Your search keyword '"Alden Deran"' showing total 7 results

1. Positive selection in noncoding genomic regions of vocal learning birds is associated with genes implicated in vocal learning and speech functions in humans

Author

Carolyn J. Khoury, David Haussler, Joel Armstrong, Alden Deran, James A. Cahill, Benedict Paten, and Erich D. Jarvis

Subjects

Vocal communication, Bioinformatics, Autism, Intellectual and Developmental Disabilities (IDD), education, Biology, Basic Behavioral and Social Science, Medical and Health Sciences, Vocalization, Songbirds, Behavioral and Social Science, otorhinolaryngologic diseases, Genetics, medicine, Animals, Humans, Learning, Speech, Gene, Genetics (clinical), Animal, Research, Tumor Suppressor Proteins, Positive selection, Brain, FOXP2, Genomics, Biological Sciences, medicine.disease, Brain Disorders, Repressor Proteins, Mental Health, Evolutionary biology, Vocal learning, Vocalization, Animal, Spoken language

Abstract

Vocal learning, the ability to imitate sounds from conspecifics and the environment, is a key component of human spoken language and learned song in three independently evolved avian groups—oscine songbirds, parrots, and hummingbirds. Humans and each of these three bird clades exhibit specialized behavioral, neuroanatomical, and brain gene expression convergence related to vocal learning, speech, and song. To understand the evolutionary basis of vocal learning gene specializations and convergence, we searched for and identified accelerated genomic regions (ARs), a marker of positive selection, specific to vocal learning birds. We found avian vocal learner-specific ARs, and they were enriched in noncoding regions near genes with known speech functions or brain gene expression specializations in humans and vocal learning birds, including FOXP2, NEUROD6, ZEB2, and MEF2C, and near genes with major neurodevelopmental functions, including NR2F1, NRP2, and BCL11B. We also found enrichment near the SFARI class S genes associated with syndromic vocal communication forms of autism spectrum disorders. These findings reveal strong candidate noncoding regions near genes for the evolutionary adaptations that distinguish vocal learning species from their close vocal nonlearning relatives and provide further evidence of molecular convergence between birdsong and human spoken language.

Published

2021

2. Progressive Cactus is a multiple-genome aligner for the thousand-genome era

Author

Alden Deran, Benedict Paten, Jeremy A. Johnson, Qi Fang, Jessica Alföldi, David Haussler, Ian T. Fiddes, Robert S. Harris, Elinor K. Karlsson, Duo Xie, Erich D. Jarvis, Mark Diekhans, Voichita D. Marinescu, Kerstin Lindblad-Toh, Glenn Hickey, Josefin Stiller, Joel Armstrong, Adam M. Novak, Diane P. Genereux, Guojie Zhang, and Shaohong Feng

Subjects

Cactaceae, Quality Control, Genome evolution, General Science & Technology, MEDLINE, Computational biology, Vertebrate genome, Biology, Genome informatics, Biochemistry, Genome, Article, Phylogenetics, Genetics, Animals, Humans, Computer Simulation, Amnion, Genetik, Molecular Biology, Scaling, Phylogeny, Comparative genomics, Multidisciplinary, Extramural, Human Genome, Cell Biology, Genomics, Current analysis, Haplotypes, Evolutionary biology, Vertebrates, Genome alignment, Sequence Alignment, Algorithms, Software, Biotechnology

Abstract

New genome assemblies have been arriving at a rapidly increasing pace, thanks to decreases in sequencing costs and improvements in third-generation sequencing technologies1–3. For example, the number of vertebrate genome assemblies currently in the NCBI (National Center for Biotechnology Information) database4 increased by more than 50% to 1,485 assemblies in the year from July 2018 to July 2019. In addition to this influx of assemblies from different species, new human de novo assemblies5 are being produced, which enable the analysis of not only small polymorphisms, but also complex, large-scale structural differences between human individuals and haplotypes. This coming era and its unprecedented amount of data offer the opportunity to uncover many insights into genome evolution but also present challenges in how to adapt current analysis methods to meet the increased scale. Cactus6, a reference-free multiple genome alignment program, has been shown to be highly accurate, but the existing implementation scales poorly with increasing numbers of genomes, and struggles in regions of highly duplicated sequences. Here we describe progressive extensions to Cactus to create Progressive Cactus, which enables the reference-free alignment of tens to thousands of large vertebrate genomes while maintaining high alignment quality. We describe results from an alignment of more than 600 amniote genomes, which is to our knowledge the largest multiple vertebrate genome alignment created so far., The Progressive Cactus program can create reference-free alignments of hundreds of large vertebrate genomes efficiently, and is used for the alignment of more than 600 amniote genomes.

