Structural flexibility of apolipoprotein E-derived arginine-rich peptides improves their cell penetration capability

Amphipathic arginine-rich peptide, A2-17, exhibits moderate perturbation of lipid membranes and the highest cell penetration among its structural isomers. We investigated the direct cell-membrane penetration mechanism of the A2-17 peptide while focusing on structural flexibility. We designed conformationally constrained versions of A2-17, stapled (StpA2-17) and stitched (StchA2-17), whose α-helical conformations were stabilized by chemical crosslinking. Circular dichroism confirmed that StpA2-17 and StchA2-17 had higher α-helix content than A2-17 in aqueous solution. Upon liposome binding, only A2-17 exhibited a coil-to-helix transition. Confocal microscopy revealed that A2-17 had higher cell penetration efficiency than StpA2-17, whereas StchA2-17 remained on the cell membrane without cell penetration. Although the tryptophan fluorescence analysis suggested that A2-17 and its analogs had similar membrane-insertion positions between the interface and hydrophobic core, StchA2-17 exhibited a higher membrane affinity than A2-17 or StpA2-17. Atomic force microscopy demonstrated that A2-17 reduced the mechanical rigidity of liposomes to a greater extent than StpA2-17 and StchA2-17. Finally, electrophysiological analysis showed that A2-17 induced a higher charge influx through transient pores in a planer lipid bilayer than StpA2-17 and StchA2-17. These findings indicate that structural flexibility, which enables diverse conformations of A2-17, leads to a membrane perturbation mode that contributes to cell membrane penetration.

www.nature.com/scientificreports/non-endocytic entry predominance in cells at 4 °C, where all the membrane trafficking mechanisms, including endocytosis, are suppressed [8][9][10] .This direct cell membrane penetration process is a spontaneous physicochemical phenomenon independent of specific membrane proteins or energy derived from the hydrolysis of adenosine triphosphate [10][11][12] .The direct penetration process likely occurs via a membrane perturbation mechanism, wherein the interaction between Arg residues of peptides and oxonium anion groups, including phosphate groups of lipids, perturbs and induces the lipid bilayer to locally form short-life transient non-lamellar defects or pores; which then enables ARPs to traverse the membrane barrier [12][13][14] .
Amphipathic helical structures can be used to develop highly cell-penetrable ARPs, as observed in many cell-penetrating peptides 6,12,15 .An amphipathic ARP peptide-named A2-17-was designed based on the glyocosaminoglycan-binding region of human apolipoprotein E 9,16,17 , a structural protein found on lipoproteins.It exhibits direct cell membrane penetration even at low peptide concentrations, unlike conventional ARPs, such as Tat, polyarginine, and Rev 9,10 .The increased amphipathicity of A2-17 leads to enhanced insertion and membrane perturbation, which results in generation of transient defects or pores in the membrane 18 .The amphipathic nature of ARPs facilitates their binding to lipid membranes, establishing a concentration gradient that drives lipid membrane penetration.However, our previous study revealed that, for efficient cell penetration, the amino acid arrangement of the amphipathic helix of A2-17 outperformed its isomers with higher or lower amphipathicity 18 .While the importance of conformation-restricting intramolecular linking in improving peptide cell penetration has been reported, the significance of structural flexibility in cell-penetrating peptides, including A2-17, remains unclear [19][20][21][22][23][24][25] .

