Apidaecin-type peptides: biodiversity, structure-function relationships and mode of action

Apidaecins (apidaecin-type peptides) refer to a series of small, proline-rich (Pro-rich), 18- to 20-residue peptides produced by insects. They are the largest group of Pro-rich antimicrobial peptides (AMPs) known to date. Structurally, apidaecins consist of two regions, the conserved (constant) region, responsible for the general antibacterial capacity, and the variable region, responsible for the antibacterial spectrum. The small, gene-encoded and unmodified apidaecins are predominantly active against many gram-negative bacteria by special antibacterial mechanisms. The mechanism of action by which apidaecins kill bacteria involves an initial non-specific binding of the peptides to an outer membrane (OM) component. This binding is followed by invasion of the periplasmic space, and by a specific and essentially irreversible combination with a receptor/docking molecule that may be a component of a permease-type transporter system on inner membrane (IM). In the final step, the peptide is translocated into the interior of the cell where it meets its ultimate target. Evidence that apidaecins are non-toxic for human and animal cells is a prerequisite for using them as novel antibiotic drugs. This review presents the biodiversity, structure-function relationships, and mechanism of action of apidaecins.     

Design of synthetic bactericidal peptides derived from the bactericidal domain P(18-39) of aprotinin.

A bactericidal domain, P(18-39), of the proteinase inhibitor aprotinin, possesses the structural feature of two antiparallel beta-sheets connected by a short turn. In order to understand the structural requirements for antibacterial activity, two peptides, each having the sequence corresponding to a single beta-sheet structure of P(18-39), were synthesized and their antibacterial properties investigated. One peptide, P(18-28), with the sequence IIRYFYNAKAG, was active against almost all the bacterial strains investigated. However, the bactericidal activity of P(18-28) was reduced compared to the parent molecule, P(18-39). The other peptide, P(29-39), with the sequence LCQTFVYGGCR, was only weakly bactericidal against Pseudomonas aeruginosa. A peptide, P(18-26), devoid of the C-terminus dipeptide Ala-Gly of P(18-28), retained the bactericidal activity of P(18-28) against most of the bacterial strains investigated. Only Klebsiella pneumoniae, P. aeruginosa and Staphylococcus aureus were resistant to P(18-26). Replacement of lysine 26 by arginine in P(18-26) (IIRYFYNAR) improved the bactericidal activity. The retropeptide, RANYFYRII, retained the antibacterial activity of IIRYFYNAR toward Gram-negative bacteria, but it was less active against Gram-positive bacteria. The random peptide, IANRIYRYF, was as bactericidal as IIRYFYNAR. Moreover, the random peptide possessed, in contrast to IIRYFYNAR, a strong antifungal activity against Candida albicans. Elimination of the N-hydrophobic terminal Ile-Ile from P(18-26) (RYFYNAK) strongly reduced the bactericidal potency of the peptide. Attaching the hydrophobic peptide, FFVAP, to the C-terminal of P(18-26) (IIRYFYNAKFFVAP) increased the bactericidal potency of the peptides considerably. We concluded that the order of the amino acids in the sequence of the peptides is not, per se, a critical feature for bactericidal activity. Hydrophobic interaction between peptide and bacterial membrane is probably the most important feature involved in the bactericidal mechanism of the antibiotic peptides.     

Mapping of Apidaecin Regions Relevant for Antimicrobial Activity and Bacterial Internalization

