pc1 and psc1, zebrafish homologs of Drosophila Polycomb and Posterior sex combs, encode nuclear proteins capable of complex interactions.

Drosophila Polycomb group proteins are thought to form multimeric nuclear complexes that are responsible for stable transmission of repressed states of gene expression during the proliferation of differentiating embryos. In this study, we cloned, sequenced, and characterized two Polycomb group homologs, designated pc1 and psc1, in zebrafish. Amino acid sequence analyses determined that pc1 is a structural homolog of Drosophila Polycomb and that psc1 is a homolog of Drosophila Posterior sex combs. Northern blots and whole-mount in situ hybridization revealed that pc1 and psc1 had overlapping expression patterns at successive stages of embryogenesis. Immunocytochemistry localized both Pc1 and Psc1 protein in blastomere nuclei. Pull-down assays and two-hybrid system deletion analyses showed that these proteins were capable of homotypic and heterotypic interactions and identified the regions required for these interactions. The evidence supports the idea that zebrafish Polycomb group proteins, like those of other species, form nuclear complexes with compositions that may vary in a spatio-temporal manner during development.

Does phosphatidylinositol 3-kinase play a role in insulin-induced outgrowth of pseudopodial cables in cultured cells derived from micromeres of sea urchin embryos?

Cultured cells derived from micromeres isolated from sea urchin embryos at the 16-cell stage, which have insulin receptors, undergo pseudopodial cable growth and spicule rod formation in culture with horse serum and only cable growth in culture with insulin. Genistein, an inhibitor of protein tyrosine kinase, and wortmannin, an inhibitor of phosphatidylinositol 3-kinase (PI3kinase), inhibited pseudopodial cable growth in micromere-derived cells cultured with insulin and also growth accompanied by spicule rod formation in horse serum-treated cells. The PI3kinase activity in the immunoprecipitates obtained by anti-phosphotyrosine antibody from the cells cultured with insulin was higher than that in cells cultured without insulin or with insulin and genistein. Following immunoblotting with antibody of SH-2, Src homology 2 domains in PI3kinase regulatory subunit, a band appeared at 85 kDa in SDS-PAGE of the immunoprecipitate, obtained from the micromere-derived cells by anti-phosphotyrosine antibody. This SDS-PAGE also showed protein bands at molecular weights similar to IRS-1 and the insulin receptor ß subunit. These indicate that the insulin signal transduction pathway in micromere-derived cells is somewhat similar to the pathway, in which PI3kinase is involved, in mammalian cells.

Change in the levels of adenine-related compounds in starfish ovarian follicle cells following treatment with gonad-stimulating substance.

The resumption of meiosis in starfish oocytes is induced by 1-methyladenine (1-MeA), which is produced by ovarian foilicle cells under the influence of a gonad-stimulating substance (GSS). It has been reported that the 1-MeA produced is newly synthesized via a process of methylation, rather than being pre-stored within follicle cells or a breakdown product of some 1-MeA-containing substance. The present study examined a possible substrate for 1-MeA biosynthesis stored in follicle cells of the starfish Asterina pectinifera. Analyses using high-performance liquid chromatography indicated a large source of ATP among the adenine-related compounds in these follicle cells. When follicle cells were incubated in seawater in the presence of GSS, 1-MeA production was stimulated significantly. GSS also caused a reduction in intracellular levels of ATP. There was no change in the levels of either ADP or AMP. The amount of ATP consumed under the influence of GSS was similar to the amount of 1-MeA produced. Methionine and selenomethionine enhanced both 1-MeA production and ATP consumption by GSS in follicle cells. In contrast, ethionine and selenoethionine, competitive inhibitors of methionine, inhibited these processes. These results suggest that ATP is a possible substrate in the biosynthesis of 1-MeA by starfish ovarian follicle cells.

Does the low respiratory rate in unfertilized eggs result mainly from depression of the redox reaction catalyzed by flavoproteins? Analysis of the respiratory system by light-induced release of CO-mediated inhibition.

