THE EFFECT OF HYDROGEN ION CONCENTRATION UPON THE INDUCTION OF POLARITY IN FUCUS EGGS : I. INCREASED HYDROGEN ION CONCENTRATION AND THE INTENSITY OF MUTUAL INDUCTIONS BY NEIGHBORING EGGS OF FUCUS FURCATUS

1. The eggs of Fucus furcatus develop perfectly in sea water acidified to pH 6.0. They are retarded at pH 5.5. At pH 5.0 they do not develop, nor do they cytolize. 2. In normal sea water in the dark at 15°C., eggs develop rhizoids on the sides in the resultant direction of a mass of neighboring eggs. The polarity and the whole developmental pattern of the embryo is thereby induced. This inductive effect does not operate, however, unless the directing mass is an appreciable aggregation of cells (10 or more), or unless there are numerous other eggs in the dish. A group of five eggs alone in a dish do not carry out mutual inductions. Two eggs alone in a dish do not develop rhizoids toward each other. 3. When the sea water is acidified to pH 6.0 all sizes of aggregations carry out mutual inductions. Two eggs alone in a dish now develop rhizoids on the sides toward each other, provided they are not more than about 4 egg diameters apart. 4. Increased hydrogen ion concentration thus augments or intensifies the mutual inductive effect. 5. This may explain why only larger masses of eggs show inductions in normal sea water, since presumably the larger masses considerably increase the hydrogen ion concentration locally. 6. The nature of the inductive action is discussed. 7. In acidified sea water at pH 6.0, compared with normal sea water at pH 7.8–8.0, the rhizoids originate and extend with a strongly increased downward component. The substrate then forces further extension or growth of the rhizoid to be in the plane of the substrate.     

THE EFFECT OF HYDROGEN ION CONCENTRATION UPON THE INDUCTION OF POLARITY IN FUCUS EGGS : III. GRADIENTS OF HYDROGEN ION CONCENTRATION

1. Gradients of hydrogen ion concentration across Fucus eggs growing in sea water determine the developmental polarity of the embryo. 2. Gradients may determine polarity even if removed before the morphological response begins. 3. The rhizoid forms on the acid side of the egg unless this is too acid, in which case it develops on the basic side of the egg. 4. Since gradients of hydrogen ion concentration in sea water produce gradients of CO₂ tension, as a result of chemical action on the carbonate buffer system, it is not proven whether the physiological effects are due to the hydrogen ions, or to the CO₂ which they produce in the medium. 5. The developmental response of the eggs to gradients of hydrogen ion (or CO₂) concentration provides an adequate but not an exclusive explanation of the group effect in Fucus. 6. Hydrogen ions may exert their effect by activating growth substance. Hydrogen ions or CO₂ probably also affect the underlying rhizoid forming processes in other ways as well.     

ELECTRIC IMPEDANCE OF SINGLE MARINE EGGS

Alternating current impedance measurements have been made on several single marine eggs over the frequency range from 1 to 2500 kilocycles per second. The eggs were placed in the center of a short capillary made by heating the end of a 2 mm. thin walled glass tube until it nearly closed, and electrodes were placed in the sea water on each side of the egg. When it is assumed that the membrane conductance is negligible, the membrane capacity and internal resistances of unfertilized and fertilized Arbacia eggs agree with the values obtained from suspensions. Preliminary data on centrifugally separated half Arbacia eggs, and whole Cumingia and Chaetopterus eggs are given.     

SPECIES-SPECIFIC ADHESION OF SPERMATOZOA TO THE SURFACE OF FIXED EGGS IN SEA URCHINS

When the spermatozoa of sea urchins are added to eggs which have been fixed with glutaraldehyde and washed thoroughly, the spermatozoa swarm around the eggs and adhere to the egg surface. The mode of sperm adhesion to the fixed egg is assumed, on the evidence of electron-microscopical studies, to be the same as that of adhesion to the intact egg at the initial stage of normal fertilization. The spermatozoa and fixed eggs of five species of sea urchins were combined and heterologous crosses were studied. Species-specific adhesion of sperm to fixed eggs was clearly demonstrated. There is a direct relationship between the cross-fertilization of living gametes and the binding capacity of spermatozoa and fixed eggs in so far as the employed five species are concerned.     