Apidaecins are 18–20-residue long proline-rich peptides expressed in insects as part of the innate immune system. They are very active against Gram-negative bacteria, especially Enterobacteriaceae. The C-terminal sequence PRPPHPRL is highly conserved, whereas the N-terminal region is variable. By replacing all 18 residues of apidaecin 1a and apidaecin 1b individually by alanine (Ala-scan), we have shown that single mutations in the C-terminal half of the peptides drastically reduced and mostly abolished the antibacterial activity against Escherichia coli. Conversely, substitutions in the N-terminal eight residues produced no, or only minor effects. The activity loss was correlated to the ability of apidaecin 1b and its mutants to enter Gram-negative bacteria, most likely because they no longer bind to a protein transporter. This assumed binding, however, was not inhibited by truncated apidaecin peptides added at tenfold higher concentrations. Interestingly, the antibacterial activity of full length apidaecin 1b was enhanced about four times by addition of a N-terminally truncated apidaecin peptide [11–18]-apidaecin 1b, as indicated by lower MIC-values against E. coli, although the short 5(6)-carboxyfluorescein-labeled peptide did not enter the bacteria. In contrast, the activity against the Gram-positive bacterium Micrococcus luteus was not located in the C-terminal sequence of apidaecins 1a and b, but depended mostly on the presence of all four basic residues.     

Cell Penetrating Apidaecin Peptide Interactions with Biomimetic Phospholipid Membranes

Apidaecin peptides from Apis mellifera hemolymph are believed to attack intracellular bacterial targets. Our in vivo results for apidaecins 1a and 1b confirm that bacterial activity is non-lytic, however, the manner in which these peptides pass through the cell membrane to exert this activity is unknown. These data are combined with fluorescence (dye leakage) and quartz crystal microbalance studies to investigate the membrane interaction for these two wildtype peptides. It was found that the peptides penetrate the membrane in a trans-membrane manner. The amount of peptide uptake by the membrane is proportional to the concentration of the peptide, however, this appears to be a dynamic equilibrium which can be almost completely reversed by addition of buffer medium. Interestingly, a small residual mass remains within the membrane and the amount of peptide remaining in the membrane is a function of the buffer-salt concentration viz. in high salt, the residual peptide mass remaining is small whereas at low salt concentration, a larger mass of peptide remains bound. These results support a direct membrane penetration mechanism by the wild type apidaecins 1a and 1b. In both cases the peptide–membrane interaction has a negligible effect on the membrane, although, in high salt a permanent change in the membrane does occur at the highest peptide concentration which does not recover following peptide removal. Stefania Piantavigna and Patricia Czihal contributed equally to this article.     

The discovery and analysis of a diverged family of novel antifungal moricin-like peptides in the wax moth Galleria mellonella

Screening for components with antifungal activity in the hemolymph of immune-stimulated Galleria mellonella larvae led to the identification of four novel moricin-like peptides (A, B, C3 and D). Subsequently, eight moricin-like peptide genes (A, B, C1-5 and D) were isolated and shown to code for seven unique peptides (mature C4 and C5 are identical). These genes contained single introns which varied from 180 to 1090bp. The moricin-like peptides were particularly active against filamentous fungi, preventing the growth of Fusarium graminearum at 3 microg/ml, and were also active against yeasts, gram positive bacteria and gram negative bacteria. Searches of the databases identified 30 moricin-like peptide genes which code for 23 unique mature peptides, all belonging to the Lepidoptera (moths and butterflies). The first comprehensive phylogenetic analysis of the moricin-like peptides suggested that they fall into two basic classes which diverged a long time ago. The peptides have since diversified extensively through a high level of gene duplication within species, as seen in G. mellonella and Bombyx mori. The restriction of moricin-like peptides to the Lepidoptera combined with their potent antifungal activity suggests that this diverse peptide family may play a role in the defence response of moths and butterflies.     

