Translocation of an Aib-containing peptide through cell membranes

The biophysical characteristics and channel-forming activity of peptaibols inserted into artificial membranes have been studied over the last 30 years. However, to our knowledge, no studies have addressed directly their behavior in living cells. In this work, a novel strategy has been employed to precisely assess the living cell membrane-penetrating activity of a fluorescein-labeled Aib (α-aminoisobutyric acid)-containing peptide derived from a peptaibol, trichorovin-XIIa (TV-XIIa). We have demonstrated for the first time that the peptide containing an unusual amino acid residue, Aib, is taken up by cells via a non endocytic pathway. The replacement of Aib in the TV-XIIa sequence with Ala inhibits the cellular uptake.     

Translocation of analogues of the antimicrobial peptides magainin and buforin across human cell membranes

Cationic antimicrobial peptides play important roles in innate immunity. Compared with extensive studies on peptide-bacteria interactions, little is known about peptide-human cell interactions. Using human cervical carcinoma HeLa and fibroblastic TM12 cells, we investigated the cellular uptake of fluorescent analogues of the two representative antimicrobial peptides magainin 2 and buforin 2 in comparison with the representative Arg-rich cell-penetrating Tat-(47-57) peptide (YGRKKRRQRRR). The dose, time, temperature, and energy dependence of translocation suggested that the three peptides cross cell membranes through different mechanisms. The magainin peptide was internalized within a time scale of tens of minutes. The cooperative concentration dependence of uptake suggested that the peptide forms a pore as an intermediate similar to the observations in model membranes. Furthermore, the translocation was coupled with cytotoxicity, which was larger for tumor HeLa cells. In contrast, the buforin peptide translocated within 10 min by a temperature-independent, less concentration-dependent passive mechanism without showing any significant cytotoxicity at the highest concentration investigated (100 microm). The uptake of the Tat peptide was proportional to the peptide concentration, and the concentration dependence was lost upon ATP depletion. The peptide exhibited a moderate cytotoxicity at higher concentrations. The time course did not show saturation even after 120 min. The buforin peptide, covalently attached to the 28-kDa green fluorescent protein, also entered cells, suggesting a potency of the peptide as a vector for macromolecular delivery into cells. However, the mechanism appeared to be different from that of the parent peptide.     

Mobile charges in the cell membranes ofHalicystis parvula

Charge-pulse experiments were performed on cells of the giant marine algaHalicystis parvula. At normal pH (8.2), the voltage decay following a charge-pulse of 500 ns duration fed to the vacuole could be described by summing two exponential relaxations. The amplitudes and time constants of these relaxations were widely separated. The parameters of the two relaxation processes were found to be pH-dependent. Reduction of the external pH value from pH 8.2 to 5 resulted in a complete change of the two relaxation processes within a few minutes. Only one relaxation process could be observed at pH 5, within the time resolution of our instrumentation. The experimental data could not be explained by a two-membrane model with reasonable values for the specific capacitances of tonoplast and plasmalemma. The results of the charge-pulse relaxations were found to be consistent with the assumption that both membranes have very similar electrical properties and that both contain mobile charges with a total surface concentration of about 30 nmol·m^-2 and a translocation-rate constant of about 500·s^-1. The mobile charges became neutralized at pH 5 hhich led to a decrease of the apparent specific capacitance of the algal cells. They are presumably either part of a transport system for cations or connected with the chloride pump ofHalicystis parvula.Abbreviation RC (R)esistance·(C)apacitance     

Structural flexibility and the positive charges are the key factors in bacterial cell selectivity and membrane penetration of peptoid-substituted analog of Piscidin 1

Piscidin 1 (Pis-1) is a novel cytotoxic peptide with a cationic α-helical structure isolated from the mast cells of hybrid striped bass. In our previous study, we showed that Pis-1[PG] with a substitution of Pro⁸ for Gly⁸ in Pis-1 had higher bacterial cell selectivity than Pis-1. We designed peptoid residue-substituted peptide, Pis-1[NkG], in which Gly⁸ of Pis-1 was replaced with Nlys (Lys peptoid residue). Pis-1[NkG] had higher antibacterial activity and lower cytotoxicity against mammalian cells than Pis-1 and Pis-1[PG]. We determined the tertiary structure of Pis-1[PG] and Pis-1[NkG] in the presence of DPC micelles by NMR spectroscopy. Both peptides had a three-turn helix in the C-terminal region and a bent structure in the center. Pis-1[PG] has a rigid bent structure at Pro⁸ whereas Pis-1[NkG] existed as a dynamic equilibrium of two conformers with a flexible hinge structure at Nlys⁸. Depolarization of the membrane potential of Staphylococcus aureus and confocal laser-scanning microscopy study revealed that Pis-1[NkG] effectively penetrated the bacterial cell membrane and accumulated in the cytoplasm, whereas Pis-1[PG] did not penetrate the membrane but remained outside or on the cell surface. Introduction of a lysine peptoid at position 8 of Pis-1 provided conformational flexibility and increased the positive charge at the hinge region; both factors facilitated penetration of the bacterial cell membrane and conferred bacterial cell selectivity on Pis-1[NkG].     