RELATION BETWEEN THE ACROSOME REACTION AND FERTILIZATION IN THE SEA URCHIN. II. FERTILIZATION IN ACIDIFIED SEA WATER WITH EGG-WATER-TREATED SPERMATOZOA*

Fertilization of sea urchin eggs fails to occur at a pH lower than 6.5. Analytical studies on this problem were made with Hemicentrotus pulcherrimus, Anthocidaris crassispina and Pseudocentrotus depressus. If the spermatozoa have been pretreated with egg water, eggs can be fertilized even at pH 6.5 and 6.0. The acrosome reaction is inhibited at a pH lower than 6.5. Intact spermatozoa fail to adhere to the fixed eggs in acidified sea water, whereas egg-water-treated spermatozoa adhere even at pH 6.5 and 6.0. From these results we infer that the failure of fertilization at pH 6.5–6.0 is caused by non-occurrence of the acrosome reaction, and that fertilization reactions other than the acrosome reaction, such as the binding and fusion of the gametes, are not inhibited in this range of pH. At pH 5.5, the spermatozoa become inert and fertilization is inhibited or suppressed, even though egg-water-treated spermatozoa are employed.     

THE EFFECT OF PENICILLIN ON EGGS OF THE SEA URCHIN,ARBACIA PUNCTULATA

1. Penicillin in the range of concentration from 250 U/ml. to approximately 2650 U/ml. inhibits the rate of cell division of the fertilized sea urchin egg from 0 to 100 per cent. 2. Penicillin in the same range of concentrations has no effect on the oxygen consumption of the unfertilized or the fertilized eggs. 3. Penicillin is bound by some component of the sea urchin egg in amounts sufficiently large to lower the initial concentration, this binding apparently not being related to the inhibitory action.     

MECHANICAL PROPERTIES OF SEA URCHIN EGGS III. VISCO-ELASTICITY OF THE CELL SURFACE

When a sea urchin egg was compressed between two parallel plates, the force required to keep the distance between the plates constant gradually decreased with time. The contours of the compressed egg were different from the contours expected from the assumption that the surface forces are uniform over the entire surface. The surface forces of the egg without deformation computed from the area of the cell surface in contact with the substratum, the density of the egg and its size were 0.02–0.04 dynes/cm in Hemicentrotus pulcherrimus. Larger values were obtained in eggs during compression. Surface forces, which were computed from measurements of the form of the egg and the applied force when the egg was deformed by a rod and a plate supporting the egg, increased as the deformation increased.
From these results, it was concluded that the cell surface is visco-elastic in sea urchin eggs.     

CHANGE IN THE ACTIVITY OF ARYLESTERASE IN SEA URCHIN EGGS FOLLOWING FERTILIZATION

The activity of arylcsterase in sea urchin eggs ( Anthocidaris craxsispina ), increases at 5 min after fertilization to about 1.5-fold that in unfertilized eggs, and decreases at 15 min to a lower level than that in unfertilized eggs. Then the activity of the enzyme increases again. The enzyme activity in unfertilized eggs is enhanced by either fructose 1, 6-diphosphate (FDP) at concentrations between 4 and 10 μM, or guanosine 3', 5'-cyclic monophosphalc (cGMP) at concentrations between 0.1 and 0.3 μM. The activity is detectable in the crude microsomal fraction and also in the supernatant fraction obtained from sea urchin egg homogenates by centrifugation at 105,000 × g for 2 hr.     