Secondary structure of A2-17 derivatives
Circular dichroism (CD) spectra were recorded to analyze the secondary structures of intramolecularly crosslinked StpA2-17 and StchA2-17 (Fig. 2).The fourth and eighth leucine residues of A2-17 in StpA2-17 are replaced with S5.In StchA2-17, the fourth and eighth leucine residues of A2-17 are replaced with S5 and B5, respectively, while the fifteenth arginine residue is replaced with S8 (Fig. 1).In water, the secondary structure of A2-17 exhibits a random coil-like conformation, as indicated by a peak around 200 nm.However, upon binding to distearoylphosphatidylcholine (DSPC)-based large unilamellar vesicles (LUVs) of the cell membrane model, which included distearoylphosphatidylglycerol (DSPG) for mimicking negatively charged cell membrane surfaces 13 , it is structurally transformed into an α-helix, as revealed by double negative peaks around 206 nm and 222 nm (Fig. 2a).This behavior was similar to that observed in our previous study using small unilamellar vesicles that had a high membrane curvature 18 .The α-helix content of A2-17 increased from 19% in water to 32% upon binding to lipid membranes; however, this change was not statistically significant (Fig. 2b).In contrast, StpA2-17 and StchA2-17 showed a distinctive CD spectrum of the α-helix structure even in water (Fig. 2a), and the calculated α-helix contents of StpA2-17 (51%) and StchA2-17 (102%) were significantly higher than that of A2-17.This suggests that intramolecular cross-linking can induce a conformational restraint (Fig. 2b).Additionally, the presence of LUVs caused no prominent secondary conformational transitions in StpA2-17 and StchA2-17, indicating that they had a stable α-helical-like conformation.

Cell membrane penetration
The direct cell membrane penetration of peptides at 4 °C were compared using fluorescence detection.For this, HeLa cells treated with peptide conjugated with a small molecule drug model, 5-carboxyfluorecein (FAM), were observed using confocal fluorescent laser microscopy (Fig. 3).The intracellular FAM fluorescence intensity was in the order A2-17 > StpA2-17 > StchA-17 (Fig. 3a), and StchA2-17 remained in the peripheral region of the cells.Comparison of FAM fluorescence intensity in the cell nucleus region, after subtracting extracellular FAM fluorescence intensity, showed no significant difference between the group treated with FAM-labeled StchA2-17 and the control group without any FAM-labeled peptide (Fig. 3b).These results indicate that A2-17 exhibited higher cell membrane penetration ability than StpA2-17, whereas StchA2-17 was unable to penetrate cells.

Lipid membrane binding
The lipid membrane-binding properties of A2-17, StpA2-17, and StchA2-17 were analyzed using their intrinsic Trp fluorescence (Fig. 4).We compared the degree of membrane insertion by monitoring the fluorescence wavelength maximum (WMF).WMF shifts toward a shorter wavelength as the peptide is transferred to a more hydrophobic environment upon binding to lipid membranes 27 .When titrated with LUVs, the WMF shift occurred faster for StchA2-17 than for A2-17 and StpA2-17 (Fig. 4a), indicating that StchA2-17 has a higher lipid binding  affinity than A2-17 and StpA2-17.However, there were no significant differences between the WMF values of peptides at the plateau in the presence of a large excess of LUVs.The plateau for A2-17 or StpA2-17 was reached at a lipid/peptide molar ratio of 225, where the LUV concentration was 1.8 mM.In contrast, StchA2-17 exhibited a plateau at a lipid/peptide molar ratio of 75, where the LUV concentration was 0.6 mM.Under these conditions, only the Trp residue environment of the peptide bound to the membrane is reflected in the WMF.The WMF profiles of N-acetyl-L-tryptophanamide, which depend on dielectric constant (ε r ), were obtained by fluorescence measurements using ethanol (see Methods for details).The Trp position of the peptide inserted into the lipid membranes was estimated from the WMF value at the plateau (Fig. 4b).All plateau WMF values were around ε r of 20, suggesting that each peptide inserts into membranes to a similar extent between the lipid membrane interface region (ε r ~ 30-40) and the hydrophobic core (ε r ~ 2) 28,29 .
To determine the thermodynamic parameters for the binding of peptides to lipid membranes, we employed the partition model described by White et al. 30 , that considers the binding process as partitioning between water and the lipid bilayer.In this model, the peptide partition to lipid membranes is driven by hydrophobic and electrostatic interactions with the collective properties of the lipids in the membrane.The ultrafiltration method (see Methods section for details) revealed that the partition constant (K x ) for StchA2-17 was 1.1 × 10 7 , approximately 40-fold higher than that for A2-17 (2.7 × 10 5 ) and StpA2-17 (2.4 × 10 5 ) (Table 1).These results align with the WMF shift measurements, which indicated that StchA2-17 had the highest lipid binding affinity (Fig. 4A).In addition, the standard Gibbs free energy (ΔG x °) of transfer of peptides from water to the membrane was significantly reduced by -9 kJ/mol for StchA2-17 (

