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Ovigerous-Hair Stripping Substance (OHSS) in an Estuarine Crab: Purification, Preliminary Characterization, and Appearance of the Activity in the Developing Embryos PDF

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Preview Ovigerous-Hair Stripping Substance (OHSS) in an Estuarine Crab: Purification, Preliminary Characterization, and Appearance of the Activity in the Developing Embryos

Reference: Bio/. Bull. 197: 174-187. (October I4W) Ovigerous-Hair Stripping Substance (OHSS) in an Estuarine Crab: Purification, Preliminary Characterization, and Appearance of the Activity in the Developing Embryos MASAYUKI SA1GUSA AND HIROSHI IWASAKI Department of Biology, Faculty ofScience, Okuyama University, Tsushima 2-1-1 (General Education Buildings), Oka\amu 700-8530, Japan Abstract. Ovigerous-hair stripping substance (OHSS) is Introduction an active factor in crab hatch water (i.e., filtered medium into which zoea larvae have been released). This factor After egg-laying, the embryos of intertidal and estuarine crabs and indeed most decapod crustaceans are encased participates in stripping off the egg attachment structures (i.e., egg case, funiculus, and the coat investing ovigerous in a thick, protective capsule composed of two or three layers; these capsules are then attached to the female's hairs) that remain attached to the female's ovigerous hairs ovigerous hairs through the funiculus and investment coat after larval release. Thus this activity prepares the hairs for (Yonge, 1937, 1946; Cheung, 1966; Goudeau and Lachaise, the next clutch of embryos. OHSS activity of an estuarine 1983). The capsule breaks open during or after embryonic crab. Sesarma haematoc/ieir, eluted as a single peak on development, and hatching occurs (Davis, 1968, 1981; molecular-sieve chromatography, but this peak still showed Saigusa, 1997). two protein bands at 32 kDa and 30 kDa on SDS-PAGE. The funiculus and investment coat, as well as the broken The two protein bands stained with a polyclonal antiserum egg capsule, remain attached to the hairs after hatching (for raised to the active fractions from molecular-sieve chroma- further details, see Saigusa, 1994). But at the time ofhatch- tography. Moreover, antibodies purified from this poly- ing, an active factor we call ovigerous-hair stripping sub- clonal OHSS antiserum also recognized both the 32-kDu stance (OHSS) is released from the embryoandcauses these and 30-kDa bands. OHSS immunoreactivity and biological remnant structures to slip offthe hairs (Saigusa, 1994). The activity were associated with the attachment structures that stripping of these remnant structures is very important be- remained connected to the ovigerous hairs afterhatching. In cause it leaves the hairs clean, unbroken, and thus prepared developing embryos, both protein bands could be stained to incubate the next clutch of embryos (Saigusa, 1995). immunochemically at least 10 days before hatching. But The funiculus. the coat that wraps the ovigerous hairs, OHSS biological activity appeared only 3 days before and the outermost layerofthe egg capsule are all composed hatching. The immunoreactive protein bands were not ob- of the same material (Saigusa ct <;/.. unpub. data), and served in the zoea, but OHSS bioreactivity was present, OHSS may be an enzyme that acts on this material. In many though greatly reduced. The 32-kDa protein, at least, is other animals, a hatching enzyme is released from the probably an active OHSS, and the 30-kDaprotein band may embryos upon hatching and digests the layers of the egg also be OHSS-related. The OHSS appears to be produced case (e.g., Yamagami. 1988; Lepage and Cache. 