Sequence analysis of translationally controlled maternal mRNAs from Urechis caupo

Fertilization of Urechis coupo oocytes stimulates dramatic changes in the pattern of protein synthesis. This shift is brought about entirely through selective translation of the large pool of maternal mRNAs synthesized and stored during oogenesis. My laboratory has identified cDNA clones to more than 20 different Urechis maternal mRNAs. These have been used to determine whether the complementary mRNAs are translated in oocytes or embryos, and to analyze the polyad-enylation status of the mRNAs at different stages. For 14 of the mRNAs, multiple, overlapping cDNA clones were isolated, and the complete sequence of the mRNA molecule was determined. Of these 14 mRNAs, half are from the subset that is translated in growing and full-grown oocytes, but not in embryos. These 7 mRNAs have poly(A) tails before fertilization. The other 7 are from the subset that is not translated at any time before fertilization, and has very short poly(A) tails in oocytes. After fertilization these mRNAs are recruited onto polysomes and extensively polyadenylated. The sequence data from the two classes of maternal mRNAs was compared in an attempt to identify consensus sequences that could regulate translation directly, or indirectly, by controlling polyadenylation or secondary structure formation. Two features of the sequences correlate very well with the translation and polyadenylation of the different mRNAs-the identity of the base immediately preceding the AUG start codon, and the presence of the sequences UUUUA and UUUUUA in the 3′ untranslated region. © 1993 Wiley-Liss, Inc.     

Calcium influx following fertilization of Urechis caupo eggs.

Measurements of ⁴⁵Ca flux into and out of Urechis eggs indicate that, during the first 10 min after insemination, the eggs take up 0.24 pmole of Ca/egg. Total egg Ca measured by atomic absorption (AA) spectroscopy increased by 0.23 pmole of Ca/egg (0.56, 0.79, and 0.76 pmole of Ca/egg for unfertilized, 10-min fertilized, and 60-min fertilized eggs, respectively). Thus, the total change in egg Ca is accounted for by the influx even though the rate of efflux, measured as a release of ⁴⁵Ca from preloaded eggs, increases to twice the unfertilized rate by 15 min. The fertilization influx follows saturation kinetics (K_a = 1.3 mM). It is competitively inhibited by procaine, but is not inhibited by dinitrophenol, mersalyl acid, or ruthenium red. Ten percent of the total Ca influx has occurred by 10 sec, and it is, therefore, the most rapid response to fertilization yet known in these eggs. The influx is also observed in eggs partially activated by insemination in pH 7 seawater (SW); the other fertilization responses, except sperm penetration, do not occur in pH 7 SW. Although Ca influx alone is insufficient to activate the eggs, it may be a prerequisite for cytoplasmic activation and development, inducing other secondary responses which are prevented by low external pH.     

Fine structural investigation of the insemination response in Urechis caupo.

Electron microscopy of Urechis eggs revealed no changes in the egg cortex or investing layers until 4 min after insemination at 172C. From 4 min to about 30 min after insemination the surface coat gradually elevates, widening the perivitelline space. During this period, microvilli separate from the tightly woven layer of the surface coat, fibrogranular aggregates resembling surface coat material appear in the perivitelline space, and some cortical granules are extruded from the egg cortex into cytoplasmic processes. There is no statistically significant decrease in the number of cortical granules remaining in the egg surface during the first 95 min after insemination; many cortical granules persist in postgastrulae. Most of the cortical granules remain in fertilized eggs after removal of the surface coat with glucose-EGTA. We found no morphological correlates of the polyspermy block which is established within 1 min of insemination (Paul, 1975).     

Polyadenylation of RNA in immature oocytes and early cleavage of Urechis caupo

The poly(A) content of RNA extracted from four stages of immature oocytes, mature oocytes, and cleavage embryos through the eight-cell stage was determined by hybridization with [³H]-poly(U). During oogenesis the poly(A) content per cell gradually increases from 0.007 pg of poly(A)/cell in the 10- to 39-μm oocytes to 0.20 pg of poly(A)/cell in the 125-μm mature oocytes. After fertilization there is an additional increase to approximately 1.1 pg of poly(A)/embryo at the two-cell stage which is followed by a slight decline between the two- and eight-cell stages. Most of the increase in poly(A) after fertilization occurs in a 45-min interval coincident with the appearance of the polar bodies. The size distribution of the poly(A) in RNA from the different stages of development was determined based on the length of RNase-resistant poly(U) obtained from poly(U)-poly(A) hybrids. The size distribution of the poly(A) sequences is constant through each stage of development which indicates that the increase in the poly(A) content of the cells is the result of polyadenylation of new RNA sequences.     

Release of acid and changes in light-scattering properties following fertilization of Urechis caupo eggs.

The release of a fertilization acid, monitored by measuring the pH of egg suspensions, begins within 10 sec of insemination of Urechis caupo eggs. This is 4 min before the vitelline layer begins to elevate and is apparently unrelated to that process. The eggs of two molluscs, Mytilus californianus and Acmaea incessa, do not form a fertilization acid. The acid of Urechis eggs is not accompanied by release of “fertilization” carbohydrate, sulfate, or a nonvolatile weak acid into the seawater. The light-scattering properties of Urechis eggs change during the first 10 min after insemination. A decrease in light scattering begins by 10 sec and is complete by 1 min (Phase I). This is followed by a further decrease (3–6 min, Phase II) and an increase (6–10 min, Phase III). In striking contrast to an overtly similar situation in sea urchin eggs (fertilization acid and coincident light-scattering decrease), the release of acid and the initial light-scattering change are not the result of cortical granule discharge, and the acid, at least, is not related to the changes in shape or surface area which the eggs undergo. The processes underlying these rapid events are not yet known.     