Membrane perturbation and pore
In a previous study, we established an atomic force microscopy (AFM) method for measuring the mechanical membrane perturbation by peptides 18 .Using this method, we compared the membrane perturbation of A2-17 with that of StpA2-17 and StchA2-17 (Fig. 5).The spherical structure of LUVs was observed on the substrate in both the absence and presence of peptides (Fig. 5a), and the peptide-induced decrease in liposome stiffness was quantified as a membrane perturbation, as described in the Methods section.Despite its lower α-helicity and hydrophobicity, properties that generally enhance peptide partitioning to lipid membranes and membrane perturbation 18 , A2-17 caused a greater membrane perturbation than StpA2-17 and StchA2-17 (Fig. 5b).We also compared the characteristics of peptide-induced pores in a planar dioleoylphosphatidylcholine (DOPC) Table 1.Thermodynamic parameters for peptide partition to DSPC/DSPG membrane.a The partition constant was measured using separation method 30 (see the Methods section for details).b The standard Gibbs free energy was calculated according to ΔG x ° = −RTln K x .www.nature.com/scientificreports/bilayer membrane system using electrophysiological analyses (Fig. 6).Each current event caused by peptides can be classified into a "spike" or "long-lasting" signal based on the event duration, and the spike current signal (duration < 20 ms) is likely to be derived from the favorable trait of ARPs that can induce transient defects/ pores of the lipid membrane to penetrate cells 18,31 .Figure 6a shows the typical current signals observed after peptide addition.Spike current signals were predominant for all the peptides: A2-17 (96.3%),StpA2-17 (99.6%),StchA2-17 (90.3%).The average frequency of spike current signals was in the order: A2-17 (0.2 s -1 ) ~ StpA2-17 (0.2 s -1 ) > StchA2-17 (0.005 s -1 ).In addition, the charge flux accompanied by spike current signal was much greater for A2-17 than that for StpA2-17 or StchA2-17 (Fig. 6b).These results indicate that A2-17 had the most favorable membrane perturbation mode for cell membrane penetration.

