Pyridine nucleotide metabolites stimulate calcium release from sea urchin egg microsomes desensitized to inositol trisphosphate

Inositol trisphosphate (IP3) was previously shown to release Ca2+ from a nonmitochondrial store in sea urchin eggs. In this study, egg homogenates and purified microsomes were monitored with either fura 2 or Ca2+-sensitive minielectrodes to determine whether other stimuli would induce Ca2+ release. Pyridine nucleotides (whose concentrations are known to change at fertilization) were found to release nearly as much Ca2+ as did IP3. Average releases/ml of homogenate were: 0.6 microM IP3, 10.9 nmol of Ca2+; 50 microM NADP, 7.3 nmol of Ca2+; and 100 microM NAD, 6.5 nmol of Ca2+ (n = 6). Specificity was demonstrated by screening a series of other phosphorylated metabolites, and none was found to reproducibly release Ca2+. Calcium release induced by IP3 or NADP was immediate, whereas a lag of 1-4 min occurred with NAD. This lag before NAD-induced Ca2+ release led to the discovery that a soluble egg factor (Mr greater than 100,000) converts NAD into a highly active metabolite that releases Ca2+ without a lag. The NAD metabolite (E-NAD) was purified to homogeneity by high pressure liquid chromatography and produced half-maximal Ca2+ release at about 40 nM. Injection of E-NAD into intact eggs produced both an increase in intracellular Ca2+ (as assayed with indo-1) and a cortical reaction. Following Ca2+ release by each of the active agents (IP3, NAD, and NADP), the homogenates resequestered the released Ca2+ but were desensitized to further addition of the same agent. A series of desensitization experiments showed that homogenates desensitized to any two of these agents still responded to the third, indicating the presence of three independent Ca2+ release mechanisms. This is further supported by experiments using Percoll density gradient centrifugation in which NADP-sensitive microsomes were partially separated from those sensitive to IP3 and NAD.     

Specific binding of cyclic ADP-ribose to calcium-storing microsomes from sea urchin eggs.

Cyclic ADP-ribose (cADPR) is a metabolite of NAD+ which is as active as inositol trisphosphate (IP3) in mobilizing intracellular Ca2+ in sea urchin eggs. The enzyme responsible for synthesizing cADPR is found not only in sea urchin eggs but also in various mammalian tissue extracts, suggesting that it may be a general messenger for Ca2+ mobilization in cells. In this study I address questions of whether an intracellular receptor for cADPR exists and, if so, whether it is different from the IP3 receptor. A procedure employing nitrogen decompression was used to homogenize sea urchin eggs, and the Ca2(+)-storing microsomes were separated from mitochondria and other organelles by Percoll density centrifugation. Radioactive cADPR with high specific activity was produced by incubating [32P]NAD+ with the synthesizing enzyme and the product purified by high pressure liquid chromatography. The enzyme was membrane bound and was isolated from dog brain extracts by sucrose density gradient centrifugation. Partial purification of the enzyme was achieved by DEAE ion-exchange chromatography after solubilization with 3-[(cholamidopropyl)dimethylammonio]-1-propanesulfonate. Specific binding of 32P-labeled cADPR to a saturable site on the Ca2(+)-storing microsomes was detected by a filtration assay. Scatchard analysis indicated a binding affinity of about 17 nM and a capacity of about 25 fmol/mg protein. The binding was not affected by either NAD+ (the precursor) or ADP-ribose (the hydrolysis product) at 0.5 microM but was eliminated by 0.3 microM nonlabeled cADPR. The receptor for cADPR appeared to be different from that of IP3 since IP3 was not an effective competitor at a concentration as high as 3 microM. Similarly, heparin at a concentration that inhibits most of the IP3-induced calcium release from the microsomes did not affect the binding. The binding showed a prominent pH optimum at about 6.7. Calcium at 40 microM decreased the binding by about 50%. These dependencies of the binding on pH and Ca2+ are different from those reported for the IP3 receptor and provide further support that the intracellular receptors for cADPR and IP3 are different.     

