INTRA‐CELLULAR AND EXTRA‐CELLULAR TOXINS IN THE RED TIDE DINOFLAGELLATE,GYMNODINIUM BREVE

The marine dinoflagellate, Gymnodinium breve (Davis), produces several neurotoxins that cause neurotoxic shellfish poisoning (nsp), massive fish kills and respiratory irritation in marine mammals and humans. The common method for discerning toxic levels of G. breve for public health advisories is enumeration of live cells in a given water mass. In this study, laboratory cultures, as well as natural blooms, were added to a stirred ultra‐filtration cell concentrator to separate viable cells containing intra‐cell toxins from ambient water containing extra‐cell toxins. Methods were validated using various mixtures of lysed and whole G. breve laboratory culture. Extractions and recovery of brevetoxins were done using a C‐18 bonded‐phase glass fiber extraction disc eluted with methanol. Total PbTx toxin concentrations were quantified by HPLC/UV using a C‐18 column and an 85:15 methanol:water (1 ml min^?1) isocratic elution at 215 nm. This method of separation and extraction was subsequently applied to water samples collected during natural blooms along two different areas of the Florida Gulf coast. The results indicated that early stages of G. breve blooms contained primarily intra‐cell toxins with extra‐cell toxins increasing as the bloom progressed, even though very few viable G. breve cells were present. This suggests that enumeration of cells alone may be insufficient and additional toxin quantitation is necessary.     

DIEL PHASING OF THE CELL-CYCLE IN THE FLORIDA RED TIDE DINOFLAGELLATE, GYMNODINIUM BREVE

The diel cycle is a key regulator of the cell-cycle in many dinoflagellates, but the mechanisms by which the diel cycle entrains the cell-cycle remain poorly understood. In this study, we describe diel phasing of the cell-cycle in the Florida red tide dinoflagellate Gymnodinium breve Davis, determine the diel cue which serves to entrain the cell-cycle, and provide evidence for the presence of cyclin-dependent kinase (CDK), a cell-cycle regulator which may be responsive to this cue. Four laboratory isolates from the West Coast of Florida were compared. When grown on a 16:8 h LD cycle, all isolates displayed phased cell division, with the S-phase beginning 6–8 h into the light phase, and mitosis following 12–14 h later, as determined by flow cytometry. A naturally occurring bloom of G. breve, studied over one diel cycle, displayed diel cell-cycle phasing similar to that in the laboratory cultures, with the S-phase beginning during daylight and the peak of mitosis occurring approximately 4 h after sunset. In the laboratory cultures, the dark/light "dawn" transition was found to provide the diel cue which serves to entrain the G. breve cell-cycle, whereas the light/ dark "dusk" transition did not appear to be involved. Evidence for the presence of CDK in G. breve was obtained using two approaches: (1) identification of a 34-kDa protein, immunoreactive to an antibody against a conserved amino acid sequence (α-PSTAIR) unique to the CDK protein family and (2) inhibition of the cell-cycle by olomoucine, a selective CDK inhibitor. Together, these results provide the basis from which one can begin addressing mechanisms by which the diel cycle regulates the cell-cycle in G. breve.     

ULTRASTRUCTURAL ASPECTS OF SEXUAL REPRODUCTION IN THE RED TIDE DINOFLAGELLATE GONYAULAX TAMARENSIS1

The marine dinoflagellate Gonyaulax tamarensis Lebour is best known for its propensity to form blooms known as red tides in coastal waters worldwide. This paper examines the sexual cycle of this organism using light and electron microscopy. Sexual reproduction begins with contact between thecate gametes which subsequently shed their thecae to fuse along their pellicular layers. Nuclear fusion occurs well after cytoplasmic fusion and is characterized by several distinctive features: a highly vesiculate nucleoplasm without microtubules; nucleoli and V-shaped chromosomes abut the nuclear envelope distal to the region of nuclear contact; and each chromosome possesses a longitudinal line, the central chromosomal axis. Fusion results in a planozygote with numerous cytoplasmic storage products and a slightly thickened layer beneath the pellicle. Subsequent loss of thecal plates and a thickening of the sub-pellicular layer results in a non-motile hypnozygote. A newly-formed hypnozygote possesses numerous minute papillae along its outer surface, formed by the up-folding of the accumulating wall layer. Maturation of the hypnozygote wall results in a smooth three-layered wall, the outermost layer of which is the pellicular layer. Hypnozygote germination produces a large quadriflagellate plan-omeiocyte with a single nucleus and thecal plates identical to vegetative cells. Two subsequent divisions, presumably meiotic, result in Jour cells morphologically identical to vegetative cells.     

