Ramosin: The First Antibacterial Peptide Identified on Bolitoglossa ramosi Colombian Salamander.

The discovery and improvements of antimicrobial peptides (AMPs) have become an alternative to conventional antibiotics. They are usually small and heat-stable peptides, exhibiting inhibitory activity against Gram-negative and Gram-positive bacteria. In this way, studies on broad-spectrum AMPs found in amphibians with the remarkable capability to regenerate a wide array of tissues are of particular interest in the search for new strategies to treat multidrug-resistant bacterial strains. In this work, the use of bioinformatic approaches such as sequence alignment with Fasta36 and prediction of antimicrobial activity allowed the identification of the Ramosin peptide from the de novo assembled transcriptome of the plethodontid salamander Bolitoglossa ramosi obtained from post-amputation of the upper limb tissue, heart, and intestine samples. BLAST analysis revealed that the Ramosin peptide sequence is unique in Bolitoglossa ramosi. The peptide was chemically synthesized, and physicochemical properties were characterized. Furthermore, the in vitro antimicrobial activity against relevant Gram-positive and Gram-negative human pathogenic bacteria was demonstrated. Finally, no effect against eukaryotic cells or human red blood cells was evidenced. This is the first antibacterial peptide identified from a Colombian endemic salamander with interesting antimicrobial properties and no hemolytic activity.

Post-amputation reactive oxygen species production is necessary for axolotls limb regeneration.

Introduction: Reactive oxygen species (ROS) represent molecules of great interest in the field of regenerative biology since several animal models require their production to promote and favor tissue, organ, and appendage regeneration. Recently, it has been shown that the production of ROS such as hydrogen peroxide (H2O2) is required for tail regeneration in Ambystoma mexicanum. However, to date, it is unknown whether ROS production is necessary for limb regeneration in this animal model. Methods: forelimbs of juvenile animals were amputated proximally and the dynamics of ROS production was determined using 2'7- dichlorofluorescein diacetate (DCFDA) during the regeneration process. Inhibition of ROS production was performed using the NADPH oxidase inhibitor apocynin. Subsequently, a rescue assay was performed using exogenous hydrogen peroxide (H2O2). The effect of these treatments on the size and skeletal structures of the regenerated limb was evaluated by staining with alcian blue and alizarin red, as well as the effect on blastema formation, cell proliferation, immune cell recruitment, and expression of genes related to proximal-distal identity. Results: our results show that inhibition of post-amputation limb ROS production in the A. mexicanum salamander model results in the regeneration of a miniature limb with a significant reduction in the size of skeletal elements such as the ulna, radius, and overall autopod. Additionally, other effects such as decrease in the number of carpals, defective joint morphology, and failure of integrity between the regenerated structure and the remaining tissue were identified. In addition, this treatment affected blastema formation and induced a reduction in the levels of cell proliferation in this structure, as well as a reduction in the number of CD45+ and CD11b + immune system cells. On the other hand, blocking ROS production affected the expression of proximo-distal identity genes such as Aldha1a1, Rarß, Prod1, Meis1, Hoxa13, and other genes such as Agr2 and Yap1 in early/mid blastema. Of great interest, the failure in blastema formation, skeletal alterations, as well as the expression of the genes evaluated were rescued by the application of exogenous H2O2, suggesting that ROS/H2O2 production is necessary from the early stages for proper regeneration and patterning of the limb.

Hydrogen peroxide is necessary during tail regeneration in juvenile axolotl.

BACKGROUND: Hydrogen peroxide (H2 O2 ) is a key reactive oxygen species (ROS) generated during appendage regeneration among vertebrates. However, its role during tail regeneration in axolotl as redox signaling molecule is unclear. RESULTS: Treatment with exogenous H2 O2 rescues inhibitory effects of apocynin-induced growth suppression in tail blastema cells leading to cell proliferation. H2 O2 also promotes recruitment of immune cells, regulate the activation of AKT kinase and Agr2 expression during blastema formation. Additionally, ROS/H2 O2 regulates the expression and transcriptional activity of Yap1 and its target genes Ctgf and Areg. CONCLUSIONS: These results show that H2 O2 is necessary and sufficient to promote tail regeneration in axolotls. Additionally, Akt signaling and Agr2 were identified as ROS targets, suggesting that ROS/H2 O2 is likely to regulate epimorphic regeneration through these signaling pathways. In addition, ROS/H2 O2 -dependent-Yap1 activity is required during tail regeneration.

Hey1 gene expression patterns during the development of branchial arches and facial prominences / Patrones de expresión del gen Hey1 durante el desarrollo de arcos branquiales y prominencias faciales

ABSTRACT Objective. The present study aimed to describe in detail the expression patterns of the gene Hey1, an effector of the Notch pathway, during the development of branchial arches and facial prominences. Materials and methods. Fertilized chicken (Gallus gallus) eggs obtained from a local egg farm were incubated at 37.5 -38.5ºC with 70% relative humidity until the embryos reached Hamilton-Hamburger stages HH14 through HH25. Digoxigenin-UTP labeled probes Hey1 were generated from linearized plasmids with either T3 polimerase for in vitro transcription. Whole-mount in situ hybridization was then performed. At least 3 replicates (n=3) were obtained for each stage. To confirm the results observed in whole embryos, sagittal and coronal cryosectioning was performed using a thickness of 10 µm. Results. During developmental stages HH14 and HH18, Hey1 gene expression was localized to the endoderm of branchial pouches. Hey1 gene expression was also observed in the epithelium that covers the maxillary and mandibular prominences during developmental stages HH19 and HH21, as well as in the nasal epithelium between HH19 and HH25. Transcripts were also detected in the epithelium that covers the frontonasal prominence during stage HH21. Conclusions. These expression patterns suggest the participation of this component of the Notch signaling pathway in craniofacial morphogenesis, possibly establishing pharyngeal segmentation patterns during early stages and/or regulating cell proliferation and differentiation during the late stages of facial development.

RESUMEN Objetivo. El presente estudio tuvo como objetivo describir detalladamente los patrones de expresión del gen Hey1, un efector de la vía Notch durante el desarrollo de arcos branquiales y prominencias faciales. Materiales y métodos. Se incubaron huevos fertilizados de pollo (Gallus gallus) obtenidos de una granja local entre 37.5-38.5ºC con humedad relativa del 70% hasta que los embriones alcanzaron los estadios HH14 hasta HH25 de Hamilton-Hamburger. Las sondas Hey1 marcadas con digoxigenina-UTP se generaron a partir de plásmidos linearizados con T3 polimerasa por transcripción in vitro. Luego se realizó hibridación in situ sobre embriones completos. Se obtuvieron al menos 3 repeticiones (n=3) para cada estadio. Para confirmar los resultados observados en embriones completos, se realizaron cortes sagitales y coronales de 10 µm. Resultados. Durante los estadios de desarrollo HH14 y HH18, la expresión del gen Hey1 se localizó en el endodermo de las bolsas branquiales. La expresión génica de Hey1 también se observó en el epitelio que cubre las prominencias maxilares y mandibulares durante las etapas de desarrollo HH19 y HH21, así como en el epitelio nasal entre HH19 y HH25. También se detectaron transcritos de Hey1 en el epitelio que cubre la prominencia frontonasal durante la etapa HH21. Conclusiones. Estos patrones de expresión sugieren la participación de este componente de la vía de señalización Notch en la morfogénesis craneofacial, posiblemente estableciendo patrones de segmentación faríngea durante las primeras etapas y / o regulando la proliferación y diferenciación celular durante las últimas etapas del desarrollo facial.