Inositol trisphosphate induces calcium release from nonmitochondrial stores i sea urchin egg homogenates

This study presents evidence that inositol trisphosphate (IP3) releases Ca2+ from intracellular stores in sea urchin eggs. First, high voltage discharge was used to transiently permeabilize eggs and introduce IP3; the resultant induction of cortical reactions (a well characterized Ca2+-dependent event) provided indirect evidence that IP3 released Ca2+ from intracellular stores. Next, Ca2+ uptake and release from egg homogenates and homogenate fractions were monitored by both Ca2+ minielectrodes and the fluorescent Ca2+ indicator, quin-2. Both assay methods showed Ca2+ release upon IP3 addition, with a half-maximal response at 50-60 nM IP3 and maximal Ca2+ release at approximately 1 microM IP3. Homogenates were 300-fold more sensitive to IP3 than IP2, and Ca2+ release was 95% inhibited by the Ca2+ antagonist TMB-8 (3 mM). Fractionation by density gradient centrifugation showed that activities for Ca2+ sequestration and IP3 responsiveness co-purified with endoplasmic reticulum microsomes. Following an initial IP3 addition, homogenates were refractory (desensitized) to additional IP3. However, if homogenates were centrifuged and the vesicles resuspended in media lacking IP3, they would respond to added IP3, therefore, showing that desensitization is most likely due to the presence of IP3. This study also shows that the mechanism of IP3 action is inherent to the microsomes and ions present in the medium used, with no cytoplasmic factors being required. The stability of this microsome preparation and the purification obtained with density gradient centrifugation make this a promising system with which to further characterize the mechanism of IP3 action.     

Intracellular calcium release at fertilization in the sea urchin egg.

Fertilization or ionophore activation of Lytechinus pictus eggs can be monitored after injection with the Ca-sensitive photoprotein aequorin to estimate calcium release during activation. We estimate the peak calcium transient to reach concentrations of 2.5–4.5 μM free calcium 45–60 sec after activation and to last 2$\text{3}\text{?}$ min, assuming equal Ca²⁺ release throughout the cytoplasm. Calcium is released from an intracellular store, since similar responses are obtained during fertilization at a wide range of external calcium concentrations or in zerocalcium seawater in ionophore activations. In another effort to estimate free calcium at fertilization, we isolated egg cortices, added back calcium quantitatively, and fixed for observation with a scanning electron microscope. In this way, we determined that the threshold for discharge of the cortical granules is between 9 and 18 μM Ca²⁺. Therefore, the threshold for the in vitro cortical reaction is about five times the amount of free calcium, assuming equal distribution in the egg. This result suggests that transient calcium release is confined to the inner subsurface of the egg.     

Cyclic activation of histone H1 kinase during sea urchin egg mitotic divisions

Fertilized sea urchin eggs undergo a series of rapid and synchronized mitotic divisions. Extracts were made at various times throughout the first three mitotic divisions and assayed for phosphorylating activity toward histone H1. Histone H1 kinase (HH1K) undergoes a transient activation (8- to 10-fold increase) 20 min before each cleavage. The amplitude of the HH1K peak strongly depends on the synchrony of the egg population. Concomitant cytological observations show that the time-course of HH1K correlates with the time-course of nuclear envelope breakdown and of metaphase. This correlation is observed at each cell division cycle. HH1K from each of the three first mitoses show identical time- and concentration-dependence curves as well as identical dose-inhibition curves with 6-dimethylaminopurine and quercetin, suggesting that the same (group of) kinase(s) is (are) activated before each cleavage. Ionophore A23187 does not trigger, but inhibits, HH1K activation; however, partial activation of the eggs with ammonia at pH 9.0 (but not at pH 8.0) triggers the transient HH1K activation. Appearance of the HH1K cycle requires protein synthesis since it is completely abolished in emetine-treated eggs. Although cytochalasin B blocks egg cleavage, it does not inhibit HH1K activation nor nuclear divisions. A prolonged HH1K activation cycle is observed in eggs arrested in metaphase with colchicine or nocodazole. Despite the existence of a cycle in cAMP concentration during mitosis, forskolin, an activator of adenylate cyclase, does not modify the time-course of HH1K activation and of cell division. The cycling HH1K is independent of calcium-calmodulin, calcium-phospholipids, or cyclic AMP. It clearly resembles the mammalian "growth-associated histone kinase." The relationship between the transient activation of HH1K and the intracellular mitotic factors driving the cell cycle is discussed.     

