Self-entanglement, or knotting, is entropically favored in long polymers. Relatively short polymers such as proteins can knot as well, but in this case the entanglement is mainly driven by fine-tuned, sequence-specific interactions. The relation between the sequence of a long polymer and its topological state is here investigated by means of a coarse-grained model of DNA. We demonstrate that the introduction of two adhesive regions along the sequence of a self-avoiding chain substantially increases the probability of forming a knot
We used optical tweezers to tie individual DNA molecules in knots. Although these knots become highl...
Knots appear frequently in semiflexible (bio)polymers, including double-stranded DNA, and their pres...
We use stochastic simulation techniques to sample the conformational space of linear semiflexible po...
<div><p>Self-entanglement, or knotting, is entropically favored in long polymers. Relatively short p...
Knots are ubiquitous objects and decorative elements that have been studied since antiquity. During ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Chemical Engineering, 2015.Cata...
Ropes or yarns, especially when disorderly packed, are prone to develop knots. Polymers are no excep...
Knots have a plethora of applications in our daily life from fishing to securing surgical sutures. E...
Two knots on a string can either be separated or intertwined, and may even pass through each other. ...
We develop a coarse-grained model of double-stranded DNA which is solely based on experimentally det...
The self-knotting dynamics of DNA strands confined in nanochannels is studied with Brownian simulati...
The self-knotting dynamics of DNA strands confined in nanochannels is studied with Brownian simulati...
When linear double-stranded DNA is packed inside bacteriophage capsids, it becomes highly compacted....
We perform single-molecule experiments and simulations to study the swelling of complex knots in lin...
Circular DNA in viruses and bacteria is often knotted. While mathematically problematic, the determi...
We used optical tweezers to tie individual DNA molecules in knots. Although these knots become highl...
Knots appear frequently in semiflexible (bio)polymers, including double-stranded DNA, and their pres...
We use stochastic simulation techniques to sample the conformational space of linear semiflexible po...
<div><p>Self-entanglement, or knotting, is entropically favored in long polymers. Relatively short p...
Knots are ubiquitous objects and decorative elements that have been studied since antiquity. During ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Chemical Engineering, 2015.Cata...
Ropes or yarns, especially when disorderly packed, are prone to develop knots. Polymers are no excep...
Knots have a plethora of applications in our daily life from fishing to securing surgical sutures. E...
Two knots on a string can either be separated or intertwined, and may even pass through each other. ...
We develop a coarse-grained model of double-stranded DNA which is solely based on experimentally det...
The self-knotting dynamics of DNA strands confined in nanochannels is studied with Brownian simulati...
The self-knotting dynamics of DNA strands confined in nanochannels is studied with Brownian simulati...
When linear double-stranded DNA is packed inside bacteriophage capsids, it becomes highly compacted....
We perform single-molecule experiments and simulations to study the swelling of complex knots in lin...
Circular DNA in viruses and bacteria is often knotted. While mathematically problematic, the determi...
We used optical tweezers to tie individual DNA molecules in knots. Although these knots become highl...
Knots appear frequently in semiflexible (bio)polymers, including double-stranded DNA, and their pres...
We use stochastic simulation techniques to sample the conformational space of linear semiflexible po...