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Bio

Professional Education


  • Doctor of Philosophy, Weizmann Institute Of Science (2018)
  • Bachelor of Agriculture, Hebrew University Of Jerusalem (2009)
  • Master of Science, Weizmann Institute Of Science (2012)

Stanford Advisors


Publications

All Publications


  • The switching mechanism of the bacterial rotary motor combines tight regulation with inherent flexibility EMBO JOURNAL Afanzar, O., Di Paolo, D., Eisenstein, M., Levi, K., Plochowietz, A., Kapanidis, A. N., Berry, R., Eisenbach, M. 2021: e104683

    Abstract

    Regulatory switches are wide spread in many biological systems. Uniquely among them, the switch of the bacterial flagellar motor is not an on/off switch but rather controls the motor's direction of rotation in response to binding of the signaling protein CheY. Despite its extensive study, the molecular mechanism underlying this switch has remained largely unclear. Here, we resolved the functions of each of the three CheY-binding sites at the switch in E. coli, as well as their different dependencies on phosphorylation and acetylation of CheY. Based on this, we propose that CheY motor switching activity is potentiated upon binding to the first site. Binding of potentiated CheY to the second site produces unstable switching and at the same time enables CheY binding to the third site, an event that stabilizes the switched state. Thereby, this mechanism exemplifies a unique combination of tight motor regulation with inherent switching flexibility.

    View details for DOI 10.15252/embj.2020104683

    View details for Web of Science ID 000620692300001

    View details for PubMedID 33620739

  • The nucleus serves as the pacemaker for the cell cycle. eLife Afanzar, O., Buss, G. K., Stearns, T., Ferrell, J. E. 2020; 9

    Abstract

    Mitosis is a dramatic process that affects all parts of the cell. It is driven by an oscillator whose various components are localized in the nucleus, centrosome, and cytoplasm. In principle, the cellular location with the fastest intrinsic rhythm should act as a pacemaker for the process. Here we traced the waves of tubulin polymerization and depolymerization that occur at mitotic entry and exit in Xenopus egg extracts back to their origins. We found that mitosis was commonly initiated at sperm-derived nuclei and their accompanying centrosomes. The cell cycle was ~20% faster at these initiation points than in the slowest regions of the extract. Nuclei produced from phage DNA, which did not possess centrosomes, also acted as trigger wave sources, but purified centrosomes in the absence of nuclei did not. We conclude that the nucleus accelerates mitotic entry and propose that it acts as a pacemaker for cell cycle.

    View details for DOI 10.7554/eLife.59989

    View details for PubMedID 33284106

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