ARTICLE

Received 13 Mar 2014 | Accepted 11 Aug 2014 | Published 18 Sep 2014

Pelagia Deriziotis1, Brian J. ORoak2,3, Sarah A. Graham1, Sara B. Estruch1, Danai Dimitropoulou1, Raphael A. Bernier4, Jennifer Gerdts4, Jay Shendure2, Evan E. Eichler2,5 & Simon E. Fisher1,6

Next-generation sequencing recently revealed that recurrent disruptive mutations in a few genes may account for 1% of sporadic autism cases. Coupling these novel genetic data to empirical assays of protein function can illuminate crucial molecular networks. Here we demonstrate the power of the approach, performing the rst functional analyses of TBR1 variants identied in sporadic autism. De novo truncating and missense mutations disrupt multiple aspects of TBR1 function, including subcellular localization, interactions with co-regulators and transcriptional repression. Missense mutations inherited from unaffected parents did not disturb function in our assays. We show that TBR1 homodimerizes, that it interacts with FOXP2, a transcription factor implicated in speech/language disorders, and that this interaction is disrupted by pathogenic mutations affecting either protein. These ndings support the hypothesis that de novo mutations in sporadic autism have severe functional consequences. Moreover, they uncover neurogenetic mechanisms that bridge different neurodevelopmental disorders involving language decits.

DOI: 10.1038/ncomms5954

De novo TBR1 mutations in sporadic autism disrupt protein functions

1 Language and Genetics Department, Max Planck Institute for Psycholinguistics, Nijmegen 6525XD, The Netherlands. 2 Department of Genome Sciences, University of Washington School of Medicine, Seattle, Washington 98195, USA. 3 Department of Molecular and Medical Genetics, Oregon Health & Science University, Portland, Oregon 97239, USA. 4 Department of Psychiatry and Behavioural Sciences, University of Washington, Seattle, Washington 98195, USA.

5 Howard Hughes Medical Institute, Seattle, Washington 98195, USA. 6 Donders Institute for Brain, Cognition and Behaviour, Nijmegen 6525EN, The Netherlands. Correspondence and requests for materials should be addressed to S.E.F. (email: mailto:[email protected]

Web End [email protected] ).

NATURE COMMUNICATIONS | 5:4954 | DOI: 10.1038/ncomms5954 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications 1

& 2014 Macmillan Publishers Limited. All rights reserved.

ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5954

Autism spectrum disorders (ASD) are estimated to affect 1 in 88 individuals and are characterized by a classic triad of symptoms, which include impairments in

social interactions, decits in communication and a tendency for repetitive stereotyped behaviours (CDC 2012). Inherited genetic variants may account for 40% of the risk for developing ASD1, but as is typical for complex traits, the effect of individual common variants is small2. In recent years, next-generation sequencing in ASD probands and their families has revealed that rare and private genetic variants play a major role in the aetiology of the disorder. These studies suggest that loss-of-function mutations within any of a large number of different genes may be sufcient to cause ASD. For some genes, such as AMT, PEX7 and SYNE1, the pathogenic mechanism involves complete gene knockout through rare inherited mutations, in a homozygous or compound heterozygous state. For other genes, it is proposed that de novo loss-of-function mutations disturbing one gene copy are responsible for sporadic severe cases of ASD38.

Six genesCHD8, DYRK1A, GRIN2B, PTEN, TBR1 and TBL1XR1have been observed to harbour de novo mutations in multiple unrelated probands, strongly suggesting that heterozygous disruption of any one of these genes is sufcient to cause ASD. It is estimated that mutations at these loci may account for 1% of sporadic cases8. TBR1 is of particular interest, because it encodes a neuron-specic transcription factor of the T-box family. T-box proteins have diverse biological roles9 and haploinsufciency of this class of regulatory protein has already been established as a cause of human disease10for instance, ulnar-mammary syndrome and HoltOram syndrome are caused by haploinsufciency of TBX3 and TBX5, respectively1113. TBR1 has established roles in patterning of the central nervous system, including regulation of neuronal identities during cortical development14. It is striking that among the small number of known TBR1 targets, threeRELN, GRIN2B and AUTS2have been implicated in ASD3,7,8,1518. Of particular interest, GRIN2B is one of the six genes mutated recurrently in ASD. TBR1, RELN, GRIN2B and AUTS2 may therefore form part of a molecular network important for cortical development that is recurrently mutated in ASD.

Moreover, there are data to suggest that the TBR1 protein may be a potential interaction partner of the forkhead transcription factor FOXP2 (ref. 19), another key regulator of central nervous system development and function20. In the mammalian cortex, TBR1 and FOXP2 show striking similarities in expression pattern2124, raising the possibility that they cooperate to regulate gene networks in deep layer cortical neurons, and other neural sites of co-expression. Mutations in FOXP2 cause a rare disorder characterized by problems with sequencing speech, and impairments in expressive and receptive language affecting spoken and written domains20. Given that communication decits are a core feature of ASD, it is plausible that TBR1 and FOXP2 belong to a shared molecular network, which goes awry in different neurodevelopmental disorders involving impaired speech and/or language skills.

The recurrence of de novo TBR1 mutations in sporadic ASD suggests that the identied mutations are likely to be pathogenic. Nonetheless, functional experiments in model systems are essential to determine the precise effect of mutations on protein function and provide insight into the molecular mechanisms of the disorder25. Follow-up of ndings from genetic studies of ASD is beginning to uncover the relevant gene networks and biological pathways8,23,2628. For example, two recent independent reports highlight network clusters of ASD risk genes that are important in mid-fetal brain development and glutamatergic neuronal function23,28.

In the present study, we perform the rst functional characterization of de novo TBR1 mutations identied in sporadic cases of ASD, assessing their impact on multiple aspects of protein function including protein expression, subcellular localization, transcriptional repression and proteinprotein interactions. We compare the functional consequences of these de novo mutations with rare inherited TBR1 mutations of uncertain clinical signicance, also found in probands with sporadic ASD. Moreover, we dene functional interactions between TBR1 and FOXP2 proteins, assessing the impact of aetiological mutations in each protein on these interactions. This work demonstrates how functional analyses of de novo mutations from next-generation sequencing can be used to dene and expand a key molecular network involved in neurodevelopmental disorders.

ResultsTBR1 mutations in sporadic ASD. Four de novo TBR1 coding mutations have been reported in sporadic ASD cases (Fig. 1a and Table 1 and Supplementary Table 1)3,8. No homozygous or compound heterozygous mutations in TBR1 were observed, consistent with murine knockout models, which show neonatal lethality22. However, there were several instances of heterozygous rare variants inherited from an unaffected parent. Such mutations could represent risk factors for ASD (for example, in combination with other mutations in the genomic background)29.

Among the de novo mutations, the K228E and N374H mutations involve amino-acid substitutions at highly conserved positions within the T-box domain, which is involved in DNA-binding and proteinprotein interactions (Fig. 1b,c). These mutations may therefore disturb these functions. The A136PfsX80 and S351X mutations are predicted to yield truncated proteins missing all or part of the T-box, which are unlikely to retain DNA-binding capacity. For the A136PfsX80 variant, the additional 80 amino acids following the frameshift do not show signicant homology to known protein domains, but do alter the pI of TBR1 (pI of wild-type (WT) protein 6.9, pI of

A136PfsX80 8.9). All four mutations are suspected to be causal

due to their de novo occurrence coupled with in silico predictions of functional signicance. In this study, we undertook empirical assessment of the impact of these mutations on protein function.

Of the missense TBR1 mutations that were inherited from an unaffected parent, we selected threeQ178E, Q418R and P542Rfor functional characterization based on the phenotype of affected probands and/or predicted deleterious effects on protein function (Fig. 1a and Table 1 and Supplementary Table 1). A fourth mutation, V356M, was also chosen that was previously identied through a targeted TBR1 screen in a family with an ASD-affected sib-pair30 and is found within the T-box (Fig. 1b,c).

De novo TBR1 mutations disrupt protein cellular localization. The expression levels of WT and mutant TBR1 proteins were assessed by western blotting of lysates from transfected cells (Fig. 2a,b and Supplementary Fig. 1). WT TBR1 was detected at B78 kDa. Protein variants arising from de novo and inherited missense mutations were of identical molecular weight and expressed in similar amounts to the WT protein, with the exception of K228E, which showed increased expression. The A136PfsX80 variant yielded a severely truncated product of only B27 kDa and was expressed in higher levels compared with WT

TBR1. In contrast, the S351X variant showed reduced expression and yielded a truncated protein of B43 kDa.

