Data from: Unique and overlapping behavioral effects of isoform-specific NRXN1 deletions
Data files
Jun 18, 2026 version files 9.23 MB
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Crispant_larval_data.zip
180.76 KB
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Deletion_line_juvenile_data.zip
109.20 KB
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Deletion_line_larval_data.zip
8.93 MB
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README.md
7.06 KB
Abstract
Mutations in the human neurexin 1 (NRXN1) gene are associated with neurodevelopmental disorders, including autism and schizophrenia. Vertebrate NRXN1 produces three major NRXN1 isoforms, named α, β, and γ. Human genetic data suggest that deletions located at the 5’ region of the gene disrupting the α isoform associate mostly with clinical behavioral deficits. Yet, 3’ deletions that disrupt multiple isoforms have also been identified in clinical cases. Whether deletions that selectively affect specific NRXN1 isoforms result in specific behavioral deficits remains unclear. Here, combining larval sensorimotor assays with a custom hands-free social preference assay developed for juvenile zebrafish, we show that zebrafish harboring gene deletions that differentially encompass nrxn1a-α, -β, and/or -γ display both unique and overlapping locomotion, sensorimotor behavior, and social behavior deficits. Combined, our results strongly support a model by which domain-selective nrxn1 deletions predict behavioral phenotypes. Moreover, our results demonstrate compelling relationships between genotype and resulting behavioral phenotypes, providing functional insights into the complexity of NRXN1-associated neuropsychiatric behaviors.
Dataset DOI: 10.5061/dryad.4b8gthtt1
Description of the data and file structure
This dataset contains behavioral data from zebrafish (Danio rerio) larvae and juveniles used to characterize the effects of isoform-specific nrxn1a and nrxn1b deletions on sensorimotor and social behavior. Data are organized into three categories: (1) larval behavior from CRISPR-injected crispants, (2) larval behavior from stable germline deletion lines, and (3) juvenile behavior from stable deletion lines.
All larval behavioral data were collected at 6 days post-fertilization (dpf). Larvae were individually arrayed in 100-well acrylic plates and recorded under infrared illumination. The behavioral paradigm included a Visual Motor Response (VMR) assay, Light Flash (LF) assay, Dark Flash (DF) assay, and Acoustic Startle Response (ASR) assay, delivered sequentially over approximately two hours. Following behavioral recording, individual larvae were genotyped. Juvenile behavioral data were collected at 5 weeks post-fertilization (wpf) using a social preference assay. Full details of behavioral paradigms, stimulus parameters, tracking methods, and metric calculations are provided in the associated publication.
Files and variables
File: Deletion_line_juvenile_data.zip
Description: The zip file contains three file types:
Length file (nrxn1a-juv-length): Body length (mm) for wild-type (WT), heterozygous (het), and homozygous mutant (mut) animals from both the nrxn1a-WD and nrxn1a-alpha lines, used to confirm the absence of gross size differences between genotypes.
Social preference files (nrxn1a-WD-5wpf, nrxn1a-alpha-5wpf): Per-animal data across all 20 minutes of the social preference assay. Columns include:
- avgfromcenter — average distance from the center of the well (pixels)
- totavgspeed — average swim speed (pixels/ms)
- fractionglasstime — fraction of time spent in proximity to the glass divider separating the subject from the stimulus fish, used as the primary measure of social preference
File: Deletion_line_larval_data.zip
Description: Larval behavioral data for stable germline deletion lines: nrxn1a alpha, beta, gamma, and whole deletion (WD), and nrxn1b whole deletion (WD).
The zip file contains one folder per mutant line. Within each folder are three subfolders (VMR, DF, and ASR), each containing raw Excel files from individual biological replicates as well as a combined summary file with the subset of metrics used to generate figures in the paper.
