Intranuclear microtubules.

Intranuclear microtubules are a regular feature of spermatocyte meiosis in a crane fly (Nephrotoma suturalis Loew).

Cytochalasin B: does it affect actin-like filaments?

An in vitro system was used to test the purported action of cytochalasin B. At concentrations 100 times those used for experiments in vivo, cytochalasin B did not cause the breakdown of F-actin, did not inhibit the transformation of G-actin to F-actin, did not inhibit the binding of heavy meromyosin to F-actin, and did not inhibit the adenosine triphosphate-induced release of heavy meromyosin from F-actin.

Contractile proteins. Major components of nuclear and chromosome non-histone proteins.

Two of the major non-histone proteins from Physarum polycephalum have been isolated under nondenaturing conditions and identified as actin and myosin. A third protein has been purified from crude nuclear actomyosin and from residual nonhistone fractions and found to bind actomyosin in the presence of Mg2+. In Physarum these proteins are not components of the nuclear membrane. Based on sodium dodecylsulfate-polyacrylamide gel electrophoresis, similar proteins are also present in nuclei of HeLa cells and mouse embryo fibroblasts. Isolated metaphase chromosomes from Physarum show a several-fold enrichment in myosin and an altered ratio of actin to the Mg2+-dependent actomyosin binding protein as compared to interphase nuclei. When non-proliferative states are induced in any of these cells, the Mg2+-dependent actomyosin binding protein decreases while actin increases several fold in intranuclear concentration; concomitantly, there is a generalized condensation and inactivation of chromatin. Experiments with added purified radioactive nuclear actomyosin; comparative studies on nuclear protein during stepwise nuclear purification; and studies on isolated metaphase chromosomes indicate that these proteins exist in nuclei in vivo. These observations suggest that contractile proteins may function in the structural interconversions of chromatin and in the regulation of cell proliferation;

Actin and myosin inhibitors block elongation of kinetochore fibre stubs in metaphase crane-fly spermatocytes.

We used an ultraviolet microbeam to cut individual kinetochore spindle fibres in metaphase crane-fly spermatocytes. We then followed the growth of the "kinetochore stubs", the remnants of kinetochore fibres that remain attached to kinetochores. Kinetochore stubs elongate with constant velocity by adding tubulin subunits at the kinetochore, and thus elongation is related to tubulin flux in the kinetochore microtubules. Stub elongation was blocked by cytochalasin D and latrunculin A, actin inhibitors, and by butanedione monoxime, a myosin inhibitor. We conclude that actin and myosin are involved in generating elongation and thus in producing tubulin flux in kinetochore microtubules. We suggest that actin and myosin act in concert with a spindle matrix to propel kinetochore fibres poleward, thereby causing stub elongation and generating anaphase chromosome movement in nonirradiated cells.

Does actin produce the force that moves a chromosome to the pole during anaphase?

Chromosomes move towards spindle poles because of force produced by chromosomal spindle fibres. I argue that actin is involved in producing this force. Actin is present in chromosomal spindle fibres, with consistent polarity. Physiological experiments using ultraviolet microbeam irradiations suggest that the force is due to an actin and myosin (or myosin-equivalent) system. Other physiological experiments (using inhibitors in "leaky" cells or antibodies injected into cells) that on the face of it would seem to rule out actin and myosin on closer scrutiny do not really do so at all. I argue that in vivo the "on" ends of chromosomal spindle fibre microtubules are at the kinetochores; I discuss the apparent contradiction between this conclusion and those from experiments on microtubules in vitro. From what we know of treadmilling in microtubules in vitro, the poleward movements of irradiation-induced areas of reduced birefringence (arb) can not be explained as treadmilling of microtubules: additional assumptions need to be made for arb movements toward the pole to be due to treadmilling. If arb movement does indeed represent treadmilling along chromosomal spindle fibre microtubules, treadmilling continues throughout anaphase. Thus I suggest that chromosomal spindle fibres shorten in anaphase not because polymerization is stopped at the kinetochore (the on end), as previously assumed, but rather because there is increased depolymerization at the pole (the "off" end).

In ultraviolet microbeam irradiations, characteristics of the monochromator and lamp affect the spectral composition of the ultraviolet light and probably the biological results.

Biological conclusions recently published concerning ultraviolet (u.v.) microbeam irradiation of spindles are different from those we previously published. Several technical differences between the two sets of experiments were investigated. The spectral distributions in the light emitted from mercury-arc, xenon-mercury-arc, and xenon-arc lamps were measured, as were the spectral distributions after the light from these lamps passed through a monochromator that was set to various wavelengths and various half-band-widths. Both the source of the u.v. light and the half-band-width of the monochromator influence the spectral distribution of the light leaving the monochromator: depending on the conditions, the light leaving the monochromator is not necessarily of the same wavelength as that to which the monochromator is set. Differences in these aspects of the experiments could easily give rise to the different biological conclusions reached in the two sets of experiments.

Appearances of microtubules after various fixative procedures, and comparison with the appearances of tobacco mosaic virus.

Microtubules in crane-fly spermatids appeared altered when the glutaraldehyde-fixed cells were not postfixed with osmium tetroxide. The cytoplasmic microtubules were altered more than the doublet microtubules. Addition of osmium tetroxide after dehydration did not produce appearances identical with those of microtubules postfixed directly after glutaraldehyde, and thus at least some alterations occurred during dehydration, possibly due to extraction of microtubule-associated lipid. The omission of osmium tetroxide postfixation did not cause drastic alterations in the appearances of either tobacco mosaic virus (TMV), or polymerized tobacco mosaic virus protein (without RNA), suggesting that microtubule stability is different from TMV stability (with respect to the embedment procedure). The electron-dense stain associated with embedded-sectioned TMV is predominantly outside the TMV protein, as demonstrated by the known distribution of TMV protein compared with the dimensions of sectioned TMV and negatively stained TMV. The same might hold true for microtubules, as evidenced by the dimensions of negatively stained, isolated brain microtubules compared with those of embedded and sectioned brain microtubules.

Irradiations of rabbit myofibrils with an ultraviolet microbeam. I. Effects of ultraviolet light on the myofibril components necessary for contraction.

Glycerinated rabbit psoas myofibrils, F-actin, and myofibril ghosts were irradiated with ultraviolet light (UV) to investigate how UV blocks myofibril contraction. Myofibril contraction is most sensitive to 270- and 290-nm wavelength light. We irradiated I and A bands separately with 270- and 290-nm wavelength light using a UV microbeam and constructed dose-response curves for blocking sarcomere contraction. For both wavelengths, irradiations of A bands required less energy per area to block contraction than did irradiations of I bands, suggesting that the primary effects of both 270- and 290-nm wavelength light in stopping myofibril contraction are on myosin. We investigated whether the primary effect of UV in blocking I-band contraction is the depolymerization of actin by comparing the relative sensitivities of I-band contraction, F-actin depolymerization, and thin filament depolymerization to 270- and 290-nm light. We also compared the dose of UV required to depolymerize F-actin in solution with the dose needed to block I-band contraction and the dose required to alter thin filament structure in myofibril ghosts. The results confirm that UV blocks I-band contraction by depolymerizing actin. We discuss how the results might be relevant to the hypothesis that an actomyosin-based system is involved in chromosome movement.

Blood platelet heterogeneity: evidence for two classes of platelets in man and rat.

The platelet population of man and rat can be divided into two classes of about equal size on the basis of presence/absence of an acid phosphatase which acts on para-nitrophenylphosphate (a PNPase), at pH 5. The cytochemical reaction product is in the platelet cytoplasmic matrix, without apparent association with organelles or membrane systems. We could not relate differences in staining to differences in function: all cells responded the same to activation by thrombin, ADP, or collagen, in fibrinogen binding to activated platelets, by endocytosis of fluid-phase tracers, and in internalization of latex particles. With respect to possible physiological substrates for the PNP-ase, there was no reaction product from beta-glycerophosphate, AMP, ADP, ATP, GTP, CMP, IMP, cAMP, creatine phosphate, and inositol phosphates, and the enzyme was not inhibited by 40 mM lithium. There was reaction product from tyrosine phosphate suggesting that the physiological substrate for PNP-ase is tyrosine phosphate. In rat bone marrow, megakaryocytes also were of two classes, PNPase positive and PNPase negative, suggesting that different classes of platelets arise from different classes of megakaryocytes.

Coordinated movements between autosomal half-bivalents in crane-fly spermatocytes: evidence that 'stop' signals are sent between partner half-bivalents.

During anaphase-I in crane-fly spermatocytes, sister half-bivalents separate and move to opposite poles. When we irradiate a kinetochore spindle fibre with an ultraviolet microbeam, the associated half-bivalent temporarily stops moving and so does the partner half-bivalent with which it was paired during metaphase. To test whether a 'signal' is transmitted between partner half-bivalents we irradiated the spindle twice, once in the interzone (the region between separating partner half-bivalents) and once in a kinetochore fibre. For both irradiations we used light of wavelength 290 microns and a dose that, after irradiating a spindle fibre only, altered movement in 63% of irradiations (12/19); in 11 of the 12 cells both partner half-bivalents stopped moving after the irradiation. In control experiments we irradiated the interzone only: these irradiations generally did not stop chromosomal poleward motion but sometimes (14/29) caused poleward movement to each pole to be abruptly reduced to about half the velocity prior to irradiation. In double irradiation experiments we varied the order of the irradiations. In some double irradiation experiments we irradiated the interzonal region first and the spindle fibre second; in 75% (9/12) of the cells the half-bivalent associated with the irradiated fibre stopped moving while the partner half-bivalent moved normally, i.e. in 9/12 cells the interzonal irradiations uncoupled the movements of the partner half-bivalents. In other double irradiation experiments we irradiated the spindle fibre first and the interzone second: in 80% (4/5) of the cells the half-bivalents not associated with the irradiated spindle fibre resumed movement immediately after the irradiation while the other half-bivalent remained stopped. Interzonal irradiations therefore uncouple the poleward movements of sister half-bivalents and the uncoupling does not depend on the order of the irradiation. Our experiments suggest therefore that the irradiation of a spindle fibre causes negative ('stop') signals to be transmitted across the interzone and that irradiation of the interzone blocks the transmission of the stop signal.

The behaviour of microtubules in chromosomal spindle fibres irradiated singly or doubly with ultraviolet light.

Areas of reduced birefringence (ARBs) produced by ultraviolet microbeam irradiation are areas of depolymerized microtubules. ARBs probably move poleward either by microtubule subunit addition at the kinetochore and loss at the pole, or by microtubule subunit addition at one edge of the ARB and loss from the other edge. In this paper we have used two approaches to try to distinguish between these two models. First, we determined whether the edges of the ARB move at the same rate; if ARB motion is due solely to addition at the kinetochore and loss at the pole, with the ARB edges unable to exchange subunits, then the two edges of each ARB should move at the same rate. On the other hand, if the exchange is at the ARB edges, then, from data from microtubules in vitro, the poleward edge should move much faster than the kinetochoreward edge. We found that the two edges of the ARB move at the same rate about half the time, but half the time they do not. Second, we studied the behaviour of two ARBs on a single fibre. If ARB motion is due solely to subunit addition at the kinetochore and loss at the pole, then the two ARBs must move poleward together. We found that after two ARBs are formed on a single fibre the region between the ARBs is unstable and rapidly depolymerizes. These results do not fit either model and suggest that influences of kinetochores and poles or other factors need to be considered that are not duplicated in experiments on microtubules in vitro.

Identifying the site of microtubule polymerization during regrowth of UV-sheared kinetochore fibres using antibodies against acetylated alpha-tubulin.

Areas of reduced birefringence (ARBs) produced on chromosomal fibres of crane-fly spermatocyte spindles by ultraviolet microbeam irradiation move poleward. The ARB is due to the depolymerization of the microtubules in that area, and its poleward motion is due in part to the lengthening of that part of the kinetochore fibre which is left attached to the kinetochore after shearing the microtubules. We tested whether the lengthening of this fibre is due to the polymerization of microtubules at the growing edge of the ARB by staining growing fibres in irradiated spindles with antibodies to tubulin and to acetylated tubulin. We have previously argued that newly-polymerized kinetochore microtubules are not acetylated, whereas older kinetochore microtubules are (Wilson & Forer, 1989). Therefore we expected to see an absence of staining with antibodies to acetylated tubulin at the edge of the ARB if microtubules were polymerizing there. There is no absence of staining, however, which suggests that growth of the sheared microtubules does not occur at the ARB edge. Other possibilities are discussed.

From megakaryocytes to platelets: platelet morphogenesis takes place in the bloodstream.

We studied megakaryocyte processes formed in rat bone marrow and spleen, using both the transmission and scanning electron microscopes. Some processes were bulky, others slender and beaded. The bulky megakaryocyte processes developed a specialized arrangement of organelles at the site at which they entered the lumen: filaments present around the outside of the process seemed to support a central cylinder in which organelles flowed along microtubules. Megakaryocyte processes were present in platelet-rich plasma from both human and rat blood. When followed in living preparations, bulky processes developed pointed tips, elongated, and became slender and beaded. Fusiform proplatelets also were present in the platelet rich plasma, with pointed tips at both ends of what appeared to be single "beads"; we assume that the long, beaded megakaryocyte processes would have fragmented were we to have had proper culture conditions. The straight, shorter fusiform proplatelets in living preparations underwent characteristic curving and bending motions, eventually forming disk-shaped cells which sometimes had appendages. This behaviour suggests that the entire process of platelet morphogenesis takes place in plasma: megakaryocyte processes first elongate, then bead and fragment, and then curve and fuse to form disk-shaped platelets. This interpretation is strengthened by finding in freshly isolated plasma many of the shapes seen in the transformations studied in living cell preparations. The megakaryocyte processes and the proplatelets seemed to appear in plasma with a periodicity related to light and dark cycles--that is, with a circadian rhythm. In particular, megakaryocyte processes appear in human blood within a few hours after sunrise; we argue that this might be related to similar peak periods for heart attacks.

Evidence that actin and myosin are involved in the poleward flux of tubulin in metaphase kinetochore microtubules of crane-fly spermatocytes.

We studied the effects of various drugs on the poleward flux of tubulin in kinetochore microtubules in metaphase-I crane-fly spermatocytes. We used as a measure of tubulin flux a 'gap' in acetylation of kinetochore microtubules immediately poleward from the kinetochore; the 'gap' is caused by a time lag between incorporation of new tubulin subunits at the kinetochore and subsequent acetylation of those subunits as they flux to the pole. We confirmed that the 'gap' is due to flux by showing that the 'gap' disappeared when cells were treated briefly with the anti-tubulin drug nocodazole, which decreases microtubule dynamics. The 'gap' disappeared when cells were treated for 10 minutes with anti-actin drugs (cytochalasin D, latrunculin B, swinholide A), or with the anti-myosin drug 2,3-butanedione 2-monoxime. The 'gap' did not disappear when cells were treated with the actin stabilizing drug jasplakinolide. We studied whether these drugs altered spindle actin. We used fluorescent phalloidin to visualize spermatocyte F-actin, which was associated with kinetochore spindle fibers as well as the cell cortex, the contractile ring and finger-like protrusions at the poles. Spindle F-actin was no longer seen after cells were treated with cytochalasin D, swinholide A or a high concentration of latrunculin B, whereas a low concentration of latrunculin B, which did not completely remove the 'gap', caused reduced staining of spindle actin. Neither 2,3-butanedione 2-monoxime nor jasplakinolide altered spindle actin. These data suggest that an actomyosin mechanism drives the metaphase poleward tubulin flux.

Action spectrum for changes in spindle fibre birefringence after ultraviolet microbeam irradiations of single chromosomal spindle fibres in crane-fly spermatocytes.

Single chromosomal spindle fibres in Nephrotoma suturalis (crane-fly) spermatocytes in metaphase and anaphase were irradiated with monochromatic ultraviolet light focussed to a 2 micrometer spot. In cells in both metaphase and anaphase either the birefringence of the irradiated spindle fibre was altered in the irradiated region, or there was no change, depending on the dose and wavelength of ultraviolet light used for the irradiation. When there was an area of reduced birefringence (ARB), it moved poleward regardless of whether the associated chromosome moved poleward. When cells were irradiated in early metaphase they remained in metaphase until the ARB reached the pole. In some cells irradiated in late metaphase the chromosomes began anaphase before the ARB reached the pole; in many such cells anaphase was abnormal in that all six half-bivalents separated at the start of anaphase but none moved polewards. In all cases the ARB moved poleward at the same speed as subsequent chromosome movement; that is, at about 0.8 micrometer/min. In cells irradiated in anaphase, spindle fibre birefringence was reduced independently of blockage of chromosome movement. Because birefringence and movement were altered independently there were four classes of results: (1) in some cases there was no effect on the movement of the chromosome associated with the irradiated spindle fibre and no effect on the birefringence of the irradiated spindle fibre. (2)In some cases, primarily with 260 nm wavelength light, there was no effect on the movement of the chromosome associated with the irradiated spindle fibre and there was an effect on the birefringence of the irradiated spindle fibre. (3) In some cases, primarily with 290 nm wavelength light, there was an effect on the movement of the chromosome associated with the irradiated spindle fibre and no effect on the birefringence of the irradiated spindle fibre. (4) In some cases, primarily with 270 nm and 280 nm wavelength light, there was an effect on the movement of the chromosomes associated with the irradiated spindle fibre and there was an effect on the birefringence of the irradiated spindle fibre. The action spectrum for reducing spindle fibre birefringence in crane-fly spermatocytes had two peaks, one at 260 nm and the other, less sensitive, at 280 nm. For irradiations at 270 nm, 280 nm and 290 nm, five to fifty times more energy was needed to reduce spindle fibre birefringence than to stop chromosome movement, but for irradiations at 260 nm five times less energy was needed to reduce spindle fibre birefringence than to stop chromosome movement. The action spectrum for reducing spindle fibre birefringence is quite different from that for stopping chromosome movement.