1989; Roe and stored by the developing embryo. Upon hatching, most and Lennarz, 1990; Helvik et ai, 1991). However, there is of the material may be trapped by the remnant structures, noevidence, even afterelectron microscopy studies, that the and the remainder is released into the ambient water. glaeysetresd boyf OthHeSeSgg(Saciagpussualeete<n//c..asuinnpgublc.radbatae)m.bSroyotsheanroetidoin- that OHSS is a crustacean hatching enzyme remains unsub- Received 16 January 1997; accepted 16 June 1999. stantiated. 174 ACTIVE SUBSTANCE IN CRAB HATCH WATER 175 Although the cells that produce OHSS have not yet been and the remaining water was then passed again through a identified, we do know that this substance is secreted by the filterpaper. The resulting hatch waterwas pooled in a 50-ml -40C embryo, and not by the female. The molecular mass of plastic bottle and immediately stored at until used. OHSS was estimated by primary gel filtration to be 15-20 Most females incubate their next clutch of embryos a few kDa (Saigusa, 1995), but no other chemical characteristics days after larval release. The females were therefore kept in are known. If we are ever to characterize the physiological the laboratory for a month, and hatch water was obtained mechanism ofOHSS. or its expression during development from their second larval release. underthe control ofacircatidal clock (Saigusa. 1992. 1993, Since the OHSS activity of hatch water declines con- 1997), a purified preparation must first be obtained. stantly at ambient temperatures, the second method, in Here we describe a relatively simple procedure for puri- which the material is frozen immediately after production, fying OHSS from the hatch water ofan estuarine terrestrial yielded hatch water solutions with higher concentrations of crab, Sesarma haematocheir, and we also provide a prelim- OHSS. Moreover, since all ofthe female crabs survived and inary characterization of this material. A polyclonal anti- were able to incubate another clutch of embryos, we are serum was raised against OHSS and purified so that, by confident that the disinfection in ethanol and the dry trans- immunochemical staining, we could examine the appear- port were not deleterious to the animals. ance ofOHSS in the developing embryos and its disappear- Most of the hatch water used in this study was collected ance after hatching. Furthermore, we assessed whether in 1994. but some experiments were carried out with mate- OHSS is still associated with the remnants ofthe embryonic rial collected in 1996-1998. The concentrations of OHSS attachment structures that remain after hatching and larval obtained by the two methods would certainly have been release. different, but the biochemical properties observed were virtually identical. Materials and Methods OHSS Larval release and collection ofhatch water Bioassay of activity Specimens of Sesarma haematocheir, the estuarine ter- Our biological assay of OHSS is based on the ability of restrial crab used in this study, were collected at Kasaoka, chemically fixed ovigerous setae to respond to OHSS. In Okayama Prefecture, Japan. Here, the thicket inhabited by brief, an ovigerous seta with its attached embryos, all in the crabs is separated from the shore of a tidal creek by a early stages of development, were excised from a female small road (for their habitat, see Saigusa, 1982). Just after crab, fixed in 70% ethanol, and then stored in the refriger- 4C sunset, between 1900 and 2000 h, for several days around ator at until used. Ethanol-fixed setae with their at- the time ofthe full or new moon, large numbers ofoviger- tached clumps of embryos respond well to exogenous 4C ous female appear onto this road on their way to the shore. OHSS. even after several years of cold storage at Thus