Subcellular localization of TBR1 protein variants was examined in transfected HEK293 cells by immunocytochemistry (Fig. 2c). Consistent with its role as a transcription factor, WT TBR1

2 NATURE COMMUNICATIONS | 5:4954 | DOI: 10.1038/ncomms5954 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications

& 2014 Macmillan Publishers Limited. All rights reserved.

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5954 ARTICLE

De novo:

p.A136PfsX80 p.K228E p.S351X p.N374H

p.Q178E p.V356M p.Q418R p.P542R

T-box

Rare inherited:

T-box domain in TBR1

Human LWLKFHRHQTEMIITKQGRRMFPFLSFNISGLDPTAHYNIFVDVILADPNHWRFQGGKWVPCGKADTNVQMouse LWLKFHRHQTEMIITKQGRRMFPFLSFNISGLDPTAHYNIFVDVILADPNHWRFQGGKWVPCGKADTNVQZebra finch RRMFPFLSFNISGLDPTAHYNIFVDVILADPNHWRFQGGKWVPCGKADTNVQXenopus LWLKFHRHQTEMIITKQGRRMFPFLSFNISGLDPTAHYNIFVDVILADPNHWRFQGGKWVPCGKADTNVQZebrafish LWLKFHRHQTEMIITKQGRRMFPFLSFNISGLDPTAHYNIFVDVILADPNHWRFQGGKWVPCGKADTNVT

Human GNRVYMHPDSPNTGAHWMRQEISFGKLKLTNNKGASNNNGQMVVLQSLHKYQPRLHVVEVNEDGTEDTSQMouse GNRVYMHPDSPNTGAHWMRQEISFGKLKLTNNKGASNNNGQMVVLQSLHKYQPRLHVVEVNEDGTEDTSQZebra finch GNRVYMHPDSPNTGAHWMRQEISFGKLKLTNNKGASNNNGQMVVLQSLHKYQPRLHVVEVNEDGTEDTNQXenopus GNRVYMHPDSPNTGAHWMRQEISFGKMKLTNNKGASNNNGQMVVLQSLHKYQPRLHVVEVNEDGTEDTSQZebrafish GNRVYMHPDSPNTGAHWMRQEISFGKLKLTNNKGATNNTGQMVVLQSLHKYQPRLHVVQVNEDGTEDTSQ

Human PGRVQTFTFPETQFIAVTAYQNTDITQLKIDHNPFAKGFRDMouse PGRVQTFTFPETQFIAVTAYQNTDITQLKIDHNPFAKGFRDZebra finch PGRVQTFTFPETQFIAVTAYQNTDITQLKIDHNPFAKGFRDXenopus PGRVQTFTFPETQFIAVTAYQNTDITQLKIDHNPFAKGFRDZebrafish PGRVQTFTFPETQFIAVTAYQNTDITQLKIDHNPFAKGFRD

T-box domain

TBR1 LWLKFHRHQTEMIITKQGRRMFPFLSFNISGLDPTAHYNIFVDVILADPNHWR--FQGGKWVPCGKADTNT LWLRFKELTNEMIVTKNGRRMFPVLKVNVSGLDPNAMYSFLLDFVAADNHRWK--YVNGEWVPGGKPEPQTBX1 LWDEFNQLGTEMIVTKAGRRMFPTFQVKLFGMDPMADYMLLMDFVPVDDKRYRYAFHSSSWLVAGKADPATBX3 LWDQFHKRGTEMVITKSGRRMFPPFKVRCSGLDKKAKYILLMDIIAADDCRYK--FHNSRWMVAGKADPETBX6 LWKEFSSVGTEMIITKAGRRMFPACRVSVTGLDPEARYLFLLDVIPVDGARYR--WQGRRWEPSGKAEPR

TBR1 VQGNRVYMHPDSPNTGAHWMRQEISFGKLKLTNNKGASNNNGQMVVLQSLHKYQPRLHVVEVNEDGTEDTT APSC-VYIHPDSPNFGAHWMKAPVSFSKVKLTNK---LNGGGQ-IMLNSLHKYEPRIHIVRVG-------TBX1 TPG-RVHYHPDSPAKGAQWMKQIVSFDKLKLTNN--LLDDNGH-IILNSMHRYQPRFHVVYVDPRKDSEKTBX3 MPK-RMYIHPDSPATGEQWMSKVVTFHKLKLTNN--ISDKHGF-TILNSMHKYQPRFHIVRAN---DILKTBX6 LPD-RVYIHPDSPATGAHWMRQPVSFHRVKLTNS--TLDPHGH-LILHSMHKYQPRIHLVRAA---QLCS

TBR1 SQPGRVQTFTFPETQFIAVTAYQNTDITQLKIDHNPFAKGFRDT GPQRMITSHCFPETQFIAVTAYQNEEITALKIKYNPFAKAFLDTBX1 YAEENFKTFVFEETRFTAVTAYQNHRITQLKIASNPFAKGFRDTBX3 LPYSTFRTYLFPETEFIAVTAYQNDKITQLKIDNNPFAKGFRDTBX6 QHWGGMASFRFPETTFISVTAYQNPQITQLKIAANPFAKGFRE

Figure 1 | TBR1 variants found in sporadic cases of ASD. (a) Schematic representation of TBR1 indicating changes found in sporadic ASD cases.(b) Sequence alignment of the T-box domains of TBR1 in human (UniProt accession Q16650), mouse (Q64336), zebra nch (deduced from genome sequence), xenopus (Q0IHV5) and zebrash (B5DE34). (c) Sequence alignment of the T-box domains of human TBR1 (Q16650), T protein (O15178), TBX1 (O43435), TBX3 (O15119), TBX6 (O95947). Conserved residues are highlighted in green. Red arrows indicate residues mutated in sporadic ASD cases. The blue arrow indicates the rst residue absent in the truncated S351X variant.

localized to the nucleus and was excluded from nucleoli. Strikingly, all the de novo protein variants exhibited aberrant subcellular localization, consistent with loss-of-function. The A136PfsX80 variant exhibited a diffuse distribution in the cytoplasm and occasionally also in the nucleus. The S351X variant showed diffuse cytoplasmic distribution as well as large aggregates throughout the cell. The K228E and N374H variants retained import into the nucleus but a fraction formed abnormal aggregates. In contrast to the de novo mutants, all the variants arising from inherited mutations exhibited similar localization to the WT protein. Similar results were obtained when examining the subcellular localization of TBR1 variant proteins in transfected human neuroblastoma SHSY5Y cells (Supplementary Fig. 2).

Truncating TBR1 mutations abolish transcriptional repression. TBR1 can function as both an activator and repressor of

transcription31,32. TBR1-mediated repression of Fezf2 in layer 6 corticothalamic projection neurons restricts the origin of the corticospinal tract to layer 5, and murine Tbr1 is able to repress transcription in luciferase reporter assays through direct binding to a conserved consensus element found near Fezf2 (ref. 32). We demonstrated that human TBR1, which is 99.3% identical to the mouse protein and has an identical T-box (Fig. 1b), was also able to repress transcription from a luciferase reporter plasmid containing this element (a decrease of 562%; Po0.001) (Fig. 3).

Both truncated TBR1 variants arising from de novo mutations demonstrated signicant loss of repressive ability (Po0.001 and

Po0.01 respectively; Fig. 3), consistent with the total or partial loss of the T-box in these variants. Moreover, the A136PfsX80 variant resulted in increased reporter expression compared with cells transfected with an empty expression vector (Po0.001). This observation may be due to aberrant proteinprotein interactions involving the new section of polypeptide resulting from the

NATURE COMMUNICATIONS | 5:4954 | DOI: 10.1038/ncomms5954 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications 3

& 2014 Macmillan Publishers Limited. All rights reserved.

ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5954

Cases Controls Mutation HGVS PolyPhen2

11480.p1 De novo Chr2:162273322 NA * C * 13,006 1 0 Fs p.A136P

fsX80

N/A

13796.p1 De novo Chr2:162275481 NA * C * 13,006 1 0 Fs p.S351X N/A

13814.p1 De novo Chr2:162273603 NA A G A 13,006

G 0

1 0 Ms p.K228E Probably damaging

Table 1 | Description of TBR1 mutations found in ASD.

Proband Type Variant positionHg19 coordinates

dbSNP Reference allele

Variant allele

ESP alleles

09C86232A De novo Chr2:162275553 NA A C A 13,006

C 0

0-other study3

0 Ms p.N374H Probably damaging

12994.p1 Inherited (father) Chr2:162273453 NA C G C 13,006

G 0

2 1 Ms p.Q178E Possibly damaging

14332.p1 Inherited (father) Inherited (mother)

Chr2:162275499 rs147026901 G A G 13,004

A 2

0-other study30

1 Ms p.V356M Probably damaging

13702.p1 Inherited

(mother)

Chr2:162279942 NA A G A 13,006

G 0

1 0 Ms p.Q418R Benign

13060.p1 Inherited (father) Chr2:162280314 NA C G C 13,006

G 0

1 0 Ms p.P542R Probably damaging

ASD, autism spectrum disorder; ESP, Exome Sequencing Project; Fs, frameshift; HGVS, Human Genome Variant Society nomenclature; Ms, missense.

For indels, the position listed in the human genome hg19 assembly follows the SAMtools/VCF convention of listing the position before the event; * indicates a copy of the reference allele, while the /

indicates the sequence inserted or deleted. Samples in our cohort included 2,446 cases and 762 controls. ESP data are taken from 6,503 non-ASD exomes from various ESP cohorts and denote observed allele counts for the listed alleles. In our cohort, the p.V356M variant was identied in a control; it has also been reported in an ASD-affected sib pair by targeted sequencing of TBR1 in another study30. The p.N374H variant was identied by exome sequencing in one ASD case in another study3.

frameshift mutation, especially given the high expression level of the protein. In contrast to the truncated variants, the K228E and N374H variants did not differ signicantly from WT TBR1 in their ability to repress transcription, suggesting that they at least partially retain DNA-binding capacity despite amino-acid changes within the T-box. In our functional analyses of the inherited missense mutations (of which only the V356M variant represents an amino-acid change within the T-box), no variant showed a signicant difference in repressive ability compared with the WT protein (Fig. 3). Thus, according to this assay, such mutations do not affect DNA-binding or transcriptional repression capabilities.

Truncating mutations disrupt TBR1CASK interaction. Interaction partners of TBR1 remain largely unknownthe only protein reported to interact directly with TBR1 in the developing cerebral cortex is CASK, a membrane-associated guanylate kinase with roles in neural development and synaptic function31. Heterozygous mutations disrupting CASK have been reported in patients with severe intellectual disability (ID) and ASD4,33. Interaction between the T-box and carboxy terminal region of TBR1 and the guanylate kinase domain of CASK triggers redistribution of CASK from the plasma membrane to the nucleus, where it cooperates in the regulation of TBR1 target genes31,34. Accordingly, in our experiments, co-expression of CASK with WT TBR1 in HEK293 cells resulted in translocation of CASK to the nucleus and extensive co-localization of TBR1 with CASK (Fig. 4a). In contrast, co-expression of CASK with the truncated TBR1 variants resulting from de novo mutations revealed a lack of CASK redistribution and loss of TBR1/CASK co-localization (Fig. 4b). These ndings are consistent with the mapping of the CASK-binding site within the C-terminal region of TBR1 (ref. 31). Intriguingly, CASK co-localizes in nuclear aggregates with the K228E and N374H TBR1 variants, suggesting that these mutants continue to interact with CASK and could thereby trigger aberrant localization of CASK within neurons (Fig. 4c). The amino-acid changes in TBR1 resulting from inherited missense mutations do not disrupt recruitment of

CASK into the nucleus (Supplementary Fig. 3). The effects of the TBR1 variant proteins on CASK localization were validated in transfected SHSY5Y cells (Supplementary Fig. 4). Although three of the mutations (V356M, Q418R, P542R) lie within the known CASK-binding region, our ndings suggest that these amino acids are not crucial for CASKTBR1 interaction.

TBR1 forms homodimers. Homodimerization has been observed in a subset of T-box transcription factors, and in some cases is required for binding to palindromic DNA sites35. To determine whether TBR1 can form homodimers, we used the bioluminescence resonance energy transfer (BRET) assay, a method for monitoring proteinprotein interactions in live cells36. In this assay, a protein of interest is expressed as a fusion protein with Renilla luciferase (donor), and its putative interaction partner as a fusion protein with YFP (acceptor). An interaction between the two proteins may bring the luciferase and YFP moieties sufciently close for non-radiative energy transfer to occur, causing a measurable shift in the wavelength of the emitted light (the BRET signal). When YFPTBR1 and luciferaseTBR1 fusion proteins were co-expressed in cells, a signicant increase in BRET signal was observed compared with when YFPTBR1 was expressed with a control (nuclear-targeted) luciferase, suggesting that TBR1 is able to homodimerize (Fig. 5a). We conrmed that the fusion proteins were correctly localized in the cell (Supplementary Fig. 5).

All de novo and inherited variants carrying single amino-acid changes retained the ability to dimerize with themselves and with WT TBR1 in the BRET assay (Fig. 5a and Supplementary Fig. 6a). Strikingly, co-expression of WT TBR1 and variants resulting from de novo missense mutations (K228E, N374H) resulted in extensive co-localization of WT and mutant proteins in nuclear aggregates (see Supplementary Fig. 6b). Given that the mutations occur in the heterozygous state in ASD cases, it is possible that these TBR1 variants exert a dominant-negative effect by interfering with functions of WT TBR1. In contrast, the truncated proteins resulting from de novo mutations showed a complete loss of interaction with WT TBR1 and a lack of self-association

4 NATURE COMMUNICATIONS | 5:4954 | DOI: 10.1038/ncomms5954 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications

& 2014 Macmillan Publishers Limited. All rights reserved.

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5954 ARTICLE

+ pYFP

WT TBR1

A136PfsX80

S351X

N374H

K228E

250

Relative expression

of TBR1 variants

kDa

Empty vector

200

100

75

25

50 37

50

25

37

150

Xpress

100

50

0

-Actin

YFP

WT

TBR1

A136P

fsX80

S351X

K228E

N374H

Xpress Merge

WT TBR1

S351X

De novo

Rare inherited

A136P fsX80

N374H

Q178E

Q418R

V356M

P542R

K228E

Figure 2 | Functional characterization of TBR1 protein variants identied in ASD. (a) Immunoblotting of whole-cell lysates from HEK293 cells cotransfected with TBR1 variants in pcDNA4.HisMax and an empty pYFP plasmid as a control for testing transfection efciency. The expected molecular weights for the TBR1 proteins are: B78 kDa WT TBR1, K228E, N374H; B27 kDa A136PfsX80; B43 kDa S351X. (b) Relative expression of TBR1

variant proteins as determined by densitometric analysis of western blot data (average of two independent experimentss.e.m.). (c) Immunouorescence staining of HEK293 cells transfected with TBR1 variants. Xpress-tagged TBR1 proteins are shown in green. Nuclei were stained with Hoechst 33342 (blue). Scale bars 10 mm. Concordant results were seen in SHSY5Y cells, as shown in Supplementary Fig. 2.

200

Relative luciferase

expression

200

***

**

**

150

150

***

100

100

NS NS

NS NS NS NS

50

50

S351X

A136PfsX80

0 WT TBR1

Control

N374H

K228E

Q178E

0 WT TBR1

Control

P542R

V356M

Q418R

De novo Rare inherited

Figure 3 | De novo TBR1 truncating mutations abolish transcriptional repression activity. Luciferase reporter assays for transcriptional regulatory activity of TBR1 variants in HEK293 cells. Values are expressed relative to the control. (***Po0.001, **Po0.01; NS, not signicant when compared with

WT TBR1). The means.e.m. of three independent experiments performed in triplicate is shown.

NATURE COMMUNICATIONS | 5:4954 | DOI: 10.1038/ncomms5954 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications 5

& 2014 Macmillan Publishers Limited. All rights reserved.

ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5954

Xpress YFP

CASK

Merge

No TBR1

WT TBR1

CASK

A136PfsX80

CASK

S351X

K228E CASK

CASK

CASK

N374H

Figure 4 | De novo truncating TBR1 mutations disrupt interactions with CASK. Fluorescence micrographs of HEK293 cells co-transfected with CASK and (a) WT TBR1, (b) de novo truncating variants and (c) de novo missense variants. Xpress-tagged TBR1 proteins are shown in red (left-hand side), whereas CASK fused to YFP is shown in green (middle). Nuclei were stained with Hoechst 33342 (blue). Scale bars for ac 10 mm. Concordant results were seen

in SHSY5Y cells, as shown in Supplementary Fig. 4.

(Fig. 5a and Supplementary Fig. 6a). Loss of interaction with WT protein may be due to the aberrant subcellular localization of the truncated proteins; however, the absence of self-association suggests that the T-box and/or C-terminal region of TBR1 may be important for homodimerization.

To test this hypothesis, we created two truncated TBR1 proteins, N394X and S568X, which lack portions of the C-terminal region but retain the complete T-box (Fig. 5b). Expression of YFP-fusion proteins containing these two variants was examined by western blotting and uorescence microscopy

6 NATURE COMMUNICATIONS | 5:4954 | DOI: 10.1038/ncomms5954 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications

& 2014 Macmillan Publishers Limited. All rights reserved.

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5954 ARTICLE

0.2

0.2

Acceptor

0.15

Control

De novo Rare inherited

Donor Donor

Donor

0.15

BRET ratio

BRET ratio

TBR1

0.1

0.1

0.05

0.05

0

0

WT TBR1

Q178E

V356M

Q418R

P542R

0.05

WT TBR1

A136P fsX80

S351X K228E N374H

WT TBR1

N394X

WT TBR1

N394X

S568X

S568X

kDa

150

YFP

-Actin

100

37

75

0.2

Acceptor

Control

TBR1

0.15

BRET ratio

0.1

0.05

N394X

S568X

0

WT TBR1

N394X S568X

0.05

Figure 5 | TBR1 homodimerizes. (a) BRET assays for interaction between WT and mutant TBR1 proteins. (b) Schematic representation of synthetic TBR1 variants. (c) Immunoblot of YFPTBR1 fusion proteins in transfected HEK293 cells. (d) Fluorescence microscopy images of HEK293 cells transfected with synthetic TBR1 variants fused to YFP (shown in green). Nuclei were stained with Hoechst 33342 (blue). Arrows indicate protein in the cytoplasm. Scale bar, 20 mm. Concordant results were seen in SHSY5Ycells, as shown in Supplementary Fig. 2. (e) BRETassays for interaction between WT

TBR1 and synthetic truncations. For a and e bars represent the mean corrected BRET ratioss.e.m. of one experiment performed in triplicate. BRET assays were performed in HEK293 cells.

(Fig. 5c,d and Supplementary Fig. 2b), which revealed that both variants are predominantly nuclear but are also occasionally found in cytoplasmic aggregates. The BRET assay showed that the S568X variant, which lacks the nal 114 residues, can interact with itself and with full-length TBR1 to a similar degree as the WT protein, whereas the N394X variant, which lacks the nal 288 residues following the T-box, shows a reduced ability to associate with itself and with full-length TBR1 (Fig. 5e and Supplementary Fig. 6c), indicating that the 394568 region is important for homodimerization. Homodimerization of the N394X synthetic variant was still greater than the S351X variant found in ASD, suggesting that the T-box is sufcient for some homodimerization to occur, consistent with previous studies37. Further experiments will be required to pinpoint the region(s) within the C terminus of TBR1 that are involved in dimerization, and to determine if the C-terminal region is capable of self-association in absence of the T-box.

TBR1 interacts with the FOXP2 transcription factor. A prior yeast two-hybrid screen suggested TBR1 as a putative interactor of the FOXP2 transcription factor19. Rare disruptions of FOXP2 are implicated in a speech/language disorder, involving

developmental verbal dyspraxia accompanied by impairments in expressive and receptive language20,38,39. Thus, an interaction between TBR1 and FOXP2 could represent a molecular link between distinct neurodevelopmental disorders involving language decits. We used the BRET assay to analyse the interaction of TBR1 with three naturally occurring FOXP2 isoforms found in the brain38,40 (Fig. 6a). The canonical FOXP2 isoform (isoform I) was able to interact with TBR1, as was isoform III, which lacks the rst 92 amino acids (Fig. 6b). Isoform 10 , which lacks the C-terminal region of FOXP2 spanning the

DNA-binding domain, showed a complete loss of interaction with TBR1 (Fig. 6b). While FOXP2 isoforms I and III are nuclear, isoform 10 is localized to the cytoplasm, which may account

for its lack of interaction with WT TBR1 (Fig. 6c and Supplementary Fig. 7). Alternatively, the C-terminal region of FOXP2 may be involved in the interaction.

To locate the TBR1-binding site within FOXP2, we created a series of four C-terminal deletions in FOXP2 (Fig. 6a). A nuclear-targeting signal was appended to the C terminus of these truncated proteins, which lack endogenous nuclear-targeting signals. All these truncated proteins retained the ability to interact with TBR1 in the BRET assay (Fig. 6d), indicating that

NATURE COMMUNICATIONS | 5:4954 | DOI: 10.1038/ncomms5954 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications 7

& 2014 Macmillan Publishers Limited. All rights reserved.

ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5954

a

Yeast two-hybrid bait in Sakai et al.19

b e

0.2 Acceptor: TBR1

0.15

BRET ratio

BRET ratio BRET ratio

De novo

QL

QS

ZnF

LeuZ

FOX

FOXP2 isoform I

Isoform III

Isoform 10+

0.15

0.1

Donor: FOXP2

BRET ratio

0.1

0.05

0.05

0

delC1

delC2

delC3

delC4

delQS

delQL

delQS+QL

Control

0 FOXP2 iso I

FOXP2 iso III

FOXP2 iso10+

K228E

S351X

A136P

fsX80

WT TBR1

Control

N374H

Acceptor

Acceptor

Donor

Rare inherited

d

0.15

Donor: FOXP2

0.1

c

0.1

BRET ratio

YFP mCherry Merge

0.05

0.05

0

Q178E WT TBR1

Control

0 Control

P542R

Q418R

V356M

Control

0 FOXP2

delC1

delC2

delC3

delC4

Isoform I

TBR1

Donor

Donor

f

0.15 Acceptor: TBR1

0.15

Donor: FOXP2

BRET ratio

0.1

0.1

Isoform III

Isoform 10+ TBR1

TBR1

0.05

0.05

lQL delQS

0 FOXP2

Control

Acceptor: TBR1

del

de QS+QL

WT TBR1

N394X

S568X

Acceptor

Figure 6 | TBR1 interacts with FOXP2 through the T-box domain. (a) Schematic representation of recombinant FOXP2 proteins used in BRET assays. FOXP2 contains long (QL) and short (QS) polyglutamine tracts, and zinc nger (ZnF), leucine zipper (LeuZ) and FOX DNA-binding domains. Isoforms I, III and 10 represent natural isoforms, other constructs are synthetic. A nuclear-targeting signal appended to the C terminus in variants

delC1-delC4 is indicated in black. The putative TBR1-binding region based on yeast two-hybrid data19 is also shown. (b) BRET assays for interaction between WT TBR1 and naturally occurring FOXP2 isoforms. (c) Fluorescence images of HEK293 cells co-transfected with TBR1 and FOXP2 variants. FOXP2 variants fused to YFP are shown in green (left-hand side), whereas TBR1 fused to mCherry is shown in red (middle). Nuclei were stained with Hoechst 33342 (blue). Scale bar, 5 mm. Concordant results were seen in SHSY5Y cells, as shown in Supplementary Fig. 7. (d) BRET assays for interaction between WT TBR1 and synthetic FOXP2 variants. (e) BRETassays for interaction between WT FOXP2 and TBR1 variants found in ASD. (f) BRET assays for interaction between WT FOXP2 and synthetic TBR1 truncations. In b, df, bars represent the corrected mean BRET ratioss.e.m. of one experiment performed in triplicate. BRET assays were performed in HEK293 cells.

the TBR1-binding site lies within the N-terminal 258 residues of FOXP2. In the yeast two-hybrid screen which suggested TBR1 interaction, a region of FOXP2 encompassing residues 122382 was used as the bait protein19. Together, these ndings suggest that the TBR1-binding site lies within region 122258 of the canonical FOXP2 isoform. This region includes two polyglutamine (polyQ) tracts that are not present in other FOXP family members. We generated FOXP2 variants that lacked one or both polyQ tracts (Fig. 6a). All three variants retained the ability to interact with TBR1 (Fig. 6d), indicating that the polyQ tracts are not required for this interaction. We also tested the interaction between TBR1 and two neurally expressed FOXP2 paralogs, FOXP1 and FOXP4, which have Q-rich domains but lack polyQ tracts (Supplementary Fig. 8). In the BRET assay, both FOXP1 and FOXP4 were able to interact with TBR1, conrming our observations with the synthetic FOXP2 polyQ-deletion constructs. We conclude that TBR1 binding is likely to involve the regions anking or between the two polyglutamine tracts that are conserved in FOXP1 and FOXP4. In agreement with these results, TBR1FOXP2 interaction was not disrupted by an in-frame deletion of E400 in FOXP2

(Supplementary Fig. 8), a residue which is known to be important for FOXP2 homodimerization41.