Nisin-controlled extracellular production of apidaecin in <Emphasis Type="Italic">Lactococcus lactis</Emphasis>

Apidaecins are heat-stable, nonhelical antibacterial peptides isolated from lymph fluid of the honeybee (Apis mellifera). These peptides are active against a wide range of gram-negative bacteria and they are the most prominent components of the honeybee humoral defense against microbial invasion. In the present study, one isoform of apidaecin, apidaecin Ho, was expressed extracellularly in the food-grade bacterium Lactococcus lactis. Results showed that expression driven by the lactococcal nisA promoter and Usp45 signal peptide resulted in efficient secretion of apidaecin in L. lactis subsp. cremoris NZ9000. Recombinant apidaecin was purified by gel filtration and semipreparative RP-HPLC, and about 10 mg active recombinant apidaecin was obtained from 1,000 ml culture. This is the first report on the nisin-controlled extracellular production of active apidaecin in L. lacits. The expression and delivery of apidaecin in the food-grade L. lactis may provide a clue to facilitate the widespread application of apidaecin in the control and prevention of gram-negative bacteria infections of human and animals.     

Identification and isolation of a bactericidal domain in chicken egg white lysozyme

Chicken egg white lysozyme exhibits antimicrobial activity against both Gram-positive and Gram-negative bacteria. Fractionation of clostripain-digested lysozyme yielded a pentadecapeptide with antimicrobial activity but without muramidase activity. The peptide was isolated and its sequence found to be I-V-S-D-G-N-G-M-N-A-W-V-A-W-R (amino acids 98-112 of chicken egg white lysozyme). A synthesized peptide of identical sequence had the same bactericidal activity as the natural peptide. Replacement of Trp 108 with tyrosine significantly reduced the antibacterial capacity of the peptide. By replacement of Trp 111 with tyrosine the antibacterial activity was lost. Replacement of Asn 106 with the positively charged arginine strongly increased the antibacterial capacity of I-V-S-D-G-N-G-M-N-A-W-V-A-W-R. The peptide I-V-S-D-G-N-G-M consisting of the eight amino acids of the N-terminal side had no bactericidal properties, whereas the peptide N-A-W-V-A-W-R of the C-terminal side retained some bactericidal activity. Replacement of asparagine 106 by arginine (R-A-W-V-A-W-R) increased the bactericidal activity considerably. The D enantiomer of R-A-W-V-A-W-R was as active as the L form against five of the tested bacteria, but substantially less active against Serratia marcescens, Micrococcus luteus, Staphylococcus aureus, Staphylococcus epidermidis and Staphylococcus lentus. For these bacterial species some stereospecific complementarity between receptor structures of the bacteria and the peptide can be assumed.     

Identification of downstream target genes of latent membrane protein 1 in nasopharyngeal carcinoma cells by suppression subtractive hybridization

Proteolytic digestion of bovine beta-lactoglobulin by trypsin yielded four peptide fragments with bactericidal activity. The peptides were isolated and their sequences were found as follows: VAGTWY (residues 15-20), AASDISLLDAQSAPLR (residues 25-40), IPAVFK (residues 78-83) and VLVLDTDYK (residues 92-100). The four peptides were synthesized and found to exert bactericidal effects against the Gram-positive bacteria only. In order to understand the structural requirements for antibacterial activity, the amino acid sequence of the peptide VLVLDTDYK was modified. The replacement of the Asp (98) residue by Arg and the addition of a Lys residue at the C-terminus yielded the peptide VLVLDTRYKK which enlarged the bactericidal activity spectrum to the Gram-negative bacteria Escherichia coli and Bordetella bronchiseptica and significantly reduced the antibacterial capacity of the peptide toward Bacillus subtilis. By data base searches with the sequence VLVLDTRYKK a high homology was found with the peptide VLVATLRYKK (residues 55-64) of human blue-sensitive opsin, the protein of the blue pigment responsible for color vision. A peptide with this sequence was synthesized and assayed for bactericidal activity. VLVATLRYKK was strongly active against all the bacterial strains tested. Our results suggest a possible antimicrobial function of beta-lactoglobulin after its partial digestion by endopeptidases of the pancreas and show moreover that small targeted modifications in the sequence of beta-lactoglobulin could be useful to increase its antimicrobial function.     

