To understand the origin of vacuolar H+-ATPases (V-ATPases) and their cellular functions, the subcellular location of V-H+-ATPases was examined immunologically in root cells of oat seedlings. A V-ATPase complex from oat roots consists of a large peripheral sector (V,) that includes the 70-kD (A) catalytic and the 60-kD (6) regulatory subunits. The soluble V1 complex, thought to be synthesized in the cytoplasm, is assembled with the membrane integral sector (V.) at a yet undefined location. In mature cells, VATPase subunits A and B, detected in immunoblots with mqnoclonal antibodies (Mab) (7A5 and 2E7), were associated mainly with vacuolar membranes (20-22% sucrose) fractionated with an isopycnic sucrose gradient. However, in immature root tip cells, which lack large vacuoles, most of the V-ATPase was localized with the endoplasmic reticulum (ER) at 28 to 31% sucrose where a major ER-resident binding protein equilibrated. The peripheral subunits were also associated with membranes at 22% sucrose, at 31 to 34% sucrose (Golgi), and in plasma membranes at 38% sucrose. lmmunogold labeling of root tip cells with Mab 2E7 against subunit B showed gold particles decorating the ER as well as numerous small vesicles (0.1-0.3 pm diameter), presumably provacuoles. The immunological detection of the peripheral subunit B on the ER supports a model in which the V1 sector is assembled with the V , , on the ER. These results support the model in which the central vacuolar membrane originates ultimately from the ER. The presence of V-ATPases on several endomembranes indicates that this pump could participate in diverse functional roles.In plants, acidification of the vacuolar compartment by the V-ATPase is essential to or involved in many diverse functions (Sze et al., 1992a). Depending on the tissue, the stage of development, and the signals received, these functions include osmoregulation, transport and storage of ions and metabolites, signal transduction, storage and turnover of proteins, and storage of secondary metabolites, defense proteins, and pigments (Boller and Wiemken, 1986;Martinoia, 1992). Vacuoles are dynamic, prominent organelles. Undifferentiated and immature plant cells often possess proportionately more cytoplasm that contains an extensive endo-
We have treated living, intact stamen hair cells from the spiderwort plant, Tradescantia virginiana, with 0.5 microgram/ml or 60 micrograms/ml 1,2-dioctanoylglycerol, a potent and permeant activator of protein kinase C, and have observed the rates of progression of mitosis from prophase through anaphase. We have found that in addition to the concentration used, the time of initial treatment with 1,2-dioctanoylglycerol defines the response by the cells. The cells rapidly undergo nuclear envelope breakdown when this diglyceride is added in very late prophase, 0 to approximately 8 min prior to the time of normal nuclear envelope breakdown. Anaphase onset occurs 28 min after nuclear envelope breakdown, rather than after the 33 min interval observed in untreated cells. Rapid progression through metaphase is also observed if cells are treated with 0.5 microgram/ml 1,2-dioctanoylglycerol during prometaphase, up to 15 min after nuclear envelope breakdown. The addition of 0.5 microgram/ml 1,2-dioctanoylglycerol in late metaphase, approximately 26 min after nuclear envelope breakdown, results in sister chromatid separation slightly ahead of its normal time, 33 min after nuclear envelope breakdown, and in precocious cell plate vesicle aggregation, 3-5 min earlier than that observed in untreated cells. Treatment of cells with 60 micrograms/ml of 1,2-dioctanoylglycerol at any point during the interval from 0 to approximately 5 min prior to nuclear envelope breakdown results in precocious entry into anaphase. If cells are treated with either 0.5 microgram/ml or 60 micrograms/ml 1,2-dioctanoylglycerol earlier than 20 min before nuclear envelope breakdown, they do not enter mitosis, but instead revert to interphase without dividing. When 1,2-dioctanoylglycerol is added at other times during mitosis, the rate of subsequent mitotic progression is dramatically slowed; the cells require greater than 55 min to progress from nuclear envelope breakdown to anaphase onset, though once in anaphase, the cells progress onward to cytokinesis at normal rates. Treatments o of cells with 1,3-dioctanoylglycerol at any point during prophase, prometaphase, or metaphase are without effect on the rate of subsequent mitotic progression. The shifts in response by cells treated at specific times with 1,2-dioctanoylglycerol during mid- and late metaphase may be indicative of the existence of one or more regulatory switch points (i.e., checkpoints) just prior to anaphase onset.