An intact T-box is required for TBR1FOXP2 interaction. Next, we investigated the effects of de novo and inherited TBR1 mutations on interaction with FOXP2 (Fig. 6e). All four de novo mutations abolished interactions with FOXP2. In contrast, three TBR1 variants arising from inherited missense mutations (Q178E, V356M and P542R) showed BRET signals comparable with those seen with WT TBR1. Interestingly, the inherited Q418R variant demonstrated reduced interaction with FOXP2. This observation cannot be attributed to differential expression or aberrant subcellular localization of the mutant protein. The synthetic truncated TBR1 variants, both of which retain an intact T-box, were still able to interact with FOXP2 (Fig. 6f). Together, these data suggest that the T-box domain is mediating the TBR1FOXP2 interaction.

Aetiological FOXP2 mutations disrupt interaction with TBR1. Finally, we investigated if the TBR1FOXP2 interaction was

8 NATURE COMMUNICATIONS | 5:4954 | DOI: 10.1038/ncomms5954 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications

& 2014 Macmillan Publishers Limited. All rights reserved.

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5954 ARTICLE

YFP

mCherry

Merge

FOX

FOXP2

R553H

QL

QS

ZnF

LeuZ

FOXP2 TBR1

TBR1

R553H

R328X

R553H

0.15

Acceptor: TBR1

Donor

0.1

BRET ratio

R328X

TBR1

0.05

0 Control FOXP2 R553H R328X

Figure 7 | FOXP2 variants found in speech/language disorders do not interact with TBR1. (a) Schematic representation of FOXP2 variants foundin speech/language disorders. (b) BRET assays for interaction of WT TBR1 with FOXP2 variants. (c) Fluorescence images of HEK293 cells co-transfected with TBR1 and FOXP2 variants. FOXP2 variants fused to YFP are shown in green (left-hand side), whereas TBR1 fused to mCherry is shown in red (middle). Nuclei were stained with Hoechst 33342 (blue). Scale bar, 10 mm. Concordant results were seen in SHSY5Y cells, as shown in Supplementary

Fig. 7. In b, bars represent the corrected mean BRETratioss.e.m. of one experiment performed in triplicate. BRETassays were performed in HEK293 cells.

affected by two different pathogenic FOXP2 point mutations, each known to cause a rare monogenic speech and language disorder (Fig. 7a). The R553H mutation yields a substitution at a key residue in the DNA-binding domain of FOXP2, and was identied as the result of linkage mapping in a large multi-generational pedigree, the KE family38,42. The R328X mutation introduces a premature stop codon to yield a protein product lacking the leucine zipper dimerization domain and the DNA-binding domain, and was discovered through targeted FOXP2 screening43. Both mutations severely disrupt protein function44. Strikingly, both R553H and R328X mutations interfere with the ability of FOXP2 to interact with TBR1 (Fig. 7b). For the R328X variant, this loss of interaction with TBR1 may be largely due to cytoplasmic mislocalization of FOXP2 ref. 44 (Fig. 7c and Supplementary Fig. 7), since a comparable fragment of the protein did interact with TBR1 when articially directed to the nucleus (Fig. 6d). The reduced interaction observed with the R553H variant may also relate to its partial mislocalization to the cytoplasm or protein aggregation44 (Fig. 7c and Supplementary Fig. 7).

DiscussionWe report the rst functional characterization of TBR1 mutations identied in individuals with sporadic ASD (Table 2). We found that the de novo mutations studied here disrupted one or more of the aspects of protein function tested, whereas TBR1 mutations inherited from unaffected parents had little or no impact on protein function. These ndings provide empirical support for the effectiveness of focusing on de novo mutation events for understanding the biology underlying sporadic cases of severe neurodevelopmental disorders. Moreover, we showed that TBR1 interacts with FOXP2, a regulatory factor implicated in speech/ language disorder, demonstrating that this interaction is disrupted by pathogenic mutations in either protein, suggesting a molecular link between distinct neurodevelopmental disorders.

Two of the de novo mutations studied here are single-nucleotide indels that introduce premature termination codons

into the coding sequence. These mutations occur before the nal exon boundary and may trigger nonsense-mediated decay. However, the degradation of mutated TBR1 transcripts in patient cells cannot be assessed due to the absence of TBR1 expression in peripheral tissues. The analyses of protein function described here indicate that any truncated protein that is produced is nonfunctional, since the protein exhibits loss of nuclear localization, loss of interaction with the co-activator CASK and deciency in transcriptional repression activity. Coupled with the observation that the truncated proteins cannot dimerize with WT TBR1, it seems likely that the pathogenic mechanism of these mutations is haploinsufciency. This hypothesis is supported by the discovery of heterozygous de novo microdeletions encompassing TBR1 in probands with developmental delay, ASD and ID4547. Furthermore, anatomical and behavioural characterization of heterozygous Tbr1 mice revealed that loss of one Tbr1 allele impairs amygdalar axonal projections and results in cognitive abnormalities48.

Two of the four de novo TBR1 mutations are missense mutations within the T-box. The amino-acid residues affected by the K228E and N374H mutations are conserved in T-box sequences from divergent proteins (Fig. 1b,c), indicating that they are likely to be important for the functioning of this domain. These mutations showed more moderate effects on protein function than those resulting in truncated TBR1 protein. They did not abolish nuclear import or transcriptional repression activity in our assays, but were found to aggregate in the nucleus. It is possible that subtle effects conferred by these variants, not evident from in vitro experiments, may be important in vivo. Interestingly, it was recently shown that the over-expression of N374H in cultured amygdalar neurons from heterozygous Tbr1 mice fails to rescue the axon outgrowth defect observed in these neurons, whereas overexpression of WT TBR1 restored normal axonogenesis48. In our experiments, K228E and N374H were no longer able to interact with either the co-activator CASK or transcription factor FOXP2 (see below) suggesting that regulation of different TBR1 target genes may be selectively affected by these mutations, with particular

NATURE COMMUNICATIONS | 5:4954 | DOI: 10.1038/ncomms5954 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications 9

& 2014 Macmillan Publishers Limited. All rights reserved.

ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5954

Table 2 | Summary of functional investigations of TBR1 variants found in ASD.

Proteinprotein interactions

CASK TBR1 FOXP2

WT TBR1 Nuclear Yes Yes Yes Yes

De novoA136PfsX80 4 WT Cytoplasmic, nuclear No No No No S351X o WT Cytoplasmic, nuclear No No No No

K228E 4 WT Nuclear aggregates Yes Co-localization in nuclear aggregates Yes No N374H Similar to WT Nuclear aggregates Yes Co-localization in nuclear aggregates Yes No

Rare inheritedQ178E Similar to WT Nuclear Yes Yes Yes Yes V356M Similar to WT Nuclear Yes Yes Yes Yes Q418R Similar to WT Nuclear Yes Yes Yes No P542R Similar to WT Nuclear Yes Yes Yes Yes

ASD, autism spectrum disorder; WT, wild type.

