Purification and gene cloning of Fundulus heteroclitus hatching enzyme. A hatching enzyme system composed of high choriolytic enzyme and low choriolytic enzyme is conserved between two different teleosts, Fundulus heteroclitus and medaka Oryzias latipes

Two cDNA homologues of medaka hatching enzyme -- high choriolytic enzyme (HCE) and low choriolytic enzyme (LCE) -- were cloned from Fundulus heteroclitus embryos. Amino acid sequences of the mature forms of Fundulus HCE (FHCE) and LCE (FLCE) were 77.9% and 63.3% identical to those of medaka HCE and LCE, respectively. In addition, phylogenetic analysis clearly showed that FHCE and FLCE belonged to the clades of HCE and LCE, respectively. Exon-intron structures of FHCE and FLCE genes were similar to those of medaka HCE (intronless) and LCE (8-exon-7-intron) genes, respectively. Northern blotting and whole-mount in situ hybridization showed that both genes were concurrently expressed in hatching gland cells. Their spatio-temporal expression pattern was basically similar to that of medaka hatching enzyme genes. We separately purified two isoforms of FHCE, FHCE1 and FHCE2, from hatching liquid through gel filtration and cation exchange column chromatography in the HPLC system. The two isoforms, slightly different in molecular weight and in MCA-peptide-cleaving activity, swelled the inner layer of chorion by their limited proteolysis, like the medaka HCE isoforms. In addition, we identified FLCE by TOF-MS. Similar to the medaka LCE, FLCE hardly digested intact chorion. FHCE and FLCE together, when incubated with chorion, rapidly and completely digested the chorion, suggesting their synergistic effect in chorion digestion. Such a cooperative digestion was confirmed by electron microscopic observation. The results suggest that a hatching enzyme system composed of HCE and LCE is conserved between two different teleosts Fundulus and medaka.     

Analysis of the exon-intron structures of fish, amphibian, bird and mammalian hatching enzyme genes, with special reference to the intron loss evolution of hatching enzyme genes in Teleostei

Using gene cloning and in silico cloning, we analyzed the structures of hatching enzyme gene orthologs of vertebrates. Comparison led to a hypothesis that hatching enzyme genes of Japanese eel conserve an ancestral structure of the genes of fishes, amphibians, birds and mammals. However, the exon-intron structure of the genes was different from species to species in Teleostei: Japanese eel hatching enzyme genes were 9-exon-8-intron genes, and zebrafish genes were 5-exon-4-intron genes. In the present study, we further analyzed the gene structures of fishes belonging to Acanthopterygii. In the species of Teleostei we examined, diversification of hatching enzyme gene into two paralogous genes for HCE (high choriolytic enzyme) and LCE (low choriolytic enzyme) was found only in the acanthopterygian fishes such as medaka Oryzias latipes, Fundulus heteroclitus, Takifugu rubripes and Tetraodon nigroviridis. In addition, the HCE gene had no intron, while the LCE gene consisted of 8 exons and 7 introns. Phylogenetic analysis revealed that HCE and LCE genes were paralogous to each other, and diverged during the evolutionary lineage to Acanthopterygii. Analysis of gene synteny and cluster structure showed that the syntenic genes around the HCE and LCE genes were highly conserved between medaka and Teraodon, but such synteny was not found around the zebrafish hatching enzyme genes. We hypothesize that the zebrafish hatching enzyme genes were translocated from chromosome to chromosome, and lost some of their introns during evolution.     

Species-dependent migration of fish hatching gland cells that commonly express astacin-like proteases in common