exposed, they can easily be captured. (unpub. data). In 1994, more than 3000 females were captured on the Shortly before a bioassay was to be performed, the fixed road and placed individually into large plastic containers setae were suspended in distilled water (DW) to wash out (10 cm in diameter, 15 cm in height) containing 30 ml of the ethanol, and then placed in a glass dish with DW. The very clean ground water obtained near the collecting site. tip ofeach ovigerous seta was cut away, and the remainder The females released their larvae into this water. Immedi- was subdivided into four segments under the stereomicro- ately thereafter, the females were removed from the con- scope (see Saigusa. 1995). Each segment was placed on a tainers, and the waterwas filtered through a nylon mesh that paper towel to remove attached water, and one or two (or retained the larvae. The filtered hatch water was accumu- three in some experiments) of these segments were placed lated in 1-liter bottles, transported 50 km to the laboratory, in each of the wells (each 0.8 cm in diameter, 1.7 cm in and finally frozen at 20C. height) of a plastic culture dish; the wells also contained The method of collection was changed in 1996. In the 300-500 /J.1 of a fraction eluted through chromatography. three years 1996. 1997. and 1998, ovigerous females were The culture dish was shaken slowly on a mechanical shaker still collected at the same site at Kasaoka. but they were first for 1.0-2.2 h at about 23C. disinfected in ice-cold 70%-80% ethanol forafew minutes, Recall that each seta is equipped with 10-15 whorls of then washed with distilled water, and finally placed indi- ovigerous hairs to which the embryos are actually attached, vidually in the large plastic containers, but without water. and that the number of ovigerous hairs is about 10-20 per These containers were transferred to the laboratory, where whorl (see Saigusa, 1994, 1995). For example, each of the each crab was immediately placed in a small, covered three segments ofa seta would contain 2-5 whorls (30-100 plastic cup (5 cm in diameter, 6 or 8 cm in height) contain- ovigerous hairs). Afterthe incubation described above, each ing 9 ml ofdistilled water. As soon as larvae were released, setal segment with its cluster ofembryos was again placed the zoeas were removed by filtration through nylon mesh, in a glass dish with DW. This dish was put under a 176 M. SAIGUSA AND H. IWASAKI stereomicroscope, and tine forceps were used to pull the kDa), aldolase (39.2 kDa), trypsin inhibitor (20.1 kDa) embryos gently away from the ovigerous hairs. The per- (Sigma Chemical Co.). centage of hairs in each whorl that were stripped clean but were still undamaged was calculated. The activity ofOHSS Effects oftemperature andpH was usually taken as the mean of 3-10 whorls (one or two segments); the standard deviation was also calculated. The active fractions from molecular-sieve chromatogra- phy (fractions 6-8; Fig. 2A) were pooled and incubated for 4C 15 min at temperatures from to 100C, and were Purification procedure immediately returned to 23C. Segments of the ovigerous Stored, frozen, crude hatch water was thawed and centri- seta with their attached embryos were incubated with these fuged at 18,000 rpm for 30 min at 4C to remove the solid solutions for 1 h at 23C, and OHSS activity was bioas- pmaotwedreiral,s.lefTthoevehrnaitgchht,waatnedrcwenatsrisfautguerdataetd18wi.t0h00(iNpHm4f)o-r,S3O04 wsaeyreed.maIninatnaoitnheedraetxp4e'rCimeanntd, 2th3eCpoofolred0-ac1t2i0ve hf.raTcthieosnes min. The supernatant contained no OHSS activity. The solutions were then bioassayed for 1 h. precipitate was dissolved in 100 mM Tris-HCl buffer (pH The effects ofpH were examinedmsiMmilarly. Buffers used 