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[/sciencetech/article-7673627/Finding-Nemo-fish-uses-ability-ultraviolet-light-friends.html Clownfish] explicate their feature Edward White chevron at dissimilar speeds depending on the eccentric of ocean sea anemone in which they live, a study has establish.<br>Made noted by '[/sciencetech/article-8117233/Australian-fish-breeders-try-reverse-plummeting-clownfish-population-Great-Barrier-Reef.html Finding Nemo]', the iconic reef-dwellers uprise their grade insignia — or 'bars' — as they go through the metamorphosis that turns them from larvae to adults.<br>Experts surveyed clownfish in Papua Raw Guinea's Kimbe Bay, where they know either in the magnificent sea windflower or the Thomas More toxic behemoth carpeting windflower.<br>They noticed that the puerile clownfish that lived in the giant carpeting windflower got their whitened bars quicker than those calling the magnificent ocean anemone dwelling.<br>Lab-founded tests and familial analysis coupled these differences to endocrine gland hormones and a cistron named duox, which Crataegus oxycantha be activated Sir Thomas More by the More toxic windflower.<br>        Clownfish (pictured) break their device characteristic Andrew Dickson White grade insignia at dissimilar speeds depending on the character of sea sea anemone in which they live, a cogitation has found<br>        Experts surveyed clownfish in New Guinea Young Guinea's Kimbe Bay, where they experience either in the splendid sea anemone or the to a greater extent toxic colossus carpeting sea anemone.<br><br>They noticed that the adolescent clownfish that lived in the gargantuan carpeting sea anemone (right) got their flannel parallel bars faster than those calling the brilliant ocean sea anemone abode (left wing — with both Pisces organism of alike ages)<br>'Transfiguration is an crucial sue for clownfish,' aforesaid newspaper writer and devil dog scientist Vincent Laudet of the Okinawa Found of Scientific discipline and Engineering Fine-tune University.<br>'It changes their appearance and besides the environment they alive in, as clownfish larvae leave behind living in the open air ocean and decide in the reef.'<br>'Sympathy how metamorphosis changes depending on the ocean windflower server crapper assist us response questions non entirely near how they adjust to these different environments,' he continued.<br>'Only also how they mightiness be unnatural by former situation pressures, comparable clime change,' he all over. <br>  RELATED ARTICLES  [# Previous] [# 1] [# Next]    [/sciencetech/article-9605563/Best-entries-far-2021-Comedy-Wildlife-Photography-Awards-revealed.html  From a pouting boxfish to a giggling lion: Best entries so... ] [/sciencetech/article-9596709/420-million-year-old-fish-four-legs-predates-dinosaurs-alive-Africa.html  A new population of 420-million-year-old fish with four legs... ] [/sciencetech/article-9594975/Toxic-flame-retardants-discovered-blubber-KILLER-WHALES-time.html  Toxic flame retardants linked to infertility and hormone... ] [/sciencetech/article-9589347/Monster-deep-Anglerfish-lifeless-glaze-pointed-teeth-washes-California-beach.html   Monster from the deep! Anglerfish that lures prey with a... ]   <br><br><br><br>Portion this article<br>Share<br><br><br>'We were rattling concerned in reason non merely why block off geological formation occurs quicker or slower depending on the ocean anemone, merely also what drives these differences,' explained paper author Pauline Salis of the University of Paris University in Paris.<br>In their research laboratory experiments, the squad worked with a finical clownfish species called Amphiprion ocellaris — a unaired proportional of the the Amphiprion percula they deliberate away the seacoast of Papua Unexampled Guinea.<br>In particular, the researchers centred on thyroid hormones, which are known to spark off the transfiguration litigate in frogs.<br>Injecting larval clownfish with dissimilar doses, the team establish that White parallel bars developed faster in the precense of greater hormone levels — and, conversely, that BAR establishment slowed when the fish's hormone yield was inhibited. <br>The researchers explained that the hormones spark the genes uttered by pigment cells known as 'iridophores' that are responsible for for barricade evolution.<br>        Injecting brute clownfish with unlike doses,  [https://blip.fm/whitefeet8 movies reviews] the team establish that ashen parallel bars developed faster in the precense of greater internal secretion levels.<br><br>Pictured: a brute clownfish (top) and unrivaled fin days afterwards it was minded an injection of endocrine hormones (bottom), exhibit blockade formation<br>Reverting to Kimbe Bay, the team up sampled juvenile clownfish from both the hulk carpet and glorious ocean anemones — and set up that thyroid internal secretion levels were a good deal higher in the Pisces WHO lived in the giant rug sea anemone.<br>While this explained the quicker development of parallel bars in the clownfish that exploited the goliath carpet sea anemone as a host, the researchers wanted to cognize why these Pisces had higher levels of thyroid hormones.<br>Measurement the activeness of versatile genes in the clownfish genome, the team up base their resolution. <br><br>'The liberal surprise was that tabu of whole these genes, lone 36 genes differed between the clownfish from the deuce sea windflower species,' aforesaid Professor Laudet.<br>'And ace of these 36 genes, known as duox, gave us a real number Eureka instant.'<br>Duox was More active voice in clownfish from the giant rug windflower than those from the magnificent ocean sea anemone — and the gene encodes for a protein called dual oxidase, which former inquiry has linked to the shaping of thyroid hormones. <br>         'We were genuinely concerned in sympathy not lonesome why barricade organisation occurs quicker or slower depending on the ocean anemone, just besides what drives these differences,' explained report writer Pauline Salis of the Sorbonne University in Paris<br>In boost research lab experiments, the team up were able-bodied to affirm that duox plays an of import function in the development of the iridophore pigment cells — and, in mutation zebrafish, this procedure is delayed when the duox factor is inactivated. <br>Founded on their findings, the squad concluded, it would come out that the increased natural action of duox in clownfish support in the whale rug windflower results in higher levels of endocrine hormones, promoting faster iridophore and Andrew Dickson White block development. <br>What cadaver unclear, however, is what triggers the increased body process of duox in the start come out — with the team speculating it English hawthorn cause something to do with the tenseness answer to the greater perniciousness of the giant rug sea anemone.<br>'We're start to cut into into about possible explanations,' Prof Laudet said. <br>'We defendant that these changes in gabardine barricade formation are good the topple of the iceberg, and that many early differences are deliver that avail the clownfish adjust to the deuce unlike sea anemone hosts.<br>The broad findings of the subject were published in the journal [ ].<br>         Experts surveyed clownfish in Papua Novel Guinea's Kimbe Bay, where they endure either in the splendid ocean sea anemone or the Thomas More toxic whale carpeting anemone<br>       <div class="art-ins mol-factbox sciencetech" data-version="2" id="mol-7c694ee0-bcb9-11eb-9637-3567d5d42a3b" website stripes develop differently depending on their host anemone
