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Volume 16, Number 14, Issue of July 15, 1996 pp. 4370-4375
Copyright ©1996 Society for NeuroscienceExpression of a Kinesin-Related Motor Protein Induces Sf9 Cells to Form Dendrite-Like Processes with Nonuniform Microtubule Polarity Orientation
David J. Sharp1, Ryoko Kuriyama2, and Peter W. Baas1 1 Department of Anatomy and Program in Neuroscience, The University of Wisconsin Medical School, Madison, Wisconsin 53706, and 2 Department of Cell Biology and Neuroanatomy, The University of Minnesota Medical School, Minneapolis, Minnesota 55455
ABSTRACT
The microtubules (MTs) within neuronal processes are highly organized with regard to their polarity and yet are not attached to any detectable nucleating structure. Axonal MTs are uniformly oriented with their plus ends distal to the cell body, whereas dendritic MTs are of both orientations. Here, we sought to test the capacity of motor-driven MT transport to organize distinct MT patterns during process outgrowth. We focused on CHO1/MKLP1, a kinesin-related protein present in the midzonal region of the mitotic spindle where MTs of opposite orientation overlap. Insect ovarian Sf9 cells induced to express the N-terminal portion of the molecule form MT-rich processes with a morphology similar to that of neuronal dendrites (Kuriyama et al., 1994
Key words: microtubule; kinesin; dendrite; neuron; mitosis; spindle). Nascent processes contain uniformly plus-end-distal MTs, but these are joined by minus-end-distal MTs as the processes continue to develop. Thus, this CHO1/MKLP1 fragment establishes a nonuniform MT polarity pattern and does so by a similar sequence of events as occurs with the dendrite, the antecedent of which is a short process with a uniform MT polarity orientation. Two lines of evidence suggest that these results are elicited by motor-driven MT transport. First, there is a depletion of MTs from the cell body during process outgrowth. Second, the same polarity pattern is obtained when net MT assembly is suppressed pharmacologically during process formation. Collectively, these findings provide precedent for the idea that motor-driven transport can organize MTs into distinct patterns of polarity orientation during process outgrowth.
INTRODUCTION
The polarity orientation of microtubules (MTs) within a cell is fundamental to the organization of its cytoplasm and for regulating features of its architecture and motility. In most cell types, MTs are organized relative to their polarity by direct attachment of the minus ends of the MTs to their nucleation sites at the centrosome or basal body (Heidemann and McIntosh, 1980Precedent for motor proteins mediating interactions between MTs derives from the mitotic spindle (Hoyt, 1994
Recent studies of living cells provide support for the capacity of CHO1/MKLP1 to organize MTs. These studies demonstrate that ectopic expression of approximately half of the molecule at the N terminus can induce normally rounded insect ovarian Sf9 cells to form MT-rich processes (Kuriyama et al., 1994
MATERIALS AND METHODS
Cell culture and baculovirus infection. Sf9 cells were maintained in TNM-FH medium, which consists of Grace medium obtained from Gibco (Grand Island, NY), 0.33% yeastolate, 0.33% lactalbumin hydrolysate, and 10% fetal bovine serum, pH 6.2 (Kuriyama et al., 1994Immunofluorescence microscopy. Immunofluorescence staining of Sf9 cells was performed using one of two methods. The first method was as described previously (Kuriyama et al., 1994
20°C), transferred to cold absolute acetone (
-tubulin antibody (Amersham, Arlington Heights, IL) or to a rabbit polyclonal antiserum that recognizes sites within the N-terminal half of CHO1/MKLP1 (Kuriyama et al., 1994
MT polarity studies. MT polarity analyses were performed by a modification of methods described previously (Heidemann and McIntosh, 1981; Euteneuer and McIntosh, 1982; Baas et al., 1987
Pharmacological studies. In one set of experiments, MT assembly was suppressed by the addition of vinblastine sulfate (Sigma) to cultures at a final concentration of 10 nM. Vinblastine was added at the time of baculovirus infection.
RESULTS
Insect ovarian Sf9 cells normally are spherical in shape, do not extend cytoplasmic processes, and stain diffusely for tubulin in immunofluorescence analyses (Knops et al., 1991
Fig. 1. a, Phase-contrast micrograph of a moth ovarian Sf9 cell 3 d after infection with a baculovirus construct encoding the N-terminal half (containing the motor domain) of CHO1/MKLP1. b, Same cell immunostained for tubulin. Within 3 d of infection, up to 40% of infected cells had extended at least one process, and a portion had extended several. In the process-bearing cells, tubulin staining was concentrated within the processes. Scale bar, 8 µm.