In unfertilized eggs of the sea urchin, the quite low respiratory rate is enhanced by tetramethyl-p-phenylenediamine (TMPD), phenazine methosulfate (PMS) and sperm and this augmentation is completely inhibited by carbon monoxide (CO). Exposure to light releases eggs from this CO-mediated inhibition. The action spectra for photoreactivation of CO-inhibited cytochrome c oxidase in isolated mitochondria and CO-blocked respiration in TMPD-treated eggs were found to be similar to the absorption spectrum of CO-bound cytochrome aa3 . In PMS-treated eggs and fertilized eggs, the maximum photoreactivation of CO-inhibited respiration occurred at a light fluence rate higher than that for maximum photoreactivation of CO-inhibited respiration in TMPD-treated eggs, with peaks at the same wavelengths as those in the absorption spectrum of reduced cytochrome b. A similar phenomenon was seen for NADH cytochrome c reductase in mitochondria. Thus, cytochrome c oxidase and NADH cytochrome c reductase, whose activities are not altered by fertilization, seem to be functional, even in unfertilized eggs. In unfertilized eggs, difference spectra indicated that PMS and sperm augmented cytochrome b reduction and that TMPD accelerated cytochrome c reduction without cytochrome b reduction. Therefore, it is likely that depression of electron transport to cytochrome b, which is augmented by PMS and sperm, is responsible for the low respiratory rate in unfertilized eggs.

Fertilization envelope formation induced by melittin in sea urchin eggs does not depend on Ca2+ signalling.

In sea urchin eggs, 10 µg/mL melittin was found to induce fertilization envelope formation without any increase in [Ca2+ ]i (the intracellular free Ca2+ level). On the other hand, 10 µmol/L Br-A23187 and 100 µg/mL SDS induced fertilization envelope formation associated with [Ca2+ ]i increase. If EGTA was injected into eggs to make an intracellular concentration of 2 mmol/L, [Ca2+ ]i became quite low and was not altered by melittin, or by Br-A23187 and SDS. In eggs containing EGTA, fertilization envelope formation was induced by melittin even in Ca2+ -free artificial sea water, but not by Br-A23187 or SDS. Thus [Ca2+ ]i is essential for induction of a fertilization envelope in sea urchin eggs by Br-A23187 or SDS but not by melittin. Melittin probably activates some Ca2+ -independent reaction downstream of Ca2+ -dependent reactions in a sequential reaction system that finally results in fertilization envelope formation.

ADP-Ribosylation of Histones in Nuclei Isolated from Embryos of the Sea Urchin, Hemicentrotus pulcherrimus: (histone/ADP-ribosylation/sea urchin/development/nucleus).

Two-dimensional electrophoresis (2D-PAGE) of a histone fraction isolated from nuclei of embryos of the sea urchin Hemicentrotus pulcherrimus exhibited almost all histone species at all stages examined. At the gastrula stage, a spot of H1A became evident and three spots closely associated with one another were found in place of a single spot of H2A.1. In the histone fraction isolated from [adenylate-32 P] NAD+ -treated nuclei of all stages examined, autoradiograms of 2D-PAGE exhibited spots of mono [ADP-ribosyl] ated H1 and polymodified H2B.2, H3.1, H3.3 and H4 but did not show ADP-ribosylated H2A.1, H2A.2 or H2B.1. Poly [ADP-ribosyl] ated H3.2, found in morulae, was not detectable in blastulae and gastrulae. Treatment with dimethylsulfate, known to activate ADP-ribosylation in other cell types, induced poly [ADP-ribosyl] ation of H2A.2 and H2B.1 in embryos at all stages examined, and also polymodification of H3.2 in gastrulae. ADP-ribosylation of H1, H2B.2, H3.1 and H3.3 was hardly affected by dimethylsulfate treatment, though modification of H4 was blocked by this treatment. Probably, strong regulation of ADP-ribosyltransferase reactions causes failures of modification of H2A.2 and H2B.1 throughout early development and also of H3.2 at the gastrula stage. Regulation of histone ADP-ribosylation is thought to alter chromatin structures and the rate of gene expression, contributing to cell differentiation.

Insulin-Induced Outgrowth of Pseudopodial Cables from Cultured Micromere-Derived Cells Isolated from Sea Urchin Embryos at the 16 Cell Stage, with Special Reference to the Insulin-Receptor.: (sea urchin/micromere/insulin/psedopodial cable/receptor).

