Modeling the intronic regulation of Alternative Splicing using Deep Convolutional Neural Nets / En metod baserad på djupa neurala nätverk för att modellera regleringen av Alternativ Splicing

Linder, Johannes

January 2015

This paper investigates the use of deep Convolutional Neural Networks for modeling the intronic regulation of Alternative Splicing on the basis of DNA sequence. By training the CNN on massively parallel synthetic DNA libraries of Alternative 5'-splicing and Alternatively Skipped exon events, the model is capable of predicting the relative abundance of alternatively spliced mRNA isoforms on held-out library data to a very high accuracy (R2 = 0.77 for Alt. 5'-splicing). Furthermore, the CNN is shown to generalize alternative splicing across cell lines efficiently. The Convolutional Neural Net is tested against a Logistic regression model and the results show that while prediction accuracy on the synthetic library is notably higher compared to the LR model, the CNN is worse at generalizing to new intronic contexts. Tests on non-synthetic human SNP genes suggest the CNN is dependent on the relative position of the intronic region it was trained for, a problem which is alleviated with LR. The increased library prediction accuracy of the CNN compared to Logistic regression is concluded to come from the non-linearity introduced by the deep layer architecture. It adds the capacity to model complex regulatory interactions and combinatorial RBP effects which studies have shown largely affect alternative splicing. However, the architecture makes interpreting the CNN hard, as the regulatory interactions are encoded deep within the layers. Nevertheless, high-performance modeling of alternative splicing using CNNs may still prove useful in numerous Synthetic biology applications, for example to model differentially spliced genes as is done in this paper. / Den här uppsatsen undersöker hur djupa neurala nätverk baserade på faltning ("Convolutions") kan användas för att modellera den introniska regleringen av Alternativ Splicing med endast DNA-sekvensen som indata. Nätverket tränas på ett massivt parallelt bibliotek av syntetiskt DNA innehållandes Alternativa Splicing-event där delar av de introniska regionerna har randomiserats. Uppsatsen visar att nätverksarkitekturen kan förutspå den relativa mängden alternativt splicat RNA till en mycket hög noggrannhet inom det syntetiska biblioteket. Modellen generaliserar även alternativ splicing mellan mänskliga celltyper väl. Hursomhelst, tester på icke-syntetiska mänskliga gener med SNP-mutationer visar att nätverkets prestanda försämras när den introniska region som används som indata flyttas i jämförelse till den relativa position som modellen tränats på. Uppsatsen jämför modellen med Logistic regression och drar slutsatsen att nätverkets förbättrade prestanda grundar sig i dess förmåga att modellera icke-linjära beroenden i datan. Detta medför dock svårigheter i att tolka vad modellen faktiskt lärt sig, eftersom interaktionen mellan reglerande element är inbäddat i nätverkslagren. Trots det kan högpresterande modellering av alternativ splicing med hjälp av neurala nät vara användbart, exempelvis inom Syntetisk biologi där modellen kan användas för att kontrollera regleringen av splicing när man konstruerar syntetiska gener.

Machine Learning

Deep Learning

CNN

CNNs

Convolutional Neural Networks

Convolutional Neural Nets

Neural Networks

Neural Nets

Synthetic Biology

Alternative Splicing

AS

Splicing

DNA Regulation

Synthetic DNA

Massively Parallel Library

Maskinlärning

CNN

CNNs

Convolutional Neural Networks

Convolutional Neural Nets

Faltning

Neurala Nätverk

Neurala Nät

Syntetisk Biologi

Alternativ Splicing

Splicing

AS

DNA

Massivt Parallellt Bibliotek

Syntetiskt DNA

Computer Sciences

Datavetenskap (datalogi)

Global-Context Refinement for Semantic Image Segmentation

Menart, Christopher J., Menart

14 August 2018

No description available.

Artificial Intelligence

Computer Science

computer vision

artificial intelligence

deep learning

convolutional neural nets

semantic segmentation

image context

probabilistic inference

bayesian

PASCAL Context

NYUDv2

ADE20K

RefineNet

deep scene understanding

confusion matrices

Interaktivní segmentace 3D CT dat s využitím hlubokého učení / Interactive 3D CT Data Segmentation Based on Deep Learning

Trávníčková, Kateřina

January 2020

This thesis deals with CT data segmentation using convolutional neural nets and describes the problem of training with limited training sets. User interaction is suggested as means of improving segmentation quality for the models trained on small training sets and the possibility of using transfer learning is also considered. All of the chosen methods help improve the segmentation quality in comparison with the baseline method, which is the use of automatic data specific segmentation model. The segmentation has improved by tens of percents in Dice score when trained with very small datasets. These methods can be used, for example, to simplify the creation of a new segmentation dataset.