Defensins and other antimicrobial peptides: a historical perspective and an update

Antimicrobial peptides are effectors of innate immunity in phagocytes, body fluids and epithelia. In mammals, defensins, peptides with a characteristic six-cysteine framework, are particularly abundant and widely distributed in various animal species and tissues. The first part of this review provides a historical overview of the ideas that led to the current state-of-the-art in antimicrobial peptides, and the second part is an update on mammalian defensins and their role in host defense to infections.     

A re-evaluation of the role of host defence peptides in mammalian immunity

Host defence peptides are found in all classes of life and are a fundamental component of the innate immune response. Initially it was believed that their sole role in innate immunity was to kill invading microorganisms, thus providing direct defence against infection. Evidence now suggests that these peptides play diverse and complex roles in the immune response and that, in higher animals, their functions are not restricted to the innate immune response. In in vitro experiments certain host defence peptides have been demonstrated to be potent antimicrobial agents at modest concentrations, although their antimicrobial activity is often strongly reduced or ablated in the presence of physiological concentrations of ions such as Na(+) and Mg(2+). In contrast, in experiments done in standard tissue culture media, the composition of which more accurately represents physiological levels of ions, mammalian host defence peptides have been demonstrated to have a number of immunomodulatory functions including altering host gene expression, acting as chemokines and/or inducing chemokine production, inhibiting lipopolysaccharide induced pro-inflammatory cytokine production, promoting wound healing, and modulating the responses of dendritic cells and cells of the adaptive immune response. Animal models indicate that host defence peptides are crucial for both prevention and clearance of infection. As interest in the in vivo functions of host defence peptides is increasing, it is important to consider whether in mammals the direct antimicrobial and immunomodulatory properties observed in vitro are physiologically relevant, especially since many of these activities are concentration dependent. In this review we summarize the concentrations of host defence peptides and ions reported throughout the body and compare that information with the concentrations of peptides that are known have antimicrobial or immunomodulatory functions in vitro.     

Host defense peptides and lipopeptides: modes of action and potential candidates for the treatment of bacterial and fungal infections

Endogenous peptide antibiotics (termed also host-defense or antimicrobial peptides) are known as evolutionarily old components of innate immunity. They were found initially in invertebrates, but later on also in vertebrates, including humans. This secondary, chemical immune system provides organisms with a repertoire of small peptides that act against invasion (for both offensive and defensive purposes) by occasional and obligate pathogens. Each antimicrobial peptide has a broad but not identical spectrum of antimicrobial activity, predominantly against bacteria, providing the host maximum coverage against a rather broad spectrum of microbial organisms. Many of these peptides interact with the target cell membranes and increase their permeability, which results in cell lysis. A second important family includes lipopeptides. They are produced in bacteria and fungi during cultivation on various carbon sources, and possess a strong antifungal activity. Unfortunately, native lipopeptides are non-cell selective and therefore extremely toxic to mammalian cells. Whereas extensive studies have emerged on the requirements for a peptide to be antibacterial, very little is known concerning the parameters that contribute to antifungal activity. This review summarizes recent studies aimed to understand how antimicrobial peptides and lipopeptides select their target cell. This includes a new group of lipopeptides highly potent against pathogenic fungi and yeast. They are composed of inert cationic peptides conjugated to aliphatic acids with different lengths. Deep understanding of the molecular mechanisms underlying the differential cells specificity of these families of host defense molecule is required to meet the challenges imposed by the life-threatening infections.     

Defensins--non-antibiotic use for vaccine development

Vaccines should elicit protective and long lasting immune memory, which depends on well choreographed responses between innate and acquired immunity. Defensins are small host defense peptides of innate immunity hitherto reported to have antimicrobial activity, which also orchestrate chemotaxis and activation of effector immune cells, including immature dendritic cells. This review analyzes the biological meaning of the immunomodulatory and immunoenhancing features of defensins and their use for the development of novel vaccines to combat cancer and clinically relevant diseases.     

The cathelicidins--structure, function and evolution

The cathelicidin family of host defense peptides includes a group of cationic and usually amphipathic peptides that display a variety of activities related to host defense functions, among which the most acknowledged is a direct antimicrobial activity against various microbial pathogens. All members of this family are synthesized as precursors characterized by an N-terminal cathelin-like domain which is relatively well conserved also in evolutionary distant vertebrates. By contrast, the C-terminal region, which carries the active peptide, appears to be a focus for genetic mechanisms that have selectively generated a considerable sequence diversity. This process is particularly striking in Cetartiodactyls, where repeated gene duplication events and subsequent divergence have produced an array of distinct family members. The corresponding mature cathelicidin peptides are considerably diverse in length, amino acid sequence and structure, variously adopting alpha-helical, elongated or beta-hairpin conformations. The diverse nature of these peptides may account for distinct functions and for a diverse spectrum of activity and/or antimicrobial potency.     