[View Larger Version of this Image (89K GIF file)]
MT polarity analyses
Our principal goal was to determine the pattern of MT polarity orientation established within the motor-induced processes. To determine the orientation of the MTs within the processes, we used the standard hooking assay for MT polarity determination (see Materials and Methods). In this method, cells are extracted in the presence of exogenous brain tubulin in a buffer that promotes the formation of hooked appendages on the MTs. All hooks were viewed from the vantage point of the distal tip of the process such that clockwise hooks indicate MTs with their plus ends distal to the cell body and counterclockwise hooks indicate MTs with their minus ends distal to the cell body. Ten processes, 35-50 µm in length, were analyzed at their midpoints, and six of these were analyzed at additional points along their lengths. Figure 2 shows three points from one of these processes. The midregion contained approximately equal numbers of MTs of each orientation (Fig. 2c), distal regions contained predominantly plus-end-distal MTs (Fig. 2d), whereas regions near the cell body contained predominantly minus-end-distal MTs (Fig. 2b). All processes analyzed showed this same nonuniform pattern, with the proportion of plus-end-distal MTs increasing progressively with distance from the cell body (see Fig. 2e for data).
Fig. 2. a, Tracing of a cell that extended a thick tapering process after being induced to express the N-terminal half of CHO1/MKLP1. Arrows indicate points along the length of the process at which MT polarity orientation was determined. b-d, Electron micrographs of process cross-sections at points indicated in a. Clockwise hooks indicate MTs oriented with their plus ends distal to the cell body, whereas counterclockwise hooks indicated MTs with their minus ends distal to the cell body. e, Schematic showing the MT polarity data obtained from six processes analyzed at multiple points along their lengths. All cells chosen for analysis had extended a single process 35-50 µm in length. Four additional processes were analyzed at their midpoints only and produced results consistent with those shown here. Numerals above arrows indicate the fraction of counterclockwise to clockwise hooks counted per region and the percentage of counterclockwise hooks. The proportion of hooked MTs was high, nearly 90%, and of these, only ~15% were ambiguous. Scale bars: a, 10 µm; b-d, 0.15 µm; e, 10 µm.
[View Larger Version of this Image (71K GIF file)]
Because plus- and minus-end-distal MTs were distributed differentially, we hypothesized that MTs of different orientations may arise in the processes at different stages of their development, similar to dendrites. To investigate this possibility, we analyzed the MT arrays of five nascent processes, all of which were shorter than 10 µm. In all of these processes, the MTs were predominantly plus end distal (Fig. 3a,b; see legend for data), indicating that the nonuniform MT array of the mature process arises from an antecedent containing predominantly plus-end-distal MTs. As mentioned earlier, MT bundles are present within the cell bodies of many infected cells. They are particularly abundant in cells that had not yet extended processes and those with short nascent processes. Analyses of five of these were performed as well. Although there was no vantage point from which to judge the MTs of the bundles as plus or minus end distal, in all five cases, the MTs within the bundles were predominantly of the same orientation (Fig. 3a,c; see legend for data). This suggests that bundling of uniformly oriented MTs occurs independently of process formation.
Fig. 3. a, Tracing of a cell that extended a short nascent process after being induced to express the N-terminal half of CHO1/MKLP1. Arrows indicate points at which MT polarity was assessed. b, Electron micrograph of the MT array at the point indicated in a. c, Electron micrograph of an MT bundle observed just under the plasma membrane in the cell body. As noted in the legend to Figure 2, clockwise hooks indicate the plus ends of MTs, whereas counterclockwise hooks indicate the minus ends of MTs. In b, observations were made from the vantage point of the distal end of the process, therefore clockwise hooks indicate MTs with their plus ends distal to the cell body, whereas counterclockwise indicate MTs with their minus ends distal to the cell body. In c, MT bundles were clustered just beneath the plasma membrane and, hence, there was no point of reference from which to judge MT polarity orientation. Therefore, hooks indicate the degree of uniformity of the polarity of bundled MTs. In total, five nascent processes between 3 and 10 µm in length were analyzed at one point near the cell body, and the results were as follows: (1) 68 clockwise/12 counterclockwise, 85% plus end distal; (2) 61 clockwise/14 counterclockwise, 81% plus end distal; (3) 37 clockwise/6 counterclockwise, 86% plus end distal; (4) 42 clockwise/10 counterclockwise, 81% plus end distal; (5) 106 clockwise/8 counterclockwise, 93% plus end distal. Five MT bundles were analyzed from three different cell bodies: (1) 11 clockwise/0 counterclockwise, 100% uniformity; (2) 0 clockwise/14 counterclockwise, 100% uniformity; (3) 2 clockwise/17 counterclockwise, 89% uniformity; (4) 11 clockwise/1 counterclockwise, 92% uniformity; (5) 6 clockwise/1 counterclockwise, 86% uniformity. Scale bars: a, 4 µm; b, c, 0.125 µm.
