2. Universidad Cardenal Herrera-CEU
Permanent URI for this communityhttps://hdl.handle.net/10637/13
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- Building a "Genetics Social Network" for innovative teaching in Veterinary education
2024 Introduction: Practical competencies are crucial in teaching genetics to veterinary students, enabling them to master molecular genetics techniques for identifying genetic variants and diagnosing genetic diseases encountered in their professional practice. The Ā«Genetics Social NetworkĀ»ā project aims to bridge the gap between theoretical knowledge and practical experience in genetics for veterinary students. By leveraging their familiarity and interest in new technologies, a shift from practice to praxis is proposed, enhancing student engagement, and aligning learning outcomes. This project aims to involve students in teaching by asking them to generate audiovisual material to review genetics techniques, fostering collaborative work and responsibility and enhancing laboratory skills and precision, transforming theory into lived experience. Materials and Methods: The project spanned two academic years, taking place within the practical sessions of the genetics course. A list of the developed molecular genetics techniques was compiled and participating students, usually organized in groups, selected one of them and utilized a part of the session time to produce micro-videos, akin to those on social media platforms. These micro-videos succinctly explained the key steps of the technique and practical tips. Using the Blackboard virtual teaching platform, a dedicated folder was created for sharing the generated micro-videos, enabling all classmates to access them for exam preparation. Additionally, voluntary participation in this project allows students to earn a micro-credential within the Veterinary Communication pathway. Results and discussion: After analysing the results of the first implementation of the project, enhancements were made to the presentation of the project to the students, aiming to promote greater acceptance. The results indicated an increase in student participation and engagement in the second year. Students reported a deeper understanding of genetic practices and expressed appreciation for the hands-on experience the project provided. The social network aspect fostered a sense of community and peer support, which was reflected in improved practical skills. Challenges included fostering increased student engagement and making video editing tools available and familiar to students, thereby enabling those who may hesitate to participate due to resource constraints to contribute as well. Conclusions: The Ā«Genetics Social NetworkĀ» has demonstrated potential as an effective tool for veterinary education, merging traditional learning with digital innovation. It has shown that when studentsā technological affinity is harnessed for educational purposes, it can lead to enhanced learning outcomes. This project serves as a model for future educational innovations, suggesting that the integration of social technology in academia can be both beneficial and transformative.
- Bacteriophage-mediated spread of bacterial virulence genes
2015-02 Bacteriophages are types of viruses that infect bacteria. They are the most abundant and diverse entities in the biosphere, and influence the evolution of most bacterial species by promoting gene transfer, sometimes in unexpected ways. Although pac-type phages can randomly package and transfer bacterial DNA by a process called generalized transduction, some mobile genetic elements have developed elegant and sophisticated strategies to hijack the phage DNA-packaging machinery for their own transfer. Moreover, phage-like particles (gene transfer agents) have also evolved, that can package random pieces of the producing cell's genome. The purpose of this review is to give an overview of some of the various ways by which phages and phage-like particles can transfer bacterial genes, driving bacterial evolution and promoting the emergence of novel pathogens.
- Intra- and inter-generic transfer of pathogenicity island-encoded virulence genes by cos phages
2015-05 Bacteriophage-mediated horizontal gene transfer is one of the primary driving forces of bacterial evolution. The pac-type phages are generally thought to facilitate most of the phage-mediated gene transfer between closely related bacteria, including that of mobile genetic elements-encoded virulence genes. In this study, we report that staphylococcal cos-type phages transferred the Staphylococcus aureus pathogenicity island SaPIbov5 to non-aureus staphylococcal species and also to different genera. Our results describe the first intra- and intergeneric transfer of a pathogenicity island by a cos phage, and highlight a gene transfer mechanism that may have important implications for pathogen evolution.
- Genome hypermobility by lateral transduction
2018-10-12 Genetic transduction is a major evolutionary force that underlies bacterial adaptation.Here we report that the temperate bacteriophages ofStaphylococcusaureusengage in adistinct form of transduction we term lateral transduction. Staphylococcal prophagesdo not follow the previously described excision-replication-packaging pathway but insteadexcise late in their lytic program. Here, DNA packaging initiates in situ from integratedprophages, and large metameric spans including several hundred kilobases of theS.aureusgenome are packaged in phage heads at very high frequency. In situ replication beforeDNA packaging creates multiple prophage genomes so that lateral-transducing particles formduring normal phage maturation, transforming parts of theS.aureuschromosome intohypermobile regions of gene transfer.
- Unbalanced redox status network as an early pathological event in congenital cataracts
2023-10 The lens proteome undergoes dramatic composition changes during development and maturation. A defective developmental process leads to congenital cataracts that account for about 30% of cases of childhood blindness. Gene mutations are associated with approximately 50% of early-onset forms of lens opacity, with the remainder being of unknown etiology. To gain a better understanding of cataractogenesis, we utilized a transgenic mouse model expressing a mutant ubiquitin protein in the lens (K6W-Ub) that recapitulates most of the early pathological changes seen in human congenital cataracts. We performed mass spectrometry-based tandem-mass-tag quantitative proteomics in E15, P1, and P30 control or K6W-Ub lenses. Our analysis identified targets that are required for early normal differentiation steps and altered in cataractous lenses, particularly metabolic pathways involving glutathione and amino acids. Computational molecular phenotyping revealed that glutathione and taurine were spatially altered in the K6W-Ub cataractous lens. High-performance liquid chromatography revealed that both taurine and the ratio of reduced glutathione to oxidized glutathione, two indicators of redox status, were differentially compromised in lens biology. In sum, our research documents that dynamic proteome changes in a mouse model of congenital cataracts impact redox biology in lens. Our findings shed light on the molecular mechanisms associated with congenital cataracts and point out that unbalanced redox status due to reduced levels of taurine and glutathione, metabolites already linked to age-related cataract, could be a major underlying mechanism behind lens opacities that appear early in life.