THE PHYSIOLOGICAL ECOLOGY OF REPTILIAN EGGS AND EMBRYOS. AND THE EVOLUTION OF VIVIPARITY WITHIN THE CLASS REPTILIA

1. Eggs of Crocodilia and Chelonia, like those of birds, have a pair of egg membranes separating a thick layer of albumen from the calcareous shell. In contrast, eggs of oviparous Lepidosauria have only a single shell membrane, upon which relatively small amounts of calcium carbonate are deposited; and the volume of albumen in eggs is extraordinarily small at the time of oviposition. 2. With the possible exception of certain geckos and some chelonians, eggs of oviparous reptiles seem always to absorb water from the substrate during the course of normal incubation. In so far as the rate of water absorption exceeds the rate of water loss by transpiration from exposed surfaces, the eggs swell during incubation. The term ‘cleidoic’ cannot be used to describe eggs of this type. 3. Embryos of lizards and snakes influence the water potential of extra-embryonic fluids contained within their eggs, thereby maintaining or increasing the gradient in water potential that drives water absorption. 4. Embryos of Crocodilia and Chelonia obtain a substantial portion of the calcium used in ossification of skeletal elements from the inner surfaces of the eggshell. In contrast, embryonic lizards and snakes draw upon extensive reserves of calcium present in the yolk, and obtain little (if any) calcium from the eggshell. 5. All reptilian embryos seem to produce substantial quantities of urea as a detoxification product of protein catabolism. Contrary to expectation, uricotelism may not be common among reptilian embryos, even in those few instances where development takes place within a hard, calcareous egg. 6. In eggs of Crocodilia and Chelonia, respiratory gases seem to pass by diffusion through pores in the calcareous eggshell and through spaces between the fibres of the pair of egg membranes. No pores have been observed in the shell of lepidosaurian eggs, and so gases presumably diffuse between the fibres of the single (multilayered) shell membrane. 7. Metabolism of reptilian embryos is temperature-dependent, as is true for most ectothermic organisms. For each species, there appears to be a particular temperature at which embryonic development proceeds optimally, and departures from this optimum elicit increases in developmental anomalies and/or embryonic mortality. 8. Viviparity has evolved on numerous occasions among species of the Squamata, but seemingly never among Crocodilia or Chelonia. Since the evolution of viviparity entails a progressive reduction in the eggshell, only those organisms whose embryos do not depend upon the eggshell as a source of calcium may have the evolutionary potential to become viviparous. 9. Evolutionary transitions from oviparity to viviparity could have been driven by selection related to (i) thermal benefits to embryos consequent upon retention of eggs within the body of a parent capable of behavioural thermoregulation; (ii) protection of the eggs from nest predators and/or soil microbes; and (iii) more effective exploitation of a seasonal food resource by early emerging young.     

LOCALIZATION OF DYNEIN IN SEA URCHIN EGGS DURING CLEAVAGE*

Detection and localization of dynein in cleaving sea urchin eggs were attempted using antidynein serum (prepared against a tryptic fragment of dynein, Fragment A, of sea urchin sperm flagella) and fluorescein conjugated goat antiserum to rabbit γ-globulin. In both unfertilized and newly fertilized eggs, fluorescence was distributed rather uniformly within the cells but was absent from the nuclei. At prophase, intense fluorescence was observed on both sides of nucleus, suggesting accumulation of dynein in developing asters. From metaphase to anaphase, the whole mitotic apparatus (MA) was stained with the exceptions of the chromosomes and pole areas. Fluorescence then again became dispersed within the eggs. Throughout the mitotic process and cytokinesis, the egg cortex including the cleavage furrow was stained intensely, presumably reflecting the presence of dynein in this region. Similar distributions of fluorescence were obtained with the isolated MAs. Neither non-immune serum nor the antiserum to which Fragment A was absorbed stained the eggs. Little staining was obtained with the antiserum against starfish egg myosin. The results, together with the finding that the chromosome motion in the isolated MAs was completely inhibited by anti-dynein serum, but not with the anti-myosin serum, suggest an active role played by a tubulin-dynein system in mitosis.     

ELECTRIC IMPEDANCE OF SUSPENSIONS OF ARBACIA EGGS

Apparatus has been designed and constructed for the measurement of the electric impedance of suspensions of Arbacia eggs in sea water to alternating currents of frequencies from one thousand to fifteen million cycles per second. This apparatus is simple, rugged, compact, accurate, and rapid. The data lead to the conclusions that the specific resistance of the interior of the egg is about 90 ohm cm. or 3.6 times that of sea water, and that the impedance of the surface of the egg is probably similar to that of a "polarization capacity". The characteristics of this surface impedance can best be determined by measurements of the capacity and resistance of suspensions of eggs. No specific change has been found in the interior resistance or the surface impedance which can be related either to membrane formation or to cell division.     

