Antimicrobial properties of peptides from Xenopus granular gland secretions

Previously, we described a family of novel broad spectrum antimicrobial peptides, magainins, from the skin of Xenopus laevis. In this report we show that at least two other Xenopus peptides, present in the skin and its secretions, PGLa and a peptide released from the xenopsin precursor, exhibit antimicrobial properties comparable to the magainins. The identification of these newer members provides insight into the structural diversity of vertebrate antimicrobial peptides.     

Levitide, a neurohormone-like peptide from the skin of Xenopus laevis. Peptide and peptide precursor cDNA sequences

A novel peptide, levitide, less than Glu-Gly-Met-Ile-Gly-Thr-Leu-Thr-Ser-Lys-Arg-Ile-Lys-Gln-NH2 has been isolated from skin secretions of the South African frog Xenopus laevis and sequenced by fast atom bombardment mass spectrometry. Synthetic oligonucleotides were used as probes to screen a X. laevis skin cDNA library for species coding for preprolevitide. Two such clones were detected and their sequences are reported here. Preprolevitide is 88 residues long, exhibits a putative signal sequence at the amino terminus, and contains the levitide peptide at the carboxyl terminus. The levitide precursor shows a striking nucleotide and amino acid (86%) sequence homology with the precursor of xenopsin, a biologically active octapeptide from Xenopus skin, and also encodes a 25-residue amphipathic peptide that is released by processing at a single arginine residue.     

Characterisation of xenopsin immunoreactivity derived from pepsinised human skin and possible mechanism of in vivo generation

Human skin was subjected to a variety of extraction and enzymatic digestion procedures. Extracts and digests were subjected to neurotensin and xenopsin radioimmunoassays of known specificity. No neurotensin immunoreactivity was detected in any preparation with any region-specific antiserum. C-terminal xenopsin immunoreactivity was present in skin homogenates following incubation with both soluble and solid-phase pepsin and in those incubated with a leucocyte lysate or purified cathepsin D. The generation of xenopsin immunoreactivity was dependent on low pH and enzymes of pepsin-type specificity acting on a tissue precursor of approximately 30 kDa. Gel permeation chromatography of skin-derived xenopsin immunoreactivity identified a single molecular species larger than synthetic xenopsin which was resolved into two components by reverse-phase HPLC with retention times similar to synthetic xenopsin and kinetensin. Human skin thus contains a high-molecular-weight precursor protein and an endogenous acid protease, cathepsin D, capable of generating a peptide of similar size and C-terminal structure to amphibian xenopsin under acidic conditions such as might occur locally in wounds or at sites of inflammation.     

Novel peptide fragments originating from PGLa and the caerulein and xenopsin precursors from Xenopus laevis

Skin secretions from the South African frog Xenopus laevis have been chromatographed by high performance liquid chromatography (HPLC), fractionated, and analyzed by fast atom bombardment-mass spectrometry (FAB-MS). The HPLC chromatograms showed the secretion to be a complex mixture with over 30 components at similar levels to the four peptides previously isolated from X. laevis skin, i.e. xenopsin, caerulein, thyrotropin-releasing hormone, and PGLa. FAB-MS analysis of the HPLC fractions gave numerous protonated molecular ions ranging from m/z 491 to 2662. Preliminary assignments of these components were made by comparing these experimental molecular weights to those predicted for regions within the xenopsin, caerulein, thyrotropin-releasing hormone, and PGLa precursors. These results suggested that many of these skin secretions were peptides originating from additional processing of the xenopsin, caerulein, and PGLa precursors, primarily involving cleavage at single arginine residues, and a novel cleavage at the NH2-terminal side of single lysines. These assignments were subsequently confirmed by Edman degradation, FAB-MS peptide sequencing, and amino acid analysis. All of these peptides contain one or more lysines and would be expected to have amphiphilic structures. As yet, nothing is known about their activity, although they resemble in composition the mast cell degranulating peptides melittin and the bombolitins. These precursor fragments were also found to have limited sequence homology to bombinin, a hemolytic amphibian peptide isolated from the European Bombina toad.     