Expression levels Cellular localization Transcriptional repression

dysregulation of genes that are regulated by the TBR1CASK complex, and/or co-regulated by FOXP2. It is tempting to speculate that CASK and/or FOXP2 might be involved in TBR1-mediated axonogenesis.

Crystal structures of the T-box domains from human TBX3 and Xenopus laevis Xbra show that the residue equivalent to K228 makes direct contact with the DNA backbone in Xbra, but not in TBX3, while the residues equivalent to N374 do not make direct contact with DNA in either structure35,49. Thus, the missense mutations observed in ASD probands may not completely abolish DNA-binding activity, consistent with the retention of transcriptional repression activity presented here, but could have milder effects on the afnity or specicity of DNA recognition, or on protein stability. A crystal structure of TBR1 bound to DNA would help clarify the role of these residues in DNA recognition. The K228E and N374H variants retained the ability to dimerize with WT TBR1, causing the WT protein to become localized to nuclear aggregates. Thus, the pathogenic mechanism of these mutations may include a dominant-negative effect that reduces the effective dosage of WT protein.

Overall, our data suggest that mutations that lead to a reduction in the amount of functional TBR1 protein are causative in sporadic cases of ASD. It is intriguing that there were variable effects among these different causative mutationsaetiological missense mutations within the DNA-binding domain did not have as dramatic an effect on TBR1 protein function as the truncating mutations in our assays. These ndings are in line with the expected odds ratio for these particular classes of mutation. Interestingly, the severity of cognitive decits in individuals carrying TBR1 mutations may reect the severity of the disruption to protein function. The ASD cases carrying truncating mutations have mild-to-moderate ID, whereas those with missense mutations have milder cognitive impairments (Supplementary Table 1: non-verbal IQ scores: 41 A136PfsX80;

63 S351X; 78 K228E; 74 N374H).

Our functional characterization of TBR1 mutations supports the hypothesis that de novo mutations with highly deleterious effects on protein function are an important cause of severe sporadic ASD. With the exception of Q418R (see below), none of the inherited variants displayed signicant effects on protein function in our assays. While it remains possible that subtle effects on protein function went undetected in these analyses, overall our data do not support a contributory role for inherited TBR1 mutations in sporadic ASD.

In addition to characterizing TBR1 mutants found in ASD, we also investigated the interaction of TBR1 with the language-related transcription factor FOXP2. We conrmed an interaction between these proteins and demonstrated that this interaction involves the T-box of TBR1. Previous studies also highlighted the role of the T-box in proteinprotein interactions, such as between TBR1 and CASK31 and between TBX5 and NKX2.5 (ref. 50). The TBR1-binding site within FOXP2 was mapped to the regions anking the two polyQ tracts, a part of the protein with no established function. The interaction between TBR1 and FOXP2 is likely to be physiologically relevant due to temporal and spatial overlap in expression of the two genes in several brain areas, including layer 6 glutamatergic corticothalamic projection neurons2123,51,52. It will be interesting in future to identify the specic developmental stages and neuronal subtypes in which TBR1FOXP2 interactions occur.

Individuals with mutations in either TBR1 or FOXP2 exhibit speech and language decits, with the ASD probands showing language delay and regression. Therefore, it is interesting that the TBR1FOXP2 interaction is disrupted both by de novo TBR1 mutations in ASD probands and by FOXP2 mutations found in patients with a primary speech and language disorder (in the absence of autism). Loss of TBR1FOXP2 interaction may therefore contribute to speech and language decits in the context of two distinct neurodevelopmental disorders. Intriguingly, the interaction was also disrupted by the Q418R inherited mutation, which is predicted to be benign (Table 1). The lack of interaction between this mutant and FOXP2 may contribute to the discrepancy between non-verbal IQ (86) and verbal IQ (58) scores in this proband (Supplementary Table 1).

The importance of the TBR1FOXP2 interaction to normal speech and language development may lie in the co-regulation of gene expression by these two transcription factors. The ASD-susceptibility gene AUTS2 is a good candidate for co-regulation by TBR1 and FOXP2. AUTS2 is a known TBR1 target53 and in expression proling of human cells with inducible FOXP2 expression, upregulation of AUTS2 was one of the most signicant changes associated with induction of FOXP2 expression (P.D. and S.E.F., unpublished data).

In summary, our ndings highlight the power of coupling novel genetic ndings with empirical data to esh out more comprehensive molecular networks. By performing functional characterization of de novo and rare inherited TBR1 mutations found in sporadic ASD, we identied novel protein

10 NATURE COMMUNICATIONS | 5:4954 | DOI: 10.1038/ncomms5954 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications

& 2014 Macmillan Publishers Limited. All rights reserved.

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5954 ARTICLE

CASK interacting

FOXP2 interacting

CASK

Dimerization

TBR1

T-box

1

213 568

393

682

Cytoplasm

GRIN2B RELN AUTS2

CASK

Nucleus

FOXP2

TBR1

Figure 8 | Novel insights into TBR1-related molecular networks underlying sporadic ASD. By interacting with CASK, TBR1 regulates several ASD candidate genes, such as GRIN2B, AUTS2 and RELNall of which are recurrently mutated in ASD. In areas of the brain with overlapping expression patterns, such as in glutamatergic layer 6 neurons, the TBR1 FOXP2 interaction may result in co-ordinated regulation of common downstream targets.

characteristics, such as TBR1 homodimerization, and built on existing proteinprotein networks with new interactions, at the same time providing mechanistic bridges between neurodevelop-mental disorders (Fig. 8). Next-generation screens of larger ASD cohorts are set to reveal additional de novo mutations in candidates including TBR1, GRIN2B, RELN and AUTS2genes that are recurrently mutated and belong to shared molecular networks. Without experimental validation, such data sets will most likely remain biologically uninformative. The functional assays established here can be used to systematically investigate effects of novel mutations disrupting members of this pathway. At present, the lack of high-throughput testing of multiple genetic variants hinders the extrapolation of such assays to the clinic for diagnostic purposes. Development of such multiplex methods is underway25. Coupled with strong genetic predictors, such as de novo variants, this will undoubtedly aid in robustly dening the molecular networks that go awry in ASD.

Methods

Identication of TBR1 variants. De novo and rare inherited mutations were previously identied through whole exome or targeted resequencing3,6,8.

Cell culture and transfection. HEK293 and SHSY5Y cell lines were obtained from ECACC (catalogue numbers: 85120602 for HEK293 and 94030304 for SHSY5Y). HEK293 cells were grown in Dulbeccos modied Eagles medium and SHSY5Y cells in DMEM-F12 (Invitrogen). Media were supplemented with 10% fetal bovine serum (Invitrogen). Transfections were performed using GeneJuice (Merck-Millipore).

DNA expression constructs and site-directed mutagenesis. pcDNA4.-HisMax.TBR1, pcDNA4.HisMax.A136PfsX80 and pJET1.2.CASK were synthesized by GenScript USA. S351X, K228E, N374H, Q178E, V356M, Q418R and P542R TBR1 variants were generated using the pcDNA4.HisMax.TBR1 as template with the QuikChange II Site-Directed Mutagenesis Kit (Agilent) (primer sequences are listed in Supplementary Table 2). Synthetic TBR1 truncation variants were PCR amplied (N394X: Fwd 50-GAATTCATGCAGCTGGAGCACTGCCTT-30, Rev 50-TCTAGATTAATCCCGAAATCCTTTTGC-30; S568X: Fwd 50-GAATTCATGC AGCTGGAGCACTGCCTT-30, Rev 50- TCTAGATTAGTTGGGCCAGCAGG GCAG-30) and cloned into pCR2.1-TOPO (Invitrogen). TBR1 cDNAs were

subcloned using EcoRI/XbaI restriction sites into a modied pmCherry-C1 vector (Clontech), as well as pLuc and pYFP expression vectors36. CASK cDNA was subcloned using EcoRI/KpnI restriction sites into the pYFP expression vector. FOXP variants were PCR amplied, cloned into pCR2.1-TOPO and subcloned using BamHI/XbaI restriction sites into pLuc and pYFP expression vectors (primer sequences are listed in Supplementary Table 3). The FOXP2.delQ variants were generated using a PCR-based strategy. The control plasmids pLuc-control and pYFP-control express the Renilla luciferase and YFP proteins with a C-terminal nuclear localization signal36. All constructs were veried by Sanger sequencing.

