Antimicrobial peptides in the stomach of Xenopus laevis.

Antimicrobial peptides are widely distributed in nature and appear to play a role in the host defense of plants and animals. In this study we report the existence of antimicrobial peptides in the stomach of the vertebrate Xenopus laevis, an animal previously shown to store high concentrations of antimicrobial peptides in its skin. Antimicrobial activity was detected in extracts of X. laevis stomach tissue and nine antimicrobial peptides were then purified. A novel 24-amino acid peptide, designated PGQ, was isolated from these extracts, and has the following amino acid sequence: GVLSNVIGYLKKLGTGALNAVLKQ. PGQ is relatively basic and has the potential to form an amphipathic alpha-helix. The other peptides isolated are members of the magainin family of antimicrobial peptides, and include magainins I and II, PGLa, xenopsin precursor fragment, and four caerulein precursor fragments. None of these peptides had been previously identified in tissues other than the skin. The purification of the peptides from stomach extracts and subsequent protein sequence analysis reveals that the peptides have undergone the same processing as their dermal counterparts, and that they are stored in their processed forms. Northern blot analysis indicates that the magainin family of peptides are synthesized in the stomach, and immunohistochemical studies demonstrate that magainin is stored in a novel granular multinucleated cell in the gastric mucosa of Xenopus. This study demonstrates that the magainin family of antimicrobial peptides is found in the gastrointestinal system of X. laevis and offers an opportunity to further define the physiological role of these defense peptides.     

Localization of Aplysia neurosecretory peptides to multiple populations of dense core vesicles

Many neurons in the mollusc Aplysia are identifiable and provide a useful model system for investigating the cellular mechanisms used by the neuroendocrine system to mediate simple behaviors. In this study we determined the subcellular localization of eight Aplysia neuropeptides using immunogold labeling techniques, and analyzed the size distribution of dense core and granular vesicles in peptidergic neurons. Recent observations demonstrate that many neurons use multiple chemical messengers. Thus, an understanding of the functional significance of cotransmitters requires an analysis of their relative subcellular distributions. The peptides are expressed in a subset of neurons, or the exocrine atrial gland, and are primarily localized to dense core vesicles. Multiple regions of precursors which are cleaved into several components are co-localized. Each neuron has a distinct size distribution of peptide-containing dense core vesicles ranging in size from 65 to 600 nm. The atrial gland contains very large (up to 2 micron) peptide-containing granules. Single neurons have multiple populations of granules whose quantal sizes agree with predictions based on physical constraints. Some cells contain very large peptide-containing granules which are found in the cell soma and not in processes. Thus, the genetic determination of neuronal cell type includes not only transmitter choices but also multiple modes of packaging the intercellular messengers.     

Purification and characterization of novel antimicrobial peptides from the skin secretion of Hylarana guentheri

Linear, amphipathic and cationic antimicrobial peptides have been previously reported from a wide range of amphibian species especially frogs of the genus Rana. Such antimicrobial peptides are attracting increasing attention in pharmacological applications because they mainly act by permeabilizing and disrupting the target cell or virion membranes with a low degree of resistance. The Guenther's frog, Hylarana guentheri, is a Chinese frog of the genus Rana that is widely distributed in Southern China. It is commonly the dominant amphibian species even where the amphibian population is declining. In this study, we describe the isolation, purification, structural and biological characterization of five novel peptides from H. guentheri frog skin secretions that possess antimicrobial activity, including brevinin-2GHa, brevinin-2GHb, brevinin-2GHc, temporin-GH and a novel antimicrobial peptide named guentherin. The cDNAs encoding two novel members of the brevinin-2 family, brevinin-2GHb and brevinin-2GHc were also subsequently cloned and sequenced.     

Host defence peptides from the skin glands of the Australian blue mountains tree-frog Litoria citropa. Solution structure of the antibacterial peptide citropin 1.1.

