Cytological changes and DNA and protein synthesis in parthenogenetically activated sea urchin eggs

Summary The present study deals with cytological observations, DNA and protein synthesis in artificially activated sea urchin eggs. The eggs were activated by means of Loeb's double treatment with butyric acid and hypertonic sea water. Most of the eggs ofHemicentrotus pulcherrimus divided when the chromosomes duplicated after formation of the first monaster and other eggs divided at a later cell cycle. In the eggs ofTemnopleurus toreumaticus, however, haploid division at the first cell cycle was observed predominantly.Activated eggs that were treated for 25 min with hypertonic sea water showed a marked uptake of³H-thymidine during the two periods of 30–40 min and 90–100 min after the double treatment. These periodic changes in the³H-thymidine uptake paralleled morphological changes within the nucleus. However, these periods of increased uptake were not observed in the eggs treated with hypertonic sea water for 60 min. During exposure to hypertonic sea water, the³H-thymidine-uptake by eggs activated with butyric acid decreased gradually. When the uptake of¹⁴C-valine by eggs was measured, a very low level was seen in unfertilized eggs. The level of uptake increased strikingly when the eggs were activated with butyric acid but was suppressed by the hypertonic treatment. However, removal of the eggs to sea water allowed the uptake to return to the former high level. This pattern suggests that the hypertonic treatment has an inhibitory effect on the synthesis of protein (or enzymes) which obstruct cleavage induction.     

Effects of DNP- and NaN3-pretreatment on cleavage of the sea urchin egg

Unfertilized eggs of the sea urchin, Hemicentrotus pulcherrimus were treated with DNP-sea water (M/500 - M/2,000) or with NaN₃-sea water (M/50 - M/800) for 15 – 90 minutes, and 2 hours later they were inseminated. Such a treatment induced acceleration of the first cleavage, and the eggs had a tendency to divide directly into 4 cells in the first cleavage cycle. In another series of experiments, unfertilized eggs were developed parthenogenetically by Loeb 's double-treatment after the above-mentioned treatment. It was found that these eggs divided earlier than the controls and that they developed into swimming blastulae in higher percentages. From the results described in the present and other papers it is suggested that DNP and NaN₃ have effects to activate eggs parthenogenetically and also to induce division of the centrioles, closely relating to the cleavage.     

EFFECTS OF BENZIMIDAZOLE ON CLEAVAGE OF THE SEA URCHIN EGG*

Unfertilized eggs of sea urchins were treated with benzimidazole. They were fertilized after being kept in normal sea water for a certain period. It was found that the first cleavage occurred much earlier than in the control. The eggs had a tendency to cleave directly into 3 or 4 cells. Benzimidazole induced some visible changes in unfertilized eggs, which was considered to be the result of an insufficient activation. Benzimidazole was found to have the same effect as hypertonic solution has in Loeb's “double treatment” method for artificial parthenogenesis. When eggs activated with butyric acid were treated with benzimidazole instead of hypertonic solution, they cleaved in a high percentage.     

Acceleration of the Cleavage in Sea Urchin Eggs by Treatmentswith Local Anesthetics (I) Procaine Treatment*

Unfertilized sea urchin eggs were pre-treated with 2–10 mM procaine sea water for 10 min and then fertilized 5 min later. These eggs hatched about 1–1.5 hr earlier than the control eggs. This acceleration of hatching seems to be the result of a reduction in the individual cleavage cycles. In the second series of experiments, eggs were inseminated at 5, 30 and 60 min after the procaine treatments. In this case, the rate of accelerated cleavage decreased gradually, as the intervals between the treatments and insemination were extended. Next, the minimum time-length of procaine treatment to accelerate cleavage was determined. When eggs were immersed in procaine for 1 min, cleavage was accelerated as in the case of 10 min-treatment, although acceleration to the same degree required higher concentrations of procaine solution. When fertilized eggs were post-treated with procaine, cleavage was also accelerated, but both the rate of acceleration and the effective concentrations decreased with time after fertilization.     