Two constituent proteases of the hatching enzyme of the medaka ( Oryzias latipes ), choriolysin H (HCE) and choriolysin L (LCE), belong to the astacin protease family. Astacin family proteases have a consensus amino acid sequence of HExxHxxGFxHExxRxDR motif in their active site region. In addition, HCE and LCE have a consensus sequence, SIMHYGR, in the downstream of the active site. Oligonucleotide primers were constructed that corresponded to the above-mentioned amino acid sequences and polymerase chain reactions were performed in zebrafish ( Brachydanio rerio ) and masu salmon ( Oncorynchus masou ) embryos. Using the amplified fragments as probes, two full-length cDNA were isolated from each cDNA library of the zebrafish and the masu salmon. The predicted amino acid sequences of the cDNA were similar to that of the medaka enzymes, more similar to HCE than to LCE, and it was conjectured that hatching enzymes of zebrafish and masu salmon also belonged to the astacin protease family. The final location of hatching gland cells in the three fish species: medaka, zebrafish and masu salmon, is different. The hatching gland cells of medaka are finally located in the epithelium of the pharyngeal cavity, those of zebrafish are in the epidermis of the yolk sac, and those of masu salmon are both in the epithelium of the pharyngeal cavity and the lateral epidermis of the head. However, in the present study, it was found that the hatching gland cells of zebrafish and masu salmon originated from the anterior end of the hypoblast, the Polster, as did those of medaka by in situ hybridization. It was clarified, therefore, that such difference in the final location of hatching gland cells among these species resulted from the difference in the migratory route of the hatching gland cells after the Polster region.     

Two constituent proteases of a teleostean hatching enzyme: concurrent syntheses and packaging in the same secretory granules in discrete arrangement.

Formation, accumulation, and storage of two components of the Oryzias latipes hatching enzyme, high and low choriolytic enzymes (HCE and LCE), were examined by immunocytochemical and immunoblotting methods. Both of the enzymes were found to be formed specifically in the hatching gland cells at the stages of lens formation to eye pigmentation and their accumulation proceeded markedly and concurrently up to Day 5.5 embryos (the stage just before hatching). The amount of HCE formed was more abundant than that of LCE. In the hatching gland cells, HCE and LCE were found to be packaged in the same secretory granules but in distinct arrangement; HCE is localized to the inside of granules whereas LCE is situated at the periphery of the same granules. Their segregated arrangement is compatible with their relative quantities formed per embryo. The results provide not only the cellular and developmental basis for a view that this hatching enzyme is an enzyme system composed of HCE and LCE but also a clue to the regulatory mechanism of concurrent syntheses of two different specific proteins in the same embryonic cell.     

Conservation of the egg envelope digestion mechanism of hatching enzyme in euteleostean fishes

We purified two hatching enzymes, namely high choriolytic enzyme (HCE; EC 3.4.24.67) and low choriolytic enzyme (LCE; EC 3.4.24.66), from the hatching liquid of Fundulus heteroclitus, which were named Fundulus HCE (FHCE) and Fundulus LCE (FLCE). FHCE swelled the inner layer of egg envelope, and FLCE completely digested the FHCE-swollen envelope. In addition, we cloned three Fundulus cDNAs orthologous to cDNAs for the medaka precursors of egg envelope subunit proteins (i.e. choriogenins H, H minor and L) from the female liver. Cleavage sites of FHCE and FLCE on egg envelope subunit proteins were determined by comparing the N-terminal amino acid sequences of digests with the sequences deduced from the cDNAs for egg envelope subunit proteins. FHCE and FLCE cleaved different sites of the subunit proteins. FHCE efficiently cleaved the Pro-X-Y repeat regions into tripeptides to dodecapeptides to swell the envelope, whereas FLCE cleaved the inside of the zona pellucida domain, the core structure of egg envelope subunit protein, to completely digest the FHCE-swollen envelope. A comparison showed that the positions of hatching enzyme cleavage sites on egg envelope subunit proteins were strictly conserved between Fundulus and medaka. Finally, we extended such a comparison to three other euteleosts (i.e. three-spined stickleback, spotted halibut and rainbow trout) and found that the egg envelope digestion mechanism was well conserved among them. During evolution, the egg envelope digestion by HCE and LCE orthologs was established in the lineage of euteleosts, and the mechanism is suggested to be conserved.     

Hatching enzyme of the ovoviviparous black rockfish Sebastes schlegelii- environmental adaptation of the hatching enzyme and evolutionary aspects of formation of the pseudogene