Nineteen citropin peptides are present in the secretion from the granular dorsal glands of the Blue Mountains tree-frog Litoria citropa; 15 of these peptides are also present in the secretion from the submental gland. Two major peptides, citropin 1.1 (GLFDVIKKVASVIGGL-NH2), citropin 1.2 (GLFDIIKKVASVVGGL-NH2) and a minor peptide, citropin 1.3 (GLFDIIKKVASVIGGL-NH2) are wide-spectrum antibacterial peptides. The amphibian has an endoprotease which deactivates these membrane-active peptides by removing residues from the N-terminal end: loss of three residues gives the most abundant degradation products. The solution structure of the basic peptide citropin 1.1 has been determined by NMR spectroscopy [in a solvent mixture of trifluoroethanol/water (1 : 1)] to be an amphipathic alpha-helix with well-defined hydrophobic and hydrophilic regions. The additional four peptides produced by the dorsal glands are structurally related to the antibacterial citropin 1 peptides but contain three more residues at their C-terminus [e.g. citropin 1.1.3 (GLFDVIKKVASVIGLASP-OH)]. These peptides show minimal antibacterial activity; their role in the amphibian skin is not known.     

Skin peptides in Xenopus laevis: morphological requirements for precursor processing in developing and regenerating granular skin glands

The biosynthesis of the peptides caerulein and PGLa in granular skin glands of Xenopus laevis proceeds through a pathway that involves discrete morphological rearrangements of the entire secretory compartment. Immunocytochemical localization of these peptides during gland development indicates that biosynthetic precursors are synthesized in intact secretory cells, whereas posttranslational processing requires morphological reorganization to a vacuolated stage. The bulk of the processed secretory material is then stored in vacuolae- derived storage granules. In the mature gland, storage granules are still formed at a low level. However, in this case processing takes place in a distinct cytoplasmic structure, the multicored body, which we suggest to be functionally equivalent to vacuolae. When granular glands regenerate after having lost all their storage granules upon strong stimuli, another morphological pathway is used. 2 wk after gland depletion, secretory cells become arranged in a monolayer that covers the luminal surface of the gland. Storage granules are formed continuously within these intact secretory cells. Here, precursor processing does not require a vacuolated stage as in newly generated glands but occurs in multicored bodies. Most storage granules seem to be formed in the third week of regeneration. The high biosynthetic activity is also reflected by the high activity of the putative processing enzyme dipeptidyl aminopeptidase during this period of regeneration.     

A novel myotropic peptide from the skin secretions of the tree frog, Polypedates pingbianensis

A novel myotropic peptide, polypedatein, was purified and characterized from the skin secretions of the tree frog, Polypedates pingbianensis. Its primary structure, TLLCKYFAIC, was determined by Edman degradation and mass spectrometry. Polypedatein was subjected to bioassays including myotropic, antimicrobial, and serine protease inhibitory activities, which are related with many amphibian skin bioactive peptides. It was found to elicit concentration-dependent contractile effects on isolated rat ileum. cDNA clones encoding the precursor of polypedatein were isolated by screening a skin cDNA library of P. pingbianensis and then sequenced. The amino acid sequence deduced from the cDNA sequences matches well with the result from Edman degradation. BLAST search revealed that the sequence of polypedatein did not show similarity to known protein or peptide sequences. Especially, polypedatein does not contain conserved structural motifs of other amphibian myotropic peptides, such as bradykinins, bombesins, cholecystokinin (CCK), and tachykinins, indicating that polypedatein belongs to a novel amphibian myotropic peptide family. The signal peptide of the precursor encoding polypedatein shows significant sequence identity to that of other amphibian skin defensive peptides, such as antimicrobial peptides, bradykinins, lectins, and serine protease inhibitors, suggesting that polypedatein belongs to a novel amphibian myotropic peptide family. Polypedatein is also the first bioactive peptide from the genus of the frog, Polypedates.     

Occurrence of gastrin-releasing peptide-like and bombesin-like immunoreactivities in the epidermal sacciform gland cells of the clingfish Lepadogaster candollei

Gastrin-releasing peptide (GRP)-like and bombesin (BOM)-like immunoreactivities were localized in the exocrine sacciform gland cells and in the surface epidermis of the clingfish Lepadogaster candollei with the use of previously characterized antibodies. The GRP-like and BOM-like peptides show resemblance to those immunohistochemically found in the dermal secretory products of the amphibian skin. The immunoreactive peptides tested in this study are unusual bioactive components of secretory sources of exocrine glands since these peptides were first demonstrated in cells of the neuroendocrine system. The results suggest that such bioactive compounds may exert regulatory activity in the absorptive processes of the skin epithelium and in influencing secretion release from exocrine complexes.     

