Centrosome behaviour and orientation of centrioles under the action of energy transfer inhibitors.

2,4-dinitrophenol, dinitrophenol together with deoxyglucose, sodium azide and ouabain didn't alter cytoplasmic microtubule (MT) network of cultured PK (pig kidney embryo) cells, meanwhile they induced an increase in the average number of pericentriolar satellites and percentage of centrioles with the primary cilium in these cells. Also all drugs studied increase number of MTs attached to and oriented towards the centrosome. Under the action of ouabain the total number of MTs around the centrosome doubled, meanwhile the number of long MTs emanating from the centrosome increased more than 15 times. Under the action of all drugs studied, except sodium azide, the number of maternal centrioles oriented perpendicularly to the substrate surface increased significantly from that in control cells.     

The ultrastructure of the centrosome in cytoplasts and its alteration under the action of ouabain]

It has been shown that after enucleation of the PE cells with cytochalasin D the centrioles remain in approximately 80% of cytoplasts. Some cytoplasts contain only single centriole, either a mother (active) of a daughter (inactive) one. 20% cytoplasts have no centrioles. 2h after enucleation the centrosome structure in the cytoplasts did not differ from that in normal cells. 14-16 h after enucleation in many cytoplasts large secondary lysosomes and lipid droplets appeared around the centrosome. At this time in some cytoplasts in the centrosome we observed free microtubule convergence foci. 14-16 h after the enucleation, some cytoplasts have doubling centrioles. Under the influence of ouabain (30 min), the number of active centrioles oriented perpendicularly to the substrate plane in the cytoplasts increased. We suggest that the preferentially perpendicular orientation of centrioles to the substrate plane does not depend on the nuclear activity.     

The centrosome reaction in tissue-culture cells to depolarization of the cell membranes

Carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP), ouabain and calcium ionophore A23187 caused a centrosome restructuring expressed in mean number increase of satellites on the active (mother) centriole, in an increase of the mean slope of centrioles to the substrate surface and in the more frequent occurrence of primary cilia. In the presence of FCCP the effect appeared only in 10 min and retained for 2 h. The ouabain caused the separation of active and inactive centrioles in more than in a half of the cells. The data obtained permit to conclude that depolarization of the plasmatic membrane only is needed for the initiation of centrosome restructuring. The authors propose that this reaction of centrosome is a component of the cell overall response to nonspecific lesions.     

Centrosome Behavior under the Action of a Mitochondrial Uncoupler and the Effect of Disruption of Cytoskeleton Elements on the Uncoupler-Induced Alterations

Carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone (FCCP) induced in pig kidney embryo cells a loss of rhodamine 123 staining of mitochondria in 2-3 min. Within 5 min after FCCP inoculation of cells prestained with rhodamine 123, the diffuse staining of the cytoplasm was absent. FCCP did not induce changes in the cytoplasmic microtubule complex, but induced nonrandom (preferentially perpendicular to the substrate surface) orientation of maternal centrioles. Nonrandom orientation of maternal centrioles occurred 10 min after treatment and remained for 2 hr. At 30 min after introduction of the drug, FCCP treatment increased the mean number of pericentriolar satellites on maternal centrioles and the frequency of primary cilia. The percentage of centrioles perpendicular to the substrate induced by FCCP treatment was slightly increased by disruption of microtubules and slightly diminished by disruption of microfilaments. In both cases centrioles were oriented significantly differently from random (P < 0.01). These results suggest that microtubules are neither involved in the signaling pathway from plasma membrane to the centriole, nor do they anchor the centrioles perpendicular to the substrate, as proposed by Albrecht-Buehler and Bushnell (Experimental Cell Research 120, 1979).     

A reassessment of decreased amino acid accumulation by ehrlich ascites tumor cells in the presence of metabolic inhibitors