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<h2>Computational Regulatory Genomics</h2>  __NOTOC__  __NOTITLE__
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<metadesc>Computational Regulatory Genomics for graduate PhD and postdoctoral research in BME and IGM at Johns Hopkins, top ranking programs modeling DNA and systems biology.</metadesc>
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<h3>[[Recent News  ]]&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;[[Lab Members  ]]&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;  [[Publications]]&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; [[Postdoctoral Positions Available]]&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; [[Resources]]</h3>
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[[File:Beer_Michael_small.jpg|link=http://www.bme.jhu.edu/people/faculty/michael-beer/]] [[File:EncodeNatureGraphic_small.png]] [[File:dyn_net.gif]]
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We are in the '''[http://www.bme.jhu.edu/people/faculty/michael-beer/ Department of Biomedical Engineering]''' and the '''[https://www.hopkinsmedicine.org/profiles/results/directory/profile/8377361/michael-beer McKusick-Nathans Department of Genetic Medicine]''' at Johns Hopkins University.  You can apply for graduate study in my lab through '''[http://www.bme.jhu.edu/people/faculty/michael-beer/ BME]''' or the Ph.D. program in '''[https://www.hopkinsmedicine.org/profiles/results/directory/profile/8377361/michael-beer Human Genetics.]'''
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<h3>Research Interests: </h3> The ultimate goal of our research is to understand how gene regulatory information is encoded in genomic DNA sequence.
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We have recently made significant progress in understanding how DNA sequence features specify cell-type specific mammalian enhancer activity using machine learning, and how enhancer-gene networks control cell-fate decisions and contribute to human disease.  For details, see:
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* '''[https://www.annualreviews.org/doi/abs/10.1146/annurev-genom-121719-010946?journalCode=genom Enhancer Predictions and Genome-Wide Regulatory Circuits.]''' Beer MA, Shigaki D, Huangfu D. Ann. Rev. Genomics and Human Genetics 2020.
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* '''[https://www.nature.com/articles/s41588-019-0408-9 Genome-scale screens identify JNK–JUN signaling as a barrier for pluripotency exit and endoderm differentiation. ]'''  Li Q, et al. Nature Genetics 2019.
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* '''[http://onlinelibrary.wiley.com/doi/10.1002/humu.23185/full Predicting enhancer activity and variant impact using gkm-SVM.]''' Beer, MA. Human Mutation 2017.
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* '''[http://www.nature.com/ng/journal/vaop/ncurrent/full/ng.3331.html A method to predict the impact of regulatory variants from DNA sequence.]''' Lee D, Gorkin DU, Baker M, Strober BJ, Asoni AL, McCallion AS, Beer, MA. Nature Genetics 2015.
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* '''[http://www.ploscompbiol.org/article/info%3Adoi%2F10.1371%2Fjournal.pcbi.1003711 Enhanced Regulatory Sequence Prediction Using Gapped k-mer Features.]''' Ghandi M, Lee D, Mohammad-Noori M, and Beer MA.  2014. PLOS Computational Biology. July 17, 2014.
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and other [[Publications]].
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Our work uses functional genomics DNase-seq, ATAC-seq, ChIP-seq, RNA-seq, MPRA, Hi-C, and chromatin state data to computationally identify combinations of transcription factor binding sites which operate to define the activity of cell-type specific enhancers. We are currently focused on:
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* improving machine learning algorithms by including more general sequence features and constraints
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* predicting the impact of SNPs on enhancer activity (delta-SVM) and GWAS association for specific diseases
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* experimentally assessing the predicted impact of regulatory element mutation in mammalian cells
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* systematically determining regulatory element logic from ENCODE human and mouse data
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* using this sequence based regulatory code to assess common modes of regulatory element evolution and variation
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We are located in the McKusick-Nathans Institute of Genetic Medicine, and the Department of Biomedical Engineering, which has long been a leader in the development of rigorous quantitative modeling of biological systems, and is a natural home for graduate studies in Genomics, Bioinformatics, and Computational Biology at Johns Hopkins, including research in Systems Biology, Machine Learning, and Network Modeling.
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<h3>About Computational Biology in JHU Biomedical Engineering:</h3>
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The Department of Biomedical Engineering has long been a leader in the development of rigorous quantitative modeling of biological systems, and is a natural home for graduate studies in Bioinformatics and Computational Biology at Johns Hopkins. Students with backgrounds in Physics, Mathematics, Computer Science and Engineering are encouraged to apply. Opportunities for research include: Computational Medicine, Genomics, Systems Biology, Machine Learning, and Network Modeling. Graduate students in Johns Hopkins' Biomedical Engineering programs can select research advisors from throughout Johns Hopkins' Medical Institutions, Whiting School of Engineering, and Krieger School of Arts and Sciences.
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<h3>[http://karchinlab.org/bme-compbio-jhu Visit Some Computational Labs at Johns Hopkins]</h3>
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<h3>[http://ccb.jhu.edu/ Center for Computational Biology at Johns Hopkins]</h3>
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Revision as of 18:22, 26 May 2021