Cultured cells derived from micromeres isolated from sea urchin embryos at the 16 cell stage are known to show outgrowth of pseudopodial cables followed by spicule rod formation when cultured in the presence of horse serum. Micromere-derived cells cultured with bovine insulin showed pseudopodial cable growth but did not produce spicule rods. Micromere-derived cells reversibly bound to insulin through out the period between 3 and 20 hr of culture. The dissociation constant of insulin with these cells was about 5.1 × 10-10 M during the whole culture period examined. Horse serum, as well as blastocoelic fluid obtained from early gastrulae, concentration-dependently reduced the amount of insulin bound to these cells, but the bound insulin was scarcely replaced by any proteins tested, such as bovine serum albumin. The micromere-derived cells were bound to have an insulin-binding protein, that may be the receptor for insulin or insulin-like proteins. The insulin-binding protein had a smaller molecular weight than the insulin receptor of mammalian cells. The binding of insulin with this protein in micromere-derived cells probably results in pseudopodial cable growth.

Changes in Insulin-Binding Capacity of the Plasma Membrane Fraction during Culture in vitro of Cells Derived from Micromeres of 16-Cell-Stage Sea Urchin Embryos: (sea urchin/development/micromere/insulin/insulin receptor).

In cultured cells derived from isolated micromeres of 16-cell stage sea urchin embryos, which undergo insulin-induced pseudopodial cable growth, specific and reversible insulin binding by a 52-kDa protein, probably an insulin receptor in the plasma membrane, is augmented during 5 h of culture without any change in the dissociation constant (Kuno et al : 1994). The increase in insulin-binding capacity in micromere-derived cells was only minimally blocked by actinomycin D and cycloheximide, which inhibited [U-3 H]uridine incorporation into RNA and [35 S]methionine incorporation into protein, respectively. Insulin binding capacity was found in the plasma membrane fraction and the microsome fraction of isolated micromeres. The capacity in the plasma membrane fraction increased, accompanied by its decrease in the microsome fraction, during 5 h of culture of micromere-derived cells. The insulin receptor is probably accumulated in microsomes of presumptive micromeres prior to the 16-cell stage and transferred to the plasma membrane, resulting in an increase in the insulin binding capacity of micromere-derived cells during 5 h of culture.

Several Cell Responses to Insulin of Cultured Cells Derived from Micromeres, Isolated from Sea Urchin Embryos at the 16 Cell Stage: (Sea urchin/development/morphogenesis/insulin/micromere).

In micromere-derived cells of sea urchin embryos, treatment with insulin started for up to 24 h during culture at 20°C resulted in augmentation of 32 P incorporation into protein (protein phosphorylation) followed by activation of 32 P incorporation into RNA (RNA synthesis) and then induced pseudopodial cable growth, accompanied by considerable decreases in the rates of protein phosphorylation and RNA synthesis. This augmentation of RNA synthesis and cable growth induced by insulin were blocked by H-7, which inhibited protein phosphorylation, and were also inhibited by actinomycin D without any inhibition of protein phosphorylation. Similar results were obtained on treatment with horse serum, found to contain insulin-like compounds. In cells treated with horse serum treated cells, high rates of protein phosphorylation and RNA synthesis were maintained even after the initiation of cable growth and about 5 h later, spicule rods were produced. Insulin treatment did not induce spicule rod formation. In cells treated with horse serum, actinomycin D treatment started at the time of initiation of cable growth, cables were formed but formation of spicule rods was blocked. These results suggest that horse serum contains some other substance besides insulin-like ones, which induces expression of genes that are indispensable for spicule rod formation.

Proteins ADP-ribosylated in Nuclei and Plasma Membrane Vesicles Isolated from Sea Urchin Embryos at Various Stages of Early Development: (ADP-ribosylation/sea urchin/development/nucleus/plasma membrane).

The ADP-ribosylations of proteins in nuclei, plasma membrane vesicles, mitochondria, microsome vesicles and the soluble fraction of sea urchin embryos isolated at various stages of development were examined by measuring the radioactivities of proteins after exposure of these subcellular fractions to [adenosine-14 C]NAD or [adenylate-32 P]NAD. ADP-ribosylation of proteins was detected only in the nuclear and plasma membrane fractions. In the nuclear fraction, the rate of ADP-ribosylation of the histone fraction did not change appreciably during early development. In the TCA-insoluble protein fraction of the nuclei, the rate of ADP-ribosylation increased from fertilization to the morula stage, then decreased and again increased from the mesenchyme blastula to the late gastrula stage. After exposure of the nuclear fraction to [adenylate-32 P]NAD, a protein band with a molecular weight of 90 kDa was detected by SDS-polyacrylamide gel electrophoresis and radioautography at all stages examined. Its labeling intensity indicated that its ADP-ribosylation is higher at the morula and late gastrula stages than at other stages. In the plasma membrane fraction, proteins with molecular weights of 22 and 68 kDa were ADP-ribosylated and their rates of ADP-ribosylation hardly changed during early development.