Extremely abundant antimicrobial peptides existed in the skins of nine kinds of Chinese odorous frogs

Peptide agents are regarded as hopeful candidates to solve life-threatening resistance of pathogenic microorganisms to classic antibiotics due to their unique action mechanisms. Peptidomic and genomic investigation of natural antimicrobial peptides (AMPs) from amphibian skin secretions can provide a large amount of structure-functional information to design peptide antibiotics with therapeutic potential. In the present study, we identified a large number of AMPs from the skins of nine kinds of Chinese odorous frogs. Eighty AMPs were purified from three different odorous frogs and confirmed by peptidomic analysis. Our results indicated that post-translational modification of AMPs rarely happened in odorous frogs. cDNAs encoding precursors of 728 AMPs, including all the precursors of the confirmed 80 native peptides, were cloned from the constructed AMP cDNA libraries of nine Chinese odorous frogs. On the basis of the sequence similarity of deduced mature peptides, these 728 AMPs were grouped into 97 different families in which 71 novel families were identified. Out of these 728 AMPs, 662 AMPs were novel and 28 AMPs were reported previously in other frog species. Our results revealed that identical AMPs were widely distributed in odorous frogs; 49 presently identified AMPs could find their identical molecules in different amphibian species. Purified peptides showed strong antimicrobial activities against 4 tested microbe strains. Twenty-three deduced peptides were synthesized and their bioactivities, including antimicrobial, antioxidant, hemolytic, immunomodulatory and insulin-releasing activities, were evaluated. Our findings demonstrate the extreme diversity of AMPs in amphibian skins and provide plenty of templates to develop novel peptide antibiotics.     

Caerulein secretion by dermal glands in xenopus laevis

Since gastrin and its related peptides are secreted by a minority population of widely dispersed cells in mamamalian tissues it has, in the past, been difficult to study the subcellular aspects of their secretion. From published reports (1, 2) it seemed possible that a satisfactory system for such studies might be provided by the skin of certain amphibians such as Xenopus laevis since in these tissues high concentrations of peptides such as caerulein exist, and there is some indication (3) that this, or a similar gastrin-like peptide, may be a dermal gland secretory product. We have therefore explored this possibility by studying the structure, secretory process, and secretory product of the most prominent non mucous type of gland in the skin of X. laevis. These studies clearly demonstrate that most, if not all, of the caerulein in which the skin is contained in secretion granules within the dermal glands and that its release can be specifically evoked by adrenergic stimulation. The release process by a holocrine mechanism expels all of the stored secretion onto the skin surface and thus for biosynthetic studies it should now be possible to synchronize the processes which lead to the replenishment of the peptide.     

A novel bradykinin-related peptide from skin secretions of toad Bombina maxima and its precursor containing six identical copies of the final product

Amphibian skin contains rich bradykinin-related peptides, but the mode of biosynthesis of these peptides is unknown. In the present study, a novel bradykinin-related peptide, termed bombinakinin M, was purified from skin secretions of the Chinese red belly toad Bombina maxima. Its primary sequence was established as DLPKINRKGPRPPGFSPFR that comprises bradykinin extended from its N-terminus by a 10-residue segment DLPKINRKGP. The cDNA structure of bombinakinin M was found to contain a coding region of 624 nucleotides. The encoded precursor of bombinakinin M is composed of a signal peptide, an acidic peptide, six 100% identical copies of a 28-amino-acid peptide unit including bombinakinin M plus a spacer peptide. The sequence of bombinakinin M is preceded by a single basic residue (arginine), which represents the site of cleavage for releasing of mature bombinakinin M. This is the first cDNA cloning of bradykinin-related peptides from amphibian skin. The unique cDNA structure encoding bombinakinin M suggests that the generation modes of bradykinin-related peptides in amphibian skin and in mammalian blood system are different.     

Peptidomics and genomics analysis of novel antimicrobial peptides from the frog,Rana nigrovittata

Much attention has been paid on amphibian peptides for their wide-ranging pharmacological properties, clinical potential, and gene-encoded origin. More than 300 antimicrobial peptides (AMPs) from amphibians have been studied. Peptidomics and genomics analysis combined with functional test including microorganism killing, histamine-releasing, and mast cell degranulation was used to investigate antimicrobial peptide diversity. Thirty-four novel AMPs from skin secretions of Rana nigrovittata were identified in current work, and they belong to 9 families, including 6 novel families. Other three families are classified into rugosin, gaegurin, and temporin family of amphibian AMP, respectively. These AMPs share highly conserved preproregions including signal peptides and spacer acidic peptides, while greatly diversified on mature peptides structures. In this work, peptidomics combined with genomics analysis was confirmed to be an effective way to identify amphibian AMPs, especially novel families. Some AMPs reported here will provide leading molecules for designing novel antimicrobial agents.     

