Simulation-based inference of evolutionary parameters from adaptation dynamics using neural networks

Avecilla, Grace; Gresham, David; Ram, Yoav

doi:10.1101/2021.09.30.462581

Cited by 2 publications

(5 citation statements)

References 104 publications

(170 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This model is simple enough to simulate efficiently but complex enough to capture the genome frequency dynamics. Furthermore, SNPE is also computationally more efficient than sampling methods such as REJ-ABC due to its application of neural density estimators as well as amortization (Avecilla et al, 2021).…”

Section: Discussionmentioning

confidence: 99%

“…We used a recently developed neural-network-assisted likelihood-free inference method, sequential neural posterior estimation (SNPE) (Greenberg et al, 2019), or specifically, the SNPE-C implementation in the Python package sbi (Tejero-Cantero et al, 2020). SNPE has been recently applied for inferring the formation rate and fitness effect of copy number variation in populations of yeast evolving under nutrient limitation in a chemostat (Avecilla et al, 2021). Briefly, SNPE trains an artificial neural network on a training set of parameters (generated from the prior distribution) and simulated data (generated from the evolutionary model) to estimate the joint density of model parameters and data (conditioned on the prior distribution).…”

Section: Methodsmentioning

confidence: 99%

“…applied for inferring the formation rate and fitness effect of copy number variation in populations of yeast evolving under nutrient limitation in a chemostat (Avecilla et al, 2021)…”

Section: Sequential Neural Posterior Estimation (Snpe)mentioning

confidence: 99%

“…Importantly, MS2 has a particularly short genome of about 3,500 bases, allowing us to obtain reads that cover the entire genome.Here, we develop and test an approach to jointly infer both the mutation rate and selection parameters from sequencing data of MS2. Our approach relies on key methodological novelties: (a) long-read sequencing that covers the full length of the viral genome (i.e., haplotypes) (Callahan et al, 2021); (b) a multi-locus evolutionary model that captures the multitude of segregating haplotypes in the population; and (c) deep artificial neural networks and simulation-based inference that allow efficient and high-dimensional inference of model parameters (Avecilla et al, 2021; Cranmer et al, 2020). We applied this approach to infer the MS2 mutation rate and selection parameters from long-read haplotype sequences sampled from populations evolving in the lab.…”

mentioning

confidence: 99%

See 3 more Smart Citations

Mutation rate, selection, and epistasis inferred from RNA virus haplotypes via neural posterior estimation

Caspi

Meir

Nun

et al. 2023

Preprint

Self Cite

View full text Add to dashboard Cite

RNA viruses are particularly notorious for their high levels of genetic diversity, which is generated through the forces of mutation and natural selection. However, disentangling these two forces is a considerable challenge, and this may lead to widely divergent estimates of viral mutation rates, as well as difficulties in inferring fitness effects of mutations. Here, we develop, test, and apply an approach aimed at inferring the mutation rate and key parameters that govern natural selection, from haplotype sequences covering full length genomes of an evolving virus population. Our approach employs neural posterior estimation, a computational technique that applies simulation-based inference with neural networks to jointly infer multiple model parameters. We first tested our approach on synthetic data simulated using different mutation rates and selection parameters while accounting for sequencing errors. Reassuringly, the inferred parameter estimates were accurate and unbiased. We then applied our approach to haplotype sequencing data from a serial-passaging experiment with the MS2 bacteriophage. We estimated that the mutation rate of this phage is around 0.2 mutations per genome per replication cycle (95% highest density interval: 0.051-0.56). We validated this finding with two different approaches based on single-locus models that gave similar estimates but with much broader posterior distributions. Furthermore, we found evidence for reciprocal sign epistasis between four strongly beneficial mutations that all reside in an RNA stem-loop that controls the expression of the viral lysis protein, responsible for lysing host cells and viral egress. We surmise that there is a fine balance between over and under-expression of lysis that leads to this pattern of epistasis. To summarize, we have developed an approach for joint inference of the mutation rate and selection parameters from full haplotype data with sequencing errors, and used it to reveal features governing MS2 evolution.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

“…applied for inferring the formation rate and fitness effect of copy number variation in populations of yeast evolving under nutrient limitation in a chemostat (Avecilla et al, 2021)…”

Section: Sequential Neural Posterior Estimation (Snpe)mentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Mutation rate, selection, and epistasis inferred from RNA virus haplotypes via neural posterior estimation

Caspi

Meir

Nun

et al. 2023

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…In physics, SBI is useful from the smallest scales in particle colliders [165,166,167], where it allows us to measure the properties of the Higgs boson with a higher precision and less data, to the largest scales in the modeling of gravitational waves [168,169], stellar streams [170], gravitational lensing [171], and the evolution of the universe [172]. These methods have also been applied to study the evolutionary dynamics of protein networks [173] and in yeast strains [174]. In neuroscience, they have, e.g., been used to estimate the properties of ion channels from high-throughput voltage-clamp, and properties of neural circuits from observed rhythmic behaviour in the stomatogastric ganglion [133], to identify network models which can capture the dynamics of neuronal cultures [175], to study how the connectivity between different cell-types shapes dynamics in cortical circuits [176], and to identify biophysically realistic models of neurons in the retina [177,178].…”

Section: Examplesmentioning

confidence: 99%

Simulation Intelligence: Towards a New Generation of Scientific Methods

Lavin¹,

Zenil²,

Krakauer³

et al. 2021

Preprint

View full text Add to dashboard Cite

The original "Seven Motifs" set forth a roadmap of essential methods for the field of scientific computing, where a motif is an algorithmic method that captures a pattern of computation and data movement. 1 We present the Nine Motifs of Simulation Intelligence, a roadmap for the development and integration of the essential algorithms necessary for a merger of scientific computing, scientific simulation, and artificial intelligence. We call this merger simulation intelligence (SI), for short. We argue the motifs of simulation intelligence are interconnected and interdependent, much like the components within the layers of an operating system. Using this metaphor, we explore the nature of each layer of the simulation intelligence "operating system" stack (SI-stack) and the motifs therein:1. Multi-physics and multi-scale modeling 2. Surrogate modeling and emulation 3. Simulation-based inference 4. Causal modeling and inference 5. Agent-based modeling 6. Probabilistic programming 7. Differentiable programming 8. Open-ended optimization Machine programmingWe believe coordinated efforts between motifs offers immense opportunity to accelerate scientific discovery, from solving inverse problems in synthetic biology and climate science, to directing nuclear energy experiments and predicting emergent behavior in socioeconomic settings. We elaborate on each layer of the SI-stack, detailing the state-of-art methods, presenting examples to highlight challenges and opportunities, and advocating for specific ways to advance the motifs and the synergies from their combinations. Advancing and integrating these technologies can enable a robust and efficient hypothesis-simulation-analysis type of scientific method, which we introduce with several use-cases for human-machine teaming and automated science.

show abstract

Simulation-based inference of evolutionary parameters from adaptation dynamics using neural networks

Cited by 2 publications

References 104 publications

Mutation rate, selection, and epistasis inferred from RNA virus haplotypes via neural posterior estimation

Mutation rate, selection, and epistasis inferred from RNA virus haplotypes via neural posterior estimation

Simulation Intelligence: Towards a New Generation of Scientific Methods

Contact Info

Product

Resources

About