Translocation of protegrin I through phospholipid membranes: role of peptide folding

The protegrin PG-1, belonging to the family of β-stranded antimicrobial peptides, exerts its activity by forming pores in the target biological membranes. Linear analogues derived from PG-1 do not form pores in the phospholipid membranes and have been used successfully to deliver therapeutic compounds into eucaryotic cells. In this paper, the translocation of PG-1 and of a linear analogue through artificial phospholipid membranes was investigated, leading to a possible mechanism for the activity of these peptidic vectors. We report here that [12W]PG-1, a fluorescent analogue of PG-1, is able to translocate through lipid bilayers and we demonstrate that this property depends on its secondary structure. Our results agree with the recent mechanism proposed for the translocation and permeabilisation activities of several helical and β-stranded peptides. In addition, our data corroborate recent work suggesting that certain protegrin-derived vectors enter into endothelial cells by adsorptive-mediated endocytosis.     

Translocation of protegrin I through phospholipid membranes: role of peptide folding

The protegrin PG-1, belonging to the family of beta-stranded antimicrobial peptides, exerts its activity by forming pores in the target biological membranes. Linear analogues derived from PG-1 do not form pores in the phospholipid membranes and have been used successfully to deliver therapeutic compounds into eucaryotic cells. In this paper, the translocation of PG-1 and of a linear analogue through artificial phospholipid membranes was investigated, leading to a possible mechanism for the activity of these peptidic vectors. We report here that [12W]PG-1, a fluorescent analogue of PG-1, is able to translocate through lipid bilayers and we demonstrate that this property depends on its secondary structure. Our results agree with the recent mechanism proposed for the translocation and permeabilisation activities of several helical and beta-stranded peptides. In addition, our data corroborate recent work suggesting that certain protegrin-derived vectors enter into endothelial cells by adsorptive-mediated endocytosis.     

Translocation of peptides through microsomal membranes is a rapid process and promotes assembly of HLA-B27 heavy chain and beta 2-microglobulin translated in vitro

We have translated major histocompatibility complex (MHC) class I heavy chains and human beta 2-microglobulin in vitro in the presence of microsomal membranes and a peptide from the nucleoprotein of influenza A. This peptide stimulates assembly of HLA-B27 heavy chain and beta 2-microglobulin about fivefold. By modifying this peptide to contain biotin at its amino terminus, we could precipitate HLA-B27 heavy chains with immobilized streptavidin, thereby directly demonstrating class I heavy chain-peptide association under close to physiological conditions. The biotin-modified peptide stimulates assembly to the same extent as the unmodified peptide. Both peptides bind to the same site on the HLA-B27 molecule. Immediately after synthesis of the HLA-B27 heavy chain has been completed, it assembles with beta 2-microglobulin and peptide. These interactions occur in the lumen of the microsomes (endoplasmic reticulum), demonstrating that the peptide must cross the microsomal membrane in order to promote assembly. The transfer of peptide across the microsomal membrane is a rapid process, as peptide binding to heavy chain-beta 2-microglobulin complexes is observed in less than 1 min after addition of peptide. By using microsomes deficient of beta 2-microglobulin (from Daudi cells), we find a strict requirement of beta 2-microglobulin for detection of peptide interaction with the MHC class I heavy chain. Furthermore, we show that heavy chain interaction with beta 2-microglobulin is likely to precede peptide binding. Biotin-modified peptides are likely to become a valuable tool in studying MHC antigen interaction and assembly.     

Selective separation of tryptic beta-casein peptides through ultrafiltration membranes: Influence of ionic interactions

Peptide separation by selective membrane filtration has numerous potential applications such as production of peptides with biological activities or spectific enrichment in compounds acting as flavoring agents or as growth factors required by the fermentation industry. The retention of peptides arising from tryptic hdroysis of beta-casein using an M5 Carbosep membrane (molecular wieght cutoll = 10,000 D) has been studied. The peptides with known sequences were characterized by their molecular weight, isoelectric point, and hydrophobicity. Our experiments highlighted that their transmission involves mechanisms other than size exclusion as developed elsewhere. The effect of ionic interactions between peptides and membrance has been investgated by vrying pH, ionic strength of bulk, and electric potential of filtering material. The charge of both peptides and membrane plays an important role in the transmission, particularly with small size and high or lkow isoelectric point. Then, peptides with the same sign as the membrane have lower transmission than expected from the size xclusion model, whereas peptides with opposite sign have higher trnsmission than expected, and even higher than 1 with some of them. (c) 1995 John Wiley & Sons, Inc.     

