Tracheal antimicrobial peptide, partial

Peptidomic analysis of an extract of the skin of the stream brown frog Rana sakuraii Matsui and Matsui, 1990 led to the isolation of a C-terminally alpha-amidated peptide (VR-23; VIGSILGALASGLPTLISWIKNR x NH2) with broad-spectrum antimicrobial activity that shows structural similarity to the bee venom peptide, melittin together with two peptides belonging to the temporin family (temporin-1SKa; FLPVILPVIGKLLNGIL x NH2 and temporin-1SKb; FLPVILPVIGKLLSGIL x NH2), and peptides whose primary structures identified them as belonging to the brevinin-2 (2 peptides) and ranatuerin-2 (1 peptide) families. Using a forward primer that was designed from a conserved region of the 5'-untranslated regions of Rana temporaria preprotemporins in a 3'-RACE procedure, a cDNA clone encoding preprotemporin-1SKa was prepared from R. sakuraii skin total RNA. Further preprotemporin cDNAs encoding temporin-1SKc (AVDLAKIANIAN KVLSSL F x NH2) and temporin-1SKd (FLPMLAKLLSGFL x NH2) were obtained by RT-PCR. Unexpectedly, the 3'-RACE procedure using the same primer led to amplification of a cDNA encoding a preprobradykinin whose signal peptide region was identical to that of preprotemporin-1SKa except for the substitution Ser18-->Asn. R. sakuraii bradykinin ([Arg0,Leu1,Thr6,Trp8] BK) was 28-fold less potent than mammalian BK in effecting B2 receptor-mediated relaxation of mouse trachea and the des[Arg0] derivative was only a weak partial agonist. The evolutionary history of the Japanese brown frogs is incompletely understood but a comparison of the primary structures of the R. sakuraii dermal peptides with those of Tago's brown frog Rana tagoi provides evidence for a close phylogenetic relationship between these species.

beta-Defensins are cationic peptides with broad-spectrum antimicrobial activity that may play a role in mucosal defenses of several organs. They have been isolated in several species, and in humans, two beta-defensins have been identified. Here, we report the identification of two genes encoding beta-defensin homologues in the rat. Partial cDNAs were found by searching the expressed-sequence-tag database, and primers were designed to generate full-length mRNA coding sequences. One gene was highly similar to the human beta-defensin-1 (HBD-1) gene and mouse beta-defensin-1 gene at both the nucleic acid and amino acid levels and was termed rat beta-defensin-1 (RBD-1). The other gene, named RBD-2, was homologous to the HBD-2 and bovine tracheal antimicrobial peptide (TAP) genes. The predicted prepropeptides were strongly cationic, were 69 and 63 residues in length for RBD-1 and RBD-2, respectively, and contained the six-cysteine motif characteristic of beta-defensins. The beta-defensin genes mapped closely on rat chromosome 16 and were closely linked to the alpha-defensins genes, suggesting that they are part of a gene cluster, similar to the organization reported for humans. Northern blot analysis showed that both RBD-1 and RBD-2 mRNA transcripts were approximately 0.5 kb in length; RBD-1 mRNA was abundantly transcribed in the rat kidney, while RBD-2 was prevalent in the lung. Reverse transcription-PCR indicated that RBD-1 and RBD-2 mRNAs were distributed in a variety of other tissues. In the lung, RBD-1 mRNA expression localized to the tracheal epithelium while RBD-2 was expressed in alveolar type II cells. In conclusion, we characterized two novel beta-defensin homologues in the rat. The rat may be a useful model to investigate the function and contribution of beta-defensins to host defense in the lung, kidney, and other tissues.

Four avian beta-defension prepropeptide cDNA sequences [gallinacins: Gal 1 (synonym CHP 1, chicken heterophil peptide 1), and Gal 2; turkey heterophil peptides: THP 1 and THP 2] were amplified from chicken or turkey bone marrow mRNA samples, respectively. Partial chicken beta-defensin cDNA sequences were obtained using degenerate primers based on chicken peptide sequences (Gal 1/CHP 1 and Gal 2). The complete cDNA sequences of the chicken beta-defensins were then determined by designing specific intrapeptidal primers, from the newly acquired sequence, and pairing one primer with a specific poly A primer tail sequence (3' end) and the other primer with an adapter primer in a 5' rapid amplification of cDNA ends (RACE) reaction. The two, turkey beta-defensins were amplified from turkey marrow using primers designed from chicken beta-defensin preproregions. The complete amino acid sequences for the prepropeptides were deduced for all four avian beta-defensins. Previously, only partial mature peptide sequences for the turkey beta-defensins and complete mature peptide sequences for the chicken beta-defensins were known. All sequences obtained translated accurately to complete and partial amino acid sequences reported for beta-defensins purified from chicken and turkey heterophil granules except for one additional amino acid for Gal 1/CHP 1. The four deduced beta-defensin proregions lack the long, negatively charged propiece reported in classical defensin proregions. These regions are thought to stabilize and inactivate the positively charged mature peptide and target the propeptide to the storage granule. Instead, these beta-defensin proregions are shorter and similar to storage granule-free beta-defensins proregions reported for bovine tracheal antimicrobial peptide (TAP) and lingual antimicrobial peptide (LAP). These are the first prepropeptide beta-defensins from leukocyte granules to be completely characterized.