Does ADP-Ribosylation of Proteins in Nuclei Contribute to Ectoderm Cell Differentiation in Sea Urchin Embryos?: (ADP-ribosylation/sea urchin/development/animalization/differentiation).

In nuclei of sea urchin embryos, marked increase in ADP-ribosyltransferase activity followed by its decrease occurrs in the pre-hatching and post-hatching periods with peaks of activity at the morula and gastrula stages. Increase in its activity was blocked by cycloheximide in the pre- and post-hatching periods and by actinomycin D only in the post-hatching period. Embryo wall cells (ectoderm cells) isolated from gastrulae exhibited markedly higher activity of this enzyme than archenteron cells and mesenchyme cells. Probably, the increase in the activity of this enzyme in the post-hatching period results from expression of the gene for this enzyme mainly in ectoderm cells. In the post-hatching period, the activity increased more in animalized embryos than in normal ones, and increased little in vegetalized embryos. 3-Aminobenzamide (3-ABA), as well as luminol and nicotinamide, inhibited formation of ectoderm structures more than that of endoderm structures, such as the archenteron, in normal and animalized embryos, but had no appreciable effect on morphogenesis in vegetalized embryos. The reaction catalyzed by ADP-ribosyltransferase probably contributes to ectoderm cell differentiation. Treatment of embryos with 3-ABA in the pre-hatching period had little inhibitory effect on the morphogenesis in the post-hatching period, though it caused death of many embryos.

SCN- Blocks Hardening of the Fertilization Envelope of Sea Urchin Eggs and Adhesion of Blastomeres.

Sea urchin eggs kept in artificial sea water (ASW) containing 0.01-0.3 M NaSCN in place of NaCI from within 2 min after insemination formed thin, enlarged fertilization envelopes, which were broken on mild agitation of egg suspensions more easily than those formed in Ca2+ -free ASW. The blastomeres of almost all embryos derived from eggs treated with 0.2M SCN- for 1 hr dissociated spontaneously, and did not reassociate with other blastomeres appreciably. Thus SCN- probably denaturated some compound(s) participating in blastomere binding and hardening of the fertilization envelope. Abnormal arrangements of blastomeres, probably due to incomplete blastomere dissociation, were observed in embryos derived from eggs treated with 0.1 M SCN- for 1 hr. Treatment of fertilized or unfertilized eggs with 0.05-0.1 M SCN- for a short period caused concentration-dependent block of morphogenic processes such as formation of the archenteron and pluteus arms in the post-hatching period. The effects of SCN- on morphogenesis were not inhibited by furosemide or 4,4'-diisothiocyano 2,2'-disulfonic stilbene. Presumably, the denaturation of several compounds in the egg surface by SCN- causes abnormal morphogenesis of embryos. The inhibitory effects of SCN- on hardening of the fertilization envelope, blastomere binding and morphogenesis were greater in the absence of Ca2+ .

Expression of Na+ , K+ -ATPase α-Subunit in Animalized and Vegetalized Embryos of the Sea Urchin, Hemicentrotus pulcherrimus.

A marked increase in the Na+ , K+ -ATPase activity of sea urchin embryos occurred following an elevation of its mRNA level, revealed by Northern blotting analysis, in developmental period between the swimming blastula and the late gastrula stage. cDNA clone of Na+ , K+ -ATPase α-subunit, obtained from γgt10 cDNA library of sea urchin gastrulae, was digested with EcoRl ad Hindlll. The obtained 268 bp cDNA fragment, hybridized to a 4.6 Kb RNA, was used as probe for Northern blotting analysis. The level of Na+ , K+ -ATPase mRNA was higher in embryo-wall cell fraction isolated from late gastrulae (ectoderm cells) than the level in the bag fraction, containing mesenchyme cells (mesoderm cells) and archenteron (endoderm cells). The activity of Na+ , K+ -ATPase and the level of its mRNA were higher in animalized embryos obtained by pulse treatment with A23187 for 3 hr, starting at the 8-16 cell stage and were considerably lower in vegetalized embryos induced by 3 hr treatment with Li+ than that in normal embryos at the post gastrula corresponidng stage. Augmentation of Na+ , K+ -ATPase gene expression can be regarded as a marker for ectoderm cell differentiation at the post gastrula stage, which results from determination of cell fate in prehatching period.

