of lysine-containing peptides when the lysyl group is not essential for activity.     

Secondary structure and position of the cell-penetrating peptide transportan in SDS micelles as determined by NMR

Transportan is a 27-residue peptide (GWTLN SAGYL LGKIN LKALA ALAKK IL-amide) which has the ability to penetrate into living cells carrying a hydrophilic load. Transportan is a chimeric peptide constructed from the 12 N-terminal residues of galanin in the N-terminus with the 14-residue sequence of mastoparan in the C-terminus and a connecting lysine. Circular dichroism studies of transportan and mastoparan show that both peptides have close to random coil secondary structure in water. Sodium dodecyl sulfate (SDS) micelles induce 60% helix in transportan and 75% helix in mastoparan. The 600 MHz (1)H NMR studies of secondary structure in SDS micelles confirm the helix in mastoparan and show that in transportan the helix is localized to the mastoparan part. The less structured N-terminus of transportan has a secondary structure similar to that of the same sequence in galanin [Ohman, A., et al. (1998) Biochemistry 37, 9169-9178]. The position of mastoparan and transportan relative to the SDS micelle surface was studied by adding spin-labeled 5-doxyl- or 12-doxyl-stearic acid or Mn2+ to the peptide/micelle system. The combined results show that the peptides are for the most part buried in the SDS micelles. Only the C-terminal parts of both peptides and the central segment connecting the two parts of transportan are clearly surface exposed. For mastoparan, the secondary chemical shifts of the amide protons were found to vary periodically and display a pattern almost identical to those reported for mastoparan in phospholipid bicelles [Vold, R., et al. (1997) J. Biomol. NMR 9, 329-335], indicating similar structures and interactions in the two membrane-mimicking environments.     

Gene transfer with poly-melittin peptides

The 26 amino acid hemolytic melittin peptide was converted into a gene transfer peptide that binds to DNA and polymerized through disulfide bond formation. Melittin analogues were synthesized by the addition of one to four Lys repeats at either the C- or the N-subterminal end along with terminal Cys residues. Melittin analogues were able to bind and polymerize on plasmids resulting in the formation of DNA condensates. In the absence of DNA, melittin analogues retained their red blood cell hemolytic potency but were inactive when bound to plasmid DNA. The in vitro gene transfer efficiency mediated by poly-melittin analogues was equivalent to PEI in HepG2 cells. Attempts to truncate portions of either of the two melittin alpha-helices resulted in concurrent loss of hemolytic potency and gene transfer efficiency. The results demonstrate the ability to transform melittin into a gene transfer peptide by transiently masking its membrane lytic activity by the addition of Lys and Cys residues to promote DNA binding and polymerization.     

Calmodulin and troponin C: a comparative study of the interaction of mastoparan and troponin I inhibitory peptide [104-115]

Recent studies using bee and wasp venom peptides have led to the hypothesis that proper complex formation with calmodulin (CaM) requires the presence of a basic amphiphilic helix on the surface of the target protein [Cox, J. A. (1984) Fed. Proc., Fed. Am. Soc. Exp. Biol. 43, 3000]. We have tested this hypothesis by examining CaM and troponin C (TnC) complex formation with two basic peptides, the wasp venom tetradecapeptide mastoparan and the physiologically relevant synthetic troponin I (TnI) inhibitory peptide [104-115], using far-ultraviolet circular dichroism as a secondary structure probe. Complex formation between mastoparan and either CaM or TnC results in an increase in helical content, whereas the helical content of TnI inhibitory peptide does not increase when bound to either protein. Significantly, mastoparan is 78% alpha-helical in a 50% solution of the helix-inducing solvent trifluoroethanol and has a high helix-forming potential according to the Chou-Fasman rules while TnI inhibitory peptide contains none and is not predicted to have any. We interpret these data as indicating that these peptides exhibit substantially different secondary structures upon binding to CaM or TnC. The ability of mastoparan to regulate the acto-subfragment 1-tropomyosin ATPase has also been examined. Mastoparan and TnI inhibitory peptide inhibited 31% and 45% of the activity, respectively. TnC and CaM promote differing degrees of Ca2+-sensitive release of inhibition by both peptides. Sequence comparison suggests that the basic residues present in both peptides are important for binding. However, we conclude that an alpha-helical structure is not a prerequisite for the binding of target proteins to CaM and TnC.     