[View Larger Version of this Image (43K GIF file)]
Process formation in the absence of net MT assembly
The simplest interpretation of these data are that process formation involves the transport of MTs with specific orientations from the cell body into the developing processes. An alternate possibility, however, is that ectopic expression of the N-terminal CHO1/MKLP1 fragment induces process formation by way of large-scale MT assembly and that this results in the nonuniform MT pattern within the processes. To investigate this possibility, we infected cells in the presence of 10 nM vinblastine to prohibit any significant MT assembly from occurring during process formation. Cells grown under these conditions elaborated thick tapering processes in a manner similar to that of undrugged cells. Figure 4a-c shows immunofluorescence images of the MT polymer within an uninfected cell, an infected cell with no drug, and a cell infected in the presence of vinblastine. Quantitative fluorescence analyses were performed on 10 representative cells from of each of these culture conditions. The results of these analyses, group mean ± SD in AFUs, were as follows: control cells, 1400 ± 500 AFUs; infected cells without vinblastine, 4100 ± 1000 AFUs; infected cells with vinblastine, 1100 ± 350 AFUs. There was a threefold increase in polymer levels within the undrugged infected cells relative to the control cells, but no increase in the infected drug-treated cells. Nevertheless, similar to the undrugged infected cells, there was a diminution of polymer from the cell body and a concomitant accumulation of polymer in the developing processes. In MT polarity analyses on the midregions of five such processes, 54%, 45%, 47%, 44%, and 37% of the hooks were counterclockwise (see Fig. 4, inset). Thus, MTs of both orientations arose within the processes in the absence of new MT assembly. These results demonstrate that the transport of preassembled MTs is sufficient for the establishment of the nonuniform MT pattern within the developing processes.
Fig. 4. a, Uninfected Sf9 cells immunostained for MTs. b, Immunostain for MTs in Sf9 cells 3 d after infection with baculovirus construct encoding N-terminal half of CHO1/MKLP1. c, Immunostain for MTs in an infected Sf9 cell that developed in the presence of 10 nM vinblastine. Arrow shows the cell body, which is nearly devoid of MTs. Inset, The MT array at the midpoint of a process that developed in the presence of vinblastine. Clockwise hooks indicate MTs with their plus ends distal to the cell body, whereas counterclockwise hooks indicate MTs of the opposite orientation. Approximately half of the MTs are of each orientation. Scale bar: a-c, 9 µm; inset, 0.3 µm.
[View Larger Version of this Image (42K GIF file)]
DISCUSSION
Several different cell types including neurons, glia, and Sertoli cells extend elongate cellular processes containing arrays of MTs that are highly organized but not attached to a discrete nucleating structure. Most efforts at identifying the molecules that organize these MTs have focused on fibrous MAPs that principally function to stimulate MT bundling and assembly. When expressed ectopically in Sf9 cells, these MAPs increase MT levels and induce the formation of processes, but the MTs within the processes have the same uniformly plus-end-distal polarity pattern regardless of whether tau, an axon-enriched MAP, or MAP2, a dendrite-enriched MAP, is expressed (Baas et al., 1991Mechanisms of motor-induced MT organization
It may at first appear puzzling that a kinesin-related protein has the capacity to organize MTs, given that kinesins generally are thought to regulate organelle transport. Indeed, expression in Sf9 cells of a variety of other kinesin-related proteins has not resulted in the formation of processes or in any detectable change in MT organization (see Noda et al., 1995Based on the properties of CHO1/MKLP1 to translocate MTs of opposite orientation relative to one another, it seems reasonable that the transport properties of the motor establish the nonuniform MT pattern within the processes. However, the finding that the MT polymer mass of infected cells is three times greater than that in controls indicates that infection and, possibly, high concentrations of the expressed CHO1/MKLP1 fragment somehow result in net MT assembly during process outgrowth. This finding led to some uncertainty as to whether MT transport in fact had generated nonuniform MT polarity orientation or whether the increase in MT assembly was the critical factor. To address this issue, we infected Sf9 cells in the presence of the anti-MT drug vinblastine at a concentration that suppresses net MT assembly. As expected, the processes formed under these conditions contained fewer MTs than those formed without vinblastine. Nevertheless, the processes contained essentially the same proportions of MTs of each orientation, indicating that net MT assembly is not required for the generation of nonuniform MT polarity orientation in these processes. Furthermore, process formation always was accompanied by a decrease of MT polymer in the cell body and a concomitant increase in the developing process, whether or not the infection was carried out in the presence of the drug. These findings suggest strongly that the generation of the nonuniform MT polarity pattern within the processes is established via the transport of specifically oriented MTs from the cell body.