9.0) and, at this stage, could also be stored at -20C. This for this studymweMre as follows: 100 Na-acetate (pHm3.M0 material was called "concentrated hatch water." OHSS was and 5.0; 100 Tris-HCl (pH 7.0 and 8.5); and 100 ppurroicfeideudrefsurtwheerreianlltchraereriesdteopsu,t wasithdeascrfaisbtedprobteelionw.liTquhied ganlyecqiunale-qNuaanOtHit(ypHof1e0a.c5)h.bAucffteirv,eafnrdactthieonOsHwSerSeamctiixveitdywwiatsh chromatography system (FPLC; Pharmacia) in an experi- bioassayed for 1 h. mental chamber with the temperature controlled at 4"C: In each experiment (A-C), assays were repeated three protein elution was monitored at 280 rim. OHSS rapidly times with the same OHSS solution. The mean percentage loses its activity during purification, so the following pro- of stripped hairs in 2-5 whorls of the hair was first esti- cedures were completed within 12 h. mated, and the mean of three assays was estimated. Step 1: Hydrophobic chromatography. Concentrated hatch water (described above) was mixed with an equal Electrophoretic analysis (SDS-PAGE) mM qmuaMntity of20 Tris-HCl buffer (pH 9.0) containing 300 SDS (sodium dodecyl sulfate)-polyacrylamide gel elec- Na,SO4. This medium was applied to a column con- trophoresis (SDS-PAGE) was carried out according to the taining 10 ml of HiTrap-Octyl-Sepharose m4FMF (prepack method ofLaemmli (1970). Each fraction from gel filtration cbuoflfuemrn,conPthaairnmiancgia3)00eqmuiMlibNraat2SedO4wi(tphH 290.0). TheTrciosl-uHmCnl wbraasnecon(cCeennttrraitceodnb1y0,paAsmsaigceont)h.roTughheanfilutletrreadfilmtartaetrioinalmewma-s (wa2s emluMt/emdlwitahndaalinfelaorwgrraatdeienmtaionftaNiane2dSOa4t: 4-.80 mmlM//mimni)n. d5i%ssoSlDvSe,d i5n%an2-emqeuraclaqputaonettihtaynoolf,ly8siMs buurfefae,r 5[commpMosEitDioTnA: Fractions of 10 ml were collected. (ethylenediaminetetraacetic acid), 5% sucrose, in 125 mM Step 2: Ion-exchange chromatography. The active frac- Tris-HCl (pH 6.8)], and then kept at room temperature for tions from step 1 were pooled (60 ml), and this sample was 30 min. The molecular mass markers employed were glu- applied to an anion-exchange column (MONO-Q HR5/5. tamate dehydrogenase (55.6 kDa). aldolase (39.2 kDa), prepack, Pharmacia: 0.5mXM5 cm). The column had been triosephosphase isomerase (26.6 kDa), trypsin inhibitor pre-equilibrated with 20 Tris-HCl buffer (pH 9.0). and (20.1 kDa). and lyso/yme (14.3 kDa) (Sigma Chemical the sample was eluted with the same solution. The flow rate Co.). The gels (15%) were transblotted onto PVDF (poly- was 1.0 ml/min. and 2-ml fractions were collected. The vinyliden difluoride) membranes (Clear Blot Membrane P; fractions from the void volume were pooled, and were Atto, Japan), and were stained with Coomassie brilliant blue concentrated to 500 ju,l with an ultrafiltration membrane R-250 (CBB). (YM 10, Amicon). Step 3: Molecular-sieve chromatography. A sample of Electrophoresis ofthe activefractions without these concentrated active fractions (500 was fraction- /u,l) denaturation {native SDS-PAGE) anil biotissuy with the pateerddebxy7m5olHecRul1a0r/-3s0i,epvreecpharcko.maPthoagrrmaapchiay)(.geTlhfeilctroaltiuomn)n(hSaud- crushed gel mM been equilibrated previously with 20 Tris-HCl buffer The active fractions from gel filtration were pooled (2 ml) mM containing 150 NaCl (pH 9.0). The sample was eluted and concentrated to less than 200 jid by passage through the with the same buffer at a flow rate of0.25 ml/min, and I-ml ultrafiltration membrane. This material (80 /xl) was dis- fractions were collected. The molecular mass ofOHSS was solved in a solution containing 45 mg of saccharose added M determined by comparison with the elution volume of the in 100 n\ of 0.5 Tris-HCl (pH 6.8), and was electropho- following marker