TRANSWESD: inferring cellular networks with transitive reduction

Abstract: Motivation: Distinguishing direct from indirect influences is a central issue in reverse engineering of biological networks because it facilitates detection and removal of false positive edges. Transitive reduction is one approach for eliminating edges reflecting indirect effects but its use in reconstructing cyclic interaction graphs with true redundant structures is problematic.Results: We present TRANSWESD, an elaborated variant of TRANSitive reduction for WEighted Signed Digraphs that overcomes conceptual … Show more

“…However, in the network inference algorithms interaction strengths between genes usually play an important role. Motivated by this fact, the concept of TR of weighted graphs was introduced [4,8], where the weights correspond to interaction strengths. Both these papers take interaction signs (promoting or inhibiting) into account.…”

“…Unlike the previous work in [4,8], we adopt an approach that disregards the interaction signs. A benefit of this decision is that the TR algorithms are of polynomial complexity and amenable to parallelisation.…”

“…A benefit of this decision is that the TR algorithms are of polynomial complexity and amenable to parallelisation. In contrast, the algorithm in [8] is in the worst case NP-complete, which means that its runtime grows exponentially with the size of the networks. Tests with the Dream challenges [10] show that the omission of signs does not incur any degradation in overall performance compared to the signed weighted TR of [8].…”

“…For a similar reason, our algorithm for cyclic weighted graphs cannot be adapted to cyclic signed weighted graphs. The problems with cycles in signed graphs are discussed in [8]. …”

Efficient reconstruction of biological networks via transitive reduction on general purpose graphics processors

“…However, in the network inference algorithms interaction strengths between genes usually play an important role. Motivated by this fact, the concept of TR of weighted graphs was introduced [4,8], where the weights correspond to interaction strengths. Both these papers take interaction signs (promoting or inhibiting) into account.…”

“…Unlike the previous work in [4,8], we adopt an approach that disregards the interaction signs. A benefit of this decision is that the TR algorithms are of polynomial complexity and amenable to parallelisation.…”

“…A benefit of this decision is that the TR algorithms are of polynomial complexity and amenable to parallelisation. In contrast, the algorithm in [8] is in the worst case NP-complete, which means that its runtime grows exponentially with the size of the networks. Tests with the Dream challenges [10] show that the omission of signs does not incur any degradation in overall performance compared to the signed weighted TR of [8].…”

“…For a similar reason, our algorithm for cyclic weighted graphs cannot be adapted to cyclic signed weighted graphs. The problems with cycles in signed graphs are discussed in [8]. …”

Efficient reconstruction of biological networks via transitive reduction on general purpose graphics processors

“…The idea of transitive reductions, in a more simplistic setting or in a different form, has also been used to identify structure of gene regulatory networks [48,49,50,51,52]. Of particular interest is a network “deconvolution” problem, considered by Feizi et al .…”

Algorithmic Perspectives of Network Transitive Reduction Problems and their Applications to Synthesis and Analysis of Biological Networks

Benchmarking a Simple Yet Effective Approach for Inferring Gene Regulatory Networks from Systems Genetics Data