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Nikolaos Vakirlis

Showing results (1-10 of 21) with videos related to

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Genome Research|July 8, 2024
Large-scale investigation of species-specific orphan genes in the human gut microbiome elucidates their evolutionary originsNikolaos Vakirlis, Anne Kupczok
Methods in Molecular Biology (Clifton, N.J.)|October 10, 2018
Computational Prediction of De Novo Emerged Protein-Coding GenesNikolaos Vakirlis, Aoife McLysaght
Journal of Evolutionary Biology|July 12, 2025
Intergenic polyA/T tracts explain the propensity of yeast de novo genes to encode transmembrane domainsNikolaos Vakirlis, Timothy Fuqua
Genome Biology and Evolution|January 18, 2026
Degradation determinants are abundant in human noncanonical proteins and minor annotated isoformsClaudio Casola, Adekola Owoyemi, Nikolaos Vakirlis
Molecular Biology and Evolution|March 14, 2023
Intergenic Regions of Saccharomycotina Yeasts are Enriched in Potential to Encode Transmembrane DomainsEmilios Tassios, Christoforos Nikolaou, Nikolaos Vakirlis
Elife|February 19, 2020
Synteny-based analyses indicate that sequence divergence is not the main source of orphan genesNikolaos Vakirlis, Anne-Ruxandra Carvunis, Aoife McLysaght
Genome Biology and Evolution|November 28, 2025
De Novo Genes: Current Status and Future GoalsClaudio Casola, Victor Luria, Nikolaos Vakirlis, et al.
Cell Reports|December 21, 2022
De novo birth of functional microproteins in the human lineageNikolaos Vakirlis, Zoe Vance, Kate M Duggan, et al.
Genome Biology and Evolution|July 15, 2024
Ancestral Sequence Reconstruction as a Tool to Detect and Study De Novo Gene EmergenceNikolaos Vakirlis, Omer Acar, Vijay Cherupally, et al.
Bioinformatics Advances|February 16, 2026
Machine learning can distinguish orphans that have resulted from sequence divergence beyond recognitionEmilios Tassios, Jori de Leuw, Christoforos Nikolaou, et al.
Pageof 3

Showing results (1-10 of 21) with videos related to

Sort By:
Pageof 3
Genome Research|July 8, 2024
Large-scale investigation of species-specific orphan genes in the human gut microbiome elucidates their evolutionary originsNikolaos Vakirlis, Anne Kupczok
Methods in Molecular Biology (Clifton, N.J.)|October 10, 2018
Computational Prediction of De Novo Emerged Protein-Coding GenesNikolaos Vakirlis, Aoife McLysaght
Journal of Evolutionary Biology|July 12, 2025
Intergenic polyA/T tracts explain the propensity of yeast de novo genes to encode transmembrane domainsNikolaos Vakirlis, Timothy Fuqua
Genome Biology and Evolution|January 18, 2026
Degradation determinants are abundant in human noncanonical proteins and minor annotated isoformsClaudio Casola, Adekola Owoyemi, Nikolaos Vakirlis
Molecular Biology and Evolution|March 14, 2023
Intergenic Regions of Saccharomycotina Yeasts are Enriched in Potential to Encode Transmembrane DomainsEmilios Tassios, Christoforos Nikolaou, Nikolaos Vakirlis
Elife|February 19, 2020
Synteny-based analyses indicate that sequence divergence is not the main source of orphan genesNikolaos Vakirlis, Anne-Ruxandra Carvunis, Aoife McLysaght
Genome Biology and Evolution|November 28, 2025
De Novo Genes: Current Status and Future GoalsClaudio Casola, Victor Luria, Nikolaos Vakirlis, et al.
Cell Reports|December 21, 2022
De novo birth of functional microproteins in the human lineageNikolaos Vakirlis, Zoe Vance, Kate M Duggan, et al.
Genome Biology and Evolution|July 15, 2024
Ancestral Sequence Reconstruction as a Tool to Detect and Study De Novo Gene EmergenceNikolaos Vakirlis, Omer Acar, Vijay Cherupally, et al.
Bioinformatics Advances|February 16, 2026
Machine learning can distinguish orphans that have resulted from sequence divergence beyond recognitionEmilios Tassios, Jori de Leuw, Christoforos Nikolaou, et al.
Pageof 3