SDSPAGE and western blotting. Cells were transfected with equimolar concentrations of TBR1 expression plasmids. Whole-cell lysates were extracted by treatment with lysis buffer (100 mM Tris pH 7.5, 150 mM NaCl, 10 mM EDTA,0.2% Triton X-100, 1% PMSF, 1 protease inhibitor cocktail; all from Sigma) for

10 min at 4 C, before centrifuging at 10,000 g for 30 min at 4 C to remove cell debris. Proteins were resolved on 415% TrisGlycine gels and transferred onto polyvinylidene uoride membranes. Membranes were probed with Invitrogen mouse anti-Xpress (for pcDNA4.HisMax constructs; 1:1,000) or Clontech mouse anti-EGFP (for pYFP constructs; 1:8,000) overnight at 4 C, followed by incubation with HRP-conjugated goat anti-mouse IgG for 45 min at room temperature (Bio-Rad; 1:2,000). Proteins were visualized using Novex ECL Chemiluminescent Substrate Reagent Kit (Invitrogen) and the ChemiDoc XRS System (Bio-Rad).

Equal protein loading was conrmed by stripping blots and reprobing using Sigma anti-b-actin antibody (1:10,000). Bands were quantied by densitometry using the

Chemidoc XRS System image analysis software (Bio-Rad). A value for the

transfection efciency of TBR1 constructs was obtained by dividing the YFP signal by the b-actin signal. The relative expression of TBR1 variants was then derived by dividing the Xpress signal by the transfection efciency.

Immunouorescence. Cells were seeded onto coverslips coated with poly-L-lysine (Sigma) and 36 h post transfection, cells were xed using 4% paraformaldehyde solution (Electron Microscopy Sciences) for 10 min at room temperature. Cells were stained with mouse anti-Xpress (1:500) followed by Alexa Fluor 488-conjugated goat anti-mouse IgG (H L; 1:1,000) (both Invitrogen) to visualize pro

teins expressed from pcDNA4.HisMax. YFP and mCherry fusion proteins were visualized by direct uorescence. Nuclei were visualized with Hoechst 33342 (Invitrogen). Fluorescence images were obtained using a LSM510 confocal microscope with LSM Image Software or an Axiovert A-1 uorescent microscope with ZEN Image Software (Zeiss).

Luciferase assays. The pGL3-CMV rey luciferase reporter plasmid including the Tbr1-binding site near Fezf2 was a kind gift of Prof. Sestan, Yale University32. Cells were transfected with 45 ng of rey luciferase reporter construct, 5 ng of Renilla luciferase normalization control (pRL-TK; Promega) and 200 ng TBR1 expression construct (WT or mutant in pcDNA4.HisMax) or empty vector (pcDNA4.HisMax). Forty-eight hours post transfection, rey luciferase and Renilla luciferase activities were measured in a TECAN F200PRO microplate reader using the Dual-Luciferase Reporter Assay system (Promega).

BRET assay. BRET assays were performed as described36. Briey, cells were transfected with pairs of YFP and luciferase fusion proteins in 96-well plates. EnduRen (60 mM; Promega) was added to cells 3648 h after transfection. Four hours later, emission readings (integrated over 10 s) were taken using a TECAN F200PRO microplate reader using the Blue1 and Green1 lter sets. Expression levels of the YFP-fusion proteins were monitored by taking uorescence readings using the lter set and dichroic mirror suitable for green uorescent protein (excitation 480 nm, emission 535 nm). The corrected BRET ratio was obtained as follows: [Green1(experimental condition)/Blue1(experimental condition)] [Green1

(control

condition)/Blue1(control condition)]. The control proteins were Renilla luciferase and YFP fused to a C-terminal nuclear localization signal. The BRET assay setup, including the design of appropriate controls and data interpretation, is extensively discussed in Deriziotis et al.36

Statistical signicance. The statistical signicance of the luciferase reporter assays was analysed using a one-way analysis of variance and a Tukeys post hoc test.

References

1. Hallmayer, J. et al. Genetic heritability and shared environmental factors among twin pairs with autism. Arch. Gen. Psychiatry 68, 10951102 (2011).

2. Anney, R. et al. Individual common variants exert weak effects on the risk for autism spectrum disorders. Hum. Mol. Genet. 21, 47814792 (2012).

3. Neale, B. M. et al. Patterns and rates of exonic de novo mutations in autism spectrum disorders. Nature 485, 242245 (2012).

4. Sanders, S. J. et al. De novo mutations revealed by whole-exome sequencing are strongly associated with autism. Nature 485, 237241 (2012).

5. Iossifov, I. et al. De novo gene disruptions in children on the autistic spectrum. Neuron 74, 285299 (2012).

NATURE COMMUNICATIONS | 5:4954 | DOI: 10.1038/ncomms5954 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications 11

& 2014 Macmillan Publishers Limited. All rights reserved.

ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5954

6. ORoak, B. J. et al. Sporadic autism exomes reveal a highly interconnected protein network of de novo mutations. Nature 485, 246250 (2012).

7. ORoak, B. J. et al. Exome sequencing in sporadic autism spectrum disorders identies severe de novo mutations. Nat. Genet. 43, 585589 (2011).

8. ORoak, B. J. et al. Multiplex targeted sequencing identies recurrently mutated genes in autism spectrum disorders. Science 338, 16191622 (2012).9. Wilson, V. & Conlon, F. L. The T-box family. Genome. Biol. 3, reviews3008 (2002).

10. Packham, E. A. & Brook, J. D. T-box genes in human disorders. Hum. Mol. Genet. 12, R37R44 (2003).

11. Bamshad, M. et al. Mutations in human TBX3 alter limb, apocrine and genital development in ulnar-mammary syndrome. Nat. Genet. 16, 311315 (1997).

12. Basson, C. T. et al. Mutations in human TBX5 cause limb and cardiac malformation in Holt-Oram syndrome. Nat. Genet. 15, 3035 (1997).

13. Li, Q. Y. et al. Holt-Oram syndrome is caused by mutations in TBX5, a member of the Brachyury (T) gene family. Nat. Genet. 15, 2129 (1997).

14. McKenna, W. L. et al. Tbr1 and Fezf2 regulate alternate corticofugal neuronal identities during neocortical development. J. Neurosci. 31, 549564 (2011).

15. Talkowski, M. E. et al. Sequencing chromosomal abnormalities reveals neurodevelopmental loci that confer risk across diagnostic boundaries. Cell 149, 525537 (2012).

16. Myers, R. A. et al. A population genetic approach to mapping neurological disorder genes using deep resequencing. PLoS Genet. 7, e1001318 (2011).

17. Oksenberg, N. & Ahituv, N. The role of AUTS2 in neurodevelopment and human evolution. Trends Genet. 29, 600608 (2013).

18. Wang, Z. et al. Reelin gene variants and risk of autism spectrum disorders: an integrated meta-analysis. Am. J. Med. Genet. B Neuropsychiatr. Genet. 165B, 192200 (2014).

19. Sakai, Y. et al. Protein interactome reveals converging molecular pathways among autism disorders. Sci. Transl. Med. 3, 86ra49 (2011).

20. Fisher, S. E. & Scharff, C. FOXP2 as a molecular window into speech and language. Trends Genet. 25, 166177 (2009).

21. Ferland, R. J., Cherry, T. J., Preware, P. O., Morrisey, E. E. & Walsh, C. A. Characterization of Foxp2 and Foxp1 mRNA and protein in the developing and mature brain. J. Comp. Neurol. 460, 266279 (2003).

22. Hevner, R. F. et al. Tbr1 regulates differentiation of the preplate and layer 6. Neuron 29, 353366 (2001).

23. Willsey, A. J. et al. Coexpression networks implicate human midfetal deep cortical projection neurons in the pathogenesis of autism. Cell 155, 9971007 (2013).

24. Lai, C. S., Gerrelli, D., Monaco, A. P., Fisher, S. E. & Copp, A. J. FOXP2 expression during brain development coincides with adult sites of pathology in a severe speech and language disorder. Brain 126, 24552462 (2003).

25. Deriziotis, P. & Fisher, S. E. Neurogenomics of speech and language disorders: the road ahead. Genome Biol. 14, 204 (2013).

