Microfluidic affinity and ChIP-seq analyses converge on a conserved FOXP2-binding motif in chimp and human, which enables the detection of evolutionarily novel targets

The transcription factor forkhead box P2 (FOXP2) is believed to be important in the evolution of human speech. A mutation in its DNA-binding domain causes severe speech impairment. Humans have acquired two coding changes relative to the conserved mammalian sequence. Despite intense interest in FOXP2, it has remained an open question whether the human protein’s DNA-binding specificity and chromatin localization are conserved. Previous in vitro and ChIP-chip studies have provided conflicting consensus sequences for the FOXP2-binding site. Using MITOMI 2.0 microfluidic affinity assays, we describe the binding site of FOXP2 and its affinity profile in base-specific detail for all substitutions of the strongest binding site. We find that human and chimp FOXP2 have similar binding sites that are distinct from previously suggested consensus binding sites. Additionally, through analysis of FOXP2 ChIP-seq data from cultured neurons, we find strong overrepresentation of a motif that matches our in vitro results and identifies a set of genes with FOXP2 binding sites. The FOXP2-binding sites tend to be conserved, yet we identified 38 instances of evolutionarily novel sites in humans. Combined, these data present a comprehensive portrait of FOXP2’s-binding properties and imply that although its sequence specificity has been conserved, some of its genomic binding sites are newly evolved.

[1]  D. Geschwind,et al.  High-throughput analysis of promoter occupancy reveals direct neural targets of FOXP2, a gene mutated in speech and language disorders. , 2007, American journal of human genetics.

[2]  K. Pollard,et al.  Detection of nonneutral substitution rates on mammalian phylogenies. , 2010, Genome research.

[3]  P. Carlsson,et al.  Cloning and characterization of seven human forkhead proteins: binding site specificity and DNA bending. , 1994, The EMBO journal.

[4]  T. D. Schneider,et al.  Information content of binding sites on nucleotide sequences. , 1986, Journal of molecular biology.

[5]  M. Morange,et al.  Brain abnormalities, defective meiotic chromosome synapsis and female subfertility in HSF2 null mice , 2002, The EMBO journal.

[6]  K. Davies,et al.  Functional genetic analysis of mutations implicated in a human speech and language disorder. , 2006, Human molecular genetics.

[7]  A. Monaco,et al.  A forkhead-domain gene is mutated in a severe speech and language disorder , 2001, Nature.

[8]  Michael B. Eisen,et al.  Design of a combinatorial DNA microarray for protein-DNA interaction studies , 2006, BMC Bioinformatics.

[9]  J. Epstein,et al.  Foxp1/2/4-NuRD Interactions Regulate Gene Expression and Epithelial Injury Response in the Lung via Regulation of Interleukin-6* , 2010, The Journal of Biological Chemistry.

[10]  S. Bhattacharya,et al.  Functional role of p35srj, a novel p300/CBP binding protein, during transactivation by HIF-1. , 1999, Genes & development.

[11]  J. Hurst,et al.  An extended Family with a Dominantly Inherited Speech Disorder , 1990, Developmental medicine and child neurology.

[12]  H. Kawano,et al.  Deficiency in Protein l-Isoaspartyl Methyltransferase Results in a Fatal Progressive Epilepsy , 1998, The Journal of Neuroscience.

[13]  J. Roder,et al.  NCS-1 in the Dentate Gyrus Promotes Exploration, Synaptic Plasticity, and Rapid Acquisition of Spatial Memory , 2009, Neuron.

[14]  A. Monaco,et al.  Molecular evolution of FOXP2, a gene involved in speech and language , 2002, Nature.

[15]  S. Young,et al.  Deficiency of a protein-repair enzyme results in the accumulation of altered proteins, retardation of growth, and fatal seizures in mice. , 1997, Proceedings of the National Academy of Sciences of the United States of America.

[16]  C. Scharff,et al.  Incomplete and Inaccurate Vocal Imitation after Knockdown of FoxP2 in Songbird Basal Ganglia Nucleus Area X , 2007, PLoS biology.

[17]  David Reich,et al.  Detecting natural selection by empirical comparison to random regions of the genome , 2009, Human molecular genetics.

[18]  Johannes Schwarz,et al.  A Humanized Version of Foxp2 Affects Cortico-Basal Ganglia Circuits in Mice , 2009, Cell.

[19]  Christopher A Ross,et al.  Polyglutamine Pathogenesis Emergence of Unifying Mechanisms for Huntington's Disease and Related Disorders , 2002, Neuron.

[20]  Hao Li,et al.  fREDUCE: Detection of degenerate regulatory elements using correlation with expression , 2007, BMC Bioinformatics.

[21]  Kay E. Davies,et al.  Foxp2 Regulates Gene Networks Implicated in Neurite Outgrowth in the Developing Brain , 2011, PLoS genetics.

[22]  M. Feller,et al.  The Role of Neuronal Connexins 36 and 45 in Shaping Spontaneous Firing Patterns in the Developing Retina , 2011, The Journal of Neuroscience.

[23]  S. Ziegler,et al.  Scurfin (FOXP3) Acts as a Repressor of Transcription and Regulates T Cell Activation* , 2001, The Journal of Biological Chemistry.

[24]  M. Lu,et al.  Foxp2 and Foxp1 cooperatively regulate lung and esophagus development , 2007, Development.