There are abundant antimicrobial peptides in brains of two kinds of Bombina toads

It is well-known that there is a large amount of antimicrobial peptides in amphibian skins but few antimicrobial peptides are found in amphibian brains. Twenty-two and four antimicrobial peptides were purified and characterized from the brain homogenate of Bombina maxima and B. microdeladigitora, respectively. One hundred fifty-eight cDNA clones encoding 79 antimicrobial peptides were isolated from brain cDNA libraries of B. maxima and B. microdeladigitora. These antimicrobial peptides belong to two peptide groups (maximin and maximin-H). Twenty of them are identical to previously reported antimicrobial peptides (maximin 1-8, 10, 11, maximin H1, 3-5, 7, 9, 10, 12, 15, 16) from B. maxima skin secretions. Fifty-nine of them are novel antimicrobial peptides. Some of these antimicrobial peptides showed strong antimicrobial activities against tested microorganism strains including Gram-positive and -negative bacteria and fungi. The current diversity in peptide coding cDNA sequences is, to our knowledge, the most extreme yet described for any animal brains. The extreme diversity may give rise to interest to prospect the actual functions of antimicrobial peptides in amphibian brains.     

Active peptides in the skins of one hundred amphibian species from Australia and Papua New Guinea

Extracts prepared from the dried skins of approximately one hundred amphibian species from Australia and Papua New Guinea were subjected to biological screening in order to determine the nature and amounts of peptides active on smooth muscle preparations and systemic blood pressure present in these extracts. The most frequently and abundantly occurring peptides were those of the caerulein, bombesin and tachykinin peptide families represented, respectively, by caerulein; litorin, Glu(OMe)2-litorin and Glu(OEt)2-litorin; uperolein and Lys5-Thr6-physalaemin. Bradykinin-like peptides seem to have a rather diffuse distribution, in the species examined, but so far no peptide of this family has been isolated and sequenced. The only angiotensin-like peptide ever found in amphibian skin, crinia angiotensin II, has been isolated from skin extracts of a few species, belonging to the genera Crinia, Geocrinia, Ranidella and Litoria. The array of peptides occurring in amphibians from Australia and Papua New Guinea is destined to increase, because several apparently novel peptides have been identified in skin extracts by bioassay and radioimmunoassay.     

Antimicrobial Peptide defenses in amphibian skin

One of the most urgent problems in conservation biology todayis the continuing loss of amphibian populations on a globalscale. Recent amphibian population declines in Australia, CentralAmerica, the western United States, Europe, and Africa havebeen linked to a pathogenic chytrid fungus, Batrachochytriumdendrobatidis, which infects the skin. The skin of amphibiansis critical for fluid balance, respiration, and transport ofessential ions; and the immune defense of the skin must be integratedwith these physiological responses. One of the natural defensesof the skin is production of antimicrobial peptides in granularglands. Discharge of the granular glands is initiated by stimulationof sympathetic nerves. To determine whether antimicrobial skinpeptides play a role in protection from invasive pathogens,purified antimicrobial peptides and natural peptide mixturesrecovered from the skin secretions of a number of species havebeen assayed for growth inhibition of the chytrid fungus. Thegeneral findings are that most species tested have one or moreantimicrobial peptides with potent activity against the chytridfungus, and natural mixtures of peptides are also effectiveinhibitors of chytrid growth. This supports the hypothesis thatantimicrobial peptides produced in the skin are an importantdefense against skin pathogens and may affect survival of populations.We also report on initial studies of peptide depletion usingnorepinephrine and the kinetics of peptide recovery followinginduction. Approximately 80 nmoles/g of norepinephrine is requiredto deplete peptides, and peptide stores are not fully recoveredat three weeks following this treatment. Because many specieshave defensive peptides and yet suffer chytrid-associated populationdeclines, it is likely that other factors (temperature, conditionsof hydration, "stress," or pesticides) may alter normal defensesand allow for uncontrolled infection.     