SPONTANEOUS AND STIMULATED BIOLUMINESCENCE OF THE DINOFLAGELLATE CERATOCORYS HORRZDA (PERIDINIALES)1

This is the first report of spontaneous bioluminescence in the autotrophic dinoflagellate Ceratocorys horrida von Stein. Bioluminescence was measured, using an automated data acquisition system, in a strain of cultured cells isolated from the Sargasso Sea. Ceratocorys horrida is only the second dinoflagellate species to exhibit rhythmicity in the rate of spontaneous flashing, flash quantum flux (intensity), and level of spontaneous glowing. The rate of spontaneous flashing was maximal during hours 2–4 of the dark phase [i.e. circadian time (CT)16–18 for a 14:10 h LD cycle (LD14:10)], with approximately 2% of the population flashing-min^?1, a rate approximately one order of magnitude greater than that of the dinoflagellate Gonyaulax polyedra. Flash quantum flux was also maximal during this period. Spontaneous flashes were 134 ms in duration with a maximum flux (intensity) of 3.1×10⁹ quanta-s^?1. Light emission presumably originated from blue fluorescent microsources distributed in the cell periphery and not from the spines. Values of both spontaneous flash rate and maximum flux were independent of cell concentration. Isolated cells also produced spontaneous flashes. Spontaneous glowing was dim except for a peak of 6.4× 10⁴quanta-s^?1 cell^?1, which occurred at CT22.9 for LD14:10 and at CT22.8 for LD12:12. The total integrated emission of spontaneous flashing and glowing during the dark phase was 4×10⁹ quantacell^?1, equivalent to the total stimulable luminescence. The rhythms for C. horrida flash and glow behavior were similar to those of Gonyaulax polyedra, although flash rate and quantum flux were greater. Spontaneous bioluminescence in C. horrida may be a circadian rhythm because it persisted for at least three cycles in constant dark conditions. This is also the first detailed study of the stimulated bioluminescence of C. horrida, which also displayed a diurnal rhythm. Cultures exhibited >200 times more mechanically stimulated bioluminescence during the dark phase than during the light phase. Mechanical stimulation during the dark phase resulted in 6.7 flashes. cell^?1; flashes were brighter and longer in duration than spontaneous flashes. Cruise-collected cells exhibited variability in quantum flux with few differences in flash kinetics. The role of dinoflagellate spontaneous bioluminescence in the dynamics of near-surface oceanic communities is unknown, but it may be an important source of natural in situ bioluminescence.     

CELL CYCLE REGULATORS IN THE FLORIDA RED TIDE DINOFLAGELLATE, GYMNODINIUM BREVE

The diel cycle is a key regulator of the cell cycle in many dinoflagellates, and may play a rate limiting role in bloom formation. Diel phasing of the cell cycle in the Florida red tide dinoflagellate, Gymnodinium breve Davis was previously described in our laboratory. In cultures grown on a 16:8 light:dark cycle, S-phase began 6–8 h into the light phase, and mitosis followed 12–14 h later. The dark/light "dawn" transition was found to provide the diel cue that serves to entrain the G. breve cell cycle. However the cell cycle mechanisms and regulators acted upon by this cue are poorly understood in dinoflagellates. The cell cycle regulatory complex, CDK1-cyclinB, is therefore currently being investigated. Cyclin dependent kinase (CDK) was first identified in G. breve using two approaches: (1) identification of a 34 kDa protein immunoreactive to an antibody raised against a conserved amino acid sequence unique to the CDK protein family (PSTAIR) and (2) inhibition of the cell cycle by olomoucine, a selective CDK inhibitor. Several approaches are currently being employed in order to describe its partner, cyclin B: (1) PCR on genomic DNA with primers deduced from known cyclin box sequences, (2) G. breve expression library screening with an antibody raised against the fission yeast cyclin B (3) western blot analysis on whole protein extracts and cyclin B immunoprecipitated proteins. Current work focuses on the differential expression of the cyclin B homologue in G. breve during its cell cycle and its relation to diel cycle control.     

