Abstract. The establishment of neural circuits requires both stable and plastic properties in the neuronal cytoskeleton. In this study we show that properties of stability and lability reside in microtubules and these are governed by cellular differentiation and intracellular location. After culture for 3, 7, and 14 d in nerve growth factor-containing medium, PC-12 cells were microinjected with X-rhodamine-labeled tubulin. 8-24 h later, cells were photobleached with a laser microbe.am at the cell body, neurite shaft, and growth cone. Replacement of fluorescence in bleached zones was monitored by digital video microscopy. In 3-d cultures, fluorescence recovery in all regions occurred by 26 + 17 min. Similarly, in older cultures, complete fluorescence recovery at the cell body and growth cone occurred by 10-30 min. However, in neurite shafts, fluorescence recovery was markedly slower (71 + 48 min for 7-d and 201 + 94 min for 14-d cultures). This progressive increase in the stability of microtubules in the neurite shafts correlated with an increase of acetylated microtubules. Acetylated microtubules were present specifically in the neurite shaft and not in the regions of fast microtubule turnover, the cell body and growth cone. During the recovery of fluorescence, bleached zones did not move with respect to the cell body. We conclude that the microtubule component of the neuronal cytoskeleton is differentially dynamic but stationary. DVELOPMENT of the nervous system requires that the neuronal cytoskeleton be endowed with the seemingly incompatible properties, morphological stability and plasticity. Morphological stability is critical for maintenance and proper function of neuronal circuits, while plasticity is required for cell growth and remodeling of cell processes during response to environmental inputs or to injury. How does the cytoskeleton adapt to these different requirements? Are there changes in the cytoskeleton that reflect the state of cellular differentiation?Microtubule formation is required for the growth and structural integrity of neuronal processes (17,18,62,63) and numerous studies have demonstrated that neuronal microtubules exhibit unusual stability properties. For example, a significant fraction of tubulin in brain is not solubilized by conventional methods of temperature-reversible, assembly-dissembly procedures (10,13,27,50,59). Further, the susceptibility of microtubules to depolymerization by colchicine diminishes with increased culture age (6, 17).Several factors have been postulated to enhance microtubule stability. By binding microtubule-associated proteins microtubule stability increases (4, 40), and neurons contain a variety of microtubule-associated proteins of which MAP-1, MAP-2, tau, and chartins are quite prominent (5,8,9,42,44,45). Neuronal tubulin also undergoes posttranslational modifications including detyrosination/tyrosination (2, 49), acetylation (7), and phosphorylation (21,22). Although the physiological relevance of the differential binding reactions with microtubule-asso...
Abstract. In a previous study using PC-12 cells (Lim, S. S., P. J. Sammak, and G. G. Borisy. 1989. J. Cell Biol. 109:253-263), we presented evidence that the microtubule component of the neuronal cytoskeleton is differentially dynamic but stationary. However, neurites of PC-12 cells grow slowly, hindering a stringent test of slow axonal transport mechanisms under conditions where growth was substantial. We therefore extended our studies to primary cultures of dorsal root ganglion cells where the rate of neurite outgrowth is rapid. Ceils were microinjected with X-rhodaminelabeled tubulin 7-16 h after plating. After a further incubation for 6-18 h, the cells were photobleached with an argon ion laser. Using a cooled charged couple device and video microscopy, the cells were monitored for growth of the neurite and movement and recovery of fluorescence in the bleached zone. As for PC-12 cells, all bleached zones in the neurite recovered their fluorescence, indicating that incorporation of tubulin occurred along the neurite. Despite increases in neurite length of up to 70 ttm, and periods of observation of up to 5 h, no movement of bleached zones was observed. We conclude that neurite elongation cannot be accounted for by the transport of a microtubule network assembled only at the cell body. Rather, microtubules turn over all along the length of the neurite and neurite elongation occurs by net assembly at the tip.
