English

Efficient pooling designs for library screening

Combinatorics 2016-09-06 v1 q-bio

Abstract

We describe efficient methods for screening clone libraries, based on pooling schemes which we call ``random kk-sets designs''. In these designs, the pools in which any clone occurs are equally likely to be any possible selection of kk from the vv pools. The values of kk and vv can be chosen to optimize desirable properties. Random kk-sets designs have substantial advantages over alternative pooling schemes: they are efficient, flexible, easy to specify, require fewer pools, and have error-correcting and error-detecting capabilities. In addition, screening can often be achieved in only one pass, thus facilitating automation. For design comparison, we assume a binomial distribution for the number of ``positive'' clones, with parameters nn, the number of clones, and cc, the coverage. We propose the expected number of {\em resolved positive} clones---clones which are definitely positive based upon the pool assays---as a criterion for the efficiency of a pooling design. We determine the value of kk which is optimal, with respect to this criterion, as a function of vv, nn and cc. We also describe superior kk-sets designs called kk-sets packing designs. As an illustration, we discuss a robotically implemented design for a 2.5-fold-coverage, human chromosome 16 YAC library of n=1,298n=1,298 clones. We also estimate the probability each clone is positive, given the pool-assay data and a model for experimental errors.

Cite

@article{arxiv.math/9412222,
  title  = {Efficient pooling designs for library screening},
  author = {William J. Bruno and Emanuel Knill and David J. Balding and D. C. Bruce and N. A. Doggett and W. W. Sawhill and R. L. Stallings and Craig C. Whittaker and David C. Torney},
  journal= {arXiv preprint arXiv:math/9412222},
  year   = {2016}
}

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39 pages