Paper List

Journal: ArXiv Preprint
Published: Unknown
BioinformaticsTheoretical Computer Science

Incorporating indel channels into average-case analysis of seed-chain-extend

Carnegie Mellon University, Pittsburgh, PA, USA

Spencer Gibson, Yun William Yu
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The 30-Second View

IN SHORT: This paper addresses the core pain point of bridging the theoretical gap for the widely used seed-chain-extend heuristic by providing the first rigorous average-case analysis that accounts for insertions and deletions (indels), not just substitutions.

Innovation (TL;DR)

  • Methodology Introduces a generalized definition of 'recoverability' and a 'homologous path' to mathematically model the correct alignment under indel mutation channels, moving beyond the simpler 'homologous diagonal' used for substitutions only.
  • Theory Develops new mathematical machinery to handle the dependence structure of neighboring anchors and the existence of 'clipping anchors' (partially correct anchors), which are unique challenges introduced by indels.
  • Theory Proves that under a total mutation rate θ_T < 0.159, optimal linear-gap cost chaining achieves an expected recoverability of ≥ 1 - O(1/√m), generalizing the prior substitution-only result to a biologically realistic model.

Key conclusions

  • The expected recoverability of an optimal chain under linear-gap cost chaining is ≥ 1 - O(1/√m) when the total mutation rate θ_T (sum of substitution, insertion, deletion rates) is less than 0.159.
  • The expected runtime of the algorithm is O(m n^(3.15·θ_T) log n). For example, at a θ_T of 0.05 (similar to human-chimp divergence), the exponent is ~1.12, leading to near-linear scaling.
  • The analysis successfully bridges theory and practice by extending the proof framework to handle indels, justifying the heuristic's empirical effectiveness on real genomic data which contains indels.
Background and Gap: Prior theoretical analyses of the seed-chain-extend heuristic were limited to substitution-only mutation models, creating a significant gap with practice where indels are prevalent. The field lacked a rigorous average-case performance guarantee for this core bioinformatics algorithm under a realistic mutation model.

Abstract: Given a sequence s1 of n letters drawn i.i.d. from an alphabet of size σ and a mutated substring s2 of length m<n, we often want to recover the mutation history that generated s2 from s1. Modern sequence aligners are widely used for this task, and many employ the seed-chain-extend heuristic with k-mer seeds. Previously, Shaw and Yu showed that optimal linear-gap cost chaining can produce a chain with 1−O(1/m) recoverability, the proportion of the mutation history that is recovered, in O(mn^(2.43θ) log n) expected time, where θ<0.206 is the mutation rate under a substitution-only channel and s1 is assumed to be uniformly random. However, a gap remains between theory and practice, since real genomic data includes insertions and deletions (indels), and yet seed-chain-extend remains effective. In this paper, we generalize those prior results by introducing mathematical machinery to deal with the two new obstacles introduced by indel channels: the dependence of neighboring anchors and the presence of anchors that are only partially correct. We are thus able to prove that the expected recoverability of an optimal chain is ≥1−O(1/√m) and the expected runtime is O(mn^(3.15·θ_T) log n), when the total mutation rate given by the sum of the substitution, insertion, and deletion mutation rates (θ_T = θ_i + θ_d + θ_s) is less than 0.159.

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