Design of host defence peptides for antimicrobial and immunity enhancing activities

Host defense peptides are a vital component of the innate immune systems of humans, other mammals, amphibians, and arthropods. The related cationic antimicrobial peptides are also produced by many species of bacteria and function as part of the antimicrobial arsenal to help the producing organism reduce competition for resources from sensitive species. The antimicrobial activities of many of these peptides have been extensively characterized and the structural requirements for these activities are also becoming increasingly clear. In addition to their known antimicrobial role, many host defense peptides are also involved in a plethora of immune functions in the host. In this review, we examine the role of structure in determining antimicrobial activity of certain prototypical cationic peptides and ways that bacteria have evolved to usurp these activities. We also review recent literature on what structural components are related to these immunomodulatory effects. It must be stressed however that these studies, and the area of peptide research, are still in their infancy.     

Identification of novel peptides that stimulate human neutrophils

Neutrophils play a key role in innate immunity, and the identification of new stimuli that stimulate neutrophil activity is a very important issue. In this study, we identified three novel peptides by screening a synthetic hexapeptide combinatorial library. The identified peptides GMMWAI, MMHWAM, and MMHWFM caused an increase in intracellular Ca2+ in a concentration-dependent manner via phospholipase C activity in human neutrophils. The three peptides acted specifically on neutrophils and monocytes and not on other non-leukocytic cells. As a physiological characteristic of the peptides, we observed that the three peptides induced chemotactic migration of neutrophils as well as stimulated superoxide anion production. Studying receptor specificity, we observed that two of the peptides (GMMWAI and MMHWFM) acted on formyl peptide receptor (FPR)1 while the other peptide (MMHWAM) acted on FPR2. Since the three novel peptides were specific agonists for FPR1 or FPR2, they might be useful tools to study FPR1- or FPR2-mediated immune response and signaling.     

Autophagy and bacterial infectious diseases

Autophagy is a housekeeping process that maintains cellular homeostasis through recycling of nutrients and degradation of damaged or aged cytoplasmic constituents. Over the past several years, accumulating evidence has suggested that autophagy can function as an intracellular innate defense pathway in response to infection with a variety of bacteria and viruses. Autophagy plays a role as a specialized immunologic effector and regulates innate immunity to exert antimicrobial defense mechanisms. Numerous bacterial pathogens have developed the ability to invade host cells or to subvert host autophagy to establish a persistent infection. In this review, we have summarized the recent advances in our understanding of the interaction between antibacterial autophagy (xenophagy) and different bacterial pathogens.     

Theta-defensins: cyclic antimicrobial peptides produced by binary ligation of truncated alpha-defensins

The first cyclic peptide discovered in animals is an antimicrobial octadecapeptide that is expressed in leukocytes of rhesus monkeys. The peptide, termed rhesus Theta-defensin 1 (RTD-1) is the prototype of a new family of antimicrobial peptides, which like the previously characterized alpha- and beta-defensin families, possesses broad spectrum microbicidal activities against bacteria, fungi, and protects mononuclear cells from infection by HIV-1. The cyclic Theta-defensin structure is essential for a number of its antimicrobial properties, as demonstrated by the markedly reduced microbicidal activities of de-cyclized Theta-defensin analogs. Genetic and biochemical experiments disclosed that the biosynthesis of RTD-1 results from the head-to-tail joining of two nine-amino acid peptides, each of which is donated by a separate precursor polypeptide, which are in fact C-terminally truncated pro-alpha-defensins. Alternate combinations of the two nonapeptides generate two additional macaque Theta-defensins, RTD-2 and RTD-3. Humans do not express Theta-defensin peptides, but mRNAs encoding at least two Theta-defensins are expressed in human bone marrow. However, in each case the open reading frame is interrupted by a stop codon in the signal peptide-coding region. The mature Theta-defensin peptide is a two-stranded beta-sheet that, like the alpha- and beta-defensins, is stabilized by three disulfides. However, the parallel orientation of the Theta-defensin disulfide arrangement allows for substantial flexibility around its short axis. Unlike alpha- and beta-defensins, RTD-1 lacks an amphiphilic topology. This may partially explain the unusual interaction between Theta-defensins and phospholipid bilayers.     