The expression and localization of tensin and cortactin were examined in osteoclast precursors in comparison with isolated osteoclasts on various substrates. Initially, the ability of hen monocytes to differentiate into osteoclasts was evaluated on plastic or glass, and compared to differentiation on bone. Specifically, monocytes were isolated from the medullary bones of egg-laying hens maintained on a Ca-deficient diet. Differentiation was monitored morphologically and by quantitation of the ability to form Howship's lacunae in bone slices or resorb radiolabeled bone particles of 20-53 microns diameter. These cells differentiated into tartrate resistant acid phosphatase (TRAP)-positive, bone resorbing, multinucleated syncytia in the presence of cytosine-1-beta-D-arabinofuranoside in a time dependent manner (day 1-6). Differentiation into osteoclast-like cells was similar whether cultured on plastic, on glass, or on bone. When compared to GAP-DH control levels, tensin and cortactin mRNA levels increased by 7- and 10-fold, respectively, by day 6. Tensin and cortactin protein levels also increased by 6- and 15-fold, respectively, by day 6. Immunofluorescence of differentiating precursors showed that tensin localized between regions of cell to cell contact and colocalized with vinculin in podosomes of osteoclast-like cells and of real osteoclasts. Cortactin immunofluorescence was not detectable in monocytes but localized inside tensin/vinculin podosome structures after fusion into osteoclast-like cells and in freshly isolated osteoclasts. Both tensin and cortactin were associated with attachment complexes used by osteoclast-like cells and osteoclasts to resorb bone. Specifically, punctate cortactin staining was observed inside tensin staining which formed a double ring structure at the membrane/bone interface of resorbing osteoclasts. These data showed that tensin and cortactin can be used as osteoclast differentiation markers, that participate in attachment complexes used to resorb bone, and that tensin may participate in the fusion process of osteoclast precursors.
Fimbrin, an actin-bundling protein, is a component of the osteoclast adhesion complexes called podosomes. In this study, we (1) determined the localization of fimbrin in the mature rabbit osteoclast as well as in differentiating osteoclasts using the avian monocyte-derived osteoclast differentiation model, (2) characterized the distribution and accumulation of three fimbrin isotypes (T, L, and I) in avian monocytes as they fused to form multinucleate osteoclast-like cells, and (3) report for the first time, a close spatial relationship between podosomes and microtubules using fimbrin as a marker of the podosome. Immunofluorescence using anti-T-fimbrin, anti-L-fimbrin, and pan-isotype-anti-fimbrin antibodies, showed that fimbrin is an integral component of the podosome core in the mature rabbit osteoclast and in the monocyte-derived osteoclast throughout differentiation. Anti-I-fimbrin, however, did not show immunoreactivity in these cultures. These studies also show that in the avian model of monocyte-derived osteoclast differentiation, day 2 cells (D2) are predominantly mononucleate and have few podosomes. By days 4 and 6 in culture (D4 and D6), many cells have fused and punctate rows of podosomes are commonly observed at cell margins. Analysis by Western blot of protein accumulation showed that after an initial small rise from D2 to D4, L-fimbrin levels remained relatively constant from D4 to D6. However, T-fimbrin protein levels increase steadily from D2 to D6, suggesting that it may be related to the increase in podosome formation as monocytes fuse to form osteoclasts. Finally, we examined the distribution of podosomes relative to other cytoskeletal elements such as microtubules and intermediate filaments. Double immunofluorescence labeling using anti-fimbrin and anti-tubulin showed podosomes lying adjacent to microtubules at cell margins. When osteoclasts were treated with nocodazole (1 X 10(-6) M) to disrupt microtubules, the distribution of podosomes became more random and was no longer confined to the cell periphery. These results suggest that microtubule-podosome interactions may play a role in osteoclast adhesion.
In order to study microtubule turnover in elongating neurites, chick embryo sensory neurons were microinjected with x-rhodamine tubulin, and after 6-12 hours, short segments along chosen neurites were photobleached at multiple sites. Previous studies [Lim et al., 1989; 1990] indicated that recovery of fluorescence (FRAP) in neurites occurs by the dynamic turnover of stationary microtubules. In all cases, distal bleached zones recovered fluorescence faster than bleached zones more proximally located along the same neurites. Bleached zones at growth cones completely recovered in 30-40 minutes, while bleached zones located more proximally usually recovered in 50-120 minutes. In the most proximal regions of long neurites, recovery of fluorescence was often incomplete, indicating that a significant fraction of the microtubules in these regions were very stable. These studies indicate that there are differences in microtubule stability along the length of growing neurites. These differences may arise from the combined effects of 1) modifications that stabilize and lengthen microtubules in maturing neurites and 2) the dynamic instability of the distally oriented microtubule plus ends.
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