Cell type directed design of synthetic enhancers

Taskiran, Ibrahim Ihsan; Spanier, Katina I.; Christiaens, Valerie; Mauduit, David; Aerts, Stein

doi:10.1101/2022.07.26.501466

Cited by 35 publications

(44 citation statements)

References 65 publications

(99 reference statements)

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“…We further acknowledge that further work on model interpretation is needed to arrive at a sequence code for regulatory activity. Recent developments to this end (Shrikumar et al 2019; Avsec et al 2021b; de Almeida et al 2022; Taskiran et al 2022) show great promise, and we expect that integration of such analyses with the transfer learning scheme of ChromTransfer will be important for future efforts to understand the regulatory code.…”

Section: Discussionmentioning

confidence: 99%

Transfer learning identifies sequence determinants of regulatory element accessibility

Salvatore

Horlacher

Winther

et al. 2022

Preprint

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Dysfunction of regulatory elements through genetic variants is a central mechanism in the pathogenesis of disease. To better understand disease etiology, there is consequently a need to understand how DNA encodes regulatory activity. Deep learning methods show great promise for modeling of biomolecular data from DNA sequence, but are limited to large input data for training. Here, we develop ChromTransfer, a transfer learning method that uses a pre-trained, cell-type agnostic model of open chromatin regions as a basis for fine-tuning on regulatory sequences. We demonstrate superior performances with ChromTransfer for learning cell-type specific chromatin accessibility from sequence compared to models not informed by a pre-trained model. Furthermore, ChromTransfer enables fine-tuning on small input data with minimal decrease in accuracy. We show that ChromTransfer uses sequence features matching binding site sequences of key transcription factors for prediction. Together, these results demonstrate ChromTransfer as a promising tool for learning the regulatory code.

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Section: Discussionmentioning

confidence: 99%

Transfer learning identifies sequence determinants of regulatory element accessibility

Salvatore

Horlacher

Winther

et al. 2022

Preprint

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“…We compared this to predicted scores generated with the same feature implantation approach using a dinucleotide shuffled version of the 16bp sequence containing the TATA box motif, a random 16bp one-hot encoded sequence, and a 16bp all zeros input. We performed the in silico evolution experiments on the same set of 310 promoter sequences 31,62 . In each round, we first used in silico saturation mutagenesis to identify the mutation that increased the model score by the largest positive value (delta score).…”

Section: Methodsmentioning

confidence: 99%

“…However, due to the inherent flexibility of PL, more advanced users can customize almost all aspects of their model training strategy. For instance, custom training loops can be defined for models that implement multipart loss functions or use multiple optimizers [60][61][62] (e.g. for variational autoencoders and generative adversarial networks respectively).…”

Section: Building Workflows Through Seqdata and Basemodelmentioning

confidence: 99%

EUGENe: A Python toolkit for predictive analyses of regulatory sequences

Klie

Stites²,

Jores

et al. 2022

Preprint

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Deep learning (DL) has become a popular tool to study cis-regulatory element function. Yet efforts to design software for DL analyses in genomics that are Findable, Accessible, Interoperable and Reusable (FAIR) have fallen short of fully meeting these criteria. Here we present EUGENe (Elucidating the Utility of Genomic Elements with Neural Nets), a FAIR toolkit for the analysis of labeled sets of nucleotide sequences with DL. EUGENe consists of a set of modules that empower users to execute the key functionality of a DL workflow: 1) extracting, transforming and loading sequence data from many common file formats, 2) instantiating, initializing and training diverse model architectures, and 3) evaluating and interpreting model behavior. We designed EUGENe to be simple; users can develop and deploy workflows on new or existing datasets with functions that act on two customizable Python objects, annotated sequence data (SeqData) and PyTorch models (BaseModel). The modularity and simplicity of EUGENe also make it highly extensible and we illustrate these principles through application of the toolkit to three predictive modeling tasks. First, we train and compare a set of built-in models along with a custom architecture for the accurate prediction of activities of plant promoters from STARR-seq data. Next, we apply EUGENe to an RNA binding prediction task and showcase how seminal model architectures can be retrained in EUGENe or imported from Kipoi. Finally, we train models to classify transcription factor binding by wrapping functionality from Janngu, which can efficiently extract sequences in BED file format from the human genome. We emphasize that the code used in each use case is simple, readable, and well documented (https://eugene-tools.readthedocs.io/en/latest/index.html). We believe that EUGENe represents a springboard toward a collaborative ecosystem for DL applications in genomics research. EUGENe is available for download on GitHub (https://github.com/cartercompbio/EUGENe) along with several introductory tutorials and for installation on PyPi (https://pypi.org/project/eugene-tools/).

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“…Reporter assays have been applied to mammalian differentiation models (e.g., neuronal (21), naive to epiblast (22)), but these remain essentially simple trajectories. Single-cell chromatin accessibility data from systems containing extensive cell type heterogeneity can be used to train models predicting differential accessibility from DNA sequence (23)(24)(25), with promise to also correlatively predict cell-typespecific expression (26). However, these models remain one step removed from the functional outcome and are inherently limited given that differentially accessible genomic regions commonly lack autonomous expression-enhancing activity (27).…”

Section: Main Textmentioning

confidence: 99%

Multiplex profiling of developmental enhancers with quantitative, single-cell expression reporters

Lalanne

Regalado

Domcke

et al. 2022

Preprint

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The inability to scalably and precisely measure the activity of developmental enhancers in multicellular systems is a bottleneck in genomics. Here, we develop a dual RNA cassette that decouples the detection and quantification tasks inherent to multiplex single-cell reporter assays, resulting in accurate measurement of reporter expression over a >10,000-fold range of activity with a precision approaching the limit set by Poisson counting noise. Together with RNA barcode circularization, these single-cell quantitative expression reporters (scQers) provide high-contrast readouts analogous to classic in situ assays, but entirely from sequencing. Screening >200 enhancers in a multicellular in vitro model of early mammalian development, we identified numerous autonomous and cell-type-specific elements, including constituents of the Sox2 control region exclusively active in pluripotent cells, endoderm-specific enhancers, including near Foxa2 and Gata4, and a compact pleiotropic enhancer at the Lamc1 locus. scQers can be mobilized in developmental systems to quantitatively characterize native, perturbed, and synthetic enhancers at scale, with high sensitivity and at single-cell resolution.

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Cell type directed design of synthetic enhancers

Cited by 35 publications

References 65 publications

Transfer learning identifies sequence determinants of regulatory element accessibility

Transfer learning identifies sequence determinants of regulatory element accessibility

EUGENe: A Python toolkit for predictive analyses of regulatory sequences

Multiplex profiling of developmental enhancers with quantitative, single-cell expression reporters

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