Thomas S. Reese

Identification of a Novel Force-Generating Protein, Kinesin, Involved in Microtubule-Based Motility

Axoplasm from the squid giant axon contains a soluble protein translocator that induces movement of microtubules on glass, latex beads on microtubules, and axoplasmic organelles on microtubules. We now report the partial purification of a protein from squid giant axons and optic lobes that induces these microtubule-based movements and show that there is a homologous protein in bovine brain. The purification of the translocator protein depended primarily on its unusual property of forming a high affinity complex with microtubules in the presence of a nonhydrolyzable ATP analog, adenylyl imidodiphosphate. The protein, once released from microtubules with ATP, migrates on gel filtration columns with an apparent molecular weight of 600 kilodaltons and contains 110-120 and 60-70 kilodalton polypeptides. This protein is distinct in molecular weight and enzymatic behavior from myosin or dynein, which suggests that it belongs to a novel class of force-generating molecules, for which we propose the name kinesin.

Dendrodendritic synaptic pathway for inhibition in the olfactory bulb

Abstract Anatomical and physiological evidence based on independent studies of the mammalian olfactory bulb points to synaptic interactions between dendrites. A theoretical analysis of electric potentials in the rabbit olfactory bulb led originally to the conclusion that mitral dendrites synaptically excite granule dendrites and granule dendrites then synaptically inhibit mitral dendrites. In an independent electron micrographic study of the rat olfactory bulb, synaptic contacts were found between granule and mitral dendrites. An unusual feature was the occurrence of more than one synaptic contact per single granule ending on a mitral dendrite; as inferred from the morphology of these synaptic contacts, a single granule ending was often presynaptic at one point and postsynaptic at an adjacent point with respect to the contiguous mitral dendrite. We postulate that these synaptic contacts mediate mitral-to-granule excitation and granule-to-mitral inhibition. These dendrodendritic synapses could provide a pathway for both lateral and self inhibition.

Functional changes in frog neuromuscular junctions studied with freeze-fracture.

SummaryIn freeze-fractured frog sartorius muscles, the long terminal branches of motor axons possess a series of narrow transverse ridges on their surface, bordered by rows of relatively large particles within the presynaptic membrane. By their exclusive location opposite muscle folds, it is apparent that these ridges represent anen face view of the electron-dense cytoplasmic bands around which synaptic vesicles cluster. In resting terminals there is no sign that vesicles underlie these ridges, except for an occasional bulge where a vesicle presses against the plasmalemma; but in terminals stimulated briefly in fixative, the ridges are surrounded by a number of small dimples where synaptic vesicles attach to the plasmalemma. Such ‘vesicle sites’ do not appear when Mg++ is used to prevent the transmitter release that results from stimulation, so they presumably represent sites of transmitter discharge. However, more vesicle sites appear in terminals stimulated in more slowly acting fixatives, so they appear to accumulate for some time during fixation and do not indicate the instantaneous level of transmitter release. Vesicle sites occur in a variety of sizes and shapes that may represent different stages of vesicle discharge. Dimples which appear during stimulation under Schwann processes, where endocytosis of coated vesicles has been found to occur, are sometimes larger than vesicle sites but otherwise look much the same; so it is not possible to readily distinguish between the freeze fracture images of synaptic vesicle discharge and coated vesicle formation at this synapse. The muscle membrane beneath nerve terminals is paved with clusters of relatively large particles which mostly appear on the cytoplasmic half of the membrane after fracture. These clusters of particles occur in regions of the postsynaptic membrane that are coated by plaques of electron-dense cytoplasmic fuzz. Immediately around the clusters are a number of tightly-packed, orthogonal aggregates of slightly smaller particles.

Different axoplasmic proteins generate movement in opposite directions along microtubules in vitro.

Single microtubules from squid axoplasm support bidirectional movement of organelles. We previously purified a microtubule translocator (kinesin) that moves latex beads in only one direction along microtubules. In this study, a polar array of microtubules assembled off of centrosomes in vitro was used to demonstrate that kinesin moves latex beads from the minus to the plus ends of microtubules, a direction that corresponds to anterograde transport in the axon. A crude solubilized fraction from squid axoplasm (S1a), however, generates bidirectional movement of beads along microtubules. Retrograde bead movement (1.4 micron/sec) is inhibited by N-ethylmaleimide and 20 microM vanadate while anterograde movement (0.6 micron/sec) is unaffected by these agents. Furthermore, a monoclonal antibody against kinesin, when coupled to Sepharose, removes the anterograde, but not the retrograde, bead translocator from S1a. These results indicate that there is a retrograde bead translocator which is pharmacologically and immunologically distinct from kinesin.