Localization of xenopsin and xenopsin precursor fragment immunoreactivities in the skin and gastrointestinal tract of Xenopus laevis

Summary Xenopsin (Xp) and xenopsin precursor fragment (XPF) are bioactive peptides derived from a single precursor molecule; both were isolated previously from extracts of Xenopus laevis skin. The present immunohistochemical study was undertaken to determine the specific cellular localization of these two peptides in the skin and also in the gastrointestinal tract of adult Xenopus. We report here that Xp-like and XPF-like immuno-reactivities co-exist in the granular glands of the skin and specific granular cells in the lower esophagus and stomach. However, only Xp-like immunoreactivity, not XPF-like immunoreactivity, was detected in tall, thin cells of the duodenum and in club-shaped cells of the large intestine. The immunochemical co-localization of the two peptides in specific cells of the skin, lower esophagus and stomach suggests that the same gene is expressed in each of these cells, and that the precursor molecule undergoes similar post-translational processing. In contrast, the observation that certain cells of the duodenum and large intestine display only one peptide immunoreactivity suggests an alternative phenomenon, possibly involving selective peptide accumulation or expression of a different gene.     

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.     

Co-localization of xenopsin and gastrin immunoreactivity in gastric antral G-cells

Studies indicating evidence for the presence of the amphibian octapeptide xenopsin in gastric mucosa of mammals prompted us to investigate the cellular localization of this peptide. Using the peroxidase-antiperoxidase method and a specific antiserum to xenopsin (Xen-7) on paraffin and adjacent semithin sections of gastric antral mucosa from man, dog, and Tupaia belangeri, we found numerous epithelial cells showing a specific positive immunoreaction. These cells were of typical pyramidal shape and could be classified as of the "open" type. Cell quantification in serial sections processed for xenopsin and gastrin immunoreactivity, respectively, revealed an identical number of cells per section and an identical distribution of these cells in the middle zone of the antral mucosa. Furthermore, adjacent semithin sections demonstrated the colocalization of xenopsin and gastrin immunoreactivity within the same G-cell. The xenopsin antiserum could be completely absorbed with synthetic xenopsin but not with gastrin. Preabsorption tests with neurotensin, a xenopsin related peptide, or with somatostatin, glucagon, and enkephalins gave no evidence for crossreactivity of the xenopsin antiserum with these peptides. It is concluded that gastric antral G-cells in addition to gastrin also contain the amphibian peptide xenopsin.     

Xenopsin-related peptide generated in avian gastric extracts

Two avian counterparts to amphibian xenopsin have been identified as H-Phe-His-Pro-Lys-Arg-Pro-Trp-Ile-Leu-OH (XP-2) and its partial sequence H-His-Pro-Lys-Arg-Pro-Trp-Ile-Leu-OH (XP-1) isolated from extracts of turkey proventriculus and skin. Both peptides were shown to be present within these and other tissues primarily (99%) in precursor form(s), from which they were liberated by the action of endogenous enzyme(s) during extraction. Synthetic and native preparations of XP-2 increased vascular permeability in rats and released histamine from isolated rat mast cells at submicromolar concentrations. The ubiquitous distribution of this XP-related sequence and its pharmacologic capabilities suggest potential roles in the general regulation of tissue blood flow and fluid exchange.     

The effects of xenopsin of endocrine pancreas and gastric antrum in dogs.

Effects of synthetic xenopsin on endocrine pancreas and gastric antrum in anesthetized dogs were studied. Synthetic xenopsin was administered into the superior pancreaticoduodenal artery and plasma insulin, glucagon and gastrin in the superior pancreaticoduodenal vein and gastrin in the right gastroepiploic vein were measured radioimmunologically. Administration of 10 microgram of xenopsin per kg of body weight brought about a hyperglycemic response and rapid and sharp elevations of the hormones in the pancreatic vein. Plasma gastrin level in the gastric vein also showed an immediate and sharp increase following xenopsin administration. Xenopsin appeared more potent inducer of the glucagon. It is concluded that xenopsin acts directly on endocrine pancreas and gastric antrum to secrete their hormones.     

Isolation of a dipeptidyl aminopeptidase, a putative processing enzyme, from skin secretion of Xenopus laevis

A dipeptidyl aminopeptidase has been purified to apparent homogeneity from skin secretion of Xenopus laevis. This enzyme is a glycoprotein with a molecular mass of about 98 kDa. It hydrolyzes a variety of dipeptidyl-p-nitroanilides and oligopeptides containing proline, alanine or glycine as the second amino acid and is inhibited by diisopropylfluorophosphate. The pH optimum was found to be around 8, while at pH 6, substrates were cleaved at about one-third of the maximal rate. This dipeptidyl aminopeptidase has the specificity required for the cleavage of amino-terminal extensions preceding the sequence of caerulein and xenopsin in their respective precursors.     