Discussion
The conformation-restricting intramolecular linking has been known to enhance the cell penetration of peptides 20,24 .However, the present study showed that the introduction of hydrocarbon-stapling or hydrocarbonstitching into structurally flexible A2-17, which changes conformation in response to different physicochemical environments, results in reduced cell membrane penetration ability.
It has been argued that structural flexibility is important for ARPs to adapt to hydrophilic and hydrophobic environments (aqueous phase and lipid membranes, respectively) so that they can penetrate cell membranes 6,10,22,25 .To investigate the energetics involved in the partitioning of peptides between the water  and bilayer interface, we estimated the contribution of the hydrophobic effect using a thermodynamic cycle, as described White et al 30 .In this thermodynamic cycle, the ΔG x ° for transfer of peptides from water to the membrane includes the hydrophobic effect, denoted as ΔG hydrophobic .This effect can be expressed as ΔG hydrophobic = ΔG wif + NΔG res , where ΔG wif represents the free energy change associated with the transfer of a residue in an unfolded peptide chain, ΔG res is the partitioning-folding coupling free energy reduction per residue (-1.67 kJ/mol) in a hydrogen-bonded peptide chain 32 , and N is the number of residues forming hydrogen-bonds due to secondary structure formation, such as an α-helix.For the estimation of ΔG hydrophobic values, each nonnatural amino acid residue (S5, S8, or B5) was assumed to be a leucine residue, and we used ΔG wif values from the experimental interfacial hydrophobicity scale 33 .The value of NΔG res was calculated using the α-helix content of the peptide bound to lipid membrane (Fig. 2b).The calculated ΔG hydrophobic value for StchA2-17 was − 17 kJ/ mol, accounting for 42% of ΔG x ° (Table 1), indicating that the entropy arising from the hydrophobic effect plays a dominant role in the membrane partitioning of StchA2-17.In contrast, the ΔG hydrophobic values for A2-17 and StpA2-17 were 6.0 and 3.7 kJ/mol, respectively.Thus, the membrane partitioning of A2-17 and StpA2-17 is not driven primarily by the hydrophobic effect, which suggests that non-hydrophobic effects, such as electrostatic interactions, dominate.Consequently, although generalization is challenging owing to conflicting data 19,34,35 , stapling or stitching of amphipathic ARPs could decrease entropy in the membrane-unbound state, thereby stabilizing the membrane-bound state and compromising their cell penetration capability.The reported enhanced cell penetration of stapled or stitched polyarginines 20,24 may be derived from a moderate increase in amphipathicity or hydrophobicity by helical structures containing hydrophobic residues (S5, B5, and S8), which could improve their partitioning to lipid membranes.Our results suggest that for amphipathic ARPs, a stable helical structure with very high amphipathicity would make it difficult for the peptide to desorb from the plasma lipid membranes, resulting in poor cell penetration.
As previously discussed by Takechi-Haraya et al., the Born theory excludes the well-known solubility-diffusion mechanism of membrane penetration, where the permeating substance on one side first dissolves in the hydrophobic region of the membrane and then crosses the membrane to the other side according to the concentration gradient as the driving force 13 .Although StchA2-17 had more favorable energetics for membrane partitioning than A2-17 and StpA2-17, it consistently did not exhibit cell membrane penetration and remained on the cell membrane.
We found that the cell-penetrating A2-17 peptide softened the membrane mechanically, leading to transient membrane defects or pores 13,18 .The peptide-induced membrane perturbation, defined as a decrease in the mechanical rigidity (stiffness) of the interacting liposomes, was higher for A2-17 than for StpA2-17 and StchA2-17, as well as the increased charge flux associated with transient membrane pores caused by A2-17.StpA2-17 had lower cell penetration ability than A2-17 despite similarities in membrane insertion and partition energy; hence, it appears that A2-17 adopts favorable α-helical conformation with structural flexibility that causes the membrane perturbation required for efficient cell membrane penetration.
Chemical modifications that introduce conformational restrictions are generally advantageous for improving chemical stability, including peptidase resistance 21 .However, the present study highlights the need for careful consideration of such modifications to avoid potential loss of function in ARPs.Physicochemical characterization of the peptide in terms of secondary structure, peptide insertion and partitioning to lipid membranes, and membrane perturbation will be valuable for designing the optimal helical structures of ARPs.Hydrocarbon stapling for StpA2-17 and StchA2-17 were done in the hydrophobic face of the helical conformation, increasing the hydrophobicity (Fig. 5: A2-17 (1.000) < StpA2-17 (1.009) < StchA2-17 (1.304)) and the hydrophobic moment.Additionally, conformational restriction due to steric hindrance of the side chain hydrophobic groups at the amino acid residue level reportedly controls the cell membrane penetration of cyclic peptides 23 .Therefore, more sophisticated tuning of a stapled or stitched helical structure with optimized amino acid residues may lead to the development of novel cell-penetrating peptides.One potential way to improve the cell membrane penetration ability of a hydrocarbon-stapled peptide would be to test various positions of the staple in the helical peptide.It has been shown that extending the hydrophobic face of an amphipathic helix by the placement of a staple between the hydrophilic and hydrophobic sides of the helix increases the cell penetration ability of the peptide 34 .
In conclusion, A2-17 exhibited higher ability to penetrate cell membranes than StpA2-17, and StchA2-17 did not penetrate cells.StchA2-17 had much higher affinity for lipid membranes than A2-17 and StrpA2-17.Despite the similar degrees of membrane insertion for all peptides, A2-17 reduced the mechanical rigidity of liposomes to a greater extent than StpA2-17 and StchA2-17.Additionally, A2-17 induced a higher charge influx through transient membrane pores than StpA2-17 and StchA2-17.Our results indicate that the structural flexibility of A2-17 leads to a membrane perturbation mode that contributes to its greater cell membrane penetration ability, thus providing new insights for the future design of ARPs for drug delivery.