Proteolytic fragments of ovalbumin display antimicrobial activity

Ovalbumin, one of the major proteins present in avian egg white, was proteolytically digested by trypsin and chymotrypsin and the peptide fragments were investigated for their antimicrobial activity. The antimicrobial peptides were isolated and characterized. From the tryptic digestion, the following five antimicrobial peptide fragments were obtained: SALAM (residues 36-40), SALAMVY (residues 36-42) YPILPEYLQ (residues 111-119), ELINSW (residues 143-148) and NVLQPSS (residues 159-165). Digestion of ovalbumin by chymotrypsin yielded the antimicrobial peptides AEERYPILPEYL (residues 127-138), GIIRN (residues 155-159) and TSSNVMEER (residues 268-276). The peptides were synthesized and found to exert antimicrobial activity. They were strongly active against Bacillus subtilis and to a lesser extent against the other bacterial strains examined. A weak fungicidal activity against Candida albicans was also shown by some peptides. Ovalbumin itself was not bactericidal against all the bacteria strains examined. Our results suggest that the food protein ovalbumin may supply the organism with antimicrobial peptides, supporting the immunodefences of the organism.     

Isolation and characterization of four bactericidal domains in the bovine β-lactoglobulin

Proteolytic digestion of bovine β-lactoglobulin by trypsin yielded four peptide fragments with bactericidal activity. The peptides were isolated and their sequences were found as follows: VAGTWY (residues 15–20), AASDISLLDAQSAPLR (residues 25–40), IPAVFK (residues 78–83) and VLVLDTDYK (residues 92–100). The four peptides were synthesized and found to exert bactericidal effects against the Gram-positive bacteria only. In order to understand the structural requirements for antibacterial activity, the amino acid sequence of the peptide VLVLDTDYK was modified. The replacement of the Asp (98) residue by Arg and the addition of a Lys residue at the C-terminus yielded the peptide VLVLDTRYKK which enlarged the bactericidal activity spectrum to the Gram-negative bacteria Escherichia coli and Bordetella bronchiseptica and significantly reduced the antibacterial capacity of the peptide toward Bacillus subtilis. By data base searches with the sequence VLVLDTRYKK a high homology was found with the peptide VLVATLRYKK (residues 55–64) of human blue-sensitive opsin, the protein of the blue pigment responsible for color vision. A peptide with this sequence was synthesized and assayed for bactericidal activity. VLVATLRYKK was strongly active against all the bacterial strains tested. Our results suggest a possible antimicrobial function of β-lactoglobulin after its partial digestion by endopeptidases of the pancreas and show moreover that small targeted modifications in the sequence of β-lactoglobulin could be useful to increase its antimicrobial function.     

Structure-Activity Relationship and Mode of Action of a Frog Secreted Antibacterial Peptide B1CTcu5 Using Synthetically and Modularly Modified or Deleted (SMMD) Peptides

All life forms are equipped with rapidly acting, evolutionally conserved components of an innate immune defense system that consists of a group of unique and diverse molecules known as host defense peptides (HDPs). A Systematic and Modular Modification and Deletion (SMMD) approach was followed to analyse the structural requirement of B1CTcu5, a brevinin antibacterial peptide amide identified from the skin secretion of frog Clinotarsus curtipes, India, to show antibacterial activity and to explore the active core region. Seventeen SMMD-B1CTcu5 analogs were designed and synthesised by C and N-terminal amino acid substitution or deletion. Enhancement in cationicity by N-terminal Lys/Arg substitution or hydrophobicity by Trp substitution produced no drastic change in bactericidal nature against selected bacterial strains except S. aureus. But the sequential removal of N-terminal amino acids had a negative effect on bactericidal potency. Analog B1CTcu5-LIAG obtained by the removal of four N-terminal amino acids displayed bactericidal effect comparable to, or in excess of, the parent peptide with reduced hemolytic character. Its higher activity was well correlated with the improved inner membrane permeabilisation capacity. This region may act as the active core of B1CTcu5. Presence of C-terminal disulphide bond was not a necessary condition to display antibacterial activity but helped to promote hemolytic nature. Removal of the C-terminal rana box region drastically reduced antibacterial and hemolytic activity of the peptide, showing that this region is important for membrane targeting. The bactericidal potency of the D-peptide (DB1CTcu5) helped to rule out the stereospecific interaction with the bacterial membrane. Our data suggests that both the C and N-terminal regions are necessary for bactericidal activity, even though the active core region is located near the N-terminal of B1CTcu5. A judicious modification at the N-terminal region may produce a short SMMD analog with enhanced bactericidal activity and low toxicity against eukaryotic cells.     