This study was undertaken to examine the mechanism by which metabolic inhibition reduces amino acid active transport in ehrlich ascites tumor cells. At 37 degrees C the metabolic inhibitor combination 0.1 mM 2,4-dinitrophenol (DNP) + 10 mM 2- deoxy-D-glucose (DOG) reduced the cell ATP concentration to 0.10- 0.15 mM in less than 5 min. This inhibition was associated with a 20.6 percent +/- 6.4 percent (SD) decrease in the initial influx of α-aminoisobutyric acid (AIB), and a two- to fourfold increase in the unidirectional efflux. These effects could be dissociated from changes in cell Na(+) or K(+) concentrations. Cells incubated to the steady state in 1.0-1.5 mM AIB showed an increased steady-state flux in the presence of DNP + DOG. Steady- state fluxes were consistent with trans-inhibition of AIB influx and trans-stimulation of efflux in control cells, but trans- stimulation of both fluxes in inhibited cells. In spite of the reduction of the cell ATP concentration to less than 0.15 mM and greatly reduced transmembrane concentration gradients of Na(+) and K(+), cells incubated to the steady state in the presence of the inhibitors still established an AIB distribution ration 13.8 +/- 2.6. The results are interpreted to indicate that a component of the reduction of AIB transport produced by metabolic inhibition is attributable to other actions in addition to the reduction of cation concentration gradients. Reduction of cell ATP alone is not responsible for the effects of metabolic inhibition, and both the transmembrane voltage and direct coupling to substrate oxidation via plasma-membrane-bound enzymes must be considered as possible energy sources for amino acid active transport.     

Metabolic inhibitors and mitosis: I. Effects of dinitrophenol/deoxyglucose and nocodazole on the live spindle

Summary Dinitrophenol and deoxyglucose (DNP/DOG) were used to investigate the effects of ATP depletion on mitotic PtK₁ cells. Direct determination of cellular ATP levels showed that the drop of ATP induced by DNP/DOG was rapid; recovery to normal ATP levels was equally rapid once DNP/DOG was removed. On addition of DNP/DOG to live cells, cytoplasmic activity ceased; interphase and prophase cells showed little other response to DNP/DOG. During prometaphase, DNP/DOG induced a pronounced movement of oscillating, monopolar chromosomes towards the spindle poles. As chromosomes became bipolarly attached, DNP/DOG caused the spindle poles themselves to move together. By metaphase, DNP/DOG-treatment led to significant shortening of the spindle which remained intact. DNP/DOG rapidly stopped anaphase chromosome movement and cytokinesis.Nocodazole (NOC) caused the rapid breakdown of the mitotic spindle; prometaphase chromosomes clustered at the poles and in metaphase cells, the poles were drawn towards the chromosomes as the spindle became disorganized. When cells were pretreated with DNP/DOG and then NOC/DNP/DOG, nocodazole did not break down the spindle. When nocodazole was applied first to break down spindle MTs then DNP/DOG was added to the nocodazole, a second contraction was often induced by the DNP/DOG in the absence of spindle microtubules (MTs). Chromosomes expanded appreciably outwards from the poles when the DNP/DOG was removed, even when the cells remained in nocodazole.     

The effect of the disruption of the cytoskeletal elements on uncoupler-induced changes in the centrosome

The disruption of microtubules with nocodazole or microfilaments with cytochalasin B did not prevent mother centrioles from nonrandom, preferentially perpendicular orientation with respect to the substrate plane after FCCP treatment. The microtubules affect negatively the reorientation of centrioles, because after their disruption by nocodazole the percentage of centrioles with the perpendicular orientation (the angle is tipped to the substrate plane by over 74 degrees) is seen to increase. The microfilaments have the positive effect, because after their disruption by cytochalasin B the share of centrioles with the perpendicular orientation decreases. Thus, our observations do not support the hypothesis that the long microtubules can provide the perpendicular orientation of centrioles anchoring them in the cytoplasm.     

Rapid Shedding of Roots from Azolla filiculoides Plants in Response to Inhibitors of Respiration

Chemicals that are known to be inhibitors of respiration, namely,sodium azide, sodium cyanide, DNP, CCCP and DCCD, caused sheddingof roots of Azolla filiculoides plants. Complete shedding ofroots of more than 10 mm in length occurred when Azolla plantswere treated with sodium azide, DNP or CCCP at concentrationsabove 50µM, 30µM and 20µM, respectively. Theshedding in response to sodium azide, DNP and CCCP was veryrapid and was complete within 5–20 min. Microscopic studies revealed the presence of large cells atthe outer surface of the base of roots that were about to beshed. The tested-chemicals caused the expansion, rounding upand separation of these cells, probably via the rapid absorptionof water, with resultant shedding of roots. When detached roots were immersed in a solution of sodium azide,DNP or CCCP, the large cells expanded and rounded up. Thesecells were gradually separated from the roots. However, theseparation of the cells caused by DNP was inhibited by the presenceof various buffers at acidic pH. By contrast, buffers at neutralpH greatly facilitated the separation of cells irrespectiveof whether DNP was present or absent. The results suggest that the separation of cells involves anincrease in the pH of the external solution in the vicinityof the large cells. A change in ion fluxes of the large cells,which accompanies an increase in pH of the external solution,may cause the rapid absorption of water by the cells and resultin the expansion and separation of the cells. (Received June 15, 1993; Accepted October 25, 1993)     