proteins: glutamate dehydrogenase (55.6 resed on an SDS-polyacrylamide gel (15%). After electro- ACTIVE SUBSTANCE IN CRAB HATCH WATER 177 phoresis, a narrow strip of this gel was cut parallel to the glycine-HCl (pH 2.0) for 10 min, on ice, to elute bound direction of migration, and then stained with CBB. This antibody. The eluate was adjusted to pH 7.4-7.5 by the M strip was used to indicate the position ofthe protein bands. addition of 30-32 jul of I Tris. The remainder of the gel was cut into four equal segments For staining, a 1:1000 dilution of the antibody that was perpendicular to the direction of migration. Each of these eluted from either the 32-kDa or 30-kDa band was used as gel segments was crushed with a pestle, 500 jul of DW was the primary; dilution was with 0.5% nonfat milk in T-TBS. added, and the OHSS activity was bioassayed. The secondary antibody was peroxidase-conjugated goat- rabbit immunoglobulin (Cappel) diluted 1:5000 with 0.5% Preparation ofpolyclonal antiserum, electrophoresis, mul nonfat milk in T-TBS. mm western blotting ofOHSS Because the two bands were at most 2 apart on the gel and were not stained with CBB, we could not be sure onInSDprSe-lPimAiGnaEryweaxspecruitmefnrtosm, ath3e2g-eklDawiptrhotaeinshbarapndknsiefeen, fthoarte,thceotncweontprraotteeidnsachtaidvebefernacctoimopnlsetferloymsempoalreactueld.arT-hseireev-e mixed with Freund's complete adjuvant, and injected into a chromatography (6 and 7 in Fig. 2A) were electrophoresed c2omwmeeerkcsiaalpawrhtiteyriaeblbdite.dTnhoeseanttriesaetrmuemntswhefnourasisnjaeycetdionbsy, otrnan1sf5e%rreSdDtSo agePlVfDorFamleomnbgrearnpee.riTohdis(9prho)c,eadnurdewperroedutcheedn westernblotting. Therefore,the pooledactive fractions from a gap of5-6 mm between the upper and lower bands. The gel filtration (2 ml; 6 and 7 in Fig. 2A) were mixed with the whole membrane was stained with 0.01% Ponceau S adjuvant, and two additional injections, 2 weeks apart, were (Sigma) in 5% acetic acid for 10 min. The protein bands, 2 givIenn wtoesttheernsabmleotrtaibnbgi,t.the electrophoresed sample was wmimde)wiwdaes,ewxecrleudceudt. Touhteabnoduntdheanmtiidbdoldeiesstwriepre(atbhoeunte2lutmedm, transblotted onto PVDF membrane, and immunoreactivity as described above. was detected by chemobioluminescence with ECL western blotting reagents (Amersham). For the primary antibody, Immunochemical detection ofOHSS during the polyclonal antiserum was diluted 1:1000 with 0.5% mM mM embryonic development nonfat milk inT-TBS ( 10 Tris-HCl, 150 NaCl, and 0.05% Tween 20). The PVDF membrane was incubated At various times before hatching, an embryo cluster with with the primary antibody for 1 h at room temperature, then its attached hairs and seta (i.e., one-third of an ovigerous washed five times with T-TBS. The secondary antibody was seta altogether) was detached from a single female, crushed peroxidase-conjugated goat anti-rabbit immunoglobulin with a pestle in distilled water (300 ;ul) for 5 min. and (Cappel) diluted 1:5000 with 0.5% nonfat milk in T-TBS. denatured by the addition of 300 jid of the lysis buffer (pH After a 1 h incubation with the secondary antibody at room 6.8). The solutionwascentrifuged at 15.000rpmfor20min. temperature, the membrane was washed five times with Fifty microliters ofthe supernatant was pipetted, and 100 ^\ DW T-TBS. and was further incubated (for 1 min at room of and 100 /ul of the lysis buffer were added to this temperature) with ECL western blotting reagents. This supernatant. Thirty microliters of this solution was sub- membrane was exposed to Hyperfilm ECL (Amersham). jected to electrophoresis, and OHSS was examined by the immunochemical staining of western blots. The purified Affinitv purification ofthe OHSS antiserum