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Vol. 13, Issue 3, 1046-1057, March 2002
and
*Molecular & Cell Biology and Biochemistry Program, and
Association of motor proteins with organelles is required for the
motors to mediate transport. Because axoplasmic organelles move on
actin filaments, they must have associated actin-based motors, most
likely members of the myosin superfamily. To gain a better
understanding of the roles of myosins in the axon we used the giant
axon of the squid, a powerful model for studies of axonal physiology.
First, a ~220 kDa protein was purified from squid optic lobe, using a
biochemical protocol designed to isolate myosins. Peptide sequence
analysis, followed by cloning and sequencing of the full-length cDNA,
identified this ~220 kDa protein as a nonmuscle myosin II. This
myosin is also present in axoplasm, as determined by two independent
criteria. First, RT-PCR using sequence-specific primers detected the
transcript in the stellate ganglion, which contains the cell bodies
that give rise to the giant axon. Second, Western blot analysis using
nonmuscle myosin II isotype-specific antibodies detected a single
~220 kDa band in axoplasm. Axoplasm was fractionated through a
four-step sucrose gradient after 0.6 M KI treatment, which separates
organelles from cytoskeletal components. Of the total nonmuscle myosin
II in axoplasm, 43.2% copurified with organelles in the 15% sucrose fraction, while the remainder (56.8%) was soluble and found in the
supernatant. This myosin decorates the cytoplasmic surface of 21% of
the axoplasmic organelles, as demonstrated by immunogold electron-microscopy. Thus, nonmuscle myosin II is synthesized in the
cell bodies of the giant axon, is present in the axon, and is
associated with isolated axoplasmic organelles. Therefore, in addition
to myosin V, this myosin is likely to be an axoplasmic organelle motor.
Department of Pathology and Medicine, Brown University,
Providence, RI 02912; Marine Biological Laboratory,
Woods Hole, MA 02543; §Laboratory of Neurobiology,
National Institute of Neurological Disorders and Stroke, National
Institutes of Health, Bethesda, MD 20892
Corresponding author. E-mail address:
Elaine_Bearer{at}Brown.edu.
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