Cytochemical studies on the protamine-type protein transition in sperm nuclei after fertilization and the early embryonic histones of Urechis caupo.

Cytochemical staining characteristics of nuclear histones during postfertilization maturation division and various early embryonic stages in Urechis have been studied. The transition of protamine-type protein to adult histones in the sperm nucleus is accomplished by 15 min after entrance into the egg cytoplasm. Newly synthesized egg proteins migrate into enlarging male and female pronuclei after this transition, followed by pronuclear DNA synthesis and fusion. The shift from protamine-type protein to adult histones, which occurs in the absence of RNA synthesis during the postfertilization maturation division of the egg, may be one of the processes involved in the normal structural reorganization of chromosomes. Such a reorganization is likely to be a prerequisite for chromosome replication and mitosis. No qualitative differences are detected in the stainability of histones of unfertilized eggs and embryos at the cleavage and later stages of development.     

Patterns of maternal messenger RNA accumulation and adenylation during oogenesis in Urechis caupo

We have investigated the accumulation and adenylation of the maternal mRNA during oogenesis in the oocytes of the marine worm Urechis caupo. The analysis, using in vitro translation and cDNA probes to assay for specific mRNAs, demonstrates that different maternal mRNAs accumulate with different patterns during oogenesis. One class of maternal mRNAs accumulates throughout oogenesis and remains at a steady level in the full-grown oocyte. These mRNAs do not have a poly(A) tail long enough to mediate binding to oligo(dT)-cellulose in oocytes, but are rapidly adenylated immediately following fertilization. The other maternal mRNAs accumulate in growing oocytes as poly(A)+ RNA and undergo some deadenylation in full-grown oocytes and embryos. Some of these mRNAs attain their highest concentration fairly early in oogenesis, while others continue to accumulate during later stages. Many of the mRNAs that accumulate as poly(A)+ RNA in growing oocytes diminish dramatically in concentration in full-grown oocytes.     

Studies of oogenesis in Urechis caupo. I. Method for separating different size classes of oocytes

The immature oocytes of the echiuroid worm Urechis caupo develop while suspended as single cells in the coelomic fluid, free of any associated nurse or follicle cells. In any one female, size classes can be found ranging from 8 to 130 μm in diameter. A method is described for obtaining four to five relatively uniform size fractions by centrifuging the mixed oocyte population through a discontinuous Ficoll gradient and collecting the different size oocytes which accumulate at each step of the gradient. Phagocytosis of oocytes in vivo is also discussed.     

Oxygen binding of intact coelomic cells and extracted hemoglobin of the echiuran Urechis caupo

• 1.1. The oxygen affinity of Urechis caupo coelomic cells is the same in normoxic and in hypoxic animals. There is no Bohr effect between pH 6.8 and 8.0.
• 2.2. The oxygen affinity of intact coelomic cells is the same as that of extracted, stripped hemoglobin. The oxygen binding properties of stripped hemoglobin are not affected by 1 mM ATP, IMP, or hydrogen ions between pH 6.8 and 8.0, nor do they clearly show cooperativity. The heat of oxygenation. ΔH, = −13.1 kcal/mol between 10 and 25 C.
• 3.3. Although U. caupo coelomic cell hemoglobin is tetrameric and intracellular, it apparently exhibits neither heterotropic nor homotropic interactions.

     

Parthenogenesis in Urechis caupo (Echiura) II. Role of intracellular pH in parthenogenesis induction

A peptide (P23) isolated from sperm acrosomal protein initiates development in eggs of the marine worm Urechis caupo . We have shown previously that eggs exposed to P23 for ≥3min complete meiosis but fail to cleave. However, a brief (1.5–2 min) exposure to P23 at pH 8, followed by either acidification of the seawater to pH 7 or dilution of P23 at pH 8 causes germinal vesicle breakdown (GVBD), but eggs fail to complete meiosis and many then later advance to mitosis. In the present study we investigated the hypothesis that partial activation leading to parthenogenesis occurs when there is a partial intracellular alkalinization. Measurements with the fluorescent pH indicator bis(carboxyethyl)-carboxyfluorescein (BCECF) showed that P23 induces a pH, increase similar to that occurring during fertilization and that parthenogenesis-inducing treatments interupt this rise in pH₁ In eggs exposed to P23 for >3 min the pH₁ increase was 0.31–0.49 units, slightly higher than in fertilized eggs. In partially activated eggs exposed to P23 for 1.5–2 min at pH 8, pH₁ began to rise but then returned to control values or remained only partially elevated (< 0.2 pH units average increase). Electrophysiological measurements revealed that removal of P23 during the first few minutes of exposure caused the activation potential to terminate and experiments with [¹⁴C]-P23 confirmed that dilution results in a rapid unbinding of P23 from eggs. If proton export is driven by membrane potential as well as the pH gradient, these results explain why dilution of P23 at pH 8 also interrupts the pH_i increase.     

Binding of aromatic isonitriles to haemoglobin and myoglobin.

A series of aromatic isonitriles were synthesized and their binding to sheep haemoglobin and horse heart myoglobin was investigated. The disubstituted ligands 2,6-dimethylphenylisonitrile and 2,6-diethylphenylisonitrile were found to bind to horse-heart myoglobin with affinities ranging from 500 to 5000 times greater than that of ethylisonitrile (4.6 x 10(-6) M) which has been the tightest binding isonitrile ligand for myoglobin thus far reported. The tight binding was not found to vary significantly with pH or temperature. An explanation for the unexpectedly high affinity is offered in terms of the electronic structure of aromatic isonitriles.