The hatching enzyme of oviparous euteleostean fishes consists of two metalloproteases: high choriolytic enzyme (HCE) and low choriolytic enzyme (LCE). They cooperatively digest the egg envelope (chorion) at the time of embryo hatching. In the present study, we investigated the hatching of embryos of the ovoviviparous black rockfish Sebastes schlegelii. The chorion-swelling activity, HCE-like activity, was found in the ovarian fluid carrying the embryos immediately before the hatching stage. Two kinds of HCE were partially purified from the fluid, and the relative molecular masses of them matched well with those deduced from two HCE cDNAs, respectively, by MALDI-TOF MS analysis. On the other hand, LCE cDNAs were cloned; however, the ORF was not complete. These results suggest that the hatching enzyme is also present in ovoviviparous fish, but is composed of only HCE, which is different from the situation in other oviparous euteleostean fishes. The expression of the HCE gene was quite weak when compared with that of the other teleostean fishes. Considering that the black rockfish chorion is thin and fragile, such a small amount of enzyme would be enough to digest the chorion. The black rockfish hatching enzyme is considered to be well adapted to the natural hatching environment of black rockfish embryos. In addition, five aberrant spliced LCE cDNAs were cloned. Several nucleotide substitutions were found in the splice site consensus sequences of the LCE gene, suggesting that the products alternatively spliced from the LCE gene are generated by the mutations in intronic regions responsible for splicing.     

Hatching enzyme of Japanese eel Anguilla japonica and the possible evolution of the egg envelope digestion mechanism

We purified eel hatching enzyme (EHE) from the hatching liquid of Japanese eel Anguilla japonica belonging to Elopomorpha to a single band on SDS/PAGE. TOF-MS analysis revealed that the purified EHE contained several isozymes with similar molecular masses. Comparison of the egg envelope digestion specificities of the purified EHE and of recombinant EHE4, one of the EHE isozymes, suggested that the isozymes contained in the purified EHE were functionally the same in terms of egg envelope digestion. By electron microscopy, the egg envelope became swollen after treatment with the purified EHE. The EHE cleavage sites on the zona pellucida (ZP) protein of the egg envelope were located in the N-terminal repeat regions. In previous phylogenetic analysis, we suggested that fishes included in Elopomorpha, as basal teleosts, possess a single type of hatching enzyme genes, and that fishes in Otocephala and Euteleostei gain two types of hatching enzyme genes called clade I and II genes by duplication. Further, the clade I enzymes, zebrafish hatching enzyme (ZHE1) and medaka high choriolytic enzyme (HCE), swell the egg envelope by cleaving the N-terminal regions of ZP proteins, while the clade II enzyme, medaka low choriolytic enzyme (LCE), solubilizes the swollen envelope by cleaving the site at the middle region on the ZP domain. In this evolutionary scenario, our findings support that hatching of Japanese eel conserves the ancestral mechanism of fish egg envelope digestion. The clade I enzymes inherit the ancestral enzyme function, and the clade II enzymes gain a new function during evolution to Otocephala and Euteleostei.     

Isolation and some properties of low choriolytic enzyme (LCE), a component of the hatching enzyme of the teleost, Oryzias latipes

One of the two component proteases of the hatching enzyme of the fish, Oryzias latipes, low choriolytic enzyme (LCE), was isolated from the hatching liquid and partly characterized. The enzyme was a basic protein with molecular weight of about 25.5 kDa. Like high choriolytic enzyme (HCE), the other component of the O. latipes hatching enzyme [Yasumasu, S. et al. (1989) J. Biochem. 105, 204-211], LCE was considered to be a zinc-protease from the results of inhibitor studies and metal analyses. However, LCE was found to be distinct from HCE not only in some biochemical characteristics such as molecular weight, amino acid composition, and isoelectric point, but also in some enzymological properties such as substrate specificity, heat stability, and mode of action toward their natural substrate, chorion (egg envelope). Although LCE was almost incapable of digesting the inner layer of intact chorion, it very efficiently digested the inner layer of chorion that had been swollen previously by the action of HCE. Taking account of the fact that HCE swells the inner layer of intact chorion by partial proteolysis but does not efficiently digest the swollen chorion any more [Yasumasu, S. et al. (1989) J. Biochem. 105, 204-211], the present results demonstrated an essential role of LCE in choriolysis, in cooperation with HCE.     