Human beta-defensin 2 is induced by interleukin-1beta in the corneal epithelial cells

Mammalian epithelia produce the various antimicrobial peptides against the bacterial or viral infection, thereby acting as the active immune modulators in the innate immunity. In this study, we examined the effects of the various proinflammatory cytokines or LPS on cell viability and antimicrobial beta-defensin gene expressions in human corneal epithelial cells. Results showed that the cytokines or LPS did not exert severe cytotoxic effects on the cells, and that beta-defensin 1 was constitutively expressed, while beta-defensin 2 was specifically induced by IL-1beta, supporting the idea that these cytokines or LPS involve the defense mechanism in the cornea. Furthermore, the reporter and gel shift assay to define the induction mechanism of beta-defensin 2 by IL-1beta demonstrated that the most proximal NF-kappaB site on the promoter region of beta-defensin 2 was not critical for the process. Data obtained from the normal or patients with the varying ocular diseases showed that our in vitro results were relevant in the clinical settings. Our results clearly demonstrated that beta-defensin 1 and 2 are important antimicrobial peptides in the corneal tissues, and that the mechanistic induction process of beta-defensin 2 by IL-1beta is not solely dependent on proximal NF-kappaB site activation, thus suggesting that the long distal portion of the promoter is needed for the full responsiveness toward IL-1beta.     

Phylogenetic and experimental characterization of an acyl-ACP thioesterase family reveals significant diversity in enzymatic specificity and activity

Background

The inorganic (P_i) phosphate transporter (PiT) family comprises known and putative Na⁺- or H⁺-dependent P_i-transporting proteins with representatives from all kingdoms. The mammalian members are placed in the outer cell membranes and suggested to supply cells with P_i to maintain house-keeping functions. Alignment of protein sequences representing PiT family members from all kingdoms reveals the presence of conserved amino acids and that bacterial phosphate permeases and putative phosphate permeases from archaea lack substantial parts of the protein sequence when compared to the mammalian PiT family members. Besides being Na⁺-dependent P_i (NaP_i) transporters, the mammalian PiT paralogs, PiT1 and PiT2, also are receptors for gamma-retroviruses. We have here exploited the dual-function of PiT1 and PiT2 to study the structure-function relationship of PiT proteins.

Results

We show that the human PiT2 histidine, H₅₀₂, and the human PiT1 glutamate, E₇₀, - both conserved in eukaryotic PiT family members - are critical for P_i transport function. Noticeably, human PiT2 H₅₀₂ is located in the C-terminal PiT family signature sequence, and human PiT1 E₇₀ is located in ProDom domains characteristic for all PiT family members. A human PiT2 truncation mutant, which consists of the predicted 10 transmembrane (TM) domain backbone without a large intracellular domain (human PiT2ΔR₂₅₄-V₄₈₃), was found to be a fully functional P_i transporter. Further truncation of the human PiT2 protein by additional removal of two predicted TM domains together with the large intracellular domain created a mutant that resembles a bacterial phosphate permease and an archaeal putative phosphate permease. This human PiT2 truncation mutant (human PiT2ΔL₁₈₃-V₄₈₃) did also support P_i transport albeit at very low levels.

Conclusions

The results suggest that the overall structure of the P_i-transporting unit of the PiT family proteins has remained unchanged during evolution. Moreover, in combination, our studies of the gene structure of the human PiT1 and PiT2 genes (SLC20A1 and SLC20A2, respectively) and alignment of protein sequences of PiT family members from all kingdoms, along with the studies of the dual functions of the human PiT paralogs show that these proteins are excellent as models for studying the evolution of a protein's structure-function relationship.     

Plant pathogen recognition as a natural, original and simple model for chemogenomics: a brief overview of cell-based assays to screen for peptides acting as plant defense activators

As plants lack a circulatory system and adaptive immune system, they have evolved their own defense systems distinct from animals, in which each plant cell is capable of defending itself from pathogens. Plants induce a number of defense responses, which are triggered by a variety of molecules derived from pathogenic microorganisms, referred to as microbe-associated molecular patterns (MAMPs), including peptides, proteins, lipopolysaccharide, beta-glucan, chitin, and ergosterol. The interaction between plants and chemicals in the context of plant defense represents a "natural" and simple model for chemogenomics, at the intersection between chemical and biological diversities. For protection of crop plants from diseases, it has been shown to be effective to stimulate the plant immunity by chemical compounds, the so-called "plant defense activators". Combinatorial chemistry techniques can be applied to the search for novel plant defense activators, but it is essential to establish an efficient and reliable screening system suitable for library screening. For studies of the plant immune system, it is difficult to use isolated proteins as biological targets because the receptors for MAMP recognition are largely unknown and even the receptors identified so far are transmembrane proteins. Therefore, screening for novel peptides acting on MAMP receptors from combinatorial libraries must rely on a solution-phase assay using cells as the biological targets. In this review, we introduce the cell-based lawn format assay for identification of peptides acting as plant defense activators from combinatorial peptide libraries. The requirements and limitations in constructing the screening system using combinatorial libraries in the studies of plant sciences are also discussed.     

