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Literature DB >> 28645146

Analysis of in vitro evolution reveals the underlying distribution of catalytic activity among random sequences.

Abe Pressman^1,2, Janina E Moretti³, Gregory W Campbell^1,4, Ulrich F Müller³, Irene A Chen^1,4.

Abstract

The emergence of catalytic RNA is believed to have been a key event during the origin of life. Understanding how catalytic activity is distributed across random sequences is fundamental to estimating the probability that catalytic sequences would emerge. Here, we analyze the in vitro evolution of triphosphorylating ribozymes and translate their fitnesses into absolute estimates of catalytic activity for hundreds of ribozyme families. The analysis efficiently identified highly active ribozymes and estimated catalytic activity with good accuracy. The evolutionary dynamics follow Fisher's Fundamental Theorem of Natural Selection and a corollary, permitting retrospective inference of the distribution of fitness and activity in the random sequence pool for the first time. The frequency distribution of rate constants appears to be log-normal, with a surprisingly steep dropoff at higher activity, consistent with a mechanism for the emergence of activity as the product of many independent contributions.

Entities: Chemical Disease Mutation Species

Mesh：

Substances：
RNA, Catalytic
RNA

Year: 2017 PMID： 28645146 PMCID： PMC5737207 DOI： 10.1093/nar/gkx540

Source DB: PubMed Journal: Nucleic Acids Res ISSN： 0305-1048 Impact factor: 16.971

41 in total

Analysis of in vitro evolution reveals the underlying distribution of catalytic activity among random sequences.

1. Randomization of genes by PCR mutagenesis.

2. Rapid construction of empirical RNA fitness landscapes.

3. High-Throughput Measurement of Binding Kinetics by mRNA Display and Next-Generation Sequencing.

4. Computational analysis of fitness landscapes and evolutionary networks from in vitro evolution experiments.

5. Next-generation sequencing reveals how RNA catalysts evolve from random space.

6. A ribozyme that triphosphorylates RNA 5'-hydroxyl groups.

7. Adaptation in protein fitness landscapes is facilitated by indirect paths.

8. Influence of target concentration and background binding on in vitro selection of affinity reagents.

9. Massively parallel interrogation of aptamer sequence, structure and function.

10. High-Throughput Mutational Analysis of a Twister Ribozyme.

1. Time-lapse imaging of molecular evolution by high-throughput sequencing.

2. The Origin of Life: What Is the Question?

3. Emerging Frontiers in the Study of Molecular Evolution.

4. Systematic minimization of RNA ligase ribozyme through large-scale design-synthesis-sequence cycles.

5. A Novel Small RNA-Cleaving Deoxyribozyme with a Short Binding Arm.

6. On the emergence of structural complexity in RNA replicators.

7. A combinatorial method to isolate short ribozymes from complex ribozyme libraries.

8. A GTP-synthesizing ribozyme selected by metabolic coupling to an RNA polymerase ribozyme.

9. Generative and interpretable machine learning for aptamer design and analysis of in vitro sequence selection.

10. Comprehensive sequence-to-function mapping of cofactor-dependent RNA catalysis in the glmS ribozyme.