CYST FORMATION IN THE RED TIDE DINOFLAGELLATE ALEXANDRIUM TAMARENSE (DINOPHYCEAE): EFFECTS OF IRON STRESS1

The toxic red tide dinoflagellate Alexandrium tamarense (Lebour) Balech (synonymous with Protogonyaulax tamarensis (Lebour) Taylor) was subjected to iron stress in batch culture over a 24-day time course. Monitoring of life history stages indicated that iron stress induced formation of both temporary (= pellicular) and resting (= hypnozygotic) cysts. Our experimental induction of sexuality appeared to be associated with iron limitation rather than the total depletion of biologically available iron. Degenerative changes in organelle (i.e. chloroplast, mitochondrion and chromosome) ultrastructure were largely restricted to pellicular cysts, suggesting that these temporary cysts were more susceptible to short-term iron stress effects than were hypnozygotes. These results are consistent with the hypothesized ecological roles of cysts in maintaining viability over brief (pellicular cysts) and extended (hypnozygotes) exposure to adverse environmental conditions.     

PHOTOINHIBITION OF MECHANICALLY STIMULABLE BIOLUMINESCENCE IN THE HETEROTROPHIC DINOFLAGELLATE PROTOPERIDINIUM DEPRESSUM (PYRROPHYTA)1

Photoinhibition of mechanically stimulable bioluminescence (MSL) in the heterotrophic dinoflagellate Protoperidinium depressum Bailey was investigated using samples collected from the Massachusetts and southern Texas coasts. The times for both photoinhibition of MSL (ca. 10 min) and dark recovery from photoinhibition of MSL (ca. 45 min) in this species were similar to those reported for autotrophic dinoflagellates. The degree of photoinhibition of MSL was a linear function of the logarithm of photon flux density (PFD). The threshold PFDs for the photoinhibition of MSL were 0.02, 0.6, and 21 μmol photons · m^?2· s^?1 for broad-band blue, green, and red light, respectively. These PFDs are lower than those required for photoinhibition of MSL by the autotrophic dinoflagellates Pyrocystis lunula and Ceratium fusus. We speculate that photosynthetic pigments in autotrophic dinoflagellates shield the photoreceptor that causes photoinhibition of MSL, thus lowering the sensitivity of these dinoflagellates to light. When field-collected P. depressum were kept in the laboratory without growth for a week, photoinhibition of MSL's sensitivity to light increased progressively along with 1) a decrease in its bioluminescence capacity (BCAP), 2) a decrease in the ratio of MSL to BCAP (MSL/BCAP), and 3) a decrease in the orange pigmentation (probably carotenoid) of the dinoflagellate. The action spectrum for photoinhibition of MSL in P. depressum was characterized primarily with a broad peak in the blue extending into the green. We suggest that carotenoid was not a photoreceptor for the photoinhibition of MSL in P. depressum because the peak of the action spectrum was too broad and extended too far into the green part of the spectrum, and because the orange pigment present decreased as photoinhibition of MSL became more sensitive to light.     

ROLE OF CALCIUM IN THE CALLOSE RESPONSE OF SELF-POLLINATED BRASSICA STIGMAS

In Brassica oleracea, sporophytic self-incompatibility prevents germination of self pollen, or normal growth of self pollen tubes. After self-pollination, the papillae of stigmas synthesize callose. The role of Ca⁺⁺ in the formation of stigmatic callose was tested by adding compounds that interact with Ca⁺⁺ to suspensions of pollen that were known to induce callose formation in self stigmas. The calcium channel antagonist, lanthanum, and the calcium chelating agent, EGTA, reduced or abolished the callose response to self-pollen suspensions. In the presence of Ca⁺⁺, the calcium ionophore, A23187, induced callose in stigmatic papillae when added to pollen suspensions, or alone. Therefore, callose deposition in response to incompatible pollinations appears to be a calcium-dependent process. Pretreatment of pistils with 100 μm 2-deoxy-D-glucose abolished the callose response to self-pollination, while self pollen remained inhibited and cross pollen grew normally in treated pistils. Thus, callose formation in the stigma is not an essential part of the self-incompatibility mechanism preventing the growth of self pollen in Brassica.     