Co-localization of xenopsin and gastrin immunoreactivity in gastric antral G-cells

Summary Studies indicating evidence for the presence of the amphibian octapeptide xenopsin in gastric mucosa of mammals prompted us to investigate the cellular localization of this peptide. Using the peroxidase-antiperoxidase method and a specific antiserum to xenopsin (Xen-7) on paraffin and adjacent semithin sections of gastric antral mucosa from man, dog, and Tupaia belangeri, we found numerous epithelial cells showing a specific positive immunoreaction. These cells were of a typical pyramidal shape and could be classified as of the open type. Cell quantification in serial sections processed for xenopsin and gastrin immunoreactivity, respectively, revealed an identical number of cells per section and an identical distribution of these cells in the middle zone of the antral mucosa. Furthermore, adjacent semithin sections demonstrated the colocalization of xenopsin and gastrin immunoreactivity within the same G-cell. The xenopsin antiserum could be completely absorbed with synthetic xenopsin but not with gastrin. Preabsorption tests with neurotensin, a xenopsin related peptide, or with somatostatin, glucagon, and enkephalins gave no evidence for crossreactivity of the xenopsin antiserum with these peptides.It is concluded that gastric antral G-cells in addition to gastrin also contain the amphibian peptide xenopsin.     

Structural organization of the proopiomelanocortin gene in Xenopus laevis. 5'-end homologies within the toad and mammalian genes

This study reports the isolation and characterization of the entire proopiomelanocortin (POMC) gene of the amphibian Xenopus laevis. The Xenopus POMC gene consists of three exons of which the main exon 3 codes for all of the bioactive domains of the precursor protein. Intron A (2.6 kb) separates the segments encoding the 5'-untranslated mRNA region and intron B (2.5 kb) interrupts the protein-coding sequence near the signal peptide coding region. In that this structural organization of the Xenopus POMC gene is similar to those of the mammalian genes, apparently the POMC gene has been remarkably stable during 350 million years of vertebrate evolution. A comparative analysis of the 5'-flanking sequences of the Xenopus and mammalian POMC genes reveals the presence of several conserved regions. One of these regions is homologous with sequences located upstream of the capping sites of other glucocorticoid-regulated genes and another region contains a segment reminiscent of a viral enhancer consensus sequence.     

Sequencing and analysis of the internal transcribed spacers (ITSs) and coding regions in the EcoR I fragment of the ribosomal DNA of the Japanese pond frog Rana nigromaculata

The rDNA of eukaryotic organisms is transcribed as the 40S-45S rRNA precursor, and this precursor contains the following segments: 5' - ETS - 18S rRNA - ITS 1 - 5.8S rRNA - ITS 2 - 28S rRNA - 3'. In amphibians, the nucleotide sequences of the rRNA precursor have been completely determined in only two species of Xenopus. In the other amphibian species investigated so far, only the short nucleotide sequences of some rDNA fragments have been reported. We obtained a genomic clone containing the rDNA precursor from the Japanese pond frog Rana nigromaculata and analyzed its nucleotide sequence. The cloned genomic fragment was 4,806 bp long and included the 3'-terminus of 18S rRNA, ITS 1, 5.8S rRNA, ITS 2, and a long portion of 28S rRNA. A comparison of nucleotide sequences among Rana, the two species of Xenopus, and human revealed the following: (1) The 3'-terminus of 18S rRNA and the complete 5.8S rRNA were highly conserved among these four taxa. (2) The regions corresponding to the stem and loop of the secondary structure in 28S rRNA were conserved between Xenopus and Rana, but the rate of substitutions in the loop was higher than that in the stem. Many of the human loop regions had large insertions not seen in amphibians. (3) Two ITS regions had highly diverged sequences that made it difficult to compare the sequences not only between human and frogs, but also between Xenopus and Rana. (4) The short tracts in the ITS regions were strictly conserved between the two Xenopus species, and there was a corresponding sequence for Rana. Our data on the nucleotide sequence of the rRNA precursor from the Japanese pond frog Rana nigromaculata were used to examine the potential usefulness of the rRNA genes and ITS regions for evolutionary studies on frogs, because the rRNA precursor contains both highly conserved regions and rapidly evolving regions.     