VMR files contain 18 time bins of locomotor metrics. Bins 1–16 correspond to sequential 1-minute epochs; bins 17 and 18 capture averages of Light ON and Light OFF segments. Each bin contains the following columns (repeated for each bin number):
- fish#, genotype
- #bouts — number of locomotor bouts
- totdist — total distance traveled (pixels)
- totdisp — total displacement (pixels)
- tottimemvmt — total time in movement (ms)
- totavgspeed — average speed (pixels/ms)
- avgfromcenter / medfromcenter — mean/median distance from well center (pixels)
- fractionouter — fraction of time spent in the outer rim of the well
- avgdistperbout / meddistperbout — mean/median distance per bout (pixels)
- avgdispperbout / meddispperbout — mean/median displacement per bout (pixels)
- avgtimeperbout / medtimeperbout — mean/median bout duration (ms)
- avgspeedperbout / medspeedperbout — mean/median speed per bout (pixels/ms)
DF files contain data from three blocks of 14 dark flash stimuli (1 s darkness, recorded at 500 fps). Each block (prefixed 1–, 2–, 3–) contains:
- avglat / medianlat — mean/median latency to movement (ms)
- %slc — fraction performing O-bend response
- %react / %nomovmt — fraction reacting / fraction showing no movement
- %rightturn / directionbias — turn direction metrics
- %towards / %towardshalf — orientation relative to stimulus
- avgbend / medianbend — mean/median maximum bend angle (rad)
- avgangvelmax / medianangvelmax — mean/median maximum angular velocity (rad/frame)
- avgorient / medianorient — mean/median change in orientation (rad)
- avgdisp / mediandisp — mean/median displacement (pixels)
- avgdist / mediandist — mean/median distance traveled (pixels)
- avgduration / medianduration — mean/median response duration (ms)
- habslc — O-bend habituation index (blocks 2 and 3): calculated as (1 − [O-bend frequency for last 14 stimuli]) ÷ [O-bend frequency for first 14 stimuli]
ASR files contain data from 10 stimulus blocks including low, medium, and high intensity taps, and prepulse inhibition (PPI) trials. Blocks 1–6 contain per-stimulus response metrics identical in structure to DF. Blocks 3–6 additionally contain PPI metrics (prefixed ppi-): ppislc, ppiavglat, ppimedlat, ppiavgbend, ppimedbend, ppiavgangvel, ppimedangvel, ppiavgorient, ppimedorient, ppiavgdisp, ppimeddisp, ppiavgdist, ppimeddist, ppiavgduration, ppimedduration. Block 7 additionally contains AUC (area under the SLC frequency vs. stimulus intensity curve, the sensitivity index). Blocks 8–10 contain habituation metrics (prefixed hab-): habslc, habavglat, habmedlat, habavgbend, habmedbend, habavgangvel, habmedangvel, habavgorient, habmedorient, habavgdisp, habmeddisp, habavgdist, habmeddist, habavgduration, habmedduration. ASR habituation is calculated as (1 − [SLC frequency for last 10 high-intensity stimuli at 1 s ISI]) ÷ [SLC frequency for 10 high-intensity stimuli at 20 s ISI]. PPI is calculated as (1 − [SLC frequency for 10 PPI4 trials]) ÷ [SLC frequency for 10 high-intensity stimuli at 20 s ISI].
File: Crispant_larval_data.zip
Description: Three biological replicates of nrxn1a (file starts with 1a) and nrxn1b crispants (file starts with 1b). Each file contains data from one assay, indicated by the file suffix: -BL (VMR), -DF (Dark Flash), -LF (Light Flash), -Tap (ASR). The crispant files contain a subset of metrics from the full deletion line dataset, corresponding to key bins and metrics used for figure generation:
VMR (-BL): bins 1, 8, 9, 16 — #bouts, totdist, tottimemvmt, totavgspeed, avgfromcenter, fractionouter, avgdistperbout, avgtimeperbout, avgspeedperbout
Dark Flash (-DF): block 1: avglat, %slc, %react, %nomovmt, avgbend, avgangvelmax, avgorient, avgdisp, avgdist, avgduration; block 3: habslc
Light Flash (-LF): avglat, %react, %nomovmt, avgbend, avgangvelmax, avgorient, avgdisp, avgdist, avgduration
ASR (-Tap): block 6: ppislc; block 7: avglat, %slc, AUC, %llc, %react, avgbend, avgangvelmax, avgorient, avgdist, avgduration; block 10: habslc
Code/software
None. All data are provided as Excel files. Behavioral metrics were computed using custom Python tracking software; the behavioral paradigm, tracking approach, and metric definitions are described in full in the associated publication.
Access information
None