Electrophoretic mobility of Alzheimer's amyloid-beta peptides in urea-sodium dodecyl sulfate-polyacrylamide gel electrophoresis

The 43-amino acid Alzheimer's amyloid-beta peptide (Abeta peptide) retains a predominantly alpha-helix and beta-strand structure in sodium dodecyl sulfate (SDS) solution. This conformer has a high tendency to aggregate during conventional SDS-polyacrylamide gel electrophoresis (PAGE). Both the secondary structure and the proclivity for aggregation are obviated by the use of urea-SDS-PAGE: In 8M urea-with or without SDS-the Abeta peptide becomes 100% random coil and remains monomeric. However, during electrophoresis in this medium, the peptide and its truncated variants do not obey the law of mass/mobility relationship that most proteins-including Abeta peptides-follow in conventional SDS-PAGE. Rather, the smaller carboxy-terminally truncated peptides migrate slower than the larger full-length peptide, while the amino terminally truncated peptide does migrate faster than the full-length Abeta peptide. Thus, despite their small size (2-4kDa) and minor differences between their lengths, the Abeta peptides display a wide separation in this low-porosity (12% acrylamide) gel. We found that this unusual electrophoretic mobility in 8M urea is due to the fact that the quantity of [35S]SDS bound to the Abeta peptides, instead of being proportional to the total number of amino acids, is rather proportional to the sum of the hydrophobicity consensus indices of the constituent amino acids. It is then their hydrophobicity and, hence, the net negative charges contributed by the peptide-bound SDS that plays a major role in determining the mobility of Abeta peptides in 8M urea-SDS-PAGE. The high selectivity of the 8M urea-SDS-PAGE method allowed us to detect the presence of hitherto unknown Abeta peptide variants that were secreted in the conditioned medium by cultured HeLa cells.     

Factors influencing the ability of nuclear localization sequence peptides to enhance nonviral gene delivery

Nonviral gene delivery is limited by inefficient transfer of DNA from the cytoplasm to the nucleus. Nuclear localization sequence (NLS) peptides have been widely used to exploit intracellular transport mechanisms and promote nuclear uptake of DNA. However, the exact conditions to successfully utilize the properties of NLS peptides are still unclear. In the present study a panel of NLS peptides that bind different transport receptors were compared for their ability to enhance nonviral gene transfer. Several factors such as method of incorporating the NLS peptide, type of NLS peptide, DNA morphology, and proper characterization of NLS peptide/DNA conjugates were identified as important considerations in utilizing NLS peptides to enhance gene transfer. In particular, it was shown that a peptide derived from human T cell leukaemia virus type 1 (HTLV) was able to effectively condense DNA into discrete particles and mediate levels of transgene expression up to 32-fold greater than polylysine-based polyplexes. This is the first study to demonstrate efficient transfection mediated by an importin beta-binding peptide based on the HTLV sequence. Promising results were also achieved with a 7-fold increase in gene expression using a NLS peptide/DNA conjugate formed by site-specific linkage of an extended SV40 peptide via a peptide nucleic acid (PNA) clamp. Altogether, the results from this study should help to define the requirements for successful NLS-enhanced transfection.     

A potent new class of reductively activated peptide gene delivery agents

A new class of peptide gene delivery agents were developed by inserting multiple cysteine residues into short (dp 20) synthetic peptides. Substitution of one to four cysteine residues for lysine residues in Cys-Trp-Lys(18) resulted in low molecular weight DNA condensing peptides that spontaneously oxidize after binding to plasmid DNA to form interpeptide disulfide bonds. The stability of cross-linked peptide DNA condensates increased in proportion to the number of cysteines incorporated into the peptide. Disulfide bond formation led to a decrease in particle size relative to control peptide DNA condensates and prevented dissociation of peptide DNA condensates in concentrated sodium chloride. Cross-linked peptide DNA condensates were 5-60-fold more potent at mediating gene expression in HepG2 and COS 7 cells relative to uncross-linked peptide DNA condensates. The enhanced gene expression was dependent on the number of cysteine residues incorporated, with a peptide containing two cysteines mediating maximal gene expression. Cross-linking peptides caused elevated gene expression without increasing DNA uptake by cells, suggesting a mechanism involving intracellular release of DNA triggered by disulfide bond reduction. The results establish cross-linking peptides as a novel class of potent gene delivery agents that enhance gene expression through a new mechanism of action.     