Single microtubules from squid axoplasm support bidirectional movement of organelles

Single filaments, dissociated from the extruded axoplasm of the squid giant axon and visualized by video-enhanced differential interference contrast microscopy, transport organelles bidirectionally. Organelles moving in the same or opposite directions along the same filament can pass each other without colliding, indicating that each transport filament has several tracks for organelle movement. In order to characterize transport filaments, organelle movements were first examined by video microscopy, and then the same filaments were examined by electron microscopy after rapid-freezing, freeze-drying, and rotary-shadowing. Transport filaments that supported bidirectional movement of organelles are 22 nm to 27 nm in diameter and have a substructure indicative of a single microtubule. Immunofluorescence showed that virtually all transport filaments contain tubulin. These results show that single microtubules can serve as a substratum for organelle movement, and suggest that an interaction between organelles and microtubules is the basis of fast axonal transport.

The organization of cytoplasm at the presynaptic active zone of a central nervous system synapse

The axoplasm at the presynaptic active zone of excitatory synapses between parallel fibers and Purkinje cell spines contains a meshwork of distinct filaments intermingled with synaptic vesicles, seen most clearly after the rapid freezing, freeze-etch technique of tissue preparation. One set of filaments extends radially from synaptic vesicles and intersects similar filaments associated with vesicles as well as larger filaments arising from the presynaptic membrane. The small, vesicle-associated filaments appear to link synaptic vesicles to one another and to enmesh them in the vicinity of the synaptic junction. The vesicle-associated filaments could be synapsin I because they have the same molecular dimensions and are distributed in the same pattern as synapsin I immunoreactivity.

Organelle, bead, and microtubule translocations promoted by soluble factors from the squid giant axon

A reconstituted system for examining directed organelle movements along purified microtubules has been developed. Axoplasm from the squid giant axon was separated into soluble supernatant and organelle-enriched fractions. Movement of axoplasmic organelles along MAP-free microtubules occurred consistently only after addition of axoplasmic supernatant and ATP. The velocity of such organelle movement (1.6 micron/sec) was the same as in dissociated axoplasm. The axoplasmic supernatant also supported movement of microtubules along a glass surface and movement of carboxylated latex beads along microtubules at 0.5 micron/sec. The direction of microtubule movement on glass was opposite to that of organelle and bead movement on microtubules. The factors supporting movements of microtubules, beads, and organelles were sensitive to heat, trypsin, AMP-PNP and 100 microM vanadate. All of these movements may be driven by a single, soluble ATPase that binds reversibly to organelles, beads, or glass and generates a translocating force on a microtubule.

Movement of organelles along filaments dissociated from the axoplasm of the squid giant axon

Cytoplasmic filaments, separated from the axoplasm of the squid giant axon and visualized by video-enhanced differential interference contrast microscopy, support the directed movement of organelles in the presence of ATP. All organelles, regardless of size, move continuously along isolated transport filaments at 2.2 +/- 0.2 micron/sec. In the intact axoplasm, however, movements of the larger organelles are slow and saltatory. These movements may reflect a resistance to movement imposed by the intact axoplasm. The uniform rate of all organelles along isolated transport filaments suggests that a single type of molecular motor powers fast axonal transport. Organelles can attach to and move along more than one filament at a time, suggesting that organelles have multiple binding sites for this motor.

Persistent Accumulation of Calcium/Calmodulin-Dependent Protein Kinase II in Dendritic Spines after Induction of NMDA Receptor-Dependent Chemical Long-Term Potentiation

Calcium/calmodulin-dependent protein kinase II (CaMKII) is a leading candidate for a synaptic memory molecule because it is persistently activated after long-term potentiation (LTP) induction and because mutations that block this persistent activity prevent LTP and learning. Previous work showed that synaptic stimulation causes a rapidly reversible translocation of CaMKII to the synaptic region. We have now measured green fluorescent protein (GFP)-CaMKIIα translocation into synaptic spines during NMDA receptor-dependent chemical LTP (cLTP) and find that under these conditions, translocation is persistent. Using red fluorescent protein as a cell morphology marker, we found that there are two components of the persistent accumulation. cLTP produces a persistent increase in spine volume, and some of the increase in GFP-CaMKIIα is secondary to this volume change. In addition, cLTP results in a dramatic increase in the bound fraction of GFP-CaMKIIα in spines. To further study the bound pool, immunogold electron microscopy was used to measure CaMKIIα in the postsynaptic density (PSD), an important regulator of synaptic function. cLTP produced a persistent increase in the PSD-associated pool of CaMKIIα. These results are consistent with the hypothesis that CaMKIIα accumulation at synapses is a memory trace of past synaptic activity.

Organization of the core structure of the postsynaptic density

Much is known about the composition and function of the postsynaptic density (PSD), but less is known about its molecular organization. We use EM tomography to delineate the organization of PSDs at glutamatergic synapses in rat hippocampal cultures. The core of the PSD is dominated by vertically oriented filaments, and ImmunoGold labeling shows that PSD-95 is a component of these filaments. Vertical filaments contact two types of transmembrane structures whose sizes and positions match those of glutamate receptors and intermesh with two types of horizontally oriented filaments lying 10–20 nm from the postsynaptic membrane. The longer horizontal filaments link adjacent NMDAR-type structures, whereas the smaller filaments link both NMDA- and AMPAR-type structures. The orthogonal, interlinked scaffold of filaments at the core of the PSD provides a structural basis for understanding dynamic aspects of postsynaptic function.