We propose that the MT array of the motor-induced processes is established as follows. First, the CHO1/MKLP1 fragment bundles MTs of the same orientation within the cell body. In those cases in which the plus ends of the MTs are oriented toward the periphery, the MT bundles may participate in the formation of nascent processes. Second, the CHO1/MKLP1 fragment transports MTs with their minus ends leading from the cell body into these nascent processes. During this phase of process development, the motor uses the plus-end-distal MTs within the nascent processes as a substrate along which to transport the minus-end-distal MTs (see Fig. 5). The idea that both MT bundling and MT transport are served by the N-terminal half of the molecule is consistent with the fact that this portion of the molecule contains both classes of MT binding sites present on the full-length molecule.
Fig. 5. Schematic showing our model for the effects of CHO1/MKLP1 on MT bundling and transport in the mitotic spindle and of the N-terminal fragment during Sf9 process formation. Line segments with arrowheads depict MTs. Arrowheads indicate plus ends of MTs. Thinner lines connecting MTs represent CHO1/MKLP1 in the mitotic spindle and its N-teminal fragment in Sf9 cells. Three thin lines perpendicular to the MTs represent the proposed property of the motor to bundle parallel MTs. Three thin lines diagonal to the MTs represent the documented property of CHO1/MKLP1 to transport antiparallel MTs against one another. CHO1/MKLP1 localizes early during mitosis to the regions of each half-spindle where it bundles parallel MTs and then, subsequently, to the midregion where it transports antiparallel MTs against one another. During Sf9 process formation, the N-terminal fragment induces the formation of short bundles of uniformly oriented MTs. Initially, these bundles form throughout the cell body but with time cluster near the cell periphery. Then the MTs, if oriented with their plus ends facing the periphery, are able to participate in process initiation. These plus-end-distal MTs act as a substrate for the CHO1/MKLP1 fragment to transport MTs into elongating processes with their minus ends leading.
[View Larger Version of this Image (20K GIF file)]
As the process continues to develop, it is necessary for the plus-end-distal MTs to translocate down the processes to provide a ``moving substrate'' along which the motor can continue to transport the minus-end-distal MTs. This is apparent from our finding that plus-end-distal MTs are enriched distally in the process, whereas minus-end-distal MTs are enriched proximally. The latter probably become stranded once their substrate, the plus-end-distal MTs, have cleared the proximal region. Interestingly, a similar enrichment of minus-end-distal MTs has been observed in the proximal regions of dendrites grown under conditions that inhibit the replenishment of plus-end-distal MTs (Sharp et al., 1995
CONCLUSION
The present study documents that a portion of the CHO1/MKLP1 molecule is able to organize MTs into arrays with a distinctly dendritic pattern of organization. These findings are consistent with previous data suggesting that MT transport establishes the nonuniform polarity pattern of dendritic MTs (Sharp et al., 1995A broader point to be made is that motor-driven MT transport may be an important means by which many cell types organize MTs into sophisticated patterns of polarity orientation. If this is correct, then the expression of specific molecular motors may be critical for the establishment of such arrays and, in turn, for initiating developmental milestones such as the differentiation of axons and dendrites. Our studies suggest that some of these motors may be similar to those that regulate MT interactions during mitosis. We find provocative the idea that MT behaviors during mitosis and process formation may be variations on the same theme.
FOOTNOTES
Received March 1, 1996; revised April 23, 1996; accepted April 29, 1996.
This work was supported by grants from National Institutes of Health (NIH) and the National Science Foundation to P.W.B., and from NIH and the Council for Tobacco Research to R.K. P.W.B. is the recipient of a Research Career Development Award from NIH. D.J.S. is supported in part by a grant from NIH to the Neuroscience Program at The University of Wisconsin. We thank Wenqian Yu, Matthew Schwei, and Kathryn Bollinger for assistance. We especially thank Dr. Scott Brady for helpful discussions about motor proteins.
Correspondence should be addressed to Dr. Peter W. Baas, Department of Anatomy and Program in Neuroscience, The University of Wisconsin Medical School, 1300 University Avenue, Madison, WI 53706.
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Copyright ©1996 Society for Neuroscience 0270-6474/1996/164370-6$05.00/0
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