Attenuated total reflectance Fourier transform infrared studies of the interaction of melittin, two fragments of melittin, and delta-hemolysin with phosphatidylcholines

Attenuated total reflectance Fourier transform infrared spectroscopy (ATR FT-IR) has been used to monitor alterations in phospholipid organization in thin layers of 1,2-dipalmitoylphosphatidylcholine (DPPC) and 1-palmitoyl-2-oleoylphosphatidylcholine (POPC), induced by the membrane lytic peptide melittin, its fragments 1-15 (hydrophobic fragment) and 16-26 (hydrophilic fragment), and delta-hemolysin. In addition, the secondary structures of the peptides and the orientation of helical fragments were determined with respect to the bilayer. The insertion of melittin into POPC caused large perturbations in the order and increased rates of motion of the acyl chains, as monitored by the frequency and half-width of the symmetric CH2 stretching vibration near 2850 cm-1, as well as by the ATR dichroic ratio for this mode. Changes in DPPC organization were less and were consistent with peptide-induced static disordering (gauche rotamer formation) in the acyl chains. Melittin adopted primarily an alpha-helical secondary structure, although varying small proportions of beta and/or aggregated forms were noted. The helical segments were preferentially oriented perpendicular to the bilayer plane. Several modes of melittin/lipid interaction were considered in an attempt to semiquantitatively understand the observed dichroic ratios. By considering the peptide as a bent rigid rod, a plausible model for its lytic properties has been developed. The hydrophilic fragment in DPPC showed a secondary structure with little alpha-helix present. As judged by its effect on phospholipid acyl chain organizational parameters, the fragment did not penetrate the bilayer substantially. The hydrophobic fragment in DPPC gave amide I spectral patterns consistent with a mixture of predominantly beta-antiparallel pleated sheet with a smaller fraction of alpha-helix.(ABSTRACT TRUNCATED AT 250 WORDS)     

Covalently attached fatty acyl chains alter the aggregation behavior of an amyloidogenic peptide derived from human β2‐microglobulin

Aggregation of a polypeptide chain into highly ordered amyloid aggregates is a complex process. Various factors, both extrinsic and intrinsic to the polypeptide chain, have been shown to perturb this process, leading to a drastic change in the amyloidogenic behavior, which is reflected in the polymorphism of amyloid aggregates at various levels of self‐assembly. In this paper, we have investigated the ability of covalently linked long‐chain fatty acids in modulating the self‐assembly of an aromatic amino acid‐rich highly amyloidogenic sequence derived from the amino acid region 59–71 of human β₂‐microglobulin by thioflavin T (ThT) fluorescence microscopy, circular dichroism, and fluorescence spectroscopy. Our results indicate that under identical conditions of dissolution and concentration, each peptide enhances the fluorescence of ThT. However, the aggregates are morphologically distinct. For the same peptide, the aggregate morphologies are dependent on peptide concentration. Further, an optimum concentration, which varies with solution ionic strength, is required for the formation of fibrillar aggregates. We show that covalent modification of this amyloidogenic sequence, with long‐chain fatty acids, affects the way the higher order amyloid structures assemble from the cross‐β units, in fatty acyl chain‐dependent and position‐dependent manner. Our data indicate that noncovalent interactions leading to amyloid fibril formation can be modulated by the hydrophobicity of covalently attached long‐chain fatty acids resulting in self‐assembly of the peptide chain to form nonfibrillar aggregates. Copyright © 2013 European Peptide Society and John Wiley & Sons, Ltd.