Structural change in the cell center during fibroblast polarization and movement

In polarizing and migrating 3T3/Balb mouse fibroblasts, the centrioles are located between the nucleus and the leading edge of the cell. In cells within the monolayer and in migrating cells, the centrioles have a random orientation towards the substrate. In polarized cells, that still remain in the monolayer, one centriole may be perpendicular to the substrate plane in 70% of cases. Upon polarization and migration of fibroblasts, the number of microtubules, which radiate from the centriolar region, increases. These data support a hypothesis that the number of microtubules in the cell centre characterizes the rate of their renovation in the cytoplasm. It is concluded that the cell centre is strongly involved in polarization and migration of fibroblasts.     

Centrioles in the cell cycle. I. Epithelial cells

A study was made of the structure of the centrosome in the cell cycle in a nonsynchronous culture of pig kidney embryo (PE) cells. In the spindle pole of the metaphase cell there are two mutually perpendicular centrioles (mother and daughter) which differ in their ultrastructure. An electron-dense halo, which surrounds only the mother centriole and is the site where spindle microtubules converge, disappears at the end of telophase. In metaphase and anaphase, the mother centriole is situated perpendicular to the spindle axis. At the beginning of the G1 period, pericentriolar satellites are formed on the mother centriole with microtubules attached to them; the two centrioles diverge. The structures of the two centrioles differ throughout interphase; the mother centriole has appendages, the daughter does not. Replication of the centrioles occurs approximately in the middle of the S period. The structure of the procentrioles differs sharply from that of the mature centriole. Elongation of procentrioles is completed in prometaphase, and their structure undergoes a number of successive changes. In the G2 period, pericentriolar satellites disappear and some time later a fibrillar halo is formed on both mother centrioles, i.e., spindle poles begin to form. In the cells that have left the mitotic cycle (G0 period), replication of centrioles does not take place; in many cells, a cilium is formed on the mother centriole. In a small number of cells a cilium is formed in the S and G2 periods, but unlike the cilium in the G0 period it does not reach the surface of the cell. In all cases, it locates on the centriole with appendages. At the beginning of the G1 period, during the G2 period, and in nonciliated cells in the G0 period, one of the centrioles is situated perpendicular to the substrate. On the whole, it takes a mature centriole a cycle and a half to form in PE cells.     

The effect of the UV microirradiation of the centrosome on cell behavior. III. The ultrastructure of the centrosome after irradiation]

One of the spindle poles of mitotic PK cells was irradiated with UV microbeam in metaphase or in anaphase. Electron microscopy showed that immediately after irradiation the microtubules around the centrosome were maintained, and that the ultrastructure of both irradiated and nonirradiated poles was similar. After microirradiation of the centrosome in metaphase, the mitotic halo around this centrosome was retained, but in due time the number of microtubules was getting less compared to that around the nonirradiated centrosome. When daughter cells with irradiated centrosomes are passing into the interphase, their centrioles are not separated from each other, no primary cilia are formed, and no replication of centrioles occurs. In the interphase cells with irradiated centrosomes, satellites are formed on the active centriole, but centrosome-attached microtubules are practically absent.     

Behavior of the cell center during epithelial cell spreading

In the epithelial cells of mouse embryo renal channels, centrioles are located near the plasma membrane of the apical part of the cell. In most of the cells an active centriole carries a cilium, which comes out into the channel lumen. In the epithelial cells, suspended after trypsinisation and in single cells adhering to the substrate, the centrioles are located near the nucleus, and the outcoming cilia are not observed. In the spread cells of epithelial islets, the centrioles are also found near the nucleus, and in most cases an active centriole carries a cilium, which comes out of the cytoplasm at the upper side of the cell. In the peripheral cells of the islet, centrioles are positioned between the nucleus and the active edge of the cell. In the epithelial cells in situ, a relatively small number of microtubules radiate from the active centrioles. In the suspended cells, the activation of microtubule formation is observed in the cell center. In the spread cells of the epithelial islets there occurs a further increase in the number of microtubules radiating from the active centrioles. In the peripheral cells which cause translocation of the epithelial islet in the culture, the number of microtubules, radiating from the centrioles does not differ significantly from that of the inner cells of the islet. The cell center of the epithelial cells does not seem to be actively involved in the locomotion of the epithelial cells in the culture.     