Purification and partial characterization of high choriolytic enzyme (HCE), a component of the hatching enzyme of the teleost, Oryzias latipes

The hatching enzyme is an embryo-secreted enzyme(s) which digests the egg envelope, allowing the embryo to emerge at the time of hatching. The hatching enzyme of the fish, Oryzias latipes, has recently been found to consist of two kinds of proteases which may digest the inner layer of chorion (egg envelope) cooperatively [Yasumasu, S. et al. (1988) Zool. Sci. 5, 191-195]. In the present study, one of them, high choriolytic (egg envelope digesting) enzyme (HCE) was purified and some biochemical and enzymological properties were examined. The enzyme was a basic protein with a molecular weight of about 24 kDa, and exhibited choriolytic activity as well as proteolytic (caseinolytic) activity. The results of inhibitor studies and metal analyses strongly suggested that it was a zinc-protease. The purified HCE consisted of two probable isomers, HCE-1 and HCE-2. Both of them were markedly similar in amino acid composition, specific activities of choriolysis and proteolysis, and substrate specificity as determined using MCA-peptides. Moreover, they were not separable on SDS-PAGE, electrofocusing PAGE, or ultracentrifugal analysis, but were discriminated only on HPLC with a CM-300 column. Thus, the mixture of HCE-1 and HCE-2 could be regarded as almost a single enzyme, HCE. When it acted on an intact chorion, the purified HCE caused a remarkable swelling of its inner layer with concomitant release of peptides from it. Once the inner layer of chorion was swollen, the enzyme hardly digested it.     

Evolution of teleostean hatching enzyme genes and their paralogous genes

We isolated genes for hatching enzymes and their paralogs having two cysteine residues at their N-terminal regions in addition to four cysteines conserved in all the astacin family proteases. Genes for such six-cysteine-containing astacin proteases (C6AST) were searched out in the medaka genome database. Five genes for MC6AST1 to 5 were found in addition to embryo-specific hatching enzyme genes. RT-PCR and whole-mount in situ hybridization evidenced that MC6AST1 was expressed in embryos and epidermis of almost all adult tissues examined, while MC6AST2 and 3 were in mesenterium, intestine, and testis. MC6AST4 and 5 were specifically expressed in jaw. In addition, we cloned C6AST cDNA homologs from zebrafish, ayu, and fugu. The MC6AST1 to 5 genes were classified into three groups in the phylogenetic positions, and the expression patterns and hatching enzymes were clearly discriminated from other C6ASTs. Analysis of the exon–intron structures clarified that genes for hatching enzymes MHCE and MAHCE were intron-less, while other MC6AST genes were basically the same as the gene for another hatching enzyme MLCE. In the basal Teleost, the C6AST genes having the ancestral exon–intron structure (nine exon/eight intron structure) first appeared by duplication and chromosomal translocation. Thereafter, maintaining such ancestral exon–intron structure, the LCE gene was newly diversified in Euteleostei, and the MC6AST1 to 5 gene orthologs were duplicated and diversified independently in respective fish lineages. The HCE gene lost all introns in Euteleostei, whereas in the lineage to zebrafish, it was translocated from chromosome to chromosome and lost some of its introns.Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users.The nucleotide sequence data reported in the present paper will appear in the DDBJ/EMBL/GenBank nucleotide sequence databases with accession numbers from AB256940 to AB256952.     

Analysis of the origin and development of hatching gland cells by transplantation of the embryonic shield in the fish, Oryzias latipes

Hatching gland cells of the medaka, Oryzias latipes, have been observed to differentiate from the anterior end of the hypoblast, which seems to first involute at the onset of gastrulation. These results suggest that the hatching gland cells of medaka originate from the embryonic shield, the putative organizer of this fish. The present study investigated whether hatching gland cells really originate from the embryonic shield in the medaka. Transplantation experiments with embryonic shield and in situ hybridization detection of hatching enzyme gene expression as a sign of terminal differentiation of the gland cells were carried out. The analysis was performed according to the following processes. First, identification and functional characterization of the embryonic shield region were made by determining the expression of medaka goosecoid gene and its organizer activity. Second, it was confirmed that the embryonic shield had an organizer activity, inducing a secondary embryo, and that the developmental patterns of hatching gland cells in primary and secondary embryos were identical. Finally, the hatching gland cells as identified by hatching enzyme gene expression were found to coincide with the dye-labeled progeny cells of the transplanted embryonic shield. In conclusion, it was determined that hatching gland cells were derived from the embryonic shield that functioned as the organizer in medaka.     