CHANGES IN ACTIVITIES OF THYMIDYLATE SYNTHASE AND DIHYDROFOLATE REDUCTASE IN SEA URCHIN EGGS AFTER FERTILIZATION

Thymidylate synthase activity in sea urchin eggs increases just after fertilization and decreases 30 min later. Then, cyclic variation in the activity occurs in association with the cleavage cycle. Dihydrofolate reductase activity in fertilized eggs is almost the same as in unfertilized eggs and shows no marked change within 3 hr after fertilization. Aminopterin, an analogue of dihydrofolate, inhibits dihydrofolate reductase, and arrests cleavage. On incubation in sea water containing aminopterin (20-100μM) from the time of fertilization, the development of Clypeaster and Pseudocentrotus eggs was arrested at the 32–64 cell stage, and that of Anthocidaris eggs was arrested at the morula stage. Dihydrofolate (100μM) counteracts the inhibitory effect of aminopterin on egg cleavage. Thymidine at concentrations above 10μM also prevents inhibition by aminopterin. Other deoxyribonucleosides at concentrations of 10μM to 100μM do not affect inhibition of egg cleavage by aminopterin. Deoxyadenosine at concentrations above 5 mM inhibits egg cleavage, but other deoxyribonucleosides have no effect.     

A SIMPLE CASE OF SALT ANTAGONISM IN STARFISH EGGS

The jelly surrounding the eggs of the starfish, Asterias forbesi, is insoluble in normal sea water, but rapidly swells and dissolves when the eggs are washed in a pure isotonic solution of NaCl. In the presence of a small proportion of CaCl₂ this solvent and disintegrative action of the NaCl solution is entirely prevented, and in the mixed solution the jelly exhibits the same insolubility and other properties as in normal sea water. 2. This action of CaCl₂ in preventing the dissolution of the jelly runs parallel with its action in preventing certain definite effects of the pure NaCl solution on the living egg (agglutination, cytolytic action, membrane formation, prevention of maturation). 3. The inference is that the essential factor in these and similar antagonistic and protective actions is the formation of solid water-insoluble colloidal salts (e.g., soaps and proteinates) of calcium (or other metal) with the structural colloids of the protoplasm. Apparently the presence of a certain proportion of such compounds is necessary to the structural stability of the living protoplasm, and especially to the water-insolubility and semipermeability of its external layer or plasma membrane. When the cell is immersed in the pure NaCl solution, water-soluble Na compounds are substituted for the insoluble Ca compounds which normally provide the necessary insolubility and coherence, and disintegration results.     

长毛对虾卵子皮层反应的研究

Morphology of the cortical reaction in the eggs of Penaeus penicillatus was studied with the light microscopy,scanning electron microscopy　and transmission electron microscopy. The cortical reaction is divided into four stages. These stages are unreacted stages, early stages, corona stages and dissipation stage. The cortical rods were released and formed a jelly coating around the surface of the egg. The jelly coating remained until the first cleavage had finished. In the end, the hatching membrane appeared around the egg. It is believed that these cortical reaction are responsible for the prevention of polyspermy by both a chemical and physical block and that also may establish a microenvironment inside a touch chorionic membrane for the developing embryo.     

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.     

THE EFFECT OF SALT CONCENTRATION OF THE MEDIUM ON THE RATE OF OSMOSIS OF WATER THROUGH THE MEMBRANE OF LIVING CELLS

1. Using the unfertilized egg of the sea urchin, Arbacia, as osmometer, it was found that the rate with which water enters or leaves the cell depends on the osmotic pressure of the medium: the velocity constant of the diffusion process is higher when the cell is in concentrated sea water, and lower when the sea water medium is diluted with distilled water. Differences of more than tenfold in the value of the velocity constant were obtained in this way. When velocity constants are plotted against concentration of medium, a sigmoid curve is obtained. 2. These results are believed to indicate that cells are more permeable to water when the osmotic pressure of the medium is high than when it is low. This relation would be accounted for if water should diffuse through pores in a partially hydrated gel, constituting the cell membrane. In a medium of high osmotic pressure, the gel is conceived to give up water, to shrink, and therefore to allow widening of its pores with more ready diffusion of water through them. Conversely, in solutions of lower osmotic pressure, the gel would take up water and its pores become narrow.     

