Single-cell long-read mRNA isoform regulation is pervasive across mammalian brain regions, cell types, and development

Joglekar, Anoushka; Hu, Wen Yang; Zhang, Bei; Narykov, Oleksandr; Diekhans, Mark; Balacco, Jennifer; Ndhlovu, Lishomwa C.; Milner, Teresa A.; Fédrigo, Olivier; Jarvis, Erich D.; Sheynkman, Gloria; Korkin, Dmitry; Ross, M. Elizabeth; Tilgner, Hagen U

doi:10.1101/2023.04.02.535281

Cited by 8 publications

(10 citation statements)

References 92 publications

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“…Furthermore, using LR var0. 25 to predict 𝛹 values of all exons resulted in lower performance for neurons compared to glia in both HPC and FC (Figure 1D, S3). Indicating that the learned splicing patterns for variable exons in neurons do not generalize to non-variable exons -likely because the underlying molecular grammar is different in the two exon sets.…”

Section: Predicting Exon Inclusion Is More Difficult In Neurons Than ...mentioning

confidence: 99%

“…As cell-type-specific alternative splicing is partially conserved between humans and mice 25 , we hypothesized that adding mouse data to our model would increase performance. We combined human HPC data with mouse HPC 25 . Since mouse FC data is not available, we combined human FC with data from the mouse visual cortex (VIS).…”

Section: Exon Inclusion Mechanisms Are Conserved Between Human and Mousementioning

confidence: 99%

“…Long-read single-cell and single-nuclei sequencing in fresh 21,22 and frozen 23 tissue allows the study of alternative splicing at the cell-type level in the brain and other complex tissues. Such analyses revealed that most mouse genes show differential isoform expression across at least one pair of cell types, regions, and/or developmental time points in the brain 24,25 . In accordance with prior studies [26][27][28] , single-nuclei isoform RNA sequencing (SnISOr-Seq) of the human adult frontal cortex revealed that exons associated with autism spectrum disorder (ASD) are variably included across cell types 23 .…”

Section: Introductionmentioning

confidence: 99%

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Predicting cell-type-specific exon inclusion in the human brain reveals more complex splicing mechanisms in neurons than glia

Michielsen,

Hsu,

Joglekar

et al. 2024

Preprint

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Alternative splicing contributes to molecular diversity across brain cell types. RNA-binding proteins (RBPs) regulate splicing, but the genome-wide mechanisms remain poorly understood. Here, we used RBP binding sites and/or the genomic sequence to predict exon inclusion in neurons and glia as measured by long-read single-cell data in human hippocampus and frontal cortex. We found that alternative splicing is harder to predict in neurons compared to glia in both brain regions. Comparing neurons and glia, the position of RBP binding sites in alternatively spliced exons in neurons differ more from non-variable exons indicating distinct splicing mechanisms. Model interpretation pinpointed RBPs, including QKI, potentially regulating alternative splicing between neurons and glia. Finally, using our models, we accurately predict and prioritize the effect of splicing QTLs. Taken together, our models provide new insights into the mechanisms regulating cell-type-specific alternative splicing and can accurately predict the effect of genetic variants on splicing.

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Section: Predicting Exon Inclusion Is More Difficult In Neurons Than ...mentioning

confidence: 99%

Section: Exon Inclusion Mechanisms Are Conserved Between Human and Mousementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Predicting cell-type-specific exon inclusion in the human brain reveals more complex splicing mechanisms in neurons than glia

Michielsen,

Hsu,

Joglekar

et al. 2024

Preprint

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“…Both splicing 9,[11][12][13] and chromatin 14 organization are known to differentiate cell types within a brain region as well as matched cell types across brain regions 15 . Moreover, multiple modalities have undergone evolutionary changes and are affected in complex diseases such as Alzheimer's disease (AD) [16][17][18] .…”

Section: Introductionmentioning

confidence: 99%

ScISOr-ATAC reveals convergent and divergent splicing and chromatin specificities between matched cell types across cortical regions, evolution, and in Alzheimer’s Disease

