Regulation of Tubulin Organization During Meiosis

Meiotic spindle formation in Spisula solidissima oocytes hasbeen studied in vivo and in vitro. Measurements were made ofpolymerized tubulin content during the first meiotic division.The amount of polymer was high prior to activation of the eggs,fell to a minimum of about 5 min after activation and at 15min (metaphase) returned to approximately its initial value.The polymerized tubulin in the unactivated eggs appears to beorganized into granular spheres about 10–20 microns indiameter attached to the egg cortex. This particle containsfew microtubules but is composed primarily of a granular matrixand fibrous material. The granular matrix may be a polymorphicaggregate of tubulin and could be a storage form of tubulinor an intermediate in microtubule assembly. The polymerization and organization of microtubules has beenstudied in vitro, using crude homogenates of Spisula oocytes.Microtubules can be formed in homogenates of both activatedand unactivated eggs; however, in homogenates of eggs in whichnuclear membrane breakdown has occurred, microtubules form arounda central phase dense particle resulting in a structure whichresembles a spindle aster. The central particle appears to bea microtubule organizing center (MTOC). The MTOC can be pelleledby centrifugation and will induce aster formation when remixedwith the supernatant. Aster formation can be obtained usingsupernatants prepared from either activated or unactivated eggs,while the pellet must be obtained from activated eggs. Thus,tubulin subunits appear to be capable of spindle formation atall stages, while MTOC formation or activation does not occuruntil about the time of nuclear membrane breakdown.     

GROWTH AND LABILITY OF CHAETOPTERUS OOCYTE MITOTIC SPINDLES ISOLATED IN THE PRESENCE OF PORCINE BRAIN TUBULIN

Purified tubulin solutions stabilized and augmented the birefringence (BR) of isolated Chaetopterus spindles. Tubulin was extracted from pig brain tissue in cold PEG buffer (0.1 M piperazine-N-N'-bis[2-ethane sulfonic acid], 1 mM ethylene bis-[oxyethylenenitrilo]tetraacetate, [EGTA], 2.5 mM guanosine triphosphate, [GTP], pH 6.94, at 25°C), and purified by two cycles of a reversible, temperature-dependent assembly-disassembly procedure. The spindle BR of the meiotic metaphase-arrested oocytes of Chaetopterus decreased linearly at a rate of 1.5 nm/min when perfused with PEG buffer without tubulin. In this hypotonic, calcium-chelating solution, the cell lysed within 1.5 min, and after a brief, transient rise, the BR disappeared in ca. 4 min from the time of buffer application. Cells perfused with tubulin in PEG buffer also showed BR decay at the same rate until cell lysis. Immediately upon cell lysis the spindle BR increased, initially at ca. 2.3 nm/min and then more slowly until the BR attained or exceeded intact cell values. Spindle and asters grew considerably larger than those in intact cells. From the kinetics of the transient BR increase after lysis, we infer that, initially, Chaetopterus cytoplasmic tubulin contributes to increased BR; further augmentation required added pig brain tubulin and most probably reflects the addition and incorporation of heterologous porcine tubulin into the spindle and asters. Isolated, augmented spindles depolymerized rapidly at 6°C. Upon return to 23°C, spindle BR returned slowly in tubulin-PEG. The BR of the isolates also decayed in solutions containing calcium ions 2.5 mM in excess of the EGTA. However, the isolates did not respond, or responded very slowly, to 1 mM colchicine or Colcemid and to dilution of tubulin with PEG solution. Microinjection into Chaetopterus oocytes of tubulin-PEG, but not PEG alone, enhanced spindle and aster BR which reversibly disappeared upon chilling the cell.     

In vitro polymerization of microtubules into asters and spindles in homogenates of surf clam eggs

The eggs of the surf clam Spisula solidissima were artificially activated, homogenized at various times in cold 0.5 M MES buffer, 1mM EGTA at pH 6.5, and microtubule polymerization was induced by raising the temperature to 28 degrees C. In homogenates of unactivated eggs few microtubules form and no asters are observed. By 2.5 min after activation microtubules polymerize in association with a dense central cylinder, resulting in the formation of small asterlike structures. By 4.5 min after activation the asters formed in vitro contain a distinct centriole, and microtubules now radiate from a larger volume of granular material which surrounds the centriole. By 15 min (metaphase I) the granular material is more disperse and only loosely associated with the centriole. Microtubules are occasionally observed which appear to radiate directly from one end of the centriole. The organizing center can be partially isolated by centrifugation of homogenates of metaphase eggs and will induce aster formation if mixed with tubulin from either activated or unactivated eggs. Pretreatment of the eggs with colchicine does not prevent the formation of a functional organizing center. Complete spindles can also be obtained under polymerizing conditions by either homogenizing the eggs directly into warm buffer or by adding a warm high-speed supernate to spindles which have been isolated in a microtubule stabilizing medium. Extensive addition of new tubulin occurs onto the isolated spindles, resulting primarily in growth of astral fibers, although there occasionally appears to be growth of chromosomal fibers and of pole-to-pole fibers. Negatively stained aster microtubules have a strong tendency to associate side by side, and under some conditions distinct cross bridges can be observed. However, under other conditions large numbers of 300-400-A particles surround the microtubules; the presence of stain between particles can give the appearance of cross bridges.     

TRANSIENT LOCALIZATION OF γ-TUBULIN AROUND THE CENTRIOLES IN THE NUCLEAR DIVISION OF BOERGESENIA FORBESII (SIPHONOCLADALES, CHLOROPHYTA)

Mitosis in Boergesenia forbesii (Harvey) Feldman was studied by immunofluorescence microscopy using anti-β–tubulin, anti-γ–tubulin, and anti-centrin antibodies. In the interphase nucleus, one, two, or rarely three anti-centrin staining spots were located around the nucleus, indicating the existence of centrioles. Microtubules (MTs) elongated randomly from the circumference of the nuclear envelope, but distinct microtubule organizing centers could not be observed. In prophase, MTs located around the interphase nuclei became fragmented and eventually disappeared. Instead, numerous MTs elongated along the nuclear envelope from the discrete anti-centrin staining spots. Anti-centrin staining spots duplicated and migrated to the two mitotic poles. γ–Tubulin was not detected at the centrioles during interphase but began to localize there from prophase onward. The mitotic spindle in B. forbesii was a typical closed type, the nuclear envelope remaining intact during nuclear division. From late prophase, accompanying the chromosome condensation, spindle MTs could be observed within the nuclear envelope. A bipolar mitotic spindle was formed at metaphase, when the most intense staining of γ-tubulin around the centrioles could also be seen. Both spindle MT poles were formed inside the nuclear envelope, independent of the position of the centrioles outside. In early anaphase, MTs between separating daughter chromosomes were not detected. Afterward, characteristic interzonal spindle MTs developed and separated both sets of the daughter chromosomes. From late anaphase to telophase, γ-tubulin could not be detected around the centrioles and MT radiation from the centrioles became diminished at both poles. γ-Tubulin was not detected at the ends of the interzonal spindle fibers. When MTs were depolymerized with amiprophos methyl during mitosis, γ-tubulin localization around the centrioles was clearly confirmed. Moreover, an influx of tubulin molecules into the nucleus for the mitotic spindle occurred at chromosome condensation in mitosis.     

Interconversion of metaphase and interphase microtubule arrays, as studied by the injection of centrosomes and nuclei into Xenopus eggs

We have designed experiments that distinguish centrosomal , nuclear, and cytoplasmic contributions to the assembly of the mitotic spindle. Mammalian centrosomes acting as microtubule-organizing centers were assayed by injection into Xenopus eggs either in a metaphase or an interphase state. Injection of partially purified centrosomes into interphase eggs induced the formation of extensive asters. Although centrosomes injected into unactivated eggs (metaphase) did not form asters, inhibition of centrosomes is not irreversible in metaphase cytoplasm: subsequent activation caused aster formation. When cytoskeletons containing nuclei and centrosomes were injected into the metaphase cytoplasm, they produced spindle-like structures with clearly defined poles. Electron microscopy revealed centrioles with nucleated microtubules. However, injection of nuclei prepared from karyoplasts that were devoid of centrosomes produced anastral microtubule arrays around condensing chromatin. Co-injection of karyoplast nuclei with centrosomes reconstituted the formation of spindle-like structures with well-defined poles. We conclude from these experiments that in mitosis, the centrosome acts as a microtubule-organizing center only in the proximity of the nucleus or chromatin, whereas in interphase it functions independently. The general implications of these results for the interconversion of metaphase and interphase microtubule arrays in all cells are discussed.     

THE REPLICATION TIME AND PATTERN OF THE LIVER CELL IN THE GROWING RAT

Three-week-old male rats of the Wistar strain were given tritiated thymidine, 1 µc/gm body weight, intraperitoneally and were killed at intervals from 0.25 to 72 hours later. Autoradiographs were made from 5 µ sections, stained by the Feulgen method. The replication time and its component intervals were determined from the scoring of the labeling of interphase nuclei as well as of prophase, metaphase, anaphase, and telophase nuclei. Absorption of the intraperitoneally injected label is rapid and is attended by "flash" labeling during interphase. The results show that at any one time about 4 per cent of the liver cells are synthesizing DNA preliminary to cell division. These cells alternate with waves of other cells and it is estimated that about 10 per cent of the liver cell population is engaged in cell duplication. The replication time is about 21.5 hours, and its component intervals occupy the following times: DNA synthesis, 9 hours; post-DNA synthesis gap, 0.50 hour; prophase, 1.3 hours; metaphase, 1.0 hour; anaphase, 0.4 hour; telophase, 0.3 hour; postmitosis gap, 9.0 hours. A group of liver cells has been recorded in at least 3 successive replication cycles.     

Post-translational modifications of tubulin and the dynamics of microtubules in mouse oocytes and zygotes

The distribution of post-translationally modified forms of tubulin has been studied in mouse oocytes arrested in meiotic metaphase II and in interphase eggs after fertilisation. Tyrosinated and acetylated microtubules are present in the meiotic spindle but detyrosinated ones are not. Acetylation only occurs in the most stable subpopulation of microtubules in the spindles ("pole to kinetochore"). After fertilisation, many microtubules of the interphase array become acetylated, but detyrosination occurs only at a very low level.     

A THERMODYNAMIC ANALYSIS OF MITOTIC SPINDLE EQUILIBRIUM AT ACTIVE METAPHASE

The mitotic apparatus of first-division metaphase eggs of the sea urchin Strongylocentrotus drobachiensis was observed by means of polarization microscopy under controlled temperature conditions. Eggs were fertilized and grown at two temperature extremes in order to produce two different sizes of available spindle pool. Slow division time allowed successive samples of such cells to be observed at the same point in metaphase but at different equilibrium temperatures, yielding curves of metaphase equilibrium birefringence vs. observational temperature. Using the plateau value of birefringence at higher temperatures as a measure of total available spindle pool and the observed birefringence at lower temperatures as a measure of polymerized material at equilibrium, the spindle protein association was evaluated according to the method of Inoué. Both pool conditions produced linear van't Hoff functions. Analysis of these functions yielded enthalpy and entropy changes of +55–65 kcal/mol and +197–233 entropy units (eu), respectively. These values for active mitotic metaphase are quite comparable to those obtained by Inoué and co-workers for arrested meiotic metaphase cells. When other equilibrium treatments were considered, the best fit to the experimental data was still that of Inoué, a treatment which theoretically involves first-order polymerization and dissociation kinetics. Treatment of metaphase cells with D₂O by direct immersion drove the equilibrium to completion regardless of temperature, attaining or exceeding a birefringence value equal to the cell's characteristic pool size; perfusion with D₂O appeared to erase the original temperature-determined pool size differences for the two growth conditions, attaining a maximum value characteristic of the larger pool condition. These data confirm Inoué's earlier contention that D₂O treatment can modify the available spindle pool.     

ELECTRON MICROSCOPIC STUDIES OF MITOSIS IN AMEBAE : II. The Giant Ameba Pelomyxa carolinensis

Dividing nuclei from the giant ameba Pelomyxa carolinensis were fixed in osmium tetroxide solutions buffered with veronal acetate to pH 8.0. If divalent cations (0.002 M calcium, magnesium, or strontium as chlorides) were added to the fixation solution, fibrils that are 14 mµ in diameter and have a dense cortex are observed in the spindle. If the divalent ions were omitted, oriented particles of smaller size are present and fibrils are not obvious. The stages of mitosis were observed and spindle components compared. Fibrils fixed in the presence of calcium ions are not so well defined in early metaphase as later, but otherwise have the same diameter in the late metaphase, anaphase, and early telophase. Fibrils are surrounded by clouds of fine material except in early telophase, when they are formed into tight bundles lying in the cytoplasm unattached to nuclei. Metaphase and anaphase fibrils fixed without calcium ions are less well defined and are not observably different from each other. The observations are consistent with the concept that spindle fibrils are composed of polymerized, oriented protein molecules that are in equilibrium with and bathed in non-oriented molecules of the same protein. Partially formed spindle fibrils and ribosome-like particles were observed in the mixoplasm when the nuclear envelope had only small discontinuities. Remnants of the envelope are visible throughout division and are probably incorporated into the new envelope in the telophase. Ribosome-like particles are numerous in the metaphase and anaphase spindle but are not seen in the telophase nucleus, once the envelope is reestablished, or in the interphase nucleus.     

Distribution of fluorescently labeled tubulin injected into sand dollar eggs from fertilization through cleavage

Porcine brain tubulin labeled with fluorescein isothiocyanate (FITC) was able to polymerize by itself and co-polymerize with tubulin purified from starfish sperm flagella. When we injected the FITC-labeled tubulin into unfertilized eggs of the sand dollar, Clypeaster japonicus, and the eggs were then fertilized, the labeled tubulin was incorporated into the sperm aster. When injected into fertilized eggs at streak stage, the tubulin was quickly incorporated into each central region of growing asters. It was clearly visualized that the labeled tubulin, upon reaching metaphase, accumulated in the mitotic apparatus and later disappeared over the cytoplasm during interphase. The accumulation of the fluorescence in the mitotic apparatus was observed repeatedly at successive cleavage. After lysis of the fertilized eggs with a microtubule-stabilizing solution, fluorescent fibrous structures around the nucleus and those of the sperm aster and the mitotic apparatus were preserved and coincided with the fibrous structures observed by polarization and differential interference microscopy. We found the FITC-labeled tubulin to be incorporated into the entire mitotic apparatus within 20-30 s when injected into the eggs at metaphase or anaphase. This rapid incorporation of the labeled tubulin into the mitotic apparatus suggests that the equilibrium between mitotic microtubules and tubulin is attained very rapidly in the living eggs. Axonemal tubulin purified from starfish sperm flagella and labeled with FITC was also incorporated into microtubular structures in the same fashion as the FITC-labeled brain tubulin. These results suggest that even FITC-labeled heterogeneous tubulins undergo spatial and stage-specific regulation of assembly-disassembly in the same manner as does sand dollar egg tubulin.     

INDUCTION OF PROPHASE IN INTERPHASE NUCLEI BY FUSION WITH METAPHASE CELLS

Fusion of an interphase cell with a metaphase cell results in profound changes in the interphase chromatin that have been called "chromosome pulverization" or "premature chromosome condensation" In addition to the usual light microscopy, the nature of the changes has been investigated in the present study with electron microscopy and biochemical techniques Metaphase and interphase cells were mixed and fused at 37°C by means of ultraviolet-inactivated Sendai virus. After cell fusion, morphological changes in interphase nuclei occurred only in binucleate cells which contained one intact set of metaphase chromosomes Irrespective of the nuclear stage at the time of cell fusion, the morphologic changes that occurred 5–20 min later simulated very closely a sequence of events that characterizes the normal G₂-prophase transition. Radioautography revealed that, late in the process, substantial amounts of RNA and probably protein were transferred from the interphase nucleus into the cytoplasm of fused cells. Thus, the findings indicate the existence in metaphase cells of factor(s) which are capable of initiating biochemical and morphological events in interphase nuclei intrinsic to the normal mitotic process.     