肺机械扩张增进表面活性物质分泌机制的研究

采用大鼠离体肺灌流模型,观察肺泡灌洗液中肺表面活性物质(PS)含量的变化。结果表明:在增大潮气量机械扩张肺时PS分泌显著增加(p<0.05),该分泌增加现象能被细胞松弛素B及硝苯吡啶所抑制(p<0.05),但不为细胞外缺钙所抑制(p>0.05)。从而提示扩张所引起的PS分泌增加可能与细胞内的收缩结构有关,而与细胞外钙离子无关。     

THE ROLE OF SECONDARY PIT CONNECTIONS IN RED ALGAL PARASITISM1

Secondary pit connections are common between cells of hosts and parasites in the widespread phenomenon of red algal parasitism. The DNA-specific fluorochrome 4′,-6-diamidino-2-phenylindole (DAPI) reveals that in host-parasite secondary pit connection (SPC) formation between the parasitic red alga Choreocolax polysiphoniae and its host Polysiphonia confusa, a nucleus and other cytoplasmic components of the parasite are delivered into the cytoplasm of a host cell. Host cells receive large numbers of parasite nuclei and these, apparently arrested in G¹, are maintained intact in host cells for periods of several weeks. Within these enlarged, differentiated cells, starch accumulates and cytoplasmic organelles proliferate as the central vacuole decreases in size. Host nuclear DNA synthesis is stimulated in the infected host cell, resulting in an increase in the number of host nuclei, or an increase in DNA in each of the existing host nuclei (i.e. somatic polyploidy). Occasionally, infected host cells will recommence division and engender a new host branch. Microspectrofluorometry of nuclear DNA quantitatively confirms not only the identity and transfer of parasite nuclei to host cells, but also the transfer of parasite nuclei to other parasite cells. Measurements also reveal that the single nucleus of Choreocolax becomes progressively more polyploid as cells become larger and more highly differentiated. Secondary pit connection formation between Choreocolax and Polysiphonia provides the mechanism for the transfer of parasite genetic information (via the parasite nucleus and cytoplasm) into the host. The parasite nuclei may thereby control and redirect the physiology of the host for the benefit of the parasite.     

Ca~(2+)在粟酒裂殖酵母细胞周期时相中的作用

以粟酒裂殖酵母(Schizosaccharomyces pombe)为研究材料,研究了Ca~(2+)在细胞周期时相中的作用。当外源Ca~(2+)浓度在0.5-20 mmol/L范围内,随Ca~(2+)浓度增加,细胞增殖速度加快,延滞期逐渐缩短。但SD-Ca（CaCl2省略）并不能终止Sch. pombe的细胞周期。采用缺氮对群体细胞进行同步化,并以EGTA 螯合培养介质中低浓度的Ca~(2+),Sch. pombe 细胞增殖被完全抑制,细胞流式法测定结果表明：细胞周期被终止在G1期。分析认为Ca~(2+) 对Sch. pombe 细胞增殖是必不可少的,外源Ca~(2+)在G1期向S期转化过程中起着关键性的作用。     

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.     