Protein tyrosine kinase-dependent release of intracellular calcium in the sea urchin egg

The aminoguanide, methylglyoxal bis(guanylhydrazone) (MGBG), was shown to stimulate phosphorylation of RR-SRC, a synthetic protein tyrosine kinase (PTK) substrate, and different levels of tyrosyl phosphorylation of endogenous proteins in a sea urchin egg membrane-cortex preparation. Stimulating protein tyrosine kinase activity in the sea urchin egg stimulated intracellular Ca2+ release, because microinjection of 1-5 mM of MGBG into unfertilized eggs triggered a transient rise in intracellular Ca2+ activity ([Ca2+]i) after a brief latent period. Pretreating eggs with PTK-specific inhibitors, genistein or tyrphostin B42, significantly inhibited the MGBG-induced rise in [Ca2+]i. Methylglyoxal bis(guanylhydrazone) stimulation of PTK activities in the unfertilized sea urchin egg appeared to trigger Ca2+ release through phospholipase C (PLC)-dependent inositol 1,4,5-trisphosphate (InsP3) production. The MGBG-induced Ca2+ response could be suppressed in eggs preloaded with the InsP3 receptor antagonist, heparin, and was reduced in eggs pretreated with U73122, a PLC inhibitor. However, the response was unchanged in eggs treated with nicotinamide, an inhibitor of ADP-ribosyl cyclase, or nifedipine, an inhibitor of nicotinic acid adenine dinucleotide phosphate activity. These results suggest that MGBG may be useful as a chemical agonist of PTK in sea urchin eggs and allow direct testing of the PTK requirement for the transient rise in [Ca2+]i in sea urchin eggs during fertilization. Although genistein was observed to significantly delay the onset, the sperm-induced Ca2+ response in PTK inhibitor-loaded eggs otherwise appeared normal. Therefore, it was concluded that sea urchin eggs contain a PTK-dependent pathway that can mediate intracellular Ca2+ release, but PTK activity does not appear to be required for the fertilization response.     

Polycation inhibition of exocytosis from sea urchin egg cortex

Summary The Ca²⁺-stimulated release of vesicle contents from cortical fragments prepared from sea urchin eggs is an in vitro model for exocytosis. Cortical fragments have been isolated either in suspension (cell surface complex, CSC preparation), or attached to polycation-coated surfaces (cortical lawn, CL preparation). CL, but not CSC, have been reported to undergo a rapid aging process whereby they fail to respond to micromolar free Ca²⁺. Since, in principle, the only difference between the two preparations is the use of polycations in the CL preparation, polycations were suspected of being inhibitory. This hypothesis was tested by evaluating the effects of polycation-containing buffers on the Ca²⁺ threshold, rate, and extent of exocytosis in CL prepared from the eggs ofStrongylocentrotus purpuratus. A sensitive microphotometric assay, based on light scattering by the individual cortical vesicles in the CL, was used to quantitate the exocytotic response. Buffers containing polylysine were found to be potent inhibitors of cortical exocytosis. The Ca²⁺ threshold of CL that had been treated for 15 min at room temperature with 50 g/ml of polylysine was more than three orders of magnitude greater than that of freshly prepared CL. The other polycations tested (protamine, spermine and neomycin) were also found to be inhibitory, but to a lesser degree than polylysine. Two lines of evidence suggested that the polycations used in the preparation of CL are responsible for the rapid aging phenomenon: (i) CSC fragments that had been affixed to polylysine-coated coverslips were shown to aquire aging characteristics similar to the CL preparations; control CSC that had been maintained in suspension did not. (ii) Radiolabeled poly-l-lysine was shown to dissociate from coated coverslips and redistribute onto CL.     

Store-operated calcium channels trigger exocytosis of the sea urchin sperm acrosomal vesicle

The acrosome reaction (AR) of sperm is a prerequisite for fusion with the egg. In sea urchins, the complete AR (CAR) consists of exocytosis of the acrosomal vesicle (AV) and polymerization of acrosomal actin to form the approximately 1 micro m long acrosomal process. The fucose sulfate polymer (FSP) of egg jelly stimulates Ca(2+) entry through two distinct Ca(2+) channels and induces the CAR. Here we report that the second channel is blocked by SKF96365 (SKF), an inhibitor of store-operated channels. SKF also blocks the thapsigargin (TG), trifluoperazine (TFP), and calmidizolium (CMZ) stimulated Ca(2+) entry into sperm. These data indicate that the second Ca(2+) channel is a store-operated channel (SOC) that may be regulated by calmodulin. The TG, TFP, and CMZ-induced intracellular Ca(2+) elevations are similar to those induced by FSP, but the sperm acrosomal process does not polymerize. An antibody to bindin, the major protein of the AV, showed that in a significant percentage of these drug-treated sperm, the AV had undergone exocytosis. When NH(4)Cl was added to increase intracellular pH, the TG-treated sperm polymerized actin to form the acrosomal process. We conclude that the second Ca(2+) channel of sea urchin sperm is a SOC that triggers AV exocytosis.     

