Dylan P. McCuskey, Raisa E. Achiriloaie, Claire Benjamin, Jemma Kushen, Isaac Blacklow, Omar Mnfy, Jennifer L. Ross, Rae M. Robertson-Anderson, Janet Y. Sheung
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Understanding the interplay between these seemingly\nantagonistic contributions to intracellular dynamics remains a grand challenge.\nHere, we use single-molecule tracking to show that the transport of large\nlinear and circular DNA through motor-driven microtubule networks can be\nnon-gaussian and multi-modal, with the degree and spatiotemporal scales over\nwhich these features manifest depending non-trivially on the state of activity\nand DNA topology. For example, active network restructuring increases caging\nand non-Gaussian transport modes of linear DNA, while dampening these\nmechanisms for rings. We further discover that circular DNA molecules exhibit\neither markedly enhanced subdiffusion or superdiffusion compared to their\nlinear counterparts, in the absence or presence of kinesin activity, indicative\nof microtubules threading circular DNA. This strong coupling leads to both\nstalling and directed transport, providing a direct route towards parsing\ndistinct contributions to transport and determining the impact of coupling on\nthe transport signatures. More generally, leveraging macromolecular topology as\na route to programming molecular interactions and transport dynamics is an\nelegant yet largely overlooked mechanism that cells may exploit for\nintracellular trafficking, streaming, and compartmentalization. This mechanism\ncould be harnessed for the design of self-regulating, sensing, and\nreconfigurable biomimetic matter.","PeriodicalId":501040,"journal":{"name":"arXiv - PHYS - Biological Physics","volume":"107 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-09-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"DNA transport is topologically sculpted by active microtubule dynamics\",\"authors\":\"Dylan P. 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引用次数: 0
摘要
大分子(如 DNA)通过细胞骨架的运输对于从细胞质流到转录等广泛的细胞过程至关重要。组成细胞骨架的丝网所具有的刚性和立体阻碍往往会导致反常的亚扩散,而马达驱动的重组等活跃过程则会诱发热超扩散。在这里,我们利用单分子追踪技术证明,大线性和环状 DNA 通过马达驱动的微管网络的传输可以是高斯和多模式的,这些特征的表现程度和时空尺度取决于活动状态和 DNA 拓扑结构。例如,活跃的网络重组会增加线性 DNA 的笼状和非高斯传输模式,而抑制环状 DNA 的这些机制。我们进一步发现,在没有或有驱动蛋白活动的情况下,与线性 DNA 分子相比,环状 DNA 分子表现出明显增强的亚扩散或超扩散,这表明微管在穿环状 DNA。这种强耦合导致了沉积和定向传输,为解析传输的不同贡献和确定耦合对传输特征的影响提供了直接途径。更广泛地说,利用大分子拓扑学作为分子相互作用和运输动力学的编程途径,是细胞可能利用来进行胞内运输、流式运输和区隔的一种古老但却被忽视的机制。这种机制可用于设计自我调节、传感和可重新配置的生物仿生物质。
DNA transport is topologically sculpted by active microtubule dynamics
The transport of macromolecules, such as DNA, through the cytoskeleton is
critical to wide-ranging cellular processes from cytoplasmic streaming to
transcription. The rigidity and steric hindrances imparted by the network of
filaments comprising the cytoskeleton often leads to anomalous subdiffusion,
while active processes such as motor-driven restructuring can induce athermal
superdiffusion. Understanding the interplay between these seemingly
antagonistic contributions to intracellular dynamics remains a grand challenge.
Here, we use single-molecule tracking to show that the transport of large
linear and circular DNA through motor-driven microtubule networks can be
non-gaussian and multi-modal, with the degree and spatiotemporal scales over
which these features manifest depending non-trivially on the state of activity
and DNA topology. For example, active network restructuring increases caging
and non-Gaussian transport modes of linear DNA, while dampening these
mechanisms for rings. We further discover that circular DNA molecules exhibit
either markedly enhanced subdiffusion or superdiffusion compared to their
linear counterparts, in the absence or presence of kinesin activity, indicative
of microtubules threading circular DNA. This strong coupling leads to both
stalling and directed transport, providing a direct route towards parsing
distinct contributions to transport and determining the impact of coupling on
the transport signatures. More generally, leveraging macromolecular topology as
a route to programming molecular interactions and transport dynamics is an
elegant yet largely overlooked mechanism that cells may exploit for
intracellular trafficking, streaming, and compartmentalization. This mechanism
could be harnessed for the design of self-regulating, sensing, and
reconfigurable biomimetic matter.