Stamen hair cells of the spiderwort plant Tradescantia virginiana exhibit unusually predictable rates of progression through mitosis, particularly from the time of nuclear envelope breakdown (NEBD) through the initiation of cytokinesis. The predictable rate of progression through prometaphase and metaphase has made these cells a useful model system for the determination of the timing of regulatory events that trigger entry into anaphase. A number of studies suggest that the elevation of one or more protein kinase activities is a necessary prerequisite for entry into anaphase. The current experiments employ two strategies to test when these elevations in protein kinase activity actually occur during metaphase. In perfusions, we added the protein kinase inhibitors K-252a, staurosporine, or calphostin C to living stamen hair cells for 10-min intervals at known times during prometaphase or metaphase and monitored the subsequent rate of progression into anaphase. Metaphase transit times were altered as a function of the time of addition of K-252a or staurosporine to the cells; metaphase transit times were extended significantly by treatments initiated in prometaphase through early metaphase and again late in metaphase. Transit times were normal after treatments initiated in mid-metaphase, approximately 15 to 21 min after NEBD. Calphostin C had no significant effect on the metaphase transit times. In parallel, cells were microinjected with known quantities of a general-purpose protein kinase substrate peptide, VRKRTLRRL, at predefined time points during prometaphase and metaphase. At a cytosolic concentration of 100 nM to 1 microM, the peptide doubled or tripled the metaphase transit times when injected into the cytosol of mitotic cells within the first 4 min after NEBD, at any point from 7.5 to 9 min after NEBD, at any point from 14 to 16 min after NEBD, at 21 min after NEBD, or at 24 min after NEBD. At the concentration used and during these brief intervals, the peptide appeared to act as a competitive inhibitor to reveal inflection points when protein kinase activation was occurring or when endogenous substrate levels approached levels of the peptide. The timing of these inflection points coincides with the changes in protein kinase activities during prometaphase and metaphase, as indicated by our perfusions of cells with the broad spectrum kinase inhibitors. Collectively, our results suggest that the cascade that culminates in anaphase is complex and involves several successive protein kinase activation steps punctuated by the activation of one or more protein phosphatases in mid-metaphase.
Neomycin has been reported to inhibit polyphosphoinositide cycling by preventing the hydrolysis of phosphatidylinositol 4,5-bisphosphate into inositol 1,4,5-trisphosphate and 1,2-diacylglycerol. Inositol 1,4,5-trisphosphate, through the mobilization of calcium, and 1,2-diacylglycerol, through the activation of protein kinase C, trigger many physiological responses. The addition of 2 mM neomycin to stamen hair cells of Tradescantia virginiana at various points during mitosis arrests cells in prophase, prior to nuclear envelope breakdown, or in metaphase. Arrest in prophase is irreversible. Metaphase arrest can persist for over 2h before the cells attempt to revert to interphase without dividing. Entry into anaphase by the majority of cells in our sample arrested in metaphse occurred after treatment with 1,2-dioctanoylglycerol while 1,3-dioctanoylglycerol was totally ineffective at reversal. Perfusion of 100 μM calcium chloride solution past the cells was sufficient to reverse arrest in approximately half of the cells in the sample. Magnesium could not be substituted for calcium in the reversal. Clindamycin, another member of this class of aminoglycoside antibiotics, with no known inhibitory effect on polyphosphoinositide cycling, is without effect on mitotic progression in stamen hair cells. Our results indirectly implicate one or more episodes of polyphosphoinositide cycling and its resultant protein phosphorylation by protein kinase C in the regulatory cascade that leads to anaphase.
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