antibody was used in the experiments. OHSS was also examined as follows. Embryo clusters mtPraVotTDpohhgFeorrapemposeheomydlberd(oa6nnaaecnt1.id5v%Ae7fiSnrnaaDcrFStriigoo.gwnmesl2m,sAftr)raiopnwmdeorfmteohtlehceniocsnutclmreaaenrntmsrbfsaeirtreaervdnee,decehtlworeaocs--a dwattreeeonrlpaeyhtouccrrreeeunsdsethdrie.indfautgwhneeiddtlhtyhfsaeoirspOebH2su0tSflfSeemriiwnnda.e5ss0Tc0erhxie/abLnLme!diotnfaheebDdoWsvbue,ypeftarohnnredat1iiamhnm,mtmueenlwdeoaic--s- then cut on both edges (5 in width), parallel to the chemical staining of western blots. The sediment was de- dCiBreBctaionndowfermiegruasteidont.o Tinhdeisceatefilttheer sptorsiiptsiowneroefesatacihnepdrowtietihn Tnahteurseodlusteipoanrawtealsy bfuyrtthheeradcdeinttiroinfuogfedthefolrys2is0bmuifnf,erafnord 1thhe. band; the membrane was notstainedwithCBB. except these supernatant was subjected to electrophoresis followed by strips. immunochemical detection. Two protein bands located with the CBB-stained tiller strips, an upper (32 kDa) and lower (30 kDa), were cut Appearance ofOHSS activity in developing embryos: separately from the membrane. Each band was further cut bioassa\ with crushed emhryos into pieces and was incubated for 24 h in 1 ml antiserum at 4C. The pieces ofmembrane were then rinsed in PBS (pH One-third ofthe embryoclusters attached to an ovigerous 7.4) for 10 min, and this operation was repeated 5-6 times. seta were detached from a single female every day until The membrane pieces were overlain with 200 jul of 0.2 M hatching, crushed in 500 /ul of DW, and then centrifuged at 178 M. SAIGUSA AND H. IWASAKI 15.000 rpm. The OHSS activity contained in these samples extracted with the detergent (Triton-X). Remnant matter (i.e., the supernatant and sediment ofcrushed embryos) was (500 mg wet weight) was thawed and washed repeatedly bioassayed. with DW. The remnants were DthWen crushed in 600 ju.1 of Triton-X solution dissolved in (5%, 10%. and 20%), Bioassa\ ofOHSS activity in broken egg cases and were held for 30 min at room temperature (23 C). Each suspension was centrifuged for 20 min (15,000 rpm), the eulmi,bArsaynoddnesitcchreiabtcetodaactehlmisenenvwethsestriynesgt(eSomavii(gig.uees.r,ao,busr1o9hk9ae4in)r,se)rgegrmecnmaaasnietnss,ofonufnittchh-ee ds1iu.s5phear(nneadatca2hn.t23hw0.a0s/xdl)i,viadneddOinHtSoStwaoctwieviltlyswoafsabpiloasatsiscayceuldtufroer ovigerous hairs after hatching and larval release. These remnants were removed with tine forceps after hatching, and stored at -20C until used. Ovigerous hairs and setae Results were notcontained in these remnants. So the possibility that Chromatography and estimation ofthe molecular mass the OHSS activity is present in the ovigerous hairs and setae of the female was excluded. Crude hatch water from about 90 females was saturated Five hundred milligrams of the remnant matter (wet with (NH4)2SO4 overnight; no OHSS activity was found in weight) was thawed and washed repeatedly with DW, and the supernatant. The precipitate was dissolved in 100 mM centrifuged for 20 min (15,000 rpm). The sediment was Tris-HCl buffer. This solution (concentrated hatch water) crushed in 600 of DW; the suspension was divided into was subjected to hydrophobic chromatography, and each /n.1 two wells ofaplastic dish (each 300 /il), and OHSS activity fraction (10 ml) was bioassayed for 1.5 h. was bioassayed for 1.5 h and 2.0 h. As shown in Figure 1, most proteins were removed by We also determined whether the OHSS activity could be this fractionation. The peak of OHSS activity was very 2.0r 0.3 M 0.2 0.1 J 30 40 50 Fraction number Figure 1. HlutinnofOHSSactivityfromahydrophobiccolumn(HiTrap-Octyl-Sepharose4FF;mPMharmacia). Concentratedhatchwaterfrom90femaleswasappliedtoacolumnpreviouslyequilibratedwith20 