Experimental manipulation of the amount of tubulin available for assembly into the spindle of dividing sea urchin eggs

Spindle assembly is studied in the eggs of the sea urchin Lytechinus variegatus by experimentally varying the amount of polymerizable tubulin within the egg. Aliquots of fertilized eggs from the same female are individually pulsed for 1-6 min with 1 X 10(-6) M Colcemid at least 20 min before first nuclear envelope breakdown. This treatment inactivates a portion of the cellular tubulin before the spindle is formed. Upon entering mitosis, treated eggs form functional spindles that are reduced in length and birefringent retardation but not width. With increased exposure to Colcemid, the length and retardation of the metaphase spindles are progressively reduced. Similar results are obtained by pulsing the eggs with Colcemid before fertilization, which demonstrates that the tubulin found in unfertilized sea urchin eggs is later used in spindle formation. Spindles, once assembled, are responsive to increases in the amount of polymerizable tubulin within the cell. Rapid increases in the amount of polymerizable tubulin within a Colcemid-treated cell can be experimentally effected by irradiating the cells with 366-nm light. This treatment photochemically inactivates the Colcemid, thereby freeing the tubulin to polymerize. Upon irradiation, the small prometaphase spindles of Colcemid-treated cells immediately increase in length and retardation. In these irradiated cells, spindle length and retardation increase as much as four times faster than they do during prometaphase for normal spindles. This suggests that the rate of the normal prometaphase increase in retardation and spindle size may be determined by factors other than the maximum rate of tubulin polymerization in the cell.     

THE FINE STRUCTURE OF THE PIGMENT EPITHELIUM IN THE ALBINO RAT

In this report, particular attention is paid to the inclusion bodies found in the apical cytoplasm of the pigment epithelial cell. These bodies are of variable size and form. The smallest (0.4 µ diameter) consist of a granular matrix enclosed by a single membrane, and are similar to the lysosomes of hepatic cells. Larger inclusion bodies contain areas of lamellated material in addition to granular matrix. The largest particles seen (2 µ diameter) are almost entirely lamellar. These different forms seem closely related, for it is possible to find all transitional stages between the smallest and largest particles. The relationship between the lamellar inclusion bodies and the rod outer segments is discussed.     

Origin of the mitotic spindle in onion root cells

Summary Immunofluorescence studies on microtubule arrangement during the transition from prophase to metaphase in onion root cells are presented. The prophase spindle observed at late preprophase and prophase is composed of microtubules converged at two poles near the nuclear envelope; thin bundles of microtubules are tracable along the nuclear envelope. Prior to nuclear envelope breakdown diffuse tubulin staining occurs within the prophase nuclei. During nuclear envelope breakdown the prophase spindle is no longer identifiable and prominent tubulin staining occurs among the prometaphase chromosomes. Patches of condensed tubulin staining are observed in the vicinity of kinetochores. At advanced prometaphase kinetochore bundles of microtubules are present in some kinetochore regions. At metaphase the mitotic spindle is mainly composed of kinetochore bundles of microtubules; pole-to-pole bundles are scarce. Our observations suggest that the prophase spindle is decomposed at the time of nuclear envelope breakdown and that the metaphase spindle is assembled at prometaphase, with the help of kinetochore nucleating action.     

CONCERNING THE HEREDITARY ADAPTATION OF ORGANISMS TO HIGHER TEMPERATURE

1. Imagos of Drosophila raised at temperatures of from 12–28.5°C. when placed at any temperature from 15–32.5°C. produce eggs which develop normally at these temperatures. 2. Imagos raised at temperatures of from 29–32.5° and then kept permanently within these temperatures produce eggs which do not develop. 3. Imagos raised at from 28.5–32.5°C. and then placed at temperatures of from 12–25°C. produce eggs which develop normally. 4. Imagos raised at from 28.5–32.5°C. placed at 15–25°C. for 24 hours or longer and then put back into a temperature of from 28.5–32.5°C., produce eggs which will develop at the latter temperature. 5. There is no evidence of any hereditary adaptation to higher temperatures.     