Dopaminergic regulation of hatching in fish embryos

Enveloped medaka embryos and denuded zebrafish embryos were exposed to agents that are known to modify the activity of dopaminergic systems. Precocious emergence of medaka embryos was found in the presence of pimozide, salsolinol, and alpha-methyl-rho-tyrosine, whereas delayed hatching occurred with bromocriptine and apomorphine. Moreover, the hatching rate in the light period of medaka eggs, exposed to a 12-hr light/12-hr dark cycle, is significantly higher than in the dark period. Precocious hatching enzyme secretion from denuded zebrafish embryos is caused by salsolinol, whereas dopamine has an opposite effect. At the same time it turned out that in controls hatching enzyme release from denuded zebrafish embryos is well correlated with hatching of enveloped zebrafish embryos. These results do not support the hypothesis proposed by several authors that hatching enzyme is solely mechanically released, but suggest a controlling influence of dopamine receptors, probably located in the developing central nervous system. Assuming a stimulating effect of prolactin on teleostean hatching enzyme secretion, the present data indicate that hypothalamic-hypophyseal tracts are functional at the time of hatching.     

The short life of the Hoyle organ of <Emphasis Type="Italic">Sepia officinalis</Emphasis>: formation,differentiation and degradation by programmed cell death

Cephalopods encapsulate their eggs in protective egg envelopes. To hatch from this enclosure, most cephalopod embryos release egg shell-digesting choriolytic enzymes produced by the Hoyle organ (HO). After hatching, this gland becomes inactive and rapidly degrades by programmed cell death. We aim to characterize morphologically the development, maturation and degradation of the gland throughout embryonic and first juvenile stages in Sepia officinalis. Special focus is laid on cell death mechanisms and the presence of nitric oxide synthase during gland degradation. Hatching enzyme has been examined in view of metallic contents, commonly amplifying enzyme effectiveness. HO gland cells are first visualized at embryonic stage 23; secretion is observed from stage 27 onwards. Degradation of the HO occurs after hatching within two days by the rarely observed autophagic process, recognized for the first time in cephalopods. Nitric oxide synthase immunopositivity was not found in the HO cells after hatching, suggesting a possible NO role in cell death signalling. Although the HO ‘life course’ chronology in S. officinalis is similar to other cephalopods, gland degradation occurs by autophagy instead of necrosis. Eggs that combine a large perivitelline space and multi-layered integument seem to require a more complex and large gland system.     

A unique proteolytic action of HCE, a constituent protease of a fish hatching enzyme: tight binding to its natural substrate, egg envelope

High choriolytic enzyme (HCE), a constituent protease of the hatching enzyme of the teleost, Oryzias latipes, swells its natural substrate, egg envelope (chorion) by hydrolyzing it partially. This enzyme was found to be bound tightly to the chorion when it exerted catalytic action. This was evidenced by the experimental results showing (i) that the turnover of this enzyme seemed to be hindered by the chorion, (ii) that the enzyme bound to the chorion could be recovered by washing with an alkaline medium, and (iii) that the bound enzyme could be quantified by radioimmunological estimation. The bound enzyme sustained its original activity and the binding between the enzyme and the chorion seems to be stoichiometric.     

Properties of the hatching enzyme from Xenopus laevis.