Demonstration of calcium uptake and release by sea urchin egg cortical endoplasmic reticulum

The calcium indicator dye fluo-3/AM was loaded into the ER of isolated cortices of unfertilized eggs of the sea urchin Arbacia punctulata. Development of the fluorescent signal took from 8 to 40 min and usually required 1 mM ATP. The signal decreased to a minimum level within 30 s after perfusion with 1 microM InsP3 and increased within 5 min when InsP3 was replaced with 1 mM ATP. Also, the fluorescence signal was lowered rapidly by perfusion with 10 microM A23187 or 10 microM ionomycin. These findings demonstrate that the cortical ER is a site of ATP-dependent calcium sequestration and InsP3-induced calcium release. A light-induced wave of calcium release, traveling between 0.7 and 2.8 microns/s (average speed 1.4 microns/s, N = 8), was sometimes observed during time lapse recordings; it may therefore be possible to use the isolated cortex preparation to investigate the postfertilization calcium wave.     

Calcium uptake and release by isolated cortices and microsomes from the unfertilized egg of the sea urchin Strongylocentrotus droebachiensis

Isolated cortices from unfertilized sea urchin eggs sequester calcium in an ATP-dependent manner when incubated in a medium containing free calcium levels characteristic of the resting cell (approximately 0.1 microM). This ATP-dependent calcium uptake activity was measured in the presence of 5 mM Na azide to prevent mitochondrial accumulation, was increased by oxalate, and was blocked by 150 microM quercetin and 50 microM vanadate (known inhibitors of calcium uptake into the sarcoplasmic reticulum). Cortical regions preloaded with 45Ca in the presence of ATP were shown to dramatically increase their rate of calcium efflux upon the addition of (a) the calcium ionophore A23187 (10 microM), (b) trifluoperazine (200 microM), (c) concentrations of free calcium that activated cortical granule exocytosis, and (d) the calcium mobilizing agent inositol trisphosphate. This pool of calcium is most likely sequestered in the portion of the egg's endoplasmic reticulum that remains associated with the cortical region during its isolation. We have developed a method for obtaining a high yield of purified microsomal vesicles from whole eggs. This preparation also demonstrates ATP-dependent calcium sequestering activity which increases in the presence of oxalate and has similar sensitivities to calcium transport inhibitors; however, the isolated microsomal vesicles did not show any detectable release of calcium when exposed to inositol trisphosphate.     

Cytoskeleton of the unfertilized sea urchin egg

Unfertilized Paracentrotus lividus egg cytoskeleton is prepared by mild, nonionic detergent extraction at 4 degrees C in buffer systems containing either 2-methyl-2,4-pentanediol (hexylene glycol) or glycerol. These extractions allow the isolation of cytomatrices that maintain the egg form and are 70-80 micron in diameter. DNase inhibition assays show that actin is in polymerized form in these cytomatrices. Ultrastructural observations reveal that the cytoskeletons are made up essentially of 2 categories of filaments, 7-8-nm and 2-4-nm in diameter, respectively. After heavy meromyosin labelling, short, radiating actin filaments are seen in the cortical region, while longer actin filaments are found in the internal region of these cytomatrices. The 2-4-nm filaments of still unknown biochemical nature are organized in a meshwork. In contrast to results found with fertilized eggs, bundles of actin filaments and microtubules are absent; 8-13-nm filaments are not detected.     

Substructure of sea urchin egg cytoplasmic dynein

The substructure of the cytoplasmic dynein molecule was studied using the quick-freeze, deep-etch technique. Cytoplasmic dynein purified as a 12 S form from the eggs of the sea urchin Hemicentrotus pulcherrimus was composed of a single high molecular weight polypeptide. Rotary shadowing images of cytoplasmic dynein either sprayed on to a mica surface or quick-frozen on mica flakes demonstrated a single-headed molecule, in contrast to the two-headed molecule of sea urchin sperm flagellar 21 S dynein. More detailed substructure was visualized by rotary shadowing after quick-freeze deep-etching. Cytoplasmic dynein consisted of a head and a stem. The head was pear-shaped (16 nm X 11 nm) and a little smaller than the pear-shaped head of 21 S dynein (18 nm X 14 nm). The form of the stem was irregular, and its apparent length varied from 0 to 32 nm. Binding of cytoplasmic dynein to brain microtubule in the solution was observed by negative staining, and that in the precipitate was examined by the quick-freeze, deep-etch method as well. Both methods revealed the presence of two kinds of microtubules, one a fully decorated microtubule and the other a non-decorated microtubule. Cytoplasmic dynein bound to microtubule also appeared as a globular particle. Neither the periodic binding nor the crossbridges that were observed with 21 S dynein were formed by cytoplasmic dynein, although cytoplasmic dynein appeared to bind to microtubules co-operatively.