Hu,

Foord,

Hsu

et al. 2024

Preprint

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Multimodal measurements have become widespread in genomics, however measuring open chromatin accessibility and splicing simultaneously in frozen brain tissues remains unconquered. Hence, we devised Single-Cell-ISOform-RNA sequencing coupled with the Assay-for-Transposase-Accessible-Chromatin (ScISOr-ATAC). We utilized ScISOr-ATAC to assess whether chromatin and splicing alterations in the brain convergently affect the same cell types or divergently different ones. We applied ScISOr-ATAC to three major conditions: comparing (i) the Rhesus macaque (Macaca mulatta) prefrontal cortex (PFC) and visual cortex (VIS), (ii) cross species divergence of Rhesus macaque versus human PFC, as well as (iii) dysregulation in Alzheimer's disease in human PFC. We found that among cortical-layer biased excitatory neuron subtypes, splicing is highly brain-region specific for L3-5/L6 IT_RORB neurons, moderately specific in L2-3 IT_CUX2.RORB neurons and unspecific in L2-3 IT_CUX2 neurons. In contrast, at the chromatin level, L2-3 IT_CUX2.RORB neurons show the highest brain-region specificity compared to other subtypes. Likewise, when comparing human and macaque PFC, strong evolutionary divergence on one molecular modality does not necessarily imply strong such divergence on another molecular level in the same cell type. Finally, in Alzheimer's disease, oligodendrocytes show convergently high dysregulation in both chromatin and splicing. However, chromatin and splicing dysregulation most strongly affect distinct oligodendrocyte subtypes. Overall, these results indicate that chromatin and splicing can show convergent or divergent results depending on the performed comparison, justifying the need for their concurrent measurement to investigate complex systems. Taken together, ScISOr-ATAC allows for the characterization of single-cell splicing and chromatin patterns and the comparison of sample groups in frozen brain samples.

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“…Transcript and, by extension, protein isoform diversity may now be globally characterized at great depth for individual samples (Glinos et al 2022;Reese et al 2023). Transcript diversity can be readily characterized by long read RNA-Seq, which employs single molecule sequencing of individual cDNA or RNA molecules to determine the sequence across the entire length of spliced transcripts (Sharon et al 2013;Workman et al 2019;Pardo Palacios et al 2021;Tian et al 2021;Joglekar et al 2023), with platforms from Oxford Nanopore and PacBio being most commonly used (Clarke et al 2009;Eid et al 2009). Long read RNA sequencing captures long range connectivity between multiple exons of a transcript and can reveal complex splice patterns unattainable by short read sequencing (De Paoli Iseppi et al 2021), including dependencies across distal splicing events (Anvar et al 2018) and alternative 5' and 3' transcript usage.…”

Section: Introductionmentioning

confidence: 99%

Biosurfer for systematic tracking of regulatory mechanisms leading to protein isoform diversity

Murali,

Saquing,

et al. 2024

Preprint

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Long-read RNA sequencing has shed light on transcriptomic complexity, but questions remain about the functionality of downstream protein products. We introduce Biosurfer, a computational approach for comparing protein isoforms, while systematically tracking the transcriptional, splicing, and translational variations that underlie differences in the sequences of the protein products. Using Biosurfer, we analyzed the differences in 32,799 pairs of GENCODE annotated protein isoforms, finding a majority (70%) of variable N-termini are due to the alternative transcription start sites, while only 9% arise from 5' UTR alternative splicing. Biosurfer's detailed tracking of nucleotide-to-residue relationships helped reveal an uncommonly tracked source of single amino acid residue changes arising from the codon splits at junctions. For 17% of internal sequence changes, such split codon patterns lead to single residue differences, termed "ragged codons". Of variable C-termini, 72% involve splice- or intron retention-induced reading frameshifts. We found an unusual pattern of reading frame changes, in which the first frameshift is closely followed by a distinct second frameshift that restores the original frame, which we term a "snapback" frameshift. We analyzed long read RNA-seq-predicted proteome of a human cell line and found similar trends as compared to our GENCODE analysis, with the exception of a higher proportion of isoforms predicted to undergo nonsense-mediated decay. Biosurfer's comprehensive characterization of long-read RNA-seq datasets should accelerate insights of the functional role of protein isoforms, providing mechanistic explanation of the orgins of the proteomic diversity driven by the alternative splicing. Biosurfer is available as a Python package at https://github.com/sheynkman-lab/biosurfer.

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Single-cell long-read mRNA isoform regulation is pervasive across mammalian brain regions, cell types, and development

Cited by 8 publications

References 92 publications

Predicting cell-type-specific exon inclusion in the human brain reveals more complex splicing mechanisms in neurons than glia

Predicting cell-type-specific exon inclusion in the human brain reveals more complex splicing mechanisms in neurons than glia

ScISOr-ATAC reveals convergent and divergent splicing and chromatin specificities between matched cell types across cortical regions, evolution, and in Alzheimer’s Disease

Biosurfer for systematic tracking of regulatory mechanisms leading to protein isoform diversity

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