Optimizing antimicrobial host defense peptides

Antimicrobial host defense peptides constitute a major component of innate immune systems. Expectations are high to develop them into a novel class of anti-infective agents. In this issue of Chemistry & Biology, Hilpert et al. describe new design and peptide synthesis strategies for systematically investigating such concepts.     

Review: Examining the Natural Role of Amphibian Antimicrobial Peptide Magainin

Host defense peptides (HDPs) are a group of antimicrobial peptides (AMPs) that are crucial components of the innate immune system of many different organisms. These small peptides actively kill microbes and prevent infection. Despite the presence of AMPs in the amphibian immune system, populations of these organisms are in decline globally. Magainin is an AMP derived from the African clawed frog (Xenopus laevis) and has displayed potent antimicrobial effects against a wide variety of microbes. Included in this group of microbes are known pathogens of the African clawed frog and other amphibian species. Arguably, the most deleterious amphibious pathogen is Batrachochytrium dendrobatidis, a chytrid fungus. Investigating the mechanism of action of magainin can help understand how to effectively fight off infection. By understanding amphibian AMPs’ role in the frog, a potential conservation strategy can be developed for other species of amphibians that are susceptible to infections, such as the North American green frog (Rana clamitans). Considering that population declines of these organisms are occurring globally, this effort is crucial to protect not only these organisms but the ecosystems they inhabit as well.     

Amphiphilic poly(phenyleneethynylene)s can mimic antimicrobial peptide membrane disordering effect by membrane insertion

Antimicrobial peptides (AMPs) are a class of peptides that are innate to various organisms and function as a defense agent against harmful microorganisms by means of membrane disordering. Characteristic chemical and structural properties of AMPs allow selective interaction and subsequent disruption of invaders' cell membranes. Polymers based on m-phenylene ethynylenes (mPE) were designed and synthesized to mimic the amphiphilic, cationic, and rigid structure of AMPs and were found to be good mimics of AMPs in terms of their high potency toward microbes and low hemolytic activities. Using a Langmuir monolayer insertion assay, two mPEs are found to readily insert into anionic model bacterial membranes but to differ in the degree of selectivity between bacterial and mammalian erythrocyte model membranes. Comparison of grazing incidence X-ray diffraction (GIXD) data before and after the insertion of mPE clearly indicates that the insertion of mPE disrupts lipid packing, altering the tilt of the lipid tail. X-ray reflectivity (XR) measurements of the lipid/mPE system demonstrate that mPE molecules insert through the headgroup region and partially into the tail group region, thus accounting for the observed disordering of tail packing. This study demonstrates that mPEs can mimic AMP's membrane disordering.     

Influence of lipid composition on membrane activity of antimicrobial phenylene ethynylene oligomers

Host defense peptides (HDPs), part of the innate immune system, selectively target the membranes of bacterial cells over that of host cells. As a result, their antimicrobial properties have been under intense study. Their selectivity strongly depends on the chemical and mostly structural properties of the lipids that make up different cell membranes. The ability to synthesize HDP mimics has recently been demonstrated. To better understand how these HDP mimics interact with bilayer membranes, three homologous antimicrobial oligomers (AMOs) 1-3 with an m-phenylene ethynylene backbone and alkyl amine side chains were studied. Among them, AMO 1 is nonactive, AMO 2 is specifically active, and AMO 3 is nonspecifically active against bacteria over human red blood cells, a standard model for mammalian cells. The interactions of these three AMOs with liposomes having different lipid compositions are characterized in detail using a fluorescent dye leakage assay. AMO 2 and AMO 3 caused more leakage than AMO 1 from bacteria membrane mimic liposomes composed of PE/PG lipids. The use of E. coli lipid vesicles gave the same results. Further changes of the lipid compositions revealed that AMO 2 has selectively higher affinity toward PE/PG and E. coli lipids than PC, PC/PG or PC/PS lipids, the major components of mammalian cell membranes. In contrast, AMO 3 is devoid of this lipid selectivity and interacts with all liposomes with equal ease; AMO 1 remains inactive. These observations suggest that lipid type and structure are more important in determining membrane selectivity than lipid headgroup charges for this series of HDP mimics.     