Structural flexibility of Aib-containing peptides: the N-terminal tripeptide of trichotoxin

The sequence Aib-Gly-Aib which corresponds to the N-terminus of the microheterogeneous peptide antibiotic trichotoxin has been studied crystallographically in the context of different protecting groups. Peptides Ac-Aib-Gly-Aib-OH (A) and Z-Aib-Gly-Aib-OH (B) form beta-turns. Both peptides show a remarkable conformational flexibility forming a large variety of beta-turns of different types.     

Biogenesis of eel liver citrate carrier (CIC): negative charges can substitute for positive charges in the presequence

A family of structurally related carrier proteins mediates the flux of metabolites across the mitochondrial inner membrane. Differently from most other mitochondrial proteins, members of the carrier family are synthesized without an amino-terminal targeting sequence. However, in some mammalian and plant species, representatives were identified that carry a positively charged presequence. To obtain data on a carrier protein from lower vertebrates, we determined the primary structure of eel mitochondrial citrate carrier (CIC) and investigated its import pathway into the target organelle. The protein carries a cleavable presequence of 20 amino acids, including two positively charged residues. The cleavage site is recognized by a magnesium-dependent peptidase in the intermembrane space. The presequence is dispensable both for targeting and translocation, but prior to import into mitochondria, significantly increases the solubility of the precursor protein. This effect is completely retained if the positive charges are exchanged with negative charges. Following this observation, we found that several carrier proteins appear to carry non-cleavable presequences that may similarly act as charged intramolecular chaperones.     

High spatial resolution observation of single-molecule dynamics in living cell membranes

Self-organized lipid bilayers together with proteins are the essential building blocks of biological membranes. Membranes are associated with all living systems as they make up cell boundaries and provide basic barriers to cellular organelles. It is of interest to study the dynamics of individual molecules in cell membranes as the mechanism of how biological membranes function at the single molecule remains to be elucidated. In this letter we describe a study in which we incubate rat basophilic leukemia cells with a fluorescently labeled cell membrane component on a surface containing zero-mode waveguides (ZMWs). We used the ZMW to confine fluorescent excitation to an approximately 100-nm region of the membrane to monitor lipid diffusion along the cellular membrane. We showed that confinement with a ZMW largely reduced fluorescent contributions from the cytosolic pool that is present when using a more standard technique such as laser-induced confocal microscopy. We show that optical confinement with ZMWs is a facile way to probe dynamic processes on the membrane surface.     

Interactions of mast cell degranulating peptides with model membranes: A comparative biophysical study

In the last decade, there has been renewed interest in biologically active peptides in fields like allergy, autoimmune diseases and antibiotic therapy. Mast cell degranulating peptides mimic G-protein receptors, showing different activity levels even among homologous peptides. Another important feature is their ability to interact directly with membrane phospholipids, in a fast and concentration-dependent way. The mechanism of action of peptide HR1 on model membranes was investigated comparatively to other mast cell degranulating peptides (Mastoparan, Eumenitin and Anoplin) to evidence the features that modulate their selectivity. Using vesicle leakage, single-channel recordings and zeta-potential measurements, we demonstrated that HR1 preferentially binds to anionic bilayers, accumulates, folds, and at very low concentrations, is able to insert and create membrane spanning ion-selective pores. We discuss the ion selectivity character of the pores based on the neutralization or screening of the peptides charges by the bilayer head group charges or dipoles.     

Regulation of opioid peptides on the release of arginine vasotocin in the hen

Arginine vasotocin (AVT), an avian neurohypophysial hormone, is released during osmotic stimulation and oviposition. In the present study, the role of opioid peptides on AVT release was studied by examining the effects of an opioid agonist and antagonist on osmotic- and oviposition-induced secretion of AVT. The administration of hypertonic saline (1.5 M NaCl) induced an increase in the plasma levels of AVT. The simultaneous administration of morphine, an opioid receptor agonist, inhibited the osmotically induced increase in plasma levels of AVT in a dose-dependent manner. On the other hand, the co-administration of morphine with naloxone, an opioid receptor antagonist, attenuated the inhibitory effect of morphine. Moreover, injection of naloxone alone enhanced the osmotically induced increase in plasma levels of AVT. However, the administration of morphine did not inhibit the oviposition-induced increase in plasma levels of AVT. These results suggest that osmotic-induced release of AVT may be under opioid regulation, while oviposition-induced release of AVT may be controlled by a different mechanism. J. Exp. Zool. 286:481-486, 2000.     