Acceleration of the Cleavage in Sea Urchin Eggs by Treatments with Local Anesthetics (II) Treatments with Some Other Local Anesthetics than Procaine*

Unfertilized sea urchin eggs were exposed to sea water solutions of local anesthetics, such as caffeine, tetracaine and ethyl urethane, and the herbicide, isopropyl N-phenyl carbamate (IPC) for 10min and returned to normal sea water. Then they were inseminated 5min later. When eggs were pre-treated with 1–2 mM caffeine, 0.02–0.05 mM tetracaine, 50–100 mM ethyl urethane and 2% saturated sea water of IPC, respectively, they could cleave and hatch earlier than the control eggs. However, when fertilized eggs were continuously post-treated with solutions of the agents except IPC at the same concentrations as those in the case of the pre-treatments, the fertilized eggs could not cleave or were retarded in development. The possible mechanisms of the cleavage acceleration by pre-treatments with local anesthetics were discussed.     

INDUCTION OF ASTER FORMATION AND CLEAVAGE IN EGGS OF THE SEA URCHIN HEMICENTROTUS PULCHERRIMUS BY INJECTION OF SPERM COMPONENTS*

Studies were made on which components of sperm were able to induce aster formation and cleavage of eggs of the sea urchin Hemicentrotus pulcherrimus. The sperm components were separated by homogenization and centrifugation into the following 3 fractions: the head-midpiece, midpiece and tail. The head-midpiece fraction was then divided into 2 sub-fractions, the centriole sub-fraction and the centriole-free sub-fractions. Each fraction was injected into unfertilized eggs and after 15–30 min the eggs were inseminated. The ability of a fraction or a sub-fraction to induce aster formation and cleavage was deduced from the frequency of multipolar cleavage. The head-midpiece fraction and the centriole sub-fraction were effective in inducing aster formation and cleavage, but the other fractions were not. It was concluded that isolated centrioles from sea urchin sperm act as division centers in the egg.     

A CYTOLOGICAL STUDY OF ARTIFICIAL PARTHENOGENESIS IN THE SEA URCHIN ARBACIA PUNCTULATA

Eggs of the sea urchin Arbacia punctulata were artificially activated with hypertonic seawater. The artificially activated eggs undergo the cortical reaction which is not distinguished by a wavelike progression as in the case of inseminated eggs. The cortical granules are released at random loci at the surface of the egg and result in spaces separated by large cytoplasmic projections. Unreacted cortical granules and ribosomes are found within the matrix comprising the large cytoplasmic projections. No "fertilization cone" is formed. The subsequent release of additional cortical granules results in the formation of a continuous perivitelline space, 15 min following activation. 85 min postactivation, an organization of annulate lamellae, endoplasmic reticulum of the smooth variety, and microtubules around a centriole is observed prior to nuclear division. Before the breakdown of the nuclear envelope a streak stage is formed. The streak is composed of a central core of annulate lamellae and is encompassed by endoplasmic reticulum and vesicular components. Condensation of chromatin is followed by the establishment of the mitotic apparatus. Centrioles were not found in the mature egg; however, they are present after activation prior to the first nuclear division, in the four-cell embryo, multicellular embryo, and at blastula. Artificially activated eggs have been observed to develop to the pluteus stage in more than 50% of the eggs treated.     

EFFECTS OF CHEMICAL REAGENTS ON THE CYCLIC CHANGES OF CORTEX AND CYTOPLASM IN THE ACTIVATED ENUCLEATED EGG-FRAGMENTS OF THE SEA URCHIN*

Unfertilized eggs of sea urchins. Anthocidaris crassispina and Hemicentrotus pulcherrimus, were separated by centrifugation into two fractions (nucleated light and enucleated heavy fragments). The enucleated egg-fragments were activated by treatment with 1 M urea and then put into sea water solutions of the following three reagents; colcemid, cytochalasin B and Monogen at a concentration by which cleavage was suppressed. It was then examined whether the egg-fragments can exhibit cyclic changes of cytoplasm and cortex in correlation with the cleavage cycle in normally fertilized eggs without any influence of nuclear activity. The results obtained clearly showed that colcemid can suppress the cyclic appearance of cytoplasmic changes, but not that of cortical changes; on the contrary, in cytochalasin B- and Monogen-treated fragments, the periodicity in cortical activities is suppressed, while the periodic changes in the cytoplasm appear according to a timeschedule of the cleavage cycle. Therefore, it may be said that: 1) cyclic changes can occur in both the cytoplasm and the cortex independently, without the direct influence of nuclear activity; 2) if either of them is arrested, the cleavage does not take place; 3) the normal cleavage requires the simultaneous occurrence of periodic activities both in the cortex and in the cytoplasm after fertilization.     