CORTICAL AND SUBCORTICAL CHANGES PRECEDING FURROW FORMATION IN THE CLEAVAGE OF NEWT EGGS

In the first cleavage of the egg of the newt, Cynops(Triturus) pyrrhogaster, some sort of preparation for the furrow formation in the cortical and subcortical cytoplasm precedes the advancing tip of the cleavage furrow. This is shown by the following facts: (1) Incisions made close to the tip of the cleavage furrow do not stop the progress of furrowing, allowing the furrow to cross the incisions and appear on the farther sides, while incisions made far enough from the furrow tip always prevent the further travelling of the furrow, (2) Displacement of the subcortical cytoplasm ahead of the furrow by rubbing with a hair loop makes the furrow bend corresponding to the width of the rubbed area, and (3) Transplantation of the subcortical material of the furrow tip to lateral parts in the same egg causes a depression in the overlying cortex at the transplanted position. The linear extension of the prepared area for the furrow formation is the longest in the animal hemisphere and it decreases in gradient towards the vegetal pole.     

ANTIGENS IN EGGS AND DEVELOPMENTAL STAGES OF THE SEA URCHIN : II. Localization

Homogenates of fertilized eggs of the sea urchin Paracentrotus lividus were fractionated by differential centrifugation. In addition, whole eggs were fragmented, on a preparative scale, by centrifugation in sea water-sucrose gradients. The fractions and fragments were subsequently assayed for their content of soluble protein antigens described in an earlier publication. Relative concentrations of antigen present in quantitatively isolated cell fractions were estimated by graded antiserum absorption in combination with agar-diffusion technique. Two of six antigens were found to be associated mainly with the low speed sediments. Treatment of the various sediments with hypotonic medium and results obtained with fragmented eggs suggested that these two antigens and possibly a third were probably located in the yolk granules. The other antigens were more evenly distributed among the low speed sediments and the non-sedimented part of the cytoplasm. Only one of the antigens was consistently associated with the microsomal fraction.     

PRODUCTION AND UTILIZATION OF GLUCOSE 1-PHOSPHATE IN THE EGGS OF THE SEA URCHIN ANTHOCIDARIS CRASSISPINA

Concentrations of G1P, G6P, UDPG, UTP and PPi were measured in the eggs of the sea urchin, Anthocidaris crassispina. Activities of phosphorylase a (EC 2.4.1.1), phosphoglucomutase (EC 2.7.5.1), UDPG pyrophosphorylase (EC 2.7.7.9) and pyrophosphatase (EC 3.6.1.1) were also estimated. Levels of G1P and G6P increase following fertilization, but concentrations of UDPG and UTP in unfertilized eggs are very similar to those in fertilized eggs. PPi is undetectable. In unfertilized and fertilized eggs, the G1P level is very low as compared with the G6P level and is far less than that expected from the equilibrium constant in a reaction catalyzed by phosphoglucomutase. Since the phosphoglucomutase activity is higher by about 20 times than the phosphorylase a activity, G1P is probably produced in the reverse reaction, catalyzed by phosphoglucomutase, rather than in the reaction catalyzed by phosphorylase. The G1P thus produced seems to be utilized thoroughly in the reaction catalyzed by UDPG pyrophosphorylase. The reaction seems to be irreversible and tends to go to UDPG production in sea urchin eggs, since the PPi level is negligible due to high pyrophosphatase activity. The utilization of G1P in the reaction catalyzed by UDPG pyrophosphorylase seems to keep the G1P level low.     

REFRACTIVE INDEX OF THE PROTOPLASM IN SEA URCHIN EGGS*

The distribution of the refractive index (RI) of the protoplasm in sea urchin eggs was determined from the optical path differences at various regions of the cell measured by interference microscopy assuming that the cell structure is symmetrical about the line passing through the center of the cell and that of the nucleus in unfertilized eggs and about the spindle axis in fertilized eggs during mitosis and cleavage. The RI of the cytoplasm in the unfertilized egg was uniform except for the cortical region, which had the RI higher than that of the underlying endoplasm. The RI of the cortex was generally higher than that of the underlying endoplasm, which did not appreciably change during mitosis and cleavage. The RI of the nucleus was lower than that of the cytoplasm. The RI of the mitotic apparatus was lower than that of the surrounding cytoplasm. The fertilization membrane had a thickness of about 0.6 μm in hydrated state and about 25 nm in dried state (mean values). The RI of the perivitelline space was about 0.00015 higher than that of seawater, equivalent to 0.08 g/100 ml of contents.