Preparation of lipid vesicles
LUVs were prepared as described by Takechi-Haraya et al 38 .Briefly, a dried lipid film of DSPC/DSPG (4:1 molar ratio) was hydrated with 10 mM Tris buffer containing 150 mM NaCl (pH 7.4) under mechanical agitation for 5 min at 60 °C.The resultant suspension was freeze-thawed five times using dry ice-methanol slush and a water bath of 60 °C.Thereafter, the suspension was extruded 21 times through a mini-extruder equipped with a 0.1-μm polycarbonate filter (Avanti Polar Lipids, Alabaster, AL, USA) at 70 °C.

Analyses of peptide properties
To evaluate the secondary structure of peptides, far-UV CD spectra were recorded from 190 to 250 nm at 25 °C using a CD spectrometer (J-1100, JASCO, Tokyo, Japan) with a quartz cuvette of 1-mm path length.Peptide solutions (10 µM) in 10 mM Tris buffer containing 150 mM NaCl (pH 7.4) were subjected to CD measurements.This was in the absence as well as presence of LUVs (1 mM).Each CD spectrum of the peptide sample was corrected by subtracting the corresponding baseline for the same concentration of LUVs in Tris buffer.The α-helix content of peptide was determined from the mean residue ellipticity at 222 nm, assuming only the helical conformation contributes to this measurement, as described by Scholtz et al 39 .CD measurements were performed three times for each group (n = 3).To evaluate the hydrophobicity of StpA2-17 or StchA2-17 relative to A2-17, their respective retention times were measured by reversed-phase high performance liquid chromatography using a Phenomenex Gemini 150 mm × 4.6 mm C18 110 Å 5 µm column (Phenomenex, Aschaffenburg, Germany) at 40 °C.The peptides were eluted using a linear gradient over 20 min at a flow rate of 1 mL/min, ranging from 5 to 65% acetonitrile/water containing 0.1% trifluoroacetic acid, with UV detection at 220 nm.The retention time measurement was performed independently in triplicate (n = 9).

Trp fluorescence measurements
Trp emission fluorescence spectra of 8 µM of A2-17, StpA2-17 or StchA2-17 in the absence and presence of LUVs at 25 °C in 10 mM Tris buffer containing 150 mM NaCl (pH 7.4) were recorded from 300 to 420 nm at an excitation wavelength of 290 nm using an F-7000 fluorescence spectrophotometer (Hitachi, Tokyo, Japan).To minimize the scattering artifacts from LUVs, with a polarizer orientation (Ex pol = 90°, Em pol = 0°), each Trp fluorescence spectrum of the peptide was corrected by subtracting the baseline for the same concentration of lipid vesicles in buffer solution, and further corrected for decreases in fluorescence intensity by using reference samples of 8 µM L-tryptophan with or without LUVs, as described by Ladokhin et al. 27 .The WMF of each spectrum was determined by peak analysis using OriginPro software v.2023 (OriginLab Corporation, Northampton, MA, USA).In the same experimental condition, fluorescence spectra of N-acetyl-L-tryptophanamide (10 µM) in ethanol/water solvent was measured, and its dielectric constant-dependent WMF profile was obtained by the third order polynomial fitting to the data using the GraphPad prism software v.9.5.1 (GraphPad Software, La Jolla, CA).The dielectric constant of ethanol/water solvent was calculated from the equation: ε r = 78.43Vwater + 24.09V ethanol , where 78.43 and 24.09 are ε r values of water 40 and ethanol 41 at 25 ℃, respectively, and V water and V ethanol are volume fraction of aqueous buffer and ethanol, respectively.The standard Gibbs free energy of transfer from water to lipid membrane (ΔG x °) was calculated using the partition model 30 : ΔG x ° = −RTln K x ; K x = 55.3([P]−[P]f )/ [L][P] f , where K x is the partition constant, [P] and [L] are the total molar concentrations of peptide and lipid, respectively, and [P] f is the bulk molar concentration of peptide in water phase.For this analysis, at 25 °C in 10 mM Tris buffer containing 150 mM NaCl (pH 7.4), after 10 µM peptide was incubated for 30 min with or without LUVs (500 µM total lipid) in a 100 KDa MWCO Amicon Ultra® tube (Merck Millipore, Billericia, MA, USA), the sample was centrifuged at 9000×g for 15 min.For the resultant filtered solutions, Trp fluorescence intensities attributable to [P] f and [P], which are samples with and without LUVs, respectively, were measured using a Synergy H1 plate reader (BioTek, Winooski, VT) at an excitation wavelength of 290 nm and a detection wavelength of 350 nm in flat-bottom 96-well plates.Experiments were conducted by preparing three to six samples from each group (n = 3-6).