Insect immunity. Isolation from a coleopteran insect of a novel inducible antibacterial peptide and of new members of the insect defensin family.

Injection of heat-killed bacteria into larvae of the large tenebrionid beetle Zophobas atratus (Insecta, Endopterygota, Coleoptera) results in the appearance in the hemolymph of a potent antibacterial activity as evidenced by a plate growth inhibition assay. We have isolated three peptides (A-C) from this immune hemolymph which probably account for most of this activity. Their primary structures were established by a combination of peptide sequencing and molecular mass determination by mass spectrometry. Peptide A, which is bactericidal against Gram-negative cells, is a 74-residue glycine-rich molecule with no sequence homology to known peptides. We propose the name coleoptericin for this novel inducible antibacterial peptide. Peptides B and C are isoforms of a 43-residue peptide which contains 6 cysteines and shows significant sequence homology to insect defensins, initially reported from dipteran insects. This peptide is active against Gram-positive bacteria. The results are discussed in connection with recent studies on inducible antibacterial peptides present in the three other major orders of the endopterygote clade of insects: the Lepidoptera, Diptera, and Hymenoptera.     

Improvement of biological activity and proteolytic stability of peptides by coupling with a cyclic peptide

The cyclic moiety of an endothelin antagonist peptide RES-701-1, composed of 10 amino acids with an amide bond between alpha-NH(2) of Gly1 and beta-COOH of Asp9, was coupled to some biologically active peptides aiming to improve their activities and stabilities against proteolytic degradation. Coupling of the cyclic peptide to the N-terminal of RGD-peptides, maximally 4-fold improvement of in vitro activity compared to the original peptide has been achieved. Coupling of it to protein farnesyltransferase inhibiting peptides resulted to improve in vitro activity maximally 3-fold. These peptides coupled with the cyclic peptide also showed enhanced stability against some typical proteases. These results indicate that this cyclic peptide can stabilize the conformations of the peptides coupled to its C-terminus. Coupling of our cyclic peptide is anticipated to be a novel conformational stabilizing method for biologically active peptides, results to improve their activity and stability.     

Systematic peptide engineering and structural characterization to search for the shortest antimicrobial peptide analogue of gaegurin 5

As part of an effort to develop new, low molecular mass peptide antibiotics, we searched for the shortest bioactive analogue of gaegurin 5 (GGN5), a 24-residue antimicrobial peptide. Thirty-one kinds of GGN5 analogues were synthesized, and their biological activities were analyzed against diverse microorganisms and human erythrocytes. The structural properties of the peptides in various solutions were characterized by spectroscopic methods. The N-terminal 13 residues of GGN5 were identified as the minimal requirement for biological activity. The helical stability, the amphipathic property, and the hydrophobic N terminus were characterized as the important structural factors driving the activity. To develop shorter antibiotic peptides, amino acid substitutions in an inactive 11-residue analogue were examined. Single tryptophanyl substitutions at certain positions yielded some active 11-residue analogues. The most effective site for the substitution was the hydrophobic-hydrophilic interface in the amphipathic helical structure. At this position, tryptophan was the most useful amino acid conferring favorable activity to the peptide. The introduced tryptophan played an important anchoring role for the membrane interaction of the peptides. Finally, two 11-residue analogues of GGN5, which exhibited strong bactericidal activity with little hemolytic activity, were obtained as property-optimized candidates for new peptide antibiotic development. Altogether, the present approach not only characterized some important factors for the antimicrobial activity but also provided useful information about peptide engineering to search for potent lead molecules for new peptide antibiotic development.     