26. Yu, T. W. et al. Using whole-exome sequencing to identify inherited causes of autism. Neuron 77, 259273 (2013).

27. Foldy, C., Malenka, R. C. & Sudhof, T. C. Autism-associated neuroligin-3 mutations commonly disrupt tonic endocannabinoid signaling. Neuron 78, 498509 (2013).

28. Parikshak, N. N. et al. Integrative functional genomic analyses implicate specic molecular pathways and circuits in autism. Cell 155, 10081021 (2013).29. Girirajan, S. et al. Phenotypic heterogeneity of genomic disorders and rare copy-number variants. N. Engl. J. Med. 367, 13211331 (2012).

30. Bacchelli, E. et al. Screening of nine candidate genes for autism on chromosome 2q reveals rare nonsynonymous variants in the cAMP-GEFII gene. Mol. Psychiatry 8, 916924 (2003).

31. Hsueh, Y. P., Wang, T. F., Yang, F. C. & Sheng, M. Nuclear translocation and transcription regulation by the membrane-associated guanylate kinase CASK/ LIN-2. Nature 404, 298302 (2000).

32. Han, W. et al. TBR1 directly represses Fezf2 to control the laminar origin and development of the corticospinal tract. Proc. Natl Acad. Sci. USA 108, 30413046 (2011).

33. Moog, U. et al. Phenotypic spectrum associated with CASK loss-of-function mutations. J. Med. Genet. 48, 741751 (2011).

34. Wang, G. S. et al. Transcriptional modication by a CASK-interacting nucleosome assembly protein. Neuron 42, 113128 (2004).

35. Muller, C. W. & Herrmann, B. G. Crystallographic structure of the T domain-DNA complex of the Brachyury transcription factor. Nature 389, 884888 (1997).

36. Deriziotis, P., Graham, S. A., Estruch, S. B. & Fisher, S. E. Investigating protein-protein interactions in live cells using bioluminescence resonance energy transfer. J. Vis. Exp. doi:http://dx.doi.org/10.3791/51438

Web End =10.3791/51438 (2014).

37. Farin, H. F. et al. Transcriptional repression by the T-box proteins Tbx18 and Tbx15 depends on Groucho corepressors. J. Biol. Chem. 282, 2574825759 (2007).

38. Lai, C. S., Fisher, S. E., Hurst, J. A., Vargha-Khadem, F. & Monaco, A. P.

A forkhead-domain gene is mutated in a severe speech and language disorder. Nature 413, 519523 (2001).

39. Watkins, K. E., Dronkers, N. F. & Vargha-Khadem, F. Behavioural analysis of an inherited speech and language disorder: comparison with acquired aphasia. Brain 125, 452464 (2002).

40. Bruce, H. A. & Margolis, R. L. FOXP2: novel exons, splice variants, and CAG repeat length stability. Hum. Genet. 111, 136144 (2002).

41. Li, S., Weidenfeld, J. & Morrisey, E. E. Transcriptional and DNA binding activity of the Foxp1/2/4 family is modulated by heterotypic and homotypic protein interactions. Mol. Cell Biol. 24, 809822 (2004).

42. Fisher, S. E., Vargha-Khadem, F., Watkins, K. E., Monaco, A. P. & Pembrey, M. E. Localisation of a gene implicated in a severe speech and language disorder. Nat. Genet. 18, 168170 (1998).

43. MacDermot, K. D. et al. Identication of FOXP2 truncation as a novel cause of developmental speech and language decits. Am. J. Hum. Genet. 76, 10741080 (2005).

44. Vernes, S. C. et al. Functional genetic analysis of mutations implicated in a human speech and language disorder. Hum. Mol. Genet. 15, 31543167 (2006).

45. Traylor, R. N. et al. Investigation of TBR1 Hemizygosity: four Individuals with 2q24 microdeletions. Mol. Syndromol. 3, 102112 (2012).

46. Palumbo, O. et al. TBR1 is the candidate gene for intellectual disability in patients with a 2q24.2 interstitial deletion. Am. J. Med. Genet. A 164A, 828833 (2014).

47. Belengeanu, V. et al. A de novo 2.3Mb deletion in 2q24.2q24.3 in a 20-month-old developmentally delayed girl. Gene 539, 168172 (2014).

48. Huang, T. N. et al. Tbr1 haploinsufciency impairs amygdalar axonal projections and results in cognitive abnormality. Nat. Neurosci. 17, 240247 (2014).

49. Coll, M., Seidman, J. G. & Muller, C. W. Structure of the DNA-bound T-box domain of human TBX3, a transcription factor responsible for ulnar-mammary syndrome. Structure 10, 343356 (2002).

50. Hiroi, Y. et al. Tbx5 associates with Nkx2-5 and synergistically promotes cardiomyocyte differentiation. Nat. Genet. 28, 276280 (2001).

51. Bulfone, A. et al. T-brain-1: a homolog of Brachyury whose expression denes molecularly distinct domains within the cerebral cortex. Neuron 15, 6378 (1995).

52. Hisaoka, T., Nakamura, Y., Senba, E. & Morikawa, Y. The forkhead transcription factors, Foxp1 and Foxp2, identify different subpopulations of projection neurons in the mouse cerebral cortex. Neuroscience 166, 551563 (2010).

53. Bedogni, F. et al. Tbr1 regulates regional and laminar identity of postmitotic neurons in developing neocortex. Proc. Natl Acad. Sci. USA 107, 1312913134 (2010).

Acknowledgements

We wish to thank Arianna Vino and Flavia Bianca Cristian for technical assistance. This work was supported by the Max Planck Society and a grant from the Simons Foundation Autism Research Initiative (SFARI 303241 to E.E.E.) and NIH (MH101221 to E.E.E.). We are grateful to all of the families at the participating Simons Simplex Collection (SSC) sites, as well as the principal investigators (A. Beaudet, J. Constantino, E. Cook,E. Fombonne, D. Geschwind, R. Goin-Kochel, E. Hanson, D. Grice, A. Klin, D. Ledbetter,C. Lord, C. Martin, D. Martin, R. Maxim, J. Miles, O. Ousley, K. Pelphrey, B. Peterson,J. Piggot, C. Saulnier, M. State, W. Stone, J. Sutcliffe, C. Walsh, Z. Warren, E. Wijsman). We appreciate obtaining access to phenotypic data on SFARI Base. Approved researchers can obtain the SSC population data set described in this study (https://ordering.base.sfari.org/~browse_collection/archive

Web End =https://order https://ordering.base.sfari.org/~browse_collection/archive

Web End =ing.base.sfari.org/Bbrowse_collection/archive [ssc_v13]/ui:view) by applying at https://base.sfari.org

Web End =https://

https://base.sfari.org

Web End =base.sfari.org .

Author contributions

P.D. and S.E.F. designed the study, interpreted results and drafted the manuscript. S.E.F. supervised the study. P.D. performed the experiments. P.D., S.A.G., S.B.E. and D.D. generated the expression constructs used in transfections. B.J.O., J.S. and E.E.E. identied and characterized the TBR1 mutations and followed-up with ASD probands. R.A.B. and J.G. analysed the clinical information. S.A.G, B.J.O. and E.E.E. contributed to the manuscript.

Additional information

Supplementary Information accompanies this paper at http://www.nature.com/naturecommunications

Web End =http://www.nature.com/ http://www.nature.com/naturecommunications

Web End =naturecommunications

Competing nancial interests: E.E.E. is on the scientic advisory boards (SABs) of DNAnexus, Inc. and was an SAB member of Pacic Biosciences, Inc. (2009-2013) and SynapDx Corp. (2011-2013). The remaining authors declare no competing nancial interests.

Reprints and permission information is available online at http://npg.nature.com/reprintsandpermissions/

Web End =http://npg.nature.com/ http://npg.nature.com/reprintsandpermissions/

Web End =reprintsandpermissions/

How to cite this article: Deriziotis, P. et al. De novo TBR1 mutations in sporadic autism disrupt protein functions. Nat. Commun. 5:4954 doi: 10.1038/ncomms5954 (2014).

12 NATURE COMMUNICATIONS | 5:4954 | DOI: 10.1038/ncomms5954 | http://www.nature.com/naturecommunications

Web End =www.nature.com/naturecommunications

& 2014 Macmillan Publishers Limited. All rights reserved.