CLSM
CLSM observation via the z-stack imaging mode was performed by a slight modification of our previous procedure 9 , using a confocal microscope (Nikon A1, Tokyo, Japan) with a 20 × objective lens (CFI Plan Apo Lambda 20×, NA 0.75, WD 1.00 mm) at an excitation wavelength of 488 nm to visualize FAM-labeled peptides.Z-stack images were acquired from the periphery of the cells attached to the glass-bottom dish toward the opposite periphery by scanning every 0.78 μm.The detection pinhole diameter was set to be 1.0 times of the diameter of the Airy Disk, resulting in an optical section thickness of < 2.1 μm.HeLa cells (2 × 10 5 cells) were plated in a 35-mm glass-bottomed dish coated with poly-L-lysine (Matsunami Glass Ind. Ltd., Osaka, Japan) and were incubated in Dulbecco's modified Eagle medium (DMEM; Thermo Fisher Scientific) supplemented with 10% fetal bovine serum (Sigma-Aldrich).After incubation for 24 h (37 °C, 5% CO 2 ), the cells were incubated with 1 µM FAM-labeled peptide for 30 min at 4 °C in DMEM.After incubation, the cells were washed three times with phosphate-buffered saline on ice and stored in the phosphate-buffered saline, followed by confocal microscopy.The nuclei of the cells were counterstained with Cellstain® Hoechst 33,342 solution (DOJINDO LABORATORIES, Kumamoto, Japan) following the manufacturer's instructions and visualized at an excitation wavelength of 405 nm.Throughout the image acquisition, the laser intensity, photomultiplier detector sensitivity, and pinhole aperture values were kept constant.ImageJ Fiji software 42 was used to analyze the FAM fluorescence intensity of the nucleus region by subtracting the background intensity outside the cells, and the cell penetration of peptides was compared.Fluorescence analysis was performed on more than 40 cells (n = 40-125).

Channel current analysis for membrane penetration of peptides
Electrophysiological measurements were performed using a MECA 16 TC chip with an Orbit 16 TC device (Nanion Technologies GmbH, Munich, Germany) according to the manufacturer's instructions.The MECA 16 TC chamber was filled with 200 µL of buffer solution (150 mM KCl, 10 mM MOPS, pH 7.0); 1 µL of DOPC (lipid/n-decan, 10 mg/mL) solution was added to the chamber, and planar lipid bilayers were automatically prepared using the Orbit 16TC stirrer.The peptide was then dissolved in the chamber at 10 µM (a lipid/peptide molar ratio of ~ 6 in the chamber system), and 100 mV of voltage was applied.The channel current was monitored using the Orbit 16 TC Elements Data Reader 4 v.1.0.