THE ESSENTIAL ROLE OF CALCIUM ION IN POLLEN GERMINATION AND POLLEN TUBE GROWTH

Brewbaker, James L., and Beyoung H. Kwack. (U. Hawaii, Honolulu.) The essential role of calcium ion in pollen germination and pollen tube growth. Amer. Jour. Bot. 50(9): 859–865. Illus. 1963.—A pollen population effect occurs whenever pollen grains are grown in vitro. Small pollen populations germinate and grow poorly if at all, under conditions which support excellent growth of large pollen populations. The pollen population effect is overcome completely by a growth factor obtained in water extracts of many plant tissues. This factor is shown to be the calcium ion, and its action confirmed in 86 species representing 39 plant families. Other ions (K⁺, Mg⁺⁺, Na⁺) serve in supporting roles to the uptake or binding of calcium. The high requirement of calcium (300–5000 ppm, as Ca (NO₃)₂·4H₂O, for optimum growth) and low calcium content of most pollen may conspire to give calcium a governing role in the growth of pollen tubes both in vitro and in situ. It is suspected that ramifications of this role extend to the self-incompatibilities of plants and to the curious types of arrested tube growth distinguishing, for example, the orchids. A culture medium which proved its merit in a wide variety of pollen growth studies included, in distilled water, 10% sucrose, 100 ppm H₃BO₃, 300 ppm Ca (NO₃)₂·4H₂O, 200 ppm MgSO₄·7H₂O and 100 ppm KNO₃.     

LFA-1/ICAM-1在ConA诱导的小鼠胸腺细胞活化中的作用

用抗LFA-1/ICAM-1粘附分子单克隆抗体和ConA联合刺激小鼠胸腺细胞,初步研究了该膜分子在经TCR/CD3介导的胸腺细胞活化信号传导以及胸腺细胞亚群选择中的作用。在ConA刺激系统中,抗ALFA-1/ICAM-1单抗均能抑制胸腺细胞的增殖应答,且以抗LFA-1单抗的作用更为显著;而在PMA加钙离子载体A23187刺激体系中,抗LFA-1单抗却表现出明显的促活化效应。当加入IL-2 时,抗LFA——1/ICAM-1单抗便不能抑制ConA刺激的胸腺细胞活化。此外,抗体对已活化的胸腺母细胞增殖也无影响。FACS分析的结果还显示,抗LFA-1单抗可明显降低CD4~-CD8~ 胸腺细胞亚群的比例,而抗ICAM-1单抗对此无影响。表明胸腺细胞表面粘附分子LFA-1具有直接参与TCR/CD3途径介导的跨膜信号传导的功能,并对CD4~-CD8~ 胸腺细胞亚群的功能分化与成熟可能起重要作用。     

OBSERVATIONS ON THE PECULIAR DIURNAL MIGRATION OF A RED TIDE DINOPHYCEAE IN TROPICAL SHALLOW WATERS1

The dinoflagellate Peridinium cf. quinquecorne Abé forms red tide-like blooms in eutrophic shallow waters in the Philippines. The organism moves into a distinct near-surface layer when intensive solar radiation occurs, but only during the incoming tide. Shortly before high tide, regardless of light levels, the dinoflagellates seem to disappear. Simple experiments show that once intensive radiation has been reduced Peridinium quinquecorne moves out of the water column and attaches itself to solid objects away from the light. The morphology of the organism, especially as related to attachment, was studied through SEM. Its high swimming velocity and the reaction to radiation and tidal changes are described. The possibility that, superimposed on its reaction to light, this dinoflagellate may follow intrinsic tide-dependent oscillations is discussed.     

THE ROLE OF F-ACTIN DURING FERTILIZATION IN THE RED ALGA AGLAOTHAMNION OOSUMIENSE (RHODOPHYTA)