The role of the tryptophyl residue in the hypotensive peptide xenopsin

The role of the Trp⁶ residue in the biological activity of the hypotensive peptide xenopsin (<Glu-Gly-Lys-Arg-Pro-Trp-Ile-Leu-OH) was investigated. This residue was satisfactorily reduced to 2,3-dihydro-Trp on treatment with excess pyridine-borane in trifluoroacetic acid without any detectable change in other parts of the molecule. The analogous peptide, (Lys², Gly³) xenopsin, was also reduced in a similar manner. Both reduction products were purified by gel filtration and characterized by UV absorption, amino acid composition, and structural analysis.The reduced peptides were assayed on the fundus strip of isolated rat stomach and were found to possess less than 1 percent of the activity of the original peptides. Although each of the reduced analogs had an indoline substituted for an indole in the tryptophyl residue, their biological activity was virtually lost. This suggests that the tryptophyl residue of xenopsin is crucial for its biological activity.     

Biogenic amines and active peptides in the skin of fifty-two African amphibian species other than bufonids

1. Extracts prepared from dried or fresh skins of 52 African amphibian species, other than bufonids, were subjected to chemical (colour reactions) and biological screening, to determine occurrence and contents of aromatic biogenic amines and peptides active on smooth muscle preparations and blood pressure. 2. Only indolealkylamines were detectable in the skins. They were represented by 5-hydroxytryptamine, its N-methylated derivatives and tryptamine. The indolealkylamines considered included the alkaloid trypargine, a carboline derivative resulting from the condensation of tryptamine with arginine. 3. The peptide families identified in skin extracts of the African frogs were as follows: caeruleins (caerulein, [Asn2, Leu5] caerulein), tachykinins (kassinin, [Glu2, Pro5] kassinin, hylambatin), bradykinins [( Hyp3] bradykinin), xenopsin, thyrotropin releasing hormone, peptide PYLa and the magainins I and II. The last five peptides have been so far identified only in the skin of Xenopus laevis, together with their precursors. 4. Since numerous other peptide molecules await isolation, elucidation of structure, and definition of possible biological activities, the array of peptides occurring in the skin of African amphibians, as in that of Australian and American amphibians, is destined to increase.     

Xenopsin immunoreactivity in antral G-cells may reside in the N-terminus of gastrin 17

Summary The nature of xenopsin immunoreactivity in mammalian antral G-cells has been reassessed. Xenopsin immunostaining was most intense in human antral G-cells, present in those of the dog and pig and not detected in guinea pig or rat tissues. Rigorous specificity controls for ionic binding of immunoglobulins to antral G-cell granules indicated that this mechanism was not responsible for xenopsin immunostaining. Preincubation of the xenopsin antiserum with xenopsin, human gastrin 1–13 and gastrin 2–17 completely abolished immunostaining at similar molar concentrations. Gastrin 34 was ineffective at much higher concentrations. These results infer that xenopsin-immunoreactivity in antral G-cells resides in the N-terminal region of gastrin 17. Examination of the primary structures of xenopsin and the N-terminal regions of some mammalian gastrins reveals a hitherto unrecognized homology.     

Xenopsin immunoreactivity in antral G-cells may reside in the N-terminus of gastrin 17

The nature of xenopsin immunoreactivity in mammalian antral G-cells has been reassessed. Xenopsin immunostaining was most intense in human antral G-cells, present in those of the dog and pig and not detected in guinea pig or rat tissues. Rigorous specificity controls for ionic binding of immunoglobulins to antral G-cell granules indicated that this mechanism was not responsible for xenopsin immunostaining. Preincubation of the xenopsin antiserum with xenopsin, human gastrin 1-13 and gastrin 2-17 completely abolished immunostaining at similar molar concentrations. Gastrin 34 was ineffective at much higher concentrations. These results infer that xenopsin-immunoreactivity in antral G-cells resides in the N-terminal region of gastrin 17. Examination of the primary structures of xenopsin and the N-terminal regions of some mammalian gastrins reveals a hitherto unrecognized homology.     