Effects of dimerization of the cell‐penetrating peptide Tat analog on antimicrobial activity and mechanism of bactericidal action

The cell‐penetrating peptide Tat (48–60) (GRKKRRQRRRPPQ) derived from HIV‐1 Tat protein showed potent antibacterial activity (MIC: 2–8 µM ). To investigate the effect of dimerization of Tat (48–60) analog, [Tat(W): GRKKRRQRRRPWQ‐NH₂], on antimicrobial activity and mechanism of bactericidal action, its dimeric peptides, di‐Tat(W)‐C and di‐Tat(W)‐K, were synthesized by a disulfide bond linkage and lysine linkage of monomeric Tat(W), respectively. From the viewpoint of a weight basis and the monomer concentration, these dimeric peptides displayed almost similar antimicrobial activity against six bacterial strains tested but acted more rapidly against Staphylococcus aureus on kinetics of bactericidal activity, compared with monomeric Tat(W). Unlike monomeric Tat(W), these dimeric peptides significantly depolarized the cytoplasmic membrane of intact S. aureus cells at MIC and induced dye leakage from bacterial‐membrane‐mimicking egg yolk L ‐α‐phosphatidylethanolamine/egg yolk L ‐α‐phosphatidyl‐DL ‐glycerol (7:3, w/w) vesicles. Furthermore, these dimeric peptides were less effective to translocate across lipid bilayers than monomeric Tat(W). These results indicated that the dimerization of Tat analog induces a partial change in the mode of its bactericidal action from intracellular target mechanism to membrane‐targeting mechanism. Collectively, our designed dimeric Tat peptides with high antimicrobial activity and rapid bactericidal activity appear to be excellent candidates for future development as novel antimicrobial agents. Copyright © 2009 European Peptide Society and John Wiley & Sons, Ltd.     

Antibiotic and synergistic effect of Leu-Lys rich peptide against antibiotic resistant microorganisms isolated from patients with cholelithiasis

Pseudomonas aeruginosa has eventually developed resistance against flomoxef sodium, isepamicin and cefpiramide. Therefore, in this study, the antibacterial activity and synergistic effects of the amphipathic-derived P5-18mer antimicrobial peptide were tested against pathogens associated with cholelithiasis that have developed resistance against commonly used antibiotics. The results were then compared with the activities of the amphipathic-derived peptide, P5-18mer, melittin and common antibiotics. Growth inhibition of planktonic bacteria was tested using the National Committee for Clinical Laboratory Standards (NCCLS). The bactericidal activity of the antimicrobial peptides was measured using time-kill curves. Synergistic effects were evaluated by testing the effects of P5-18mer alone and in combination with flomoxef sodium, isepamicin or cefpiramide at 0.5 × MIC. P5-18mer peptide displayed strong activity against pathogens and flomoxef sodium, isepamicin and cefpiramide-resistant bacteria cell lines obtained from a patient with gallstones; however, it did not exert cytotoxicity against the human keratinocyte HaCat cell line. In addition, the results of time-kill curves indicated that P5-18mer peptide exerted bactericidal activity against four strains of P. aeruginosa. Finally, the use of P5-18mer and antibiotics exerted synergistic effects against cell lines that were resistant to commonly used antibiotics. These results indicate that this class of peptides has a rapid microbicidal effect on flomoxef sodium, isepamicin and cefpiramide-resistant strains of P. aeruginosa. Therefore, these peptides may be used as a lead drug for the treatment of acquired pathogens from patients with cholelithiasis who are affected with antibiotic-resistant bacteria.     

