Computational methods for RNA integrative biology

Selega, Alina

January 2018

Ribonucleic acid (RNA) is an essential molecule, which carries out a wide variety of functions within the cell, from its crucial involvement in protein synthesis to catalysing biochemical reactions and regulating gene expression. Such diverse functional repertoire is indebted to complex structures that RNA can adopt and its flexibility as an interacting molecule. It has become possible to experimentally measure these two crucial aspects of RNA regulatory role with such technological advancements as next-generation sequencing (NGS). NGS methods can rapidly obtain the nucleotide sequence of many molecules in parallel. Designing experiments, where only the desired parts of the molecule (or specific parts of the transcriptome) are sequenced, allows to study various aspects of RNA biology. Analysis of NGS data is insurmountable without computational methods. One such experimental method is RNA structure probing, which aims to infer RNA structure from sequencing chemically altered transcripts. RNA structure probing data is inherently noisy, affected both by technological biases and the stochasticity of the underlying process. Most existing methods do not adequately address the issue of noise, resorting to heuristics and limiting the informativeness of their output. In this thesis, a statistical pipeline was developed for modelling RNA structure probing data, which explicitly captures biological variability, provides automated bias-correcting strategies, and generates a probabilistic output based on experimental measurements. The output of our method agrees with known RNA structures, can be used to constrain structure prediction algorithms, and remains robust to reduced sequence coverage, thereby increasing sensitivity of the technology. Another recent experimental innovation maps RNA-protein interactions at very high temporal resolution, making it possible to study rapid binding events happening on a minute time scale. In this thesis, a non-parametric algorithm was developed for identifying significant changes in RNA-protein binding time-series between different conditions. The method was applied to novel yeast RNA-protein binding time-course data to study the role of RNA degradation in stress response. It revealed pervasive changes in the binding to the transcriptome of the yeast transcription termination factor Nab3 and the cytoplasmic exoribonuclease Xrn1 under nutrient stress. This challenged the common assumption of viewing transcriptional changes as the major driver of changes in RNA expression during stress and highlighted the importance of degradation. These findings inspired a dynamical model for RNA expression, where transcription and degradation rates are modelled using RNA-protein binding time-series data.

Determination of the Structure of the Spliceosomal U6 snRNP from Yeast, <i>Saccharomyces cerevisiae</i> / Untersuchung der Struktur des spliceosomalen U6 snRNPs in der Hefe, <i>Saccharomyces cerevisiae</i>

Karaduman, Ramazan

02 November 2006

No description available.

500 Naturwissenschaften allgemein

Mathematics and Computer Science

hefe U6 snRNP

hefe U6 snRNA

Prp24p

LSm Proteine

RNA Struktur Probing

Elektronenmikroskopie

YFP-Markierung

yeast U6 snRNP

yeast U6 snRNA

Prp24p

LSm2 8p proteins

RNA structure probing

electron microscopy

YFP labelling

42.13

WF

Drug Discovery Targeting Bacterial and Viral non-coding RNA: pH Modulation of RNAStability and RNA-RNA Interactions

Hossain, Md Ismail

23 May 2022

No description available.

Biochemistry

Biology

Genetics

Non-coding RNA

T-box Riboswitch

Stem-Loop II Motif

RNA thermometer

ompA

shuT

shuA

Drug Discovery

SARS-CoV-2

tRNA-mRNA interaction

In vitro transcription

Fluorescence Anisotropy

EMSA

Thermal denaturation

pH

RNA stability and conformation

RNA structure probing

Thermal hysteresis

16S rRNA

Nucleic acid research