FURTHER OBSERVATIONS ON THE CLUSTERS OF GRANULAR MATERIAL AROUND THE CENTRIOLE IN THE SEA URCHIN EGG: CHANGES IN DISTRIBUTION DURING MITOSIS*

Changes in the distribution of pericentriolar material, which was called “clusters of granular material”, in a previous paper were observed during mitosis of the sea urchin egg by electron microscopy using thick sections. At prophase, small clusters in an early stage of formation were observed near the nucleus. At prometaphase, the clusters appeared to aggregate loosely at the poles of the spindle. They formed large masses at metaphase, while at late anaphase they became reduced in size and formed an array at right angles to the spindle axis. Some clusters still remained near the karyomeres at telophase and then became closely associated with the daughter nucleus. The clusters were closely associated with the astral microtubules and spindle microtubules at prophase and prometaphase, respectively. The granular material is suggested to be a nucleating site of microtubule assembly during mitosis.     

MITOSIS IN THE FUNGUS THRAUSTOTHECA CLAVATA

The ultrastructure of mitosis is described in Thraustotheca clavata, an oömycete fungus. An intranuclear spindle develops between differentiated regions of the nuclear envelope which move apart, each associated with 180° oriented centriole pairs. The spindle contains low numbers of continuous and interdigitating microtubules in addition to chromosomal microtubules. Each kinetochore is attached to only one microtubule. Serial section analysis shows that at meiosis there are probably 12 chromosomes in the diploid nucleus, yet at mitosis the methods utilized in the present study suggest that there may be less than 12 kinetochores connected to each pole. At mitosis many of the kinetochores within a given spindle are not arranged in opposite pairs. The behavior of the spindle microtubules during mitosis is comparable to that of higher organisms but the rarity of short intertubular distances appears to preclude significant force generation by means of intertubular bridge mechanisms. Evidence is presented for a nuclear envelope-microtubule interaction which is capable of generating shear forces during both mitosis and interphase nuclear movements.     

THE MITOTIC APPARATUS : Fine Structure of the Isolated Unit

The fine structure of the mitotic apparatus isolated from the sea urchin egg has been investigated. The isolation was accomplished by lysis of metaphase eggs in a 1 M solution of hexanediol, buffered at pH 6. The fine structure of the isolated apparatus was studied after fixation with osmium tetroxide directly in the isolation medium. The spindle is composed of fine fibrils, approximately 20 mµ in diameter, which appear tubular. Similar fibrils, radially oriented, are found in the aster. If the isolated mitotic apparatus is exposed to water at pH 6 before fixation, the structure is considerably modified. The most pronounced effects are an increase in the number of large membrane-bounded vesicles and in the amount of free granular material present. The conditions necessary for the fixation of the mitotic apparatus in dividing cells are discussed in the light of these observations on the isolated unit.     

ELECTRON MICROSCOPY OF MITOSIS IN A RADIOSENSITIVE GIANT AMOEBA

Various aspects of the ultrastructure of the dividing nuclei in the large radiosensitive amoeba Pelomyxa illinoisensis are demonstrated. Evidence of nuclear envelope breakdown is presented, and membrane fragments are traced throughout metaphase to envelope reconstruction in anaphase and telophase. Annuli in the nuclear envelope and its fragments are shown throughout mitosis. During metaphase and anaphase some 15 to 20 mitochondria are aligned at each end of the spindle, and are called polar mitochondria. The radioresistant amoebae Pelomyxa carolinensis and Amoeba proteus do not have polar mitochondria, and Pelomyxa illinoisensis is unique in this regard. The shape of the P. illinoisensis interphase nucleoli differs from that in the two radioresistant species, and certain aspects of nucleolar dissolution in the prophase vary. Helical coils in the interphase nucleoplasm are similar to those in the radioresistant amoebae. A "blister" phase in the flatly shaped telophase nuclei of P. illinoisensis is described which is interpreted to be the result of a rapid nuclear expansion leading to the formation of the normal spherical interphase nuclei.