THE EXTRACELLULAR RELEASE OF ECHINOCHROME

A study was made of the diffusion of the red pigment echinochrome from the eggs of the sea urchin, Arbacia punctulata, into sea water. Unfertilized eggs retained their pigment, over periods of hours. Outward diffusion of pigment from unfertilized eggs normally is entirely negligible, or does not occur at all. Enchancing the calcium or potassium content of the artificial sea water (while retaining isosmotic conditions) did not induce pigment release. Under anaerobic conditions, unfertilized eggs release pigment in small quantities. Fertilization alone brings about echinochrome release. Fertilized eggs invariably released pigment, whether in normal sea water, or sea water with increased calcium or potassium. This diffusion of the pigment began during the first cleavage, possibly soon after fertilization. The pigment release is not a consequence solely of the cell''s permeability to echinochrome (or chromoprotein, or other pigment combination) but is preceded by events leading to a release of echinochrome from the granules in which it is concentrated within the cell. These events may be initiated by activation or by anaerobiosis. The phenomenon was not due to cytolysis.     

THE RELATION BETWEEN THE ELECTRICAL CONDUCTIVITY OF THE EXTERNAL MEDIUM AND THE RATE OF CELL DIVISION IN SEA URCHIN EGGS

Dilution of sea water with isotonic sugar solution leaves the rate of cleavage of Arbacia eggs almost unchanged until the proportion of sea water is decreased to 20 or 25 volumes per cent. From this point cleavage becomes progressively slower with further dilution. Many eggs fail to cleave at dilutions of 5 to 6 volumes per cent. No cleavage occurs in 2 volumes per cent sea water or in pure sugar solution. Eggs returned from these media to sea water resume cleavage and development. There is thus no relation between the rate of cleavage and the electrical conductivity of the medium, except possibly within the range of dilutions from 20 to 5 volumes per cent sea water. In this range cleavage rate decreases as conductivity decreases, but the relation is not a linear one.     

Adenosine receptor activation in quiescent Swiss 3T3 cells. Enhancement of cAMP levels, DNA synthesis and cell division

Anti-tubulin immunofluorescence microscopy is used here to demonstrate that eggs of Lytechinus variegatus are induced to assemble cytoplasmic microtubules upon artificial activation. These microtubules progress through three distinct configurations followed by cycles of abortive division. The first of these is a configuration in which microtubules are found in a disordered network near the egg cortex; the progressive thickening of the microtubule-containing layer appears to be responsible for the centripetal movement of the egg nucleus that occurs shortly after activation. These microtubules are replaced at about 40 min by a population of long, radially arrayed microtubules, which are restructured by about 70 min to form the apolar mitotic apparatus. Each of the microtubule configurations characteristic of activated eggs becomes more prominent when eggs are treated at the appropriate times after activation with the microtubule-stabilizing drug taxol. Any microtubule organizing centers within the activated egg must have very limited authority, since aster-like structures are not seen, and microtubules are not observed to be closely associated with the nucleus or egg cortex. Activation of eggs with ammonia in Ca²⁺-free sea water (a treatment that bypasses the cortical reaction and the Ca²⁺ transient) induces the appearance of microtubules as readily and in the same patterns as does treatment with ionophore A23187 or butyric acid, both of which activate by inducing an intracellular calcium release and the cortical reaction.     

ELECTROPHORETIC MOBILITY OF SEA-URCHIN EGGS DURING THE DIVISION CYCLE

The electrokinetic potential of fertilized sea-urchin eggs, without the fertilization membrane and hyaline layer, was investigated by measuring the electrophoretic mobility of the eggs from fertilization to the second cleavage. A cyclic change in mobility was found to accompany the division cycle: the peak of the change was observed about 15 min before the appearance of both the first and second cleavage furrows.
A smaller peak was observed at 20–30 min after fertilization, but such a peak was not repeated between the first and the second cleavage.
Fertilized eggs with the fertilization membrane intact did not show a significant change in electrophoretic mobility throughout the division cycle.     