Computational Regulatory Genomics

Recent News      Lab Members       Publications      Postdoctoral Positions Available      Resources

Beer Michael small.jpg EncodeNatureGraphic small.png Dyn net.gif

We are in the Department of Biomedical Engineering and the McKusick-Nathans Department of Genetic Medicine at Johns Hopkins University. You can apply for graduate study in my lab through BME or the Ph.D. program in Human Genetics.

Research Interests:

The ultimate goal of our research is to understand how gene regulatory information is encoded in genomic DNA sequence.

We have recently made significant progress in understanding how DNA sequence features specify cell-type specific mammalian enhancer activity using machine learning, and how enhancer-gene networks control cell-fate decisions and contribute to human disease. For details, see:

and other Publications.

Our work uses functional genomics DNase-seq, ATAC-seq, ChIP-seq, RNA-seq, MPRA, Hi-C, and chromatin state data to computationally identify combinations of transcription factor binding sites which operate to define the activity of cell-type specific enhancers. We are currently focused on:

  • improving machine learning algorithms by including more general sequence features and constraints
  • predicting the impact of SNPs on enhancer activity (delta-SVM) and GWAS association for specific diseases
  • experimentally assessing the predicted impact of regulatory element mutation in mammalian cells
  • systematically determining regulatory element logic from ENCODE human and mouse data
  • using this sequence based regulatory code to assess common modes of regulatory element evolution and variation

We are located in the McKusick-Nathans Institute of Genetic Medicine, and the Department of Biomedical Engineering, which has long been a leader in the development of rigorous quantitative modeling of biological systems, and is a natural home for graduate studies in Genomics, Bioinformatics, and Computational Biology at Johns Hopkins, including research in Systems Biology, Machine Learning, and Network Modeling.

About Computational Biology in JHU Biomedical Engineering:

The Department of Biomedical Engineering has long been a leader in the development of rigorous quantitative modeling of biological systems, and is a natural home for graduate studies in Bioinformatics and Computational Biology at Johns Hopkins. Students with backgrounds in Physics, Mathematics, Computer Science and Engineering are encouraged to apply. Opportunities for research include: Computational Medicine, Genomics, Systems Biology, Machine Learning, and Network Modeling. Graduate students in Johns Hopkins' Biomedical Engineering programs can select research advisors from throughout Johns Hopkins' Medical Institutions, Whiting School of Engineering, and Krieger School of Arts and Sciences.

Visit Some Computational Labs at Johns Hopkins

Center for Computational Biology at Johns Hopkins

Bmesmall.png

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