Identification of GTP-Binding Proteins by ADP-Ribosylation in the Presence of Cholera Toxin, Pertussis Toxin and Botulinum Toxin D in Plasma Membrane Isolated from Eggs and Embryos of Sea Urchin.

In plasma membrane fraction isolated from eggs and embryos of sea urchin, 32 P-labeled proteins were found on the fluorographs of SDS-polyacrylamide gel electrophoresis, performed after an exposure of the fraction to [adenylate-32 P] nicotinamide adenine dinucleotide in the presence of cholera toxin, pertussis toxin or botulinum toxin D. The molecular weights of proteins, thus ADP-ribosylated in the presence of cholera toxin and pertussis toxin are 45 and 39 K, which correspond to Gs and Gi or Go, respectively. Protein with the molecular weight of 24 K, labeled in the presence of botulinum toxin D, corresponds to small molecular weight G-protein. The labeling intensity of 45 K protein, probably proportional to its amount, became high at the blastula stage. The labeling intensity of 39 K protein was hardly altered up to the blastula stage. The labeling intensity of 24 K protein increased after fertilization and further increase occurred at the blastula stage. At the gastrula stage, the labeling intensities of these proteins became somewhat lower than at the blastula stage. Transmembrane signaling system, in which these G-proteins are involved, is probably altered in its function during early development.

Change in the Activity of Na1 , K+ -ATPase in Embryos of the Sea Urchin, Hemicentrotus pulcherrimus, during Early Development: (sea urchin embryo/Na+ , K+ -ATPase/RNA synthesis/ectodermal cell/actinomycin D).

The activity of ouabain-sensitive Na+ , K+ -ATPase in sea urchin embryos at the morula and the swimming blastula stage was practically the same to that in unfertilized eggs. The activity increased during the period between the mesenchyme blastula and the late gastrula stages. In embryo-wall cell fraction, which contained presumptive ectodermal cells as well as those of other cell lineages at the pre-gastrula stage and ectodermal cells at the late gastrula stage, the Na+ , K+ -ATPase activity increased in this developmental period more largely than in another cell fraction, containing mesenchyme cells and archenteron cells. Cycloheximide did not only block the activity increase in this period but also caused evident decrease in the activity in embryos at all examined stages. The activity increase in this period was strongly blocked by the treatment with actinomycin D, starting before the mesenchyme blastula stage, and was not seriously inhibited by the treatment starting at the mesenchyme blastula stage. The treatment starting at the initiation of gastrulation only slightly blocked further increase in the activity. Probably, an accumulation of mRNA encoding Na+ , K+ -ATPase occurs mainly in ectodermal cells and is completed up to the early gastrula stage.

Animalizing Effect of A23187 on Sea Urchin Embryos: (sea urchin/animalization/vegetalization/A23187/tetracaine).

Pulse treatment of sea urchin embryos with 3 µM A23187 for 2 hr starting at a stage in initial 10 hr period of development at 20°C, followed by a culture in normal sea water up to the pluteus corresponding stage (45 hr after fertilization), yielded many large exogastrulae with thin embryo walls. The pulse treatment starting at a time between 10 and 13 hr after fertilization yielded considerable number of large prisms and gastrulae having thin embryo walls. Probably, the pulse treatment exerts stimulating effects on ectodermal cell determination in whole span of pre-hatching period to produce animalized embryos. On the other hand, pulse treatment with A23187 in pre-hatching period exerts stage-specific effects on gut formation. Embryos, thus treated for 2 hr starting at stages between 3 and 5 hr after fertilization, produced quite small exoguts but those treated at stages between 7 and 8 hr formed well developed and long exoguts. In embryos treated at the other stages than above, guts or exoguts were almost the same in their size to those in normal ones. These effects of A23187 on morphogenesis were canceled by procaine, tetracaine and ruthenium red. Probably, artificial Ca2+ signal induced by A23187 alters the determination of cell fates, programmed in pre-hatching period.

Pulse treatment of sea urchin embryos with A23187 blocks their hatching out.