Cytoplasmic and sperm nuclear transformations in fertilized ammonia-activated sea urchin (Arbacia punctulata) eggs

Studies examining cytoplasmic and sperm nuclear transformations in sea urchin (Arbacia punctulata) eggs inseminated at different periods after ammonia activation have been caried out at the light- and electron-microscopic levels of observation. Arbaca eggs treated with ammonia-seawater demonstrated chromosome condensation after DNA synthesis and underwent a chromosome cycle similar to that described for Lytechinus [Mazia, 1947]. Cortical granule reaction, fertilization cone formation, and sperm aster development in eggs fertilized at 20 (interphase), 50 (prometaphase), and 180 (interphase) min after ammonia activation were structurally simialr to processes in untreated zygotes. Cyclical changes in the formation of fertilization cones and sperm asters, as reported for eggs fertilized after activation by agents that induce a cortical granule reaction, were not observed. Although sperm nuclear transformations were prolonged (14 vs 18 min), male pronuclei that developed in eggs fertilized 20 min after ammonia activation were morphologically similar to those observed in fertilized, untreated ova and incorporated ³H-thymidine. Sperm incorporated into eggs at 50 min after ammonia activation underwent nuclear envelope breakdown and chromatin despersion; however, ³H-thymidine incorporation was not observed, and male pronuclei rarely developed (less than 5% of all specimens examined). Subsequent to dispersion, the paternal chromatin condensed into chromosomes which were associated with an aster. These results demonstrate that although ammonia-activated eggs inseminated at interphase or prometaphase undergo similar cytoplasmic alterations, sperm nuclear transformations vary with the chromosome cycle of the egg.     

PERIODIC CHANGE IN THE TENSION AT THE SURFACE OF ACTIVATED NON-NUCLEATE FRAGMENTS OF SEA-URCHIN EGGS

Unfertilized eggs of the sea urchin, Hemicentrotus pulcherrimus , were separated into two fragments by centrifugal force. The enucleate fragment (merogone) was subsequently activated by treating it with butyric acid and the tension at the surface was continuously measured by a compression method. The activated merogone was found to exhibit cyclic changes in tension, with a temporal pattern very similar to that of the changes accompanying the division cycle of normally fertilized eggs. This indicates quantitatively the presence in the cytoplasm of some periodic activity which can be triggered without nuclear control. Further, a periodic thickening of the intrahyaloplasmic space of the activated merogone, as noted by K ojima (14), was confirmed on the basis of extended observation.     

CHANGE IN THE ACTIVITY OF LIPASE IN SEA URCHIN EGGS AND EMBRYOS DURING EARLY DEVELOPMENT*

During the early development of the sea urchin, Anthocidaris crassispina, the activity of lipase was maintained at the same level as in unfertilized eggs until the mesenchymal blastula stage (20 hr culture at 20°C) and then increased gradually after gastrulation. The activity in the embryos kept in SO^2?₄-free artificial sea water changed in a similar manner to that in those kept in normal sea water, during the development until 36 hr of fertilization. At 48 hr, the activity in the embryos, which had developed to the permanent blastulae in SO^2?₄-free sea water, was markedly lower than in normal plutei and was similar to that in unfertilized eggs. The lipase activity in fertilized eggs 30 min after fertilization, which was almost the same as that in unfertilized eggs was found mainly to be localized in the precipitate fraction obtained by the centrifugation at 12,000 x g for 20 min, whereas the activity in unfertilized eggs was found in the precipitate by the centrifugation at 105,000 x g for 60 min. Ca²⁺, adenosine 3′, 5′-cyclic monophosphate (cAMP) and guanosine 3′, 5′-cyclic monophosphate (cGMP) had no effect on the lipase activity.     

Delayed sperm injection and fertilization in parthenogenetically activated insect egg (Athalia rosae,Hymenoptera)

Summary Mature eggs dissected from the ovary of unmated females of Athalia rosae ruficornis Jakovlev (Hymenoptera, Tenthredinidae) can be activated to develop (into haploid parthenogenetic males) simply by exposing them to distilled water. These eggs, which are primary oocytes arrested at the first meiotic metaphase, resume meiosis upon activation and reach the first meiotic telophase in 20 min. Mature eggs immediately upon dissection have previously been shown to complete karyogamy and develop as fertilized diploid females if injected with sperm. We show here that the eggs activated in water for 20 min have a much higher rate of successful fertilization if injected with sperm, and that the eggs activated for 40 min, upon sperm injection, though at a reduced frequency still develop as diploid fertilized females. Eggs left in water for 60 min, however, are no longer fertilized upon sperm injection and develop as haploid males.     

