Your search keyword '"Michelle Flanner"' showing total 2 results

1. A Symmetry Motivated Link Table

Author

Mariel Vazquez, Michelle Flanner, and Shawn Witte

Subjects

0301 basic medicine, link table, Physics and Astronomy (miscellaneous), Computer science, General Mathematics, chirality, knot table, Symmetry group, Type (model theory), Prime (order theory), 03 medical and health sciences, symbols.namesake, Knot (unit), writhe, Computer Science (miscellaneous), link symmetries, Link (knot theory), lattice polygons, Writhe, geometry_topology, Discrete mathematics, lcsh:Mathematics, Linking number, lcsh:QA1-939, DNA topology, 030104 developmental biology, Chemistry (miscellaneous), symbols, nomenclature, Symmetry (geometry)

Abstract

Proper identification of oriented knots and 2-component links requires a precise link nomenclature. Motivated by questions arising in DNA topology, this study aims to produce a nomenclature unambiguous with respect to link symmetries. For knots, this involves distinguishing a knot type from its mirror image. In the case of 2-component links, there are up to sixteen possible symmetry types for each link type. The study revisits the methods previously used to disambiguate chiral knots and extends them to oriented 2-component links with up to nine crossings. Monte Carlo simulations are used to report on writhe, a geometric indicator of chirality. There are ninety-two prime 2-component links with up to nine crossings. Guided by geometrical data, linking number, and the symmetry groups of 2-component links, canonical link diagrams for all but five link types (9 5 2, 9 34 2, 9 35 2, 9 39 2, and 9 41 2) are proposed. We include complete tables for prime knots with up to ten crossings and prime links with up to nine crossings. We also prove a result on the behavior of the writhe under local lattice moves.

Published

2018

2. Pathways of DNA unlinking: A story of stepwise simplification

Author

Mariel Vazquez, Reuben Brasher, Michelle Flanner, Koya Shimokawa, Kai Ishihara, Robert Stolz, David J. Sherratt, and Masaaki Yoshida

Subjects

0301 basic medicine, Models, Molecular, Computer science, lcsh:Medicine, 01 natural sciences, chemistry.chemical_compound, Models, lcsh:Science, Link (knot theory), Topology (chemistry), Recombination, Genetic, 0303 health sciences, Multidisciplinary, biology, Escherichia coli Proteins, Bacterial, Chromosomes, Bacterial, Monomer, DNA, Bacterial, DNA Replication, Computational biology, Network topology, Article, Chromosomes, 03 medical and health sciences, Genetic, Escherichia coli, 0101 mathematics, 030304 developmental biology, Topological complexity, Markov chain, Integrases, business.industry, Topoisomerase, lcsh:R, 010102 general mathematics, Escherichia coli DNA, Chromosome, Membrane Proteins, Molecular, DNA, Replication (computing), Recombination, 030104 developmental biology, chemistry, biology.protein, lcsh:Q, Artificial intelligence, business

Abstract

In Escherichia coli DNA replication yields interlinked chromosomes. Controlling topological changes associated with replication and returning the newly replicated chromosomes to an unlinked monomeric state is essential to cell survival. In the absence of the topoisomerase topoIV, the site-specific recombination complex XerCD- dif-FtsK can remove replication links by local reconnection. We previously showed mathematically that there is a unique minimal pathway of unlinking replication links by reconnection while stepwise reducing the topological complexity. However, the possibility that reconnection preserves or increases topological complexity is biologically plausible. In this case, are there other unlinking pathways? Which is the most probable? We consider these questions in an analytical and numerical study of minimal unlinking pathways. We use a Markov Chain Monte Carlo algorithm with Multiple Markov Chain sampling to model local reconnection on 491 different substrate topologies, 166 knots and 325 links, and distinguish between pathways connecting a total of 881 different topologies. We conclude that the minimal pathway of unlinking replication links that was found under more stringent assumptions is the most probable. We also present exact results on unlinking a 6-crossing replication link. These results point to a general process of topology simplification by local reconnection, with applications going beyond DNA.

Published

2017