Pulse treatment of sea urchin embryos with 3 µM A23187 for 2 h at 20° C, starting from 3 to 6 h of development, prevented the embryos from hatching. Many embryos thus treated with A23187 produced mesenchyme cells and underwent gastrulation while still enclosed within the fertilization membrane. The pulse treatment in this pre-hatching period exerts markedly stronger inhibitory effects on hatching than on other events in early development. Treatment beginning at times earlier than 2 h and later than 8 h of development caused only a slight delay of hatching. The activity of hatching enzyme, known to increase between 6 and 8 h after fertilization, was quite low, if present at all, in embryos in which hatching was blocked by A23187. Hatching enzyme synthesis is probably blocked by the preceding pulse treatment. However, overall protein synthesis, estimated with methionine S 35 incorporation, was somewhat augmented in embryos by the pulse treatment. The blockage of hatching and the augmentation of overall protein synthesis by A23187 were appreciably reversed by procaine, tetracaine, ruthenium red or verapamil. Probably, an artificial Ca2+ signal induced by A23187 activates protein synthesis but blocks the induction of hatching enzyme synthesis.

Vegetalization Induced by Procaine and Tetracaine in Sea Urchin Embryos: (sea urchin/development/vegetalization/procaine/tetracaine).

Vegetalization of sea urchin embryos was induced by the treatment with procaine and tetracaine, inhibitors of Ca2+ mobilization, for 3 hr starting 3-5 hr after insemination at 20°C. The treatment starting 7 hr after insemination sometimes produced similar type of vegetalized embryos. The pulse treatment starting at the other stages hardly yielded vegetalized embryos. The stages at which these compounds were effective to produce vegetalized embryos were almost the same to those for Li+ to make embryos vegetalized. On the basis of known inhibitory effects of tetracaine, procaine and Li+ on Ca2+ mobilization, we postulate that Ca2+ dependent reactions participate in the process of cell determination at these stages. Inhibitory effects of procaine, tetracaine and Li+ on Ca2+ dependent induction of fertilization membrane formation, found in the present study, indicate that these compounds block Ca2+ mobilization in sea urchin eggs.

Fertilization Membrane Formation in Sea Urchin Eggs Induced by Drugs Known to Cause Ca2+ Release from Isolated Sarcoplasmic Reticulum: (sea urchin egg/fertilization membrane/ryanodine/micronazole/procaine).

Ryanodine, miconazole, clotrimazole, doxorubicin, quercetin, halothane, caffeine and chloroform, which activate Ca2+ -induced Ca2+ release from Ca2+ stores, induced Ca2+ release from a particulate fraction isolated from sea urchin eggs, Ca2+ influx into eggs and formation of a fertilization membrane in an appreciable number of eggs. Their minimum effective concentrations for inducing a fertilization membrane increased in the order of these drugs listed above, and this order was also the same as that of their minimum effective concentrations for inducing Ca2+ release from the isolated particulate fraction. Their effect in inducing a fertilization membrane was blocked by ruthenium red and procaine, which inhibit Ca2+ release from Ca2+ stores. Thus these drugs probably induced sufficient Ca2+ release to make the cytosolic Ca2+ level high enough in many eggs for formation of a fertilization membrane. In the absence of external Ca2+ , fewer eggs treated with these drugs formed a fertilization membrane and more eggs did so on further treatment with either A23187 or carbonylcyanide-p-trifluoromethoxy-phenylhydrazone (FCCP). Thus, a high level of Ca2+ is probably derived from Ca2+ release through Ca2+ releasing channels (by A23187), from mitochondria (by FCCP) and its transport from the external medium.

Respiration and Motility in Starfish Spermatozoa at Various Times in the Breeding Season: (starfish/sperm, motility/respiration).

In the spermatozoa of Asterias amurensis, patterns of changes in the respiratory rate and motility following dilution of dry sperm in sea water varied among batches and were classified into three types. The type I spermatozoa were immotile and exhibited quite low respiratory rate. Ethylenediamine tetraacetic acid made the type I spermatozoa motile and elevated their respiratory rate. The type II spermatozoa were also immotile and the respiratory rate remained quite low for about 5 min after the dilution. Thereafter, they spontaneously became motile and the respiratory rate increased. The type III spermatozoa became motile upon their dilution and exhibited high respiratory rate. Differences in the motility and respiratory rate of spermatozoa among batches probably result from degree of their maturation. In moving spermatozoa, the ADP and AMP levels increased at the expense of ATP. 2,4-Dinitrophenol elevated the respiratory rate only in immotile spermatozoa, which showed a high ATP level and quite low ADP level, but did not made them motile. Oligomycin inhibited the respiration of both motile and immotile spermatozoa. Probably, the respiratory rate is made low by a shortage of ADP in immotile spermatozoa and is enhanced by ADP production due to the initiation of their movement.