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Cytoplasmic streaming with extremely high velocity (∼70 μm s−1) occurs in cells of the characean algae (Chara). Because cytoplasmic streaming is caused by myosin XI, it has been suggested that a myosin XI with a velocity of 70 μm s−1, the fastest myosin measured so far, exists in Chara cells. However, the velocity of the previously cloned Chara corallina myosin XI (CcXI) was about 20 μm s−1, one-third of the cytoplasmic streaming velocity in Chara. Recently, the genome sequence of Chara braunii has been published, revealing that this alga has four myosin XI genes. We cloned these four myosin XI (CbXI-1, 2, 3, and 4) and measured their velocities. While the velocities of CbXI-3 and CbXI-4 motor domains (MDs) were similar to that of CcXI MD, the velocities of CbXI-1 and CbXI-2 MDs were 3.2 times and 2.8 times faster than that of CcXI MD, respectively. The velocity of chimeric CbXI-1, a functional, full-length CbXI-1 construct, was 60 μm s−1. These results suggest that CbXI-1 and CbXI-2 would be the main contributors to cytoplasmic streaming in Chara cells and show that these myosins are ultrafast myosins with a velocity 10 times faster than fast skeletal muscle myosins in animals. We also report an atomic structure (2.8-Å resolution) of myosin XI using X-ray crystallography. Based on this crystal structure and the recently published cryo-electron microscopy structure of acto-myosin XI at low resolution (4.3-Å), it appears that the actin-binding region contributes to the fast movement of Chara myosin XI. Mutation experiments of actin-binding surface loops support this hypothesis.
It has been predicted that the fastest myosin in the biological world exists in alga Chara, but its identity has remained unknown. Recently, we succeeded in cloning the fastest myosin and characterized its amino acid sequence. We also we succeeded in solving the first atomic structure (2.8 Å resolution) of myosin 11, the fastest myosin class, using X-ray crystallography. Based on this crystal structure and mutation experiments, it appears that that the actin-binding region contributes to the fast movement of Chara myosin 11. myosin / motor protein / cytoplasmic streaming / actin / crystal structure analysis
Cytoplasmic streaming with extremely high velocity (~70 μm s−1) occurs in cells of the characean algae (Chara). Because cytoplasmic streaming is caused by organelle-associated myosin XI sliding along actin filaments, it has been suggested that a myosin XI, which has a velocity of 70 μm s−1, the fastest myosin measured so far, exists in Chara cells. However, the previously cloned Chara corallina myosin XI (CcXI) moved actin filaments at a velocity of around 20 μm s−1, suggesting that an unknown myosin XI with a velocity of 70 μm −1 may be present in Chara. Recently, the genome sequence of Chara braunii has been published, revealing that this alga has four myosin XI genes. In the work reported in this paper, we cloned these four myosin XIs (CbXI-1, 2, 3, and 4) and measured their velocities. While the velocities of CbXI-3 and CbXI-4 were similar to that of CcXI, the velocities of CbXI-1 and CbXI-2 were estimated to be 73 and 66 μm s−1, respectively, suggesting that CbXI-1 and CbXI-2 are the main contributors to cytoplasmic streaming in Chara cells and showing that CbXI-1 is the fastest myosin yet found. We also report the first atomic structure (2.8 Å resolution) of myosin XI using X-ray crystallography. Based on this crystal structure and the recently published cryo-EM structure of acto-myosin XI at low resolution (4.3 Å), it appears that the actin-binding region contributes to the fast movement of Chara myosin XI. Mutation experiments of actin-binding surface loop 2 support this hypothesis.
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