The actin cytoskeletons in spermatia and trichogynes of Aglaothamnion oosumiense Itono were studied using fluorescein isothiocyanate (FITC) conjugated phalloidin and the cytoskeletal inhibitors, potassium iodide (KI), cytochalasin-B, and latrunculin-A. Microfilaments were localized to the distal ends of elongated spermatia and trichogynes and were more prominent in the trichogyne before spermatium binding. The actin cytoskeleton in spermatia and trichogynes was disrupted by treatment with 0.6 M KI, 100 μM cytochalasin-B, or 10 μM latrunculin-A. The actin cytoskeleton in trichogynes recovered within 24 h of removal from the inhibitor, but no recovery was observed in spermatia. Spermatial nuclei entered mitosis as soon as spermatia attached to the trichogyne. The greatest percentage (50%– 60%) of spermatia having completed mitosis was obtained at 60 min after spermatial binding to trichogynes. During mitosis, actin accumulated in the center of the spermatium, thereby separating the two daughter nuclei. Cytoskeletal inhibitors did not affect initial binding of spermatia to trichogynes but did block subsequent stages of fertilization, including spermatial mitosis and gamete fusion. The accumulation of cellulose or β-linked polysaccharide on the spermatial surface was also blocked by treatment with actin inhibitors. Exposure of the trichogyne to actin inhibitors after gamete fusion caused spermatial nuclei in trichogynes to stop moving and to condense. These results suggest that the microfilaments involved in nuclear division, cellulose deposition into the spermatial wall, gamete fusion, and migration of spermatial nuclei in trichogynes during fertilization in Aglaothamnion oosumiense.     

ROLE OF CALCIUM IN POTASSIUM UPTAKE BY PLANT ROOTS

The effects of EDTA·Mg or GEDTA·Mg on the uptakeof nutrient ions, the release of Ca⁺⁺ and nucleotides into themedium and the nucleic acid contents in rice and red bean rootswere investigated.

1. Both EDTA and EDTA·Mg induced similarly the release ofCa from roots.
2. EDTA·Mg as well as EDTA brought abouta significant repressionin K uptake, but had an insignificantor no effect on P, NH₄and NO₃ uptakes. EDTA·Ca did notrepress K, P, NH₄ andNO₃ uptakes.
3. EDTA or GEDTA acceleratedthe degradation of nucleic acid andthe release of nucleotides,while EDTA·Mg or GEDTA·Mghad no such effect.

These results indicate that the indispensable role of intracellularCa in K uptake does not appear to be directly associated withRNA metabolism. (Received July 29, 1965; )     

钙在IAA诱导绿豆下胚轴原生质体膨大过程中的作用

含钙培养液(对照)和仅用IAA处理的原生质体的体积和~(45)Ca~(2 )放射性强度均无变化。IAA处理含钙培养液中的原生质体,5min后~(45)Ca~(2 )积累明显增多,体积开始膨大。处理30min时~(45)Ca~(2 )积累最多,此时原生质体的膨大效应最好;随后~(45)Ca~(2 )积累和膨大效应逐渐下降。K~ 、Zn~(2 )、Ba~(2 )、Mg~(2 )等也可在一定程度上代替Ca~(2 )使原生质体体积膨大。原生质体的吸水在膨大中起着一定作用。EGTA、LaCl_3和verapamil均抑制IAA诱导的原生质体~(45)Ca~(2 )积累和体积膨大。说明Ca~(2 )可能在6-BA诱导原生质体膨大的过程中起着重要作用。     

THE ROLE OF METABOLISM AND CALCIUM IN THE CONTROL OF MITOSIS AND OOPLASMIC MOVEMENTS IN INSECT EGGS: A WORKING HYPOTHESIS

Patterns of mitosis and ooplasmic movements in the plasmodial phase of insect embryogenesis and their supramolecular basis are reviewed. Evidence is provided for both the relative independence and the precise correlation of the nuclear cycle and various cycling movements of the ooplasm. I suggest that the timing of these cycles is controlled by a metabolic cycle. The latter may act via a cyclic rise and fall either of the level of free calcium or of the sensitivity of contractile cytoplasmic proteins to a constant level of free calcium. Thus mitotic patterns may reflect metabolic patterns, which in turn may reflect the distribution and activity of mitochondria and may also be related to egg size and shape by a gradient of surface-to-volume ratios. The total number of cycles may depend on a limiting cytoplasmic factor, which together with the number of nuclei in a given cycle defines the nucleo-cytoplasmic ratio. I also propose that both natural and experimental activation of insect eggs trigger the metabolic cycle either directly, by supplying oxygen or water, or indirectly, via a calcium pulse. Possible molecular mechanisms of control are discussed and applied to mitosis and ooplasmic movements. A brief discussion of various cell cycle models in light of data from insect embryogenesis is included.