Video digitizer analysis of birefringence along the lengths of single chromosomal spindle fibres. I. Description of the system and general results.

A new system, based on a video digitizer interfaced to a microcomputer, has been developed to quantify birefringence of individual chromosomal spindle fibres from videotaped images of spindles. (The system also can be used for any other purpose that requires the analysis of video intensities.) Retardations along the lengths of single chromosomal spindle fibres have been studied throughout metaphase and anaphase in cells kept at constant temperatures. The instrumental readings are accurate to within less than 0.06 nm retardation, but operationally the retardation values along a single chromosomal spindle fibre can vary by up to 0.15 nm, primarily because of variation in operator definition of the spindle fibre. Retardations vary with position along the fibre. During anaphase the retardations along a given chromosomal spindle fibre do not move poleward, but rather change as if the oriented material is disorganized at the kinetochore. The retardation at the kinetochore of a chromosomal spindle fibre does not change during anaphase, except for nonpredictable jumps of 20-30% that sometimes occur. Thus there is no 'decay of birefringence' during anaphase, such as has been described in other species. In this regard our data, that pertain only to single chromosomal spindle fibres, differ from those previously published; we argue that this is because the published data deal with mixtures of chromosomal and continuous spindle fibres, and because changes in birefringence can appear to occur, artefactually, when measurements of birefringence are made at a single spot in a spindle.

Video digitizer analysis of birefringence along the lengths of single chromosomal spindle fibres. II. Crane-fly spermatocyte chromosomal spindle fibres are not temperature-labile.

Retardations were measured along the lengths of single chromosomal spindle fibres, from metaphase through anaphase, from video-taped images of crane-fly spermatocytes incubated at various temperatures (4-30 degrees C). These measurements were made using a video digitizer interfaced to a microcomputer. Over most of the range of temperatures at which normal anaphase movement occurs the chromosomal spindle fibres are not temperature-labile. The non-specific and continuous fibre birefringence is temperature-labile, however. The data are discussed with respect to the 'dynamic equilibrium' model of anaphase chromosome movement. We conclude that, since single chromosomal fibre birefringence is not temperature-labile over most of the range of temperatures at which normal anaphase chromosome movement occurs, these data do not support the dynamic equilibrium model of anaphase chromosome movement.

Irradiations of rabbit myofibrils with an ultraviolet microbeam. II. Phalloidin protects actin in solution but not in myofibrils from depolymerization by ultraviolet light.

We tested whether phalloidin protects actin in myofibrils from depolymerization by ultraviolet light (UV). I bands in glycerinated rabbit psoas myofibrils were irradiated with a UV microbeam in the presence and absence of phalloidin. We used the retention of contractility of the irradiated I band as the assay for protection of actin by phalloidin, since previous experiments indicated that UV blocks contraction of an irradiated I band by depolymerizing the thin filaments. The I bands of myofibrils incubated in phalloidin were as sensitive to UV as control I bands, indicating that phalloidin did not protect the thin filaments. However, phalloidin did protect F-actin in solution from depolymerization by UV. This apparent contradiction between F-actin in myofibrils and F-actin in solution was resolved by observing unirradiated myofibrils that were stained with rhodamine-phalloidin. It was found that phalloidin does not bind uniformly to the thin filaments, though as the fluorescence image is observed over time the staining pattern changes until it does appear to bind uniformly. We conclude that phalloidin does not protect F-actin in myofibrils from depolymerization by UV because it does not bind uniformly to the filaments.

The role of the phosphatidylinositol cycle in mitosis in sea urchin zygotes. Lithium inhibition is overcome by myo-inositol but not by other cyclitols or sugars.

We have investigated the role of the phosphatidylinositol (PI) cycle in cellular events between fertilization and first cleavage in zygotes of the sea urchin Lytechinus pictus. The effects of lithium were studied: The lithium-induced changes due to effects on the PI cycle were reversed by myo-inositol, the next step in the cycle after the lithium block, but were not reversed by scyllo-inositol or other cyclitols or sugars. In this way we implicated the PI cycle in the formation of streak birefringence, in nuclear membrane breakdown, in onset of anaphase, and in cytokinesis. With respect to karyokinesis, mitotic apparatus (MA) structure often was altered when the PI cycle was blocked, and anaphase was blocked when the PI cycle was blocked. For all stages, the effects of 400 mM lithium were overcome by 10-100 microM myo-inositol. Excess myo-inositol potentiated the effect of lithium on MA structure (and on cytokinesis), suggesting that there is a negative feedback loop in the control of the PI cycle.