Effect of positive charges in the structural interaction of crabrolin isoforms with lipopolysaccharide

Antimicrobial peptides (AMPs) appear as chemical compounds of increasing interest for their role in killing bacteria and, more recently, for their ability to bind endotoxin (lipopolysaccharide, LPS) that is released during bacterial infection and that may lead to septic shock. This dual role in the mechanism of action can further be enhanced in a synergistic way when two or more AMPs are combined together. Not all AMPs are able to bind LPS, suggesting that several modes of binding to the bacterial surface may exist. Here we analyze a natural AMP, crabrolin, and two mutated forms, one with increased positive charge (Crabrolin Plus) and the other with null charge (Crabrolin Minus), and compare their binding abilities to LPS. While Crabrolin WT as well Crabrolin Minus do not show binding to LPS, the mutated Crabrolin Plus exhibits binding and forms a well defined structure in the presence of LPS. The results strengthen the importance of positive charges for the binding to LPS and suggest the mutated form with increased positive charge as a promising candidate for antimicrobial and antiseptic activity.     

Control of arginine metabolism in Neurospora: flux through the biosynthetic pathway.

The flux into the arginine biosynthetic pathway of Neurospora crassa was investigated using a mutant strain lacking the ornithine-degrading enzyme ornithine aminotransferase (EC 2.6.1.13). Flux was measured by the increase in the sum of the radioactivity (derived from [14C]glutamic acid) in the ornithine pool, the arginine pool, and arginine incorporated into proteins. Complete cessation of flux occurred immediately upon the addition of arginine to the growth medium. This response occurred prior to expansion of the arginine pool. After short-term exposure to arginine (80 min), flux resumed quickly upon exhaustion of arginine from the medium. This took place despite the presence of an expanded arginine pool. Initiation of flux required approximately 80 min when the mycelia were grown in arginine-supplemented medium for several generations before exhaustion of the exogenous arginine. The arginine pool of such mycelia was similar to that found in mycelia exposed to exogenous arginine for only 80 min. The results are consistent with rapid onset and release of feedback inhibiton of arginine biosynthesis in response to brief exposure to exogenous arginine. The insensitivity of flux to the size of the arginine pool is consistent with a role for compartmentation in this regulatory process. The lag in initiation of flux after long-term growth in the presence of exogenous arginine suggests the existence of an additional regulatory mechanism(s). Several possibilities are discussed.     

Role of membranes in the activities of antimicrobial cationic peptides

Cationic amphiphilic peptides that are found throughout nature have very broad-spectrum activities against microbes. The initial sites of interaction are with microbial membranes. Although dogma suggests that their lethal action involves disruption of the cytoplasmic membranes, a number of cationic peptides can traverse intact membranes to interact with internal targets.     

Transport properties of mobile charges in algal membranes: Influence of pH and turgor pressure

Summary Charge-pulse experiments were performed on giant algal cells ofValonia utricularis. If the tonoplast and plasmalemma in series are charged to voltages of the order of 10mV, the decay of the initial voltage with time can be described by the sum of two or three exponential relaxations. It is not possible to explain the exponential decay of the voltage by twoRC-circuits in series (e.g. tonoplast and plasmalemma), because this would lead to unreasonable values for the specific capacities of the two membranes. The exponential relaxations might be attributable to the transport of mobile negative charges present in both membranes, possibly as a part of a transport system. From an analysis of the experimental results in terms of the proposed model, the translocation rate constantk and the total surface densityN _t of the mobile charges in one membrane could be evaluated. On averagek is of the order of 600 sec^–1 andNt is about 5×10^–12 mol cm^–2 (average turgor pressure 1.6 bar). The transport properties of the mobile charges within the tonoplast and plasmalemma were studied as a function of different parameters such as external pH, glutardialdehyde, electrical breakdown and turgor pressure. When the pH is lowered from 8.2 to 4 or 5 the mobile charges disappear completely, presumably as the result of protonation of the anionic groups. This pH effect was found to be completely reversible. Electrical breakdown causes a reversible disappearance of the relaxation with the longer half-time due to the decrease in membrane resistance. The value of the electrical breakdown voltage determined by injection of charge pulses of 300-sec duration into the cell is pH-independent and therefore is consistent with the mobile charge model and with results previously reported (U. Zimmermann & R. Benz.J. Membrane Biol 53:33–43, 1980). Addition of glutardialdehyde leads also to a disappearance of the mobile charges probably due to cross-linkage. Increase of the turgor pressure from 0.05 bar to 2 bar results in an increase ink by a factor of 2 and inNt by about 30%. The increase ink is in reasonable agreement with that expected on the basis of the assumed compressibility of the membranes. The elastic compressive modulus perpendicular to the membrane plane calculated from the pressure dependence of the translocation rate constantk is in very good agreement with that derived from electrical breakdown experiments (14 and 13 bar, respectively). The presence of charges within the membranes as well as the compressibility of the membranes are discussed in terms of a possible turgor-pressure-sensing mechanism.