AFM
To measure the membrane perturbation of peptides, we performed AFM at 25 ± 1 °C in 10 mM Tris buffer containing 150 mM NaCl (pH 7.4) using a BioLever mini cantilever (BL-AC40TS, Olympus Co., Tokyo, Japan) via the QI mode of a JPK Nanowizard Ultra Speed microscope equipped with the Data Processing JPK software v.6.0 (JPK Instruments AG, Berlin, Germany) according to our previous procedure 18 .Briefly, 200 μL of DSPC/DSPG-LUVs (50 μM of total lipids) in Tris buffer solution was incubated on an aminopropyl-modified mica substrate for 20 min, and an additional 1.4 mL of Tris buffer solution with or without the peptide was added, followed by AFM measurement.For the peptide samples, the final peptide/lipid molar ratio was 1.The AFM images were recorded at a resolution of < 8 nm/pixel.To obtain the lipid vesicle stiffness, a linear fit was performed over the linear region of the force-deformation curve at the center of a lipid vesicle using JPK Software.Peptide-induced membrane perturbation was defined as a decrease in lipid vesicle stiffness using (S control −S)/S control , where S control and S are the stiffnesses of control lipid vesicles and lipid vesicles treated with peptide, respectively 18 .Using the average stiffness for S control , we evaluated the membrane perturbation of lipid vesicles with peptides.Small lipid vesicles exhibit increased stiffness due to their relatively high membrane curvature 43 .In this study, we analyzed the stiffness data of liposomes with a height (h) described by the equation 10x + 10 > h ≧ 10x, where x ranged from 5 to 14. Membrane perturbations were then obtained for each x group and averaged across all perturbations.The experiment was repeated three times and AFM analysis was performed on a total of 176 to 384 liposomes (n = 176-384).

Statistical analysis
The results are presented as mean ± standard error.Statistical analyses were performed using GraphPad prism version 9.5.1.Differences between groups were analyzed using a one-way ANOVA with Tukey's multiple comparison test.The results were considered statistically significant at a p-value < 0.05.

Figure 1 .
Figure 1.Design of stapled A2-17 (StpA2-17) and stitched A2-17 (StchA2-17) peptides.Helical wheel and helical net diagrams of A2-17 are used to display the site where the chemical linkage is introduced to StpA2-17 and StchA2-17.The helical wheel is arranged as an ideal α-helix (100° rotation per residue) as observed from the top of the long axis from the amino-terminal end.The blue and black circles indicate polar and nonpolar residues, respectively.The position of red arrow in the helical wheel plot indicates the orientation of the hydrophobic moment of the peptide.

Figure 3 .
Figure 3. Cell membrane penetration of peptides.(a) Representative confocal fluorescent images of HeLa cells treated with 1 μM of FAM-labeled A2-17, StpA2-17, or StchA2-17 for 30 min at 4 °C.FAM fluorescence (green) and Hoechst fluorescence (blue) of counterstained nuclei are shown in the merge images (labelled as Merge in the photo) along with the FAM fluorescence images (labelled as FAM in the photo).The scale bars represent 20 μm.(b) Quantification of the FAM fluorescence intensity attributable to the peptide remaining in the nucleus region of cells.****p < 0.0001; ns: not significant.

Figure 4 .
Figure 4. Lipid membrane binding of peptides.(a) Changes in WMF of Trp residue for A2-17, StpA2-17, and StchA2-17 as a function of molar ratio of total lipid of LUVs to peptide (lipid/peptide molar ratio changes from 0 to 250).One-phase decay curve fitting using the least squares method was applied to obtain the WMF at plateau.Solid lines represent the best fit.(b) The membrane location of the Trp residue in the peptide was estimated using the WMF profile of N-acetyl-L-tryptophanamide under different values of dielectric constant.The experimental data of N-acetyl-L-tryptophanamide was fitted with a third-order polynomial line that provided the best fit, and a 95% confidence band was included.The dashed line represents the extrapolation to a WMF value of 330, where the WMF values of A2-17, StpA2-17, and StchA2-17 at the plateau were fitted to the profile.

22 .
The channel current signals were detected using a 4-kHz low-pass filter at a sampling frequency of 20 kHz.Analysis of the channel signals was performed using pCLAMP ver.10.7 (Molecular Devices, CA, USA).The data obtained in this measurement are n (number of current signals): 2081 > n > 311; N (number of experiments) > 3.
Given that the energy difference (− 9 kJ/mol) corresponds to 3.6 times the thermal energy RT, these results indicate that the membrane-bound state of StchA2-17 is more stable than that of A2-17 and StpA2-17.