The role of amphibian antimicrobial peptides in protection of amphibians from pathogens linked to global amphibian declines

Amphibian species have experienced population declines and extinctions worldwide that are unprecedented in recent history. Many of these recent declines have been linked to a pathogenic skin fungus, Batrachochytrium dendrobatidis, or to iridoviruses of the genus Ranavirus. One of the first lines of defense against pathogens that enter by way of the skin are antimicrobial peptides synthesized and stored in dermal granular glands and secreted into the mucus following alarm or injury. Here, I review what is known about the capacity of amphibian antimicrobial peptides from diverse amphibians to inhibit B. dendrobatidis or ranavirus infections. When multiple species were compared for the effectiveness of their in vitro antimicrobial peptides defenses against B. dendrobatidis, non-declining species of rainforest amphibians had more effective antimicrobial peptides than species in the same habitat that had recently experienced population declines. Further, there was a significant correlation between the effectiveness of the antimicrobial peptides and resistance of the species to experimental infection. These studies support the hypothesis that antimicrobial peptides are an important component of innate defenses against B. dendrobatidis. Some amphibian antimicrobial peptides inhibit ranavirus infections and infection of human T lymphocytes by the human immunodeficiency virus (HIV). An effective antimicrobial peptide defense against skin pathogens appears to depend on a diverse array of genes expressing antimicrobial peptides. The production of antimicrobial peptides may be regulated by signals from the pathogens. However, this defense must also accommodate potentially beneficial microbes on the skin that compete or inhibit growth of the pathogens. How this delicate balancing act is accomplished is an important area of future research.     

Enteric defensins: antibiotic peptide components of intestinal host defense

Five intestinal defensins, termed cryptdins 1-5, have been purified from mouse small bowel, sequenced, and localized to the epithelium by immunohistochemistry. Although identified as members of the defensin peptide family by peptide sequencing, enteric defensins are novel in that four cryptdins have amino termini which are three to six residues longer than those of leukocyte-derived defensins. A fifth cryptdin is the first defensin to diverge from the previously invariant spacing of cysteines in the peptide structure. The most abundant enteric defensin, cryptdin-1, had antimicrobial activity against an attenuated phoP mutant of Salmonella typhimurium but was not active against the virulent wild-type parent. Immunohistochemical localization demonstrated that cryptdin-1, and probably cryptdins 2 and 3, occur exclusively in Paneth cells, where the peptides appear to be associated with cytoplasmic granules. Biochemical and immunologic analysis of the luminal contents of the small intestine suggest that cryptdin peptides are secreted into the lumen, similar to Paneth cell secretion of lysozyme. The presence of several enteric defensins in the intestinal epithelium, evidence of their presence in the lumen, and the antibacterial activity of cryptdin-1 suggest that these peptides contribute to the antimicrobial barrier function of the small bowel mucosa.     

Anti-infection peptidomics of amphibian skin

Peptidomics and genomics analyses were used to study an anti-infection array of peptides of amphibian skin. 372 cDNA sequences of antimicrobial peptides were characterized from a single individual skin of the frog Odorrana grahami that encode 107 novel antimicrobial peptides. This contribution almost triples the number of currently reported amphibian antimicrobial peptides. The peptides could be organized into 30 divergent groups, including 24 novel groups. The diversity in peptide coding cDNA sequences is, to our knowledge, the most extreme yet described for any animal. The patterns of diversification suggest that point mutations as well as insertion, deletion, and "shuffling" of oligonucleotide sequences were responsible for the diversity. The diversity of antimicrobial peptides may have resulted from the diversity of microorganisms. These diverse peptides exhibited both diverse secondary structure and "host defense" properties. Such extreme antimicrobial peptide diversity in a single amphibian species is amazing. This has led us to reconsider the strong capability of innate immunity and molecular genetics of amphibian ecological diversification and doubt the general opinion that 20-30 different antimicrobial peptides can protect an animal because of the relatively wide specificity of the peptide antibiotics. The antimicrobial mechanisms of O. grahami peptides were investigated. They exerted their antimicrobial functions by various means, including forming lamellar mesosome-like structures, peeling off the cell walls, forming pores, and inducing DNA condensation. With respect to the development of antibiotics, these peptides provide potential new templates to explore further.