English

DNA toroids form via a flower intermediate

Biological Physics 2021-02-24 v1

Abstract

DNA in sperm cells must undergo an extreme compaction to almost crystalline packing levels. To produce this dense packing, DNA is condensed by protamine, a positively charged protein that loops the DNA into a toroid. Our goal is to determine the pathway and mechanism for toroid formation. We first imaged short-length (L=217-1023 nm) DNA molecules in 0-5.0 μ\muM protamine using an atomic force microscope (AFM). At low protamine concentrations (0.2-0.6 μ\muM), molecules dramatically condensed, folding into a flower structure. Dynamic folding measurements of the DNA using a tethered particle motion (TPM) assay revealed a corresponding, initial folding event, which was >3 loops at L=398 nm. The initial folding event was made up of smaller (<1 loop) events that had similar dynamics as protamine-induced bending. This suggests that flowers form in an initial step as protamine binds and bends the DNA. It was not until higher protamine concentrations (>2 μ\muM) that DNA in the AFM assay formed small (<10 loop), vertically packed toroids. Taken together, these results lead us to propose a nucleation-growth model of toroid formation that includes a flower intermediate. This pathway is important in both in vivo DNA condensation and in vitro engineering of DNA nanostructures.

Keywords

Cite

@article{arxiv.2101.05392,
  title  = {DNA toroids form via a flower intermediate},
  author = {Ryan B. McMillan and Hilary Bediako and Luka M. Devenica and Yuxing E. Ma and Donna M. Roscoe and Ashley R. Carter},
  journal= {arXiv preprint arXiv:2101.05392},
  year   = {2021}
}

Comments

24 pages and 7 figures in main article, 15 pages and 9 figures in supplemental

R2 v1 2026-06-23T22:08:50.873Z