Superantibodies: synergy of innate and acquired immunity

The antibody molecule possesses a number of so-called unconventional binding sites in the variable domain that are expressed and function independently from the antigen-binding site. These sites are encoded in the germline, and are predominantly composed of framework residues. By this definition, these sites function as part of the innate immunity, and are not subject to antigen-driven mutation and maturation. In this article, we focus on the evidence for the function and utility of the self-binding domain. The self-binding or autophilic domain has been discovered on murine germline-encoded antibodies from the S107/T15 Vh family. Autophilic antibodies form self-complexes after attaching to targets, but remain monomeric in solution. A peptide has been identified that confers self-binding if chemically attached to antibodies. Because this modification enhances the overall avidity of antibodies for target binding, therapeutic and diagnostic antibodies can be biotechnologically improved. The concept of superantibodies is introduced here to describe the unique coexistence and synergism of acquired immunity with innate immunity via antigen-specific and unconventional functional domains. As not every antibody qualifies as a superantibody, biotechnological engineering can produce superantibodies with superior targeting and therapeutic properties.     

Superantibodies

The antibody molecule possesses a number of so-called unconventional binding sites in the variable domain that are expressed and function independently from the antigen-binding site. These sites are encoded in the germiline, predominantly in framework residues. By this definition, these sites function as part of the innate immunity, and are not subject to antigendriven mutation and maturation. In this article, we focus on the evidence for the function and utility of the self-binding domain. The self-binding or autophilic domain has been discovered on murine germline-encoded antibodies from the S107/T15 Vh family. Autophilic antibodies form self-complexes after attaching to targets, but remain monomeric in solution. A peptide has been identified that confers self-binding if chemically attached to antibodies. Because this modification enhances the overall avidity of antibodies for target binding, therapeutic and diagnostic antibodies can be biotechnologically improved. The concept of super antibodies is introduced here to describe the unique coexistence and synergism of acquired immunity with innate immunity via antigen-specific and unconventional functional domains. As not every antibody qualifies as a super antibody, biotechnology engineering can produce superantibodies with superior targeting and therapeutic properties.     

Innate immunity probed by lipopolysaccharides affinity strategy and proteomics

Lipopolysaccharides (LPSs) are ubiquitous and vital components of the cell surface of Gram-negative bacteria that have been shown to play a relevant role in the induction of the immune-system response. In animal and plant cells, innate immune defenses toward microorganisms are triggered by the perception of pathogen associated molecular patterns. These are conserved and generally indispensable microbial structures such as LPSs that are fundamental in the Gram-negative immunity recognition. This paper reports the development of an integrated strategy based on lipopolysaccharide affinity methodology that represents a new starting point to elucidate the molecular mechanisms elicited by bacterial LPS and involved in the different steps of innate immunity response. Biotin-tagged LPS was immobilized on streptavidin column and used as a bait in an affinity capture procedure to identify protein partners from human serum specifically interacting with this effector. The complex proteins/lipopolysaccharide was isolated and the protein partners were fractionated by gel electrophoresis and identified by mass spectrometry. This procedure proved to be very effective in specifically binding proteins functionally correlated with the biological role of LPS. Proteins specifically bound to LPS essentially gathered within two functional groups, regulation of the complement system (factor H, C4b, C4BP, and alpha 2 macroglobulin) and inhibition of LPS-induced inflammation (HRG and Apolipoproteins). The reported strategy might have important applications in the elucidation of biological mechanisms involved in the LPSs-mediated molecular recognition and anti-infection responses.     

Functions of antimicrobial peptides in host defense and immunity

Antimicrobial peptides (AMPs) are effector molecules of the innate immune system. AMPs have a broad antimicrobial spectrum and lyse microbial cells by interaction with biomembranes. Besides their direct antimicrobial function, they have multiple roles as mediators of inflammation with impact on epithelial and inflammatory cells influencing diverse processes such as cytokine release, cell proliferation, angiogenesis, wound healing, chemotaxis, immune induction, and protease-antiprotease balance. Furthermore, AMPs qualify as prototypes of innovative drugs that may be used as antibiotics, anti-lipopolysaccharide drugs, or modifiers of inflammation. This review summarizes the current knowledge about the basic and applied biology of antimicrobial peptides and discusses features of AMPs in host defense and inflammation.