Published

2020

3. Improved genome assembly of American alligator genome reveals conserved architecture of estrogen signaling

Author

Ian T. Fiddes, Richard E. Green, Carl J. Schmidt, John St. John, Cathy Gresham, Liana F. Lareau, Joel Armstrong, Edward S. Rice, Satomi Kohno, Jonathan M. Howard, Colin Kern, David Haan, David A. Ray, Brendan O'Connell, Tan Phan, Jeremy R. Sanford, Roy N. Platt, Alden Deran, Son Pham, Benedict Paten, Fiona M. McCarthy, Glenn Hickey, and Louis J. Guillette

Subjects

Male, 0301 basic medicine, CCCTC-Binding Factor, Bioinformatics, Sequence analysis, 1.1 Normal biological development and functioning, Alligator, Genomics, Medical and Health Sciences, Synteny, Genome, Conserved sequence, Contig Mapping, 03 medical and health sciences, 0302 clinical medicine, Underpinning research, biology.animal, Gene expression, Genetics, Animals, American alligator, Gene, Conserved Sequence, Genetics (clinical), Alligators and Crocodiles, biology, Research, Human Genome, Embryo, Estrogens, DNA, Sequence Analysis, DNA, Biological Sciences, Sex Determination Processes, biology.organism_classification, Estrogen, Chromatin, 030104 developmental biology, Female, Sequence Analysis, 030217 neurology & neurosurgery, Signal Transduction

Abstract

The American alligator, Alligator mississippiensis, like all crocodilians, has temperature-dependent sex determination, in which the sex of an embryo is determined by the incubation temperature of the egg during a critical period of development. The lack of genetic differences between male and female alligators leaves open the question of how the genes responsible for sex determination and differentiation are regulated. One insight into this question comes from the fact that exposing an embryo incubated at male-producing temperature to estrogen causes it to develop ovaries. Because estrogen response elements are known to regulate genes over long distances, a contiguous genome assembly is crucial for predicting and understanding its impact.We present an improved assembly of the American alligator genome, scaffolded with in vitro proximity ligation (Chicago) data. We use this assembly to scaffold two other crocodilian genomes based on synteny. We perform RNA sequencing of tissues from American alligator embryos to find genes that are differentially expressed between embryos incubated at male-versus female-producing temperature. Finally, we use the improved contiguity of our assembly along with the current model of CTCF-mediated chromatin looping to predict regions of the genome likely to contain estrogen-responsive genes. We find that these regions are significantly enriched for genes with female-biased expression in developing gonads after the critical period during which sex is determined by incubation temperature. We thus conclude that estrogen signaling is a major driver of female-biased gene expression in the post-temperature sensitive period gonads.

Published

2017

4. Progressive alignment with Cactus: a multiple-genome aligner for the thousand-genome era

Author

Joel Armstrong, Glenn Hickey, Mark Diekhans, Alden Deran, Qi Fang, Duo Xie, Shaohong Feng, Josefin Stiller, Diane Genereux, Jeremy Johnson, Voichita Dana Marinescu, David Haussler, Jessica Alföldi, Kerstin Lindblad-Toh, Elinor Karlsson, Erich D. Jarvis, Guojie Zhang, and Benedict Paten

Subjects

Computer science, Cactus, Genome alignment, Computational biology, Vertebrate genome, Genome

Abstract

Cactus, a reference-free multiple genome alignment program, has been shown to be highly accurate, but the existing implementation scales poorly with increasing numbers of genomes, and struggles in regions of highly duplicated sequence. We describe progressive extensions to Cactus that enable reference-free alignment of tens to thousands of large vertebrate genomes while maintaining high alignment quality. We show that Cactus is capable of scaling to hundreds of genomes and beyond by describing results from an alignment of over 600 amniote genomes, which is to our knowledge the largest multiple vertebrate genome alignment yet created. Further, we show improvements in orthology resolution leading to downstream improvements in annotation.

Published

2019

5. Toil enables reproducible, open source, big biomedical data analyses

Author

Christopher Ketchum, Audrey Musselman-Brown, Melissa S. Cline, Kate R. Rosenbloom, Alden Deran, John Vivian, Jingchun Zhu, Megan Hanna, Peter Amstutz, Benedict Paten, Jake Narkizian, David Haussler, Anthony D. Joseph, Sasha Zaranek, W. James Kent, Brian Craft, Mary Goldman, Chet Birger, Arjun A. Rao, Gad Getz, Hannes Schmidt, Jacob Pfeil, David A. Patterson, Brian O'Connor, Joel Armstrong, Frank Austin Nothaft, and Adam M. Novak

Subjects

0301 basic medicine, Electronic Data Processing, Biomedical Research, Database, Computer science, business.industry, Extramural, Biomedical Engineering, Bioengineering, Cloud computing, computer.software_genre, Applied Microbiology and Biotechnology, Article, 03 medical and health sciences, 030104 developmental biology, Open source, Workflow, Software, Biomedical data, Humans, Molecular Medicine, business, computer, Biotechnology

Abstract

Toil is portable, open-source workflow software that supports contemporary workflow definition languages and can be used to securely and reproducibly run scientific workflows efficiently at large-scale. To demonstrate Toil, we processed over 20,000 RNA-seq samples to create a consistent meta-analysis of five datasets free of computational batch effects that we make freely available. Nearly all the samples were analysed in under four days using a commercial cloud cluster of 32,000 preemptable cores.