Tris-HCl buffer containing 300 m/M Na2SO4, and the proteins were eluted with a lineargradient: -8 mM Na:SO4/min (broken line). Open circles (O): 280 nm absorption indicating protein concentration in each fraction (10 ml). Bioassay: incubation time, 1.3 h; OHSS activity, percentage ofstripped, unbroken ovigerous hairs per whorl: datapointsarcthe meanpercentagesof3-10whorls(Asolidtriangles);verticalbarsindicatestandarddeviation; conltol assay(Abottom right),incubationwithbuffer(detailsofassay in Methods). Verticalarrowsindicatethe 6 active tractions (60 ml) applied to anion exchange chromatography. ACTIVE SUBSTANCE IN CRAB HATCH WATER 179 broad, and only halfofit coincided with a protein peak that 20.1 kDa eluted after mM Na2SO4 was reached. A bioassay with an incubation of 1.0 h was also attempted; the results were 0.3 r similar to those shown in Figure 1, although the peak of activity was narrower than that with the longer incubation (not shown). The pooled active fractions from hydrophobic chroma- jteocgtreadphtyo a(n6i0onml;exscihxanvgereticchalroamrartoowgsraipnhyF.ig.Th1e) OweHrSeSsuabc-- 0.2 - -1100 % tivity appeared in the pass-through fractions (not shown). These active fractions (60 ml) were concentrated to 500 4 by ultrafiltration and were then subjected to molecular- /Lil >, sieve chromatography. Each fraction was bioassayed for 1.5 h. As shown in Figure 2A, the activity appeared as a 0.1 50 single peak in fractions 6-8. The molecular mass of the X eluted protein peak was estimated at 35 kDa by comparison o with standard proteins. Similar results were also obtained with the solutions bioassayed for 1.0 h (not shown). 01 23456 78910 SDS-PAGE Conlro1 Fraction number Each fraction eluted in molecular-sieve chromatography (Fig. 2A) was concentrated, and the proteins were analyzed B 23Frac4tion5num6ber7 by SDS-PAGE. As shown in Figure 2B. two common 89 protein bands appeared in fractions 6 and 7, both of which had high OHSS activity (Fig. 2A). Fraction 8. which also had high OHSS activity, had little or no staining. The 55.6 molecular masses of these bands were estimated to be 32 39.2 kDa and 30 kDa by comparison with the marker proteins. An additional band (22 kDa) appeared in fractions 5 and 6; 26.6 itis veryweak in Figure 2B, but isclearin Figure 5A. Itwas clearthat the OHSS activity bioassayed with ovigerous setal segments does not correspond to the 22-kDa band in frac- tions 5 and 6 (compare Fig. 2A with Fig. 2B). 14.3 The concentrated active fractions (6 and 7) from molec- kDa ular-sieve chromatography were also electrophoresed with- out denaturation; the proteins were clearly separated (Fig. 3A). The gel was cut into quarters, and each segment ofthe Figure 2. Purification ofOHSS activity by molecular-sieve chroma- gel was bioassayed for 1.5 h and 2.0 h. The OHSS activity tography with protein analysis on SDS-PAGE. (A) The pass-through ualpapreamraesdsibnetthweeesnec4o0ndkDsaegamnedn2t3(kb)Dao)f,twhheigcehlcsotrnitpai(nmeodletch-e bfryacutlitornasfil(t6r0atmioln),farnodmaanniaolniq-ueoxtch(a5n0g0e/cilh)rowmaastoagprplaipehdytwoermoelceocnucleanrt-rsaiteevde chromatography; fractions are I ml. Open circles (O): protein concentra- 32-kDa and 30-kDa protein bands (Fig. 3B). tion in each fraction (280 nm absorption). Solid triangles (A): the OHSS activityofeach fraction; bioassayscarriedout for 1.5 h withone (ortwo) Characterization ovigerous setal segments perfraction; errorbars: standarddeviation. Con- trol assay (A bottom right). Downward-pointing arrows indicate the mo- Active fractions 6-8 from molecular-sieve chromatogra- lecular masses of marker proteins: glutamate dehydrogenase (55.6 kDa). phy (Fig. 2A) were pooled, and the thermostability of the aldolase (39.2 kDa). and trypsin inhