Joe Howard, PhD
Eugene Higgins Professor of Molecular Biophysics and Biochemistry and Professor of PhysicsCards
About
Titles
Eugene Higgins Professor of Molecular Biophysics and Biochemistry and Professor of Physics
Biography
Jonathon (Joe) Howard is the Eugene Higgins Professor of Molecular Biophysics & Biochemistry, a Professor of Physics, and a member of the Quantitative Biology Institute at Yale University. He is best known for his research on the mechanical properties of motor proteins and the cytoskeleton, and the development of techniques for observing, measuring and manipulating individual biological molecules. His group studies several cellular systems in which force and motion play key roles, including the motility of cilia, and the branching of developing neurons.
Brought up in Australia, where he studied mathematics and neurobiology at the Australian National University, Professor Howard was a professor at the University of Washington Medical School in Seattle, a founding Director of the Max Planck Institute for Molecular Cell Biology and Genetics in Dresden, Germany, before moving to Yale 2013 where he enjoys new research projects and teaching.
Appointments
Molecular Biophysics and Biochemistry
ProfessorPrimary
Other Departments & Organizations
- Biochemistry, Quantitative Biology, Biophysics and Structural Biology (BQBS)
- Interdepartmental Neuroscience Program
- Molecular Biophysics and Biochemistry
- Neuroscience Track
- Swartz Program in Theoretical Neurobiology
- Yale Combined Program in the Biological and Biomedical Sciences (BBS)
- Yale Ventures
Education & Training
- Postdoctoral Fellow
- University of California, San Francisco (1987)
- Postdoctoral Fellow
- University of Bristol (1985)
- PhD
- Australian National University, Neurobiology (1983)
- BSc (Hon)
- Australian National University, Mathematics (1979)
Research
Overview
Motor and Cytoskeletal Systems: From molecules to cells
Tubulin exchange in and out of the microtubule wall and its role in severing, rigidity & dynamics
Microtubules are tubular polymers whose protein subunits, tubulin, associate in a head-to-tail geometry to form protofilaments, thirteen of which form the microtubule’s cylindrical wall. The pipe-like geometry gives the microtubule high rigidity for its protein mass. High bending rigidity is essential for the structural roles that microtubules play in cellular architecture: as tracks for motor proteins such as kinesins and dyneins, and as scaffolds that support force-generating organelles such as the mitotic spindle and the cilium (Howard 2001).
Microtubules grow and shrink by addition and subtraction of tubulin dimers at their ends, processes that are regulated by a host a microtubule associated proteins (Howard and Hyman 2007, Bowne-Anderson et al. 2015). Recently, however, it has become clear that, in addition to removal and addition of tubulin at microtubule ends, significant tubulin exchange also occurs within the wall of the microtubule. Removal can be mediated by microtubule severing enzymes such as spastin and katanin (Kuo & Howard 2021, Kuo et al. 2022), by motor proteins such as kinesins and dyneins, and by mechanical forces applied to the microtubule. Removal of tubulin from the microtubule lattice leads to holes, whose enlargement leads to microtubule softening and eventual breakage, and whose repair by incorporation of new GTP-tubulin from solution can promote microtubule growth. Together, the growth and repair of these defects can profoundly rearrange the microtubule cytoskeleton in cells.
We are developing new techniques for visualizing microtubule defects and to study the kinetic and structural mechanisms of microtubule severing.
Branching morphogenesis of neurons
The architecture of the brain and its constituent neurons is staggeringly complex. This complexity is enabled by the highly branched morphologies of dendrites and axons, which allow each neuron to connect to thousands of other neurons. We recently showed, using Drosophila sensory neurons as a model system, that the branching, growth, and retraction of dendrite tips can generate many of the morphological features of dendrites including the rate of growth of their arbors during development, and the average length, density, and orientation of their branches (Shree et al. 2022, Ouyang et al. in preparation). Branch diameters, another important morphological feature of neurons, change systematically across branch points, which facilitates the distribution of materials and nutrients through the network (Liao et al. 2019). Furthermore, neuronal dendrites have a scale-invariant network architecture that optimizes their function and metabolism (Liao et al. 2023).
Currently, we are using genetic perturbations and high-resolution imaging to elucidate the role of the microtubule cytoskeleton in generating dendrite morphology.
The motility of cilia and flagella
A major open question in cell motility is how the dynein motors, which power the bending of cilia and flagella, are coordinated to give the periodic beating patterns that drive cell motion (Howard et al. 2022). We are using the single-celled alga Chlamydomonas reinhardtii as a model system to test different models of motor coupling (Geyer et al. 2016, Sartori et al. 2016, Geyer 2022).
Currently, we are analyzing waveforms of different mutants by high-speed light microscopy and high-resolution electron cryo-microscopy.
Medical Research Interests
Academic Achievements & Community Involvement
News & Links
Media
- These cells tile the surface of the larva and detect attacks by the ovipositor barbs of parasitic wasps
- Animal pole with mitochondria labeled in green. The embryos is 800 micrometers in diameter. Rodenfels et al. (2019).
- Read all about Motor Proteins and the Cytoskeleton! Howard (2001). Sinauer Associates, Sunderland MA
- Computer-assisted tracking of the flagellar beat of the single-celled alga, Chlamydomonas reinhardtii. Sartori et al. (2016)
- Hierarchy of scales from the single molecule (tubulin), the polymer (microtubule), organelles (centriole and centrosome) through to the cell and organism
- Left. Image of the dendritic arbor of 100-hour old Drosophila class IV mechanoreceptors (scale bar 100 microns). Right. Segmentation of one of the cells. The arrow points to the cell body.
- Differential-interference micrograph of a one-cell embryo from the nematode worm C. elegans overlaid with a fluorescence micrograph showing the mitotic spindle (beta-tubulin and histones labelled with GFP). The shadow is the tip of a magnetic probe used to apply forces to the spindle. Garzon-Coral et al. 2016.
- Microtubules (red) with the kinesin-related protein MCAK bound to their ends. Helenius et al. (2006).
- Coupling between ATP hydrolysis, the mechanochemical cycle of the motor protein dynein, the flagellar beat and the swimming of microorganisms.
- Superfamily of the kinesin superfamily of motor proteins.
News
- August 02, 2022
Researchers Visualize the Intricate Branching of the Nervous System
- November 07, 2017
Microscopy@Yale symposium Nov. 15
- February 21, 2017
Jonathon (Joe) Howard elected to Connecticut Academy of Science and Engineering
- November 01, 2015
Yale’s Howard receives NIH’s Pioneer Award