Using an anti-(glutathione S-transferase-UVS.2 cDNA) Ig and uterine egg vitelline envelope (UEVE) protein of Xenopus laevis as probes, the hatching enzyme (HE) from Xenopus was solubilized in hatching medium and purified by gel-filtration and ion-exchange chromatography, and characterized in terms of its molecular mass and enzymatic properties. The hatching medium solubilized the UEVE and contained molecules reactive to the anti-(GST UVS.2) Ig against Xenopus HE. It was found that the HE had a molecular mass of 60 kDa, and often preparations also contained a 40-kDa form. The 60-kDa HE had a high hydrolytic and UEVE-solubilizing activity, and its activities against Boc-Leu-Gly-Arg-7-amino-4-methylcoumarin (-NH-Mec) and UEVE were inhibited by anti-(GST UVS.2) Ig in a dose-dependent manner. The 60-kDa form was easily autodigested into a 40-kDa form. The 40-kDa molecule alone had no detectable UEVE-solubilizing activity, even it still had high hydrolytic activity. It probably represents the main protease domain of the 60-kDa form after loss of two CUB repeats during autodigestion or digestion. The autodigestion of the 60-kDa molecule into 40-kDa molecule is probably a congenital behavior for successfully dissolving the embryo envelope during the hatching process. The two molecules may play different roles at different stages of the hatching process, during which they co-ordinate with each other to achieve complete solubilization of the embryo envelope, similar to the high and low choriolytic enzymes in medaka (Oryzias latipes). Their hydrolytic activity against Boc-Leu-Gly-Arg-NH-Mec was optimal at pH of 7.4, and with an apparent Km value of 200 micromol.L-1 at 30 degrees C. The HE is very sensitive to trypsin-specific inhibitors such as leupeptin, (4-amidino-phenyl)methane sulfonyl fluoride, diisopropyl fluorophosphate (DFP) and N-alpha-tosyl-L-lysylchloromethane (Tos-Lys-CH2Cl), indicates that it is a trypsin-type protease. The results on EDTA and some metal ions, combined with the occurrence of a astacin family metalloprotease-specific 'HExHxxGFxHE' sequence in the deduced HE amino-acid sequence, indicates that this HE is a Zn2+ metalloprotease.     

Purification and characterization of hatching enzyme of the pike (Esox lucius)

• 1.1. A choriolytic enzyme was isolated from the hatching medium of the pike, Esox lucius.
• 2.2. The enzyme is defined as hatching enzyme.
• 3.3. The molecular weight of the enzyme is 24,000.
• 4.4. The enzyme is a glycoprotein containing 2% carbohydrate.
• 5.5. Its isoelectric point is 6.5.
• 6.6. The pH optimum is around pH 8.
• 7.7. The enzyme molecule contains two disulfide bonds but no free cysteine.
• 8.8. Inhibitor studies and metal analysis show that the enzyme is a zinc-metalloprotease.

     

Presence of Active Hatching Enzyme in the Secretory Granule of Prehatching Medaka Embryos

Secretory granules of hatching gland were isolated from a 0.3 M sucrose homogenate of whole medaka embryos at prehatching stage by differential centrifugation, followed by a Percoll density gradient centrifugation. The obtained preparation was almost free of melanosomes and composed exclusively of the secretory granules of hatching gland (hatching enzyme granules), as judged by morphological as well as enzymological criteria.
The aqueous extracts of the purified secretory granules showed a specific choriolytic activity as high as about 40 times that of a partially purified secretory granule preparation, P_1,000, and represented a single protein band with molecular weight of about 21,000 on SDS-polyacrylamide gel electrophoresis. It was also revealed that a major component of the hatching enzyme preparation (P II–0.3 enzyme, 13) purified from the hatching liquid was identical with the 21,000 molecular weight band.
These results suggest that the hatching enzyme is present in the secretory granules of prehatching embryos in an active molecular form.     

Purification and characterization of the sea urchin embryo hatching enzyme

The sea urchin hatching enzyme provides an interesting model for the control of gene expression during early development. In order to study its properties and developmental regulation, the hatching enzyme of the species Paracentrotus lividus has been purified. The fertilization envelopes of the embryos were digested before hatching by a crude culture supernatant previously made. The enzyme was then solubilized by 1 M NaCl and 0.5% 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate and purified by hydrophobic chromatography on Procion-agarose. A 470-fold increase in specific activity was obtained. The kinetic parameters of the proteolytic activity using dimethylcasein as substrate are: Km = 120 micrograms x ml-1, Vm = 200 mumol x min-1 x mg-1, and kcat = 180 s-1 at 500 mM NaCl, 10 mM CaCl2, pH 8.0, at 35 degrees C. The purified enzyme is highly active on fertilization envelopes: at 20 degrees C and 500 mM NaCl, 10 mM CaCl2, pH 8.0, 100 ng of enzyme completely denudes embryos in about 20 min under standard conditions. The molecular mass of the enzyme was estimated as 57 kDa by gel filtration, 51 kDa by gel electrophoresis, and 52 kDa by amino acid analysis. The hatching enzyme was shown to be a glycoprotein which autolyzes to a 30-kDa inactive form. Antibodies raised against the 51- or 30-kDa forms reacted with both these forms. Immunoblotting experiments showed that the hatching supernatants contain important amounts of the autolyzed species.