Design and synthesis of novel antimicrobial peptides on the basis of alpha helical domain of Tenecin 1, an insect defensin protein, and structure-activity relationship study

Tenecin 1, a peptide consisting of 43 amino acids, exhibits a potent bactericidal activity against various Gram-positive bacteria and shares a common structural feature of insect defensin family corresponding to cysteine stabilized alpha/beta motif. Our previous research indicated that an active fragment was successfully extracted from C-terminal beta sheet domain of Tenecin 1, whereas the fragment corresponding to the alpha helical region of the protein had no antibacterial activity. We chose this inactive fragment corresponding to alpha helical region of Tenecin 1 and synthesized derivatives with a different net positive charge by using rational design. Interestingly, we successfully endowed antibacterial activity as well as antifungal activity to the inactive alpha helical fragment by single or double amino acid replacement(s) without an increase of hemolytic activity. The leakage of dye from vesicles induced by the active peptides suggested that these peptides act on the membranes of pathogen as a primary mode of action. Structure-activity relationship study of a series of the active derivatives revealed that amphiphilic structure and high net positive charge were prerequisite factors for the activity and that there was a relationship between the antibacterial activity and the isoelectric point of the active peptides. In this work, we showed an efficient method to endow the antibacterial activity as well as antifungal activity to the inactive fragment derived from a cyclic insect defensin protein and suggested a facile method to screen for active fragments from cyclic host defense peptides.     

Denatured bactericidal proteins: Active per se,or reservoirs of active peptides?

According to the structure-to-function paradigm proteins fold into a 3D structure for exerting their functions. Intrinsically destructured proteins with important biological functions have been identified and studied, but they assume a structure when interacting in the cell with their partners. There are instead bactericidal proteins, endowed also with other diverse activities (glycoside hydrolases, RNases, a defensin), which are lost when the proteins are denatured or inactivated, whereas the bactericidal activity is surprisingly conserved.The hypothesis is advanced that these proteins are not bactericidal per se, but because they store in their amino acid sequences peptide segments that display bactericidal activity when cut out as free peptides from the proteins. These bactericidal proteins would thus be merely containers of bactericidal peptides.     

The antimicrobial potential of a new derivative of cathelicidin from <Emphasis Type="Italic">Bungarus fasciatus</Emphasis> against methicillin-resistant <Emphasis Type="Italic">Staphylococcus aureus</Emphasis>

Cathelicidins are a family of antimicrobial peptides which exhibit broad antimicrobial activities against antibiotic-resistant bacteria. Considering the progressive antibiotic resistance, cathelicidin is a candidate for use as an alternative approach to treat and overcome the challenge of antimicrobial resistance. Cathelicidin-BF (Cath-BF) is a short antimicrobial peptide, which was originally extracted from the venom of Bungarus fasciatus. Recent studies have reported that Cath-BF and some related derivatives exert strong antimicrobial and weak hemolytic properties. This study investigates the bactericidal and cytotoxic effects of Cath-BF and its analogs (Cath-A and Cath-B). Cath-A and Cath-B were designed to increase their net positive charge, to have more activity against methicillin resistant S. aureus (MRSA). The results of this study show that Cath-A, with a +17-net charge, has the most noteworthy antimicrobial activity against MRSA strains, with minimum inhibitory concentration (MIC) ranging between 32–128 μg/ml. The bacterial kinetic analysis by 1 × MIC concentration of each peptide shows that Cath-A neutralizes the clinical MRSA isolate for 60 min. The present data support the notion that increasing the positive net charge of antimicrobial peptides can increase their potential antimicrobial activity. Cath-A also displayed the weakest cytotoxicity effect against human umbilical vein endothelial and H9c2 rat cardiomyoblast cell lines. Analysis of the hemolytic activity reveals that all three peptides exhibit minor hemolytic activity against human erythrocytes at concentrations up to 250 μg/ml. Altogether, these results suggest that Cath-A and Cath-B are competent candidates as novel antimicrobial compounds against MRSA and possibly other multidrug resistant bacteria.