Caerulein precursor fragment (CPF) peptides from the skin secretions of Xenopus laevis and Silurana epitropicalis are potent insulin-releasing agents

Peptidomic analysis of norepinephrine-stimulated skin secretions of the tetraploid clawed frog Xenopus laevis (Pipidae) led to the identification of 10 peptides with the ability to stimulate the release of insulin from the rat BRIN-BD11 clonal β cell line. These peptides were purified to near homogeneity and structural characterization showed that they belong to the magainin (2 peptides), peptide glycine-leucine-amide (PGLa) (1 peptide), xenopsin precursor fragment (1 peptide), and caerulein precursor fragment (CPF) (6 peptides) families. CPF-1, CPF-3, CPF-5 and CPF-6 were the most potent producing a significant (P < 0.05) increase in the rate of insulin release at concentration of 0.03 nM. CPF-7 (GFGSFLGKALKAALKIGANALGGAPQQ) produced the maximum stimulation of insulin release (571 ± 30% of basal rate at 3 μM). In addition, CPF-SE1 (GFLGPLLKLGLKGVAKVIPHLIPSRQQ), previously isolated from skin secretions of the tetraploid frog Silurana epitropicalis, produced a significant (P < 0.05) increase in the rate of insulin release at 0.03 nM with a 514 ± 13% increase over basal rate at 3 μM. No CPF peptide stimulated release of the cytosolic enzyme, lactate dehydrogenase from BRIN-BD11 cells at concentrations up to 3 μM indicating that the integrity of the plasma membrane had been preserved. The mechanism of action of the CPF peptides involves, at least in part, membrane depolarization and an increase in intracellular Ca²⁺ concentration. The CPF peptides show potential for development into agents for the treatment of Type 2 diabetes.     

Identification of an outer segment targeting signal in the COOH terminus of rhodopsin using transgenic Xenopus laevis

Mislocalization of the photopigment rhodopsin may be involved in the pathology of certain inherited retinal degenerative diseases. Here, we have elucidated rhodopsin's targeting signal which is responsible for its polarized distribution to the rod outer segment (ROS). Various green fluorescent protein (GFP)/rhodopsin COOH-terminal fusion proteins were expressed specifically in the major red rod photoreceptors of transgenic Xenopus laevis under the control of the Xenopus opsin promoter. The fusion proteins were targeted to membranes via lipid modifications (palmitoylation and myristoylation) as opposed to membrane spanning domains. Membrane association was found to be necessary but not sufficient for efficient ROS localization. A GFP fusion protein containing only the cytoplasmic COOH-terminal 44 amino acids of Xenopus rhodopsin localized exclusively to ROS membranes. Chimeras between rhodopsin and alpha adrenergic receptor COOH-terminal sequences further refined rhodopsin's ROS localization signal to its distal eight amino acids. Mutations/deletions of this region resulted in partial delocalization of the fusion proteins to rod inner segment (RIS) membranes. The targeting and transport of endogenous wild-type rhodopsin was unaffected by the presence of mislocalized GFP fusion proteins.     

Distribution patterns of neurotensin-like immunoreactive cells in the gastro-intestinal tract of higher vertebrates

Summary The endocrine system of the gastro-intestinal tract of selected species representing the five higher vertebrate classes was investigated with reference to occurrence and distribution of neurotensin-like immunoreactive cells. Using antibodies against C-terminal and N-terminal fragments of neurotensin and against the C-terminal sequence of xenopsin it was demonstrated that the intestine of all species studied contains endocrine, neurotensin-like immunoreactive cells. However, large differences in localization and frequency of these neurotensin-like immunoreactive cells were found. Except for a teleostean fish, neurotensin-like immunoreactive cells in the gastro-intestinal tract were more frequent in non-mammalian vertebrates than in mammals. In contrast to mammals, where the highest density of neurotensin-like immunoreactive cells was present in the ileal mucosa, in the non-mammalian vertebrates studied the corresponding cells were most abundant in the pyloric-duodenal junction. The exact mapping of neurotensin-like immunoreactive cells is presented throughout the entire gastro-intestinal tract of six species (Rattus, Coturnix, Lacerta, Rana, Xenopus, Carassius) including a quantitative evaluation of sequential serial sections.