Vertebrate primary cilia: a sensory part of centrosomal complex in tissue cells,but a “sleeping beauty” in cultured cells?

Primary cilium development along with other components of the centrosome in mammalian cells was analysed ultrastructurally and by immunofluorescent staining with anti-acetylated tubulin antibodies. We categorized two types of primary cilia, nascent cilia that are about 1microm long located inside the cytoplasm, and true primary cilia that are several microm long and protrude from the plasma membrane. The primary cilium is invariably associated with the older centriole of each diplosome, having appendages at the distal end and pericentriolar satellites with cytoplasmic microtubules emanating from them. Only one cilium per cell is formed normally through G(0), S and G(2)phases. However, in some mouse embryo fibroblasts with two mature centrioles, bicilates were seen. Primary cilia were not observed in cultured cells where the mature centriole had no satellites and appendages (Chinese hamster kidney cells, line 237, some clones of l-fibroblasts). In contrast to primary cilia, striated rootlets were found around active and non-active centrioles with the same frequency. In proliferating cultured cells, a primary cilium can be formed several hours after mitosis, in fibroblasts 2-4 h after cell division and in PK cells only during the S-phase. In interphase cells, formation of the primary cilium can be stimulated by the action of metabolic inhibitors and by reversed depolymerization of cytoplasmic microtubules with cold or colcemid treatments. In mouse renal epithelial cells in situ, the centrosome was located near the cell surface and mature centrioles in 80% of the cells had primary cilium protruding into the duct lumen. After cells were explanted and subcultured, the centrosome comes closer to the nucleus and the primary cilium was depolymerized or reduced. Later primary cilia appeared in cells that form islets on the coverslip. However, the centrosome in cultured ciliated cells was always located near the cell nucleus and primary cilium never formed a characteristic distal bulb. A sequence of the developmental stages of the primary cilium is proposed and discussed. We also conclude that functioning primary cilium does not necessarily operate in culture cells, which might explain some of the contradictory data on cell ciliation in vitro reported in the literature.     

Spindle microtubule dynamics: modulation by metabolic inhibitors

Recent experiments have shown that spindle microtubules are exceedingly dynamic. Measurements of fluorescence recovery after photobleaching (FRAP), in cells previously microinjected with fluorescent tubulin, provide quantitative information concerning the rate of turnover, or exchange, of tubulin subunits with the population of microtubules in living cells at steady state. In an effort to elucidate the pathways and factors that regulate tubulin exchange with microtubules in living cells, we have investigated the energy requirements for tubulin turnover as measured by FRAP. Spindle morphology was not detectably altered in cells incubated with 5 mM sodium azide and 1 mM 2-deoxyglucose (Az/DOG) for 5 minutes, as assayed by polarized light microscopy and antitubulin immunofluorescence. In FRAP experiments on these ATP-depleted cells, the average rate of recovery and the average percent of bleached fluorescence recovered were reduced to 37% and 30% of controls, respectively. When the inhibitors were removed, cells continued through mitosis, and rapid FRAP was restored. In the presence of azide and glucose, the rate of recovery and percent of fluorescence recovered were only slightly reduced, demonstrating that energy production via glycolysis can support microtubule turnover. Longer incubations with Az/DOG altered the microtubule organization in mitotic cells: astral microtubules lengthened and spindle fibers shortened. Furthermore, both astral and spindle microtubules became resistant to nocodazole-induced disassembly under these conditions. Together these observations indicate that microtubule dynamics require ATP and suggest a relationship between microtubule organization and turnover.     

Metabolic inhibitors and mitosis: II. Effects of dinitrophenol/deoxyglucose and nocodazole on the microtubule cytoskeleton

Summary To examine the effects exerted on the microtubule (MT) cytoskeleton by dinitrophenol/deoxyglucose (DNP/DOG) and nocodazole, live PtK₁ cells were treated with the drugs and then fixed and examined by immunofluorescence staining and electronmicroscopy. DNP/DOG had little effect on interphase MTs. In mitotic cells, kinetochore and some astral fibers were clearly shortened in metaphase figures by DNP/DOG. Nocodazole rapidly broke down spindle MTs (except those in the midbody), while interphase cells showed considerable variation in the susceptibility of their MTs. Nocodazole had little effect on MTs in energy-depleted (DNP/DOG-treated) cells. When cytoplasmic MTs had all been broken down by prolonged nocodazole treatment and the cells then released from the nocodazole block into DNP/DOG, some MT reassembly occurred in the ATP-depleted state. MTs in permeabilized, extracted cells were also examined with antitubulin staining; the well-preserved interphase and mitotic arrays of MTs showed no susceptibility to nocodazole. In contrast, MTs suffered considerable breakdown by ATP, GTP and ATPS; AMPPNP had little effect. This susceptibility of extracted MT cytoskeleton to nucleotide phosphates was highly variable; some interphase cells lost all MTs, most were severely affected, but some retained extensive MT networks; mitotic spindles were diminished but structurally coherent and more stable than most interphase MT arrays.We suggest that: 1. in the living cell, ATP or nucleotide triphosphates (NTPs) are necessary for normal and nocodazole-induced MT disassembly; 2. the NTP requirement may be for phosphorylation; 3. shortening of kinetochore fibers may be modulated by compression and require ATP; 4. many of these results cannot be accomodated by the dynamic equilibrium theory of MT assembly/disassembly; 5. the use and role of ATP on isolated spindles may have to be reevaluated due to the effects ATP has on the spindle cytoskeleton of permeabilized cells.     

Inhibitors of mitochondrial ATP production at the time of compaction improve development of in vitro produced porcine embryos

The relationship between partial inhibition of mitochondrial ATP production during the peri-compaction stage and porcine embryonic development was studied. In vitro produced porcine compact morulae were cultured for two days under conditions that should inhibit ATP production via oxidative phosphorylation. The culture conditions included supplementation of the culture medium with sodium azide (NaN3), an oxidative phosphorylation inhibitor; incubation in the presence of 2,4-dinitrophenol (DNP), an uncoupler of oxidative phosphorylation; or incubation under 5% O2 concentration. NaN3 (10-20 microM) increased the average nuclear number found in the resulting blastocysts (P<0.05). The embryos developed in the presence of 100 microM DNP formed blastocysts at a significantly higher incidence than the control embryos (P<0.001); the average nuclear number found in these blastocysts was also higher (P<0.005). When these treatments were applied from the 1-cell stage they proved to be detrimental. Elevations in the frequency of blastocyst formation (P<0.05), and in the average nuclear number per blastocyst (P<0.001) were also measured when compact morulae were incubated in an atmosphere containing 5% vs. 20% O2. NaN3 or DNP did not have negative effects on long term development: the treated embryos were able to form viable conceptuses by day 30 after being transferred into recipients. The data indicate that transient inhibition of mitochondrial ATP production is advantageous for porcine embryonic development in vitro.     

Calcium-modulated contractile proteins associated with the eucaryotic centrosome

Affinity-purified antibodies that recognize the 20,000-dalton molecular weight (20 kd) striated flagellar root protein of Tetraselmis striata have been used to identify antigenic homologs in other eucaryotic organisms of diverse evolutionary origins. Among the green algae, Tetraselmis and Chlamydomonas, and their colorless relative, Polytomella, the 20-kd homologs appear associated with basal bodies. This occurs most prominently in the form of flagellar roots of both striated and microtubule subtended types. Among cultured mammalian cells (PtK2 and primary mouse macrophage cell lines), flagellar root protein homologs appear as basal feet, pericentriolar fibrils, and pericentriolar satellites. Mammalian sperm cells also show flagellar root protein homologs associated with their basal bodies. We envisage a functional role for these fibrous calcium-sensitive contractile proteins in altering the orientation of centrioles or basal bodies with their associated MTOCs by responding to topological calcium fluxes.     

The orientation of primary cilia during the wound response in 3Y1 cells

Summary— The behavior of the primary cilia of 3Y1 cells in the interphase was investigated by indirect immunofluorescence microscopy and transmission electron microscopy, using an antibody for tubulin. At 4.5 h after scraping a part of a confluent cell sheet, the primary cilia of cells facing the wound were located predominantly forward of the nucleus on the wounded side, and were oriented in the direction of the leading lamellae. Cytoplasmic microtubules (MTs), emanating from around the base of the cilia, were well developed in the leading lamellae on the wounded side. On the other hand, in the cells of an unperturbed area away from the wounded edge, the primary cilia remained randomly distributed near the nucleus. The position and a certain well-defined orientation of a pair of centrioles seem to play an important role for the development of cytoplasmic MTs, and consequently the orientation of the centrioles is controlled by the primary cilia.