Cortical modifications in Paracentrotus lividus eggs after ammonia activation

We have shown by electron microscopy that ammonia activation of Paracentrotus lividus eggs alters the inner ultrastructure of cortical granules. If activated eggs are inseminated, they fail to undergo a typical cortical reaction.     

Timing system for the start of gastrulation in the Xenopus embryo

This study examined which component of the egg, the nucleus or cytoplasm, is involved in the timing of the start of gastrulation in the Xenopus embryo, and when it starts to measure time. First, nuclei of cells of 256-cell stage embryos were transplanted to enucleated eggs 60 min after activation. These eggs showed first cleavage 20-30 min later than control eggs fertilized at the same time as the activation of recipient eggs, and started gastrulation 25-35 min later than control embryos (depending on the delay in the first cleavage). Second, eggs whose nuclei were temporarily isolated by the extrusion of the portion containing the nucleus out of the fertilization envelope showed first cleavage 60-90 min later than sibling control eggs, because of delayed introduction of the nucleus from the extruded portion. They started gastrulation 60-90 min later than sibling control embryos (depending on the delay in the first cleavage). The portion inside the envelope underwent two to three rounds of oscillation in cell cycle relevant activities before the first cleavage, while the portion outside underwent the same rounds of cleavage as the inside portion. From the present and previous results it is concluded that the putative timing system for the start of gastrulation in the Xenopus embryo, whether it consists of a single or of multiple clocks, starts measuring time at or around the first cleavage, and that the presence of both the nucleus and the cytoplasm in the same cell and occurrence of mitosis and/or cleavage there are indispensable for the timing system to work, although the role of the cytoplasm is superior to that of the nucleus.     

ELECTRON MICROSCOPIC DEMONSTRATION OF A DITHIOTHREITOL-LABILE VITELLINE COAT SURROUNDING THE UNFERTILIZED EGG OF COMANTHUS JAPONICA (ECHINODERMATA: CRINOIDEA)*

In Comanthus, the unfertilized egg is surrounded by a vitelline coat, which is separated from the underlying plasma membrane by a space several hundred Ångstroms wide. By electron microscopy, the vitelline coat is a distinct layer 100 to 150 Å thick, which consists of finely granular material of moderate electron density. Treatment for 3 min in 0.01 M dithiothreitol in sea water buffered to pH 9.2 almost completely removes the vitelline coat and causes the irregularly shaped egg to become spherical. After such DTT-treated eggs have been washed for 2 min in sea water, they cannot be fertilized, but they can undergo a cortical reaction when treated with ionophore A23187. This cortical reaction consists of the exocytosis of cortical granule material directly into the surrounding sea water. By several hours after DTT treatment, most of the eggs, whether exposed to ionophore or not, fragment into spheres of diverse sizes.     

ON THE ROLE OF CALCIUM IONS IN OOCYTE MATURATION IN THE POLYCHAETE CHAETOPTERUS PERGAMENTACEUS*

The germinal vesicle of mechanically released Chaetopterus oocytes disintegrates in natural sea water (NSW), but not in artificial sea water of normal composition (ASW), calcium-free sea water (CaFSW), magnesium-free sea water (MgFSW) or calcium and magnesium-free sea water (CaMgFSW). Several methods of inducing oocyte maturation using chemically well-defined medium have been established. (1) Germinal vesicle breakdown was induced by the treatment of immature oocytes with KCl (60 mM) in ASW or MgFSW. The presence of Ca²⁺ is necessary for inducing oocyte maturation with high potassium concentration. “Differentiation without cleavage” was observed after this treatment. (2) Trypsin (0.3%) induced oocyte maturation in ASW, but not in CaFSW. Oocytes matured in this manner developed to trochophores upon insemination. (3) Immature oocytes, treated with isotonic CaCl₂ for less than 1 min and then transferred to ASW, underwent germinal vesicle breakdown. The oocytes were arrested at the first meiotic metaphase and upon insemination developed to trochophore larvae. (4) Tetracaine (0.4 mM) induced oocyte maturation in the absence of Ca²⁺ in the medium. In ASW, CaFSW or CaMgFSW containing the drug, oocytes were arrested at the first meiotic metaphase, while in MgFSW with tetracaine they developed parthenogenetically up to the 4- and 8-cell stages. The role of calcium in oocyte maturation was established and its importance was discussed based on the results obtained with the different ways of inducing oocyte maturation.