Published

2017

6. Rapid and efficient analysis of 20,000 RNA-seq samples with Toil

Author

W. James Kent, Brian Craft, Chet Birger, Christopher Ketchum, Sasha Zaranek, Gad Getz, Melissa S. Cline, John Vivian, Jingchun Zhu, Benedict Paten, Peter Amstutz, Megan Hanna, David Haussler, Anthony D. Joseph, Kate R. Rosenbloom, Jake Narkizian, Audrey Musselman-Brown, Arjun A. Rao, Hannes Schmidt, Mary Goldman, Alden Deran, Brian O'Connor, Jacob Pfeil, Adam M. Novak, Joel Armstrong, Frank Austin Nothaft, and David A. Patterson

Subjects

0303 health sciences, Database, business.industry, Computer science, Cloud computing, computer.software_genre, 03 medical and health sciences, 0302 clinical medicine, Workflow, Data mining, business, computer, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Toil is portable, open-source workflow software that supports contemporary workflow definition languages and can be used to securely and reproducibly run scientific workflows efficiently at large-scale. To demonstrate Toil, we processed over 20,000 RNA-seq samples to create a consistent meta-analysis of five datasets free of computational batch effects that we make freely available. Nearly all the samples were analysed in under four days using a commercial cloud cluster of 32,000 preemptable cores.

Published

2016

7. A community challenge for inferring genetic predictors of gene essentialities through analysis of a functional screen of cancer cell lines

Author

Mehmet Gönen, Barbara A. Weir, Glenn S. Cowley, Francisca Vazquez, Yuanfang Guan, Alok Jaiswal, Masayuki Karasuyama, Vladislav Uzunangelov, Tao Wang, Aviad Tsherniak, Sara Howell, Daniel Marbach, Bruce Hoff, Thea C. Norman, Antti Airola, Adrian Bivol, Kerstin Bunte, Daniel Carlin, Sahil Chopra, Alden Deran, Kyle Ellrott, Peddinti Gopalacharyulu, Kiley Graim, Samuel Kaski, Suleiman A. Khan, Yulia Newton, Sam Ng, Tapio Pahikkala, Evan Paull, Artem Sokolov, Hao Tang, Jing Tang, Krister Wennerberg, Yang Xie, Xiaowei Zhan, Fan Zhu, Tero Aittokallio, Hiroshi Mamitsuka, Joshua M. Stuart, Jesse S. Boehm, David E. Root, Guanghua Xiao, Gustavo Stolovitzky, William C. Hahn, Adam A. Margolin, Bahman Afsari, Yu-Chuan Chang, Tenghui Chen, Zechen Chong, Haitham Elmarakeby, Elana J. Fertig, Emanuel Gonçalves, Pinghua Gong, Christoph Hafemeister, Lenwood Heath, Łukasz Kędziorski, Niraj Khemka, Erh-kan King, Mario Lauria, Mark Liu, Daniel Machado, Mateusz Mazurkiewicz, Michael P. Menden, Szymon Migacz, Zhi Nie, Paurush Praveen, Corrado Priami, Simone Rizzetto, Miguel Rocha, Cameron Rudd, Witold R. Rudnicki, Julio Saez-Rodriguez, Lei Song, Duanchen Sun, Bence Szalai, Difei Wang, Ling-yun Wu, Jieping Ye, Yuting Ye, and Wanding Zhou

Subjects

0301 basic medicine, Histology, Gene Expression, Computational biology, Biology, Data type, Article, cancer genomics, community challenge, crowdsourcing, functional screen, machine learning, oncogene, 2734, Cell Biology, Pathology and Forensic Medicine, 03 medical and health sciences, Open research, Cell Line, Tumor, Humans, RNA, Small Interfering, Gene, ta217, ta113, Genetics, Genes, Essential, ta1184, Genomics, ta3122, 030104 developmental biology, Community resource, Identification (biology), Cancer cell lines, Algorithms, Genetic screen

Abstract

Summary We report the results of a DREAM challenge designed to predict relative genetic essentialities based on a novel dataset testing 98,000 shRNAs against 149 molecularly characterized cancer cell lines. We analyzed the results of over 3,000 submissions over a period of 4 months. We found that algorithms combining essentiality data across multiple genes demonstrated increased accuracy; gene expression was the most informative molecular data type; the identity of the gene being predicted was far more important than the modeling strategy; well-predicted genes and selected molecular features showed enrichment in functional categories; and frequently selected expression features correlated with survival in primary tumors. This study establishes benchmarks for gene essentiality prediction, presents a community resource for future comparison with this benchmark, and provides insights into factors influencing the ability to predict gene essentiality from functional genetic screens. This study also demonstrates the value of releasing pre-publication data publicly to engage the community in an open research collaboration.

Published

2017