[25]  Shanru Li,et al.  Transcriptional and DNA Binding Activity of the Foxp1/2/4 Family Is Modulated by Heterotypic and Homotypic Protein Interactions , 2004, Molecular and Cellular Biology.

[26]  S. Batzoglou,et al.  Genome-Wide Analysis of Transcription Factor Binding Sites Based on ChIP-Seq Data , 2008, Nature Methods.

[27]  J. Buxbaum,et al.  Altered ultrasonic vocalization in mice with a disruption in the Foxp2 gene. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[28]  Bo Wang,et al.  The mouse forkhead gene Foxp2 modulates expression of the lung genes. , 2010, Life sciences.

[29]  S. Quake,et al.  A Systems Approach to Measuring the Binding Energy Landscapes of Transcription Factors , 2007, Science.

[30]  R. Gaynor,et al.  Constitutive Binding of the Transcription Factor Interleukin-2 (IL-2) Enhancer Binding Factor to the IL-2 Promoter* , 1997, The Journal of Biological Chemistry.

[31]  Jianzhi Zhang,et al.  Accelerated protein evolution and origins of human-specific features: Foxp2 as an example. , 2002, Genetics.

[32]  Oded Edelheit,et al.  Simple and efficient site-directed mutagenesis using two single-primer reactions in parallel to generate mutants for protein structure-function studies , 2009, BMC biotechnology.

[33]  S. Marticke Ultra-high throughput sequencing analysis of FOXP2 occupancy in the human genome , 2008 .

[34]  Weiguo Shu,et al.  Characterization of a New Subfamily of Winged-helix/Forkhead (Fox) Genes That Are Expressed in the Lung and Act as Transcriptional Repressors* , 2001, The Journal of Biological Chemistry.

[35]  D. Haussler,et al.  Evolutionarily conserved elements in vertebrate, insect, worm, and yeast genomes. , 2005, Genome research.

[36]  H. Yanagi,et al.  Novel testis-specific protein that interacts with heat shock factor 2. , 1998, Gene.

[37]  Polly M Fordyce,et al.  Basic leucine zipper transcription factor Hac1 binds DNA in two distinct modes as revealed by microfluidic analyses , 2012, Proceedings of the National Academy of Sciences.

[38]  D. Geschwind,et al.  Human-Specific Transcriptional Networks in the Brain , 2012, Neuron.

[39]  Philip Tucker,et al.  Multiple Domains Define the Expression and Regulatory Properties of Foxp1 Forkhead Transcriptional Repressors* , 2003, Journal of Biological Chemistry.

[40]  C. Scharff,et al.  Evo-devo, deep homology and FoxP2: implications for the evolution of speech and language , 2011, Philosophical Transactions of the Royal Society B: Biological Sciences.

[41]  M. Frommer,et al.  CpG islands in vertebrate genomes. , 1987, Journal of molecular biology.

[42]  S. Quake,et al.  De Novo Identification and Biophysical Characterization of Transcription Factor Binding Sites with Microfluidic Affinity Analysis , 2010, Nature Biotechnology.

[43]  Y. Benjamini,et al.  More powerful procedures for multiple significance testing. , 1990, Statistics in medicine.

[44]  A. Charollais,et al.  Consortin, a trans-Golgi network cargo receptor for the plasma membrane targeting and recycling of connexins. , 2010, Human molecular genetics.

[45]  Charles Elkan,et al.  The Value of Prior Knowledge in Discovering Motifs with MEME , 1995, ISMB.

[46]  M. Bennett,et al.  Electrical Coupling and Neuronal Synchronization in the Mammalian Brain , 2004, Neuron.

[47]  Simon E. Fisher,et al.  Localisation of a gene implicated in a severe speech and language disorder , 1997, Nature Genetics.

[48]  Katja Nowick,et al.  Structure of the forkhead domain of FOXP2 bound to DNA. , 2006, Structure.

[49]  Feng Ding,et al.  Molecular Origin of Polyglutamine Aggregation in Neurodegenerative Diseases , 2005, PLoS Comput. Biol..

[50]  S. McMahon,et al.  Cortical Overexpression of Neuronal Calcium Sensor-1 Induces Functional Plasticity in Spinal Cord Following Unilateral Pyramidal Tract Injury in Rat , 2010, PLoS biology.

[51]  Alexandre V. Morozov,et al.  Statistical mechanical modeling of genome-wide transcription factor occupancy data by MatrixREDUCE , 2006, ISMB.

[52]  J. Stroud,et al.  FOXP3 Controls Regulatory T Cell Function through Cooperation with NFAT , 2006, Cell.

[53]  Ernest Fraenkel,et al.  TAMO: a flexible, object-oriented framework for analyzing transcriptional regulation using DNA-sequence motifs , 2005, Bioinform..

[54]  N. Sykes,et al.  Identification of FOXP2 truncation as a novel cause of developmental speech and language deficits. , 2005, American journal of human genetics.

[55]  G. Hong,et al.  Nucleic Acids Research , 2015, Nucleic Acids Research.

[56]  Gudrun A. Rappold,et al.  The distinct and overlapping phenotypic spectra of FOXP1 and FOXP2 in cognitive disorders , 2012, Human Genetics.

[57]  R. Myers,et al.  Multiple transcription start sites for FOXP2 with varying cellular specificities. , 2008, Gene.

[58]  T. Unterman,et al.  FoxO proteins in insulin action and metabolism , 2005, Trends in Endocrinology & Metabolism.