AI Article Synopsis
- Single-molecule manipulation studies allow researchers to obtain precise measurements of complex biological molecules without interference from ensemble artifacts.
- The paper introduces computational techniques designed to maximize the information extracted from noisy experimental time series, which can stem from factors like thermal motion and measurement errors.
- The main focus is on a methodology that calculates effective molecular friction from pulling data, specifically analyzing titin I27 domains, while also addressing the benefits and challenges of applying this computational approach to single-molecule data.
Article Abstract
Single-molecule manipulation studies can provide quantitative information about the physical properties of complex biological molecules without ensemble artifacts obscuring the measurements. We demonstrate computational techniques which aim at more fully utilizing the wealth of information contained in noisy experimental time series. The "noise" comes from multiple sources e.g., inherent thermal motion, instrument measurement error, etc. The primary focus of this paper is a methodology that uses time domain based methods to extract the effective molecular friction from single-molecule pulling data. We studied molecules composed of eight tandem repeat titin I27 domains, but the modeling approaches have applicability to other single-molecule mechanical studies. The merits and challenges associated with applying such a computational approach to existing single-molecule manipulation data are also discussed.
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Source |
|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2760430 | PMC |
| http://dx.doi.org/10.1002/jmr.959 | DOI Listing |
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