Microtubule bundles in the mitotic spindle: probing how mechanical and functional robustness emerge from molecular architecture

Information

  • Research Project
  • 10226166
  • ApplicationId
    10226166
  • Core Project Number
    R35GM138083
  • Full Project Number
    5R35GM138083-02
  • Serial Number
    138083
  • FOA Number
    PAR-17-190
  • Sub Project Id
  • Project Start Date
    9/1/2020 - 4 years ago
  • Project End Date
    8/31/2025 - 8 months from now
  • Program Officer Name
    GINDHART, JOSEPH G
  • Budget Start Date
    9/1/2021 - 3 years ago
  • Budget End Date
    8/31/2022 - 2 years ago
  • Fiscal Year
    2021
  • Support Year
    02
  • Suffix
  • Award Notice Date
    8/27/2021 - 3 years ago

Microtubule bundles in the mitotic spindle: probing how mechanical and functional robustness emerge from molecular architecture

Project Summary/Abstract The mitotic spindle is a microtubule-based machine that segregates chromosomes into two new daughter cells when cells divide. Accurate spindle function is critical: mistakes lead to extra or missing chromosomes, which are associated with cancer, birth defects, and miscarriage. Spindle function requires robust coupling of biochemistry and mechanics. Yet, understanding how this self-organizing machine generates the required forces in the right place at the right time remains a challenge. Our long term goal is to determine how micron-scale mechanical properties of the spindle emerge from molecular-scale biochemistry. We focus on microtubule bundles, which provide organization and underpin rigidity in the spindle and in other microtubule-based structures. We do not understand what material properties bundling molecules impart to spindle bundles, how their molecular properties allow them to do so, or how these emergent mechanical properties are tuned for biological functions. To address these questions, we will measure quantitative readouts of how bundles respond to perturbations that alter mechanics. We take a multi-system approach to understanding bundle mechanics in mammalian kinetochore-fibers (k-fibers), which attach and segregate chromosomes; in fission yeast S. pombe spindles, whose stereotyped organization facilitates probing how specific crosslinker properties affect bundles overall; and in vitro, where we have more precise control. Our approach is organized into two programs: (1) probing the molecular and mechanical organization of spindle microtubule bundles, and (2) controlling spindle microtubule bundles to alter function through novel mechanics. In Program 1, we will determine how k-fiber organization balances competing mechanical constraints of robust force-transmission for chromosome segregation with flexibility to adapt to changing spindle morphology. We will also develop new tools to measure force between microtubules within spindle bundles, determining how these bundles effectively transmit force to achieve their mechanical functions. In Program 2, we will determine how the geometric and mechanical properties of microtubule crosslinkers impart bundle-scale properties that are adapted to particular functions. We will create engineered crosslinkers whose mechanical and geometric properties we will control, and use them to build reconstituted microtubule bundles in vitro, and to alter bundle properties in vivo. By measuring the response of these bundles to molecular-scale changes, we will determine how micron-scale properties emerge. In sum, the proposed work will map how molecular scale parts impart spindle bundles with properties that balance competing mechanical constraints. In the long term, this approach may lead to new insight into how altering the cell?s ?building code? can be harnessed to target microtubule architectures with key roles in disease, or to build novel architectures. This approach can extend to understand the emergent mechanics of microtubule bundle architectures beyond the spindle, such as in cilia and axons.

IC Name
NATIONAL INSTITUTE OF GENERAL MEDICAL SCIENCES
  • Activity
    R35
  • Administering IC
    GM
  • Application Type
    5
  • Direct Cost Amount
    250000
  • Indirect Cost Amount
    116035
  • Total Cost
    366035
  • Sub Project Total Cost
  • ARRA Funded
    False
  • CFDA Code
    859
  • Ed Inst. Type
    SCHOOLS OF ARTS AND SCIENCES
  • Funding ICs
    NIGMS:366035\
  • Funding Mechanism
    Non-SBIR/STTR RPGs
  • Study Section
    ZRG1
  • Study Section Name
    Special Emphasis Panel
  • Organization Name
    NORTH CAROLINA STATE UNIVERSITY RALEIGH
  • Organization Department
    PHYSICS
  • Organization DUNS
    042092122
  • Organization City
    RALEIGH
  • Organization State
    NC
  • Organization Country
    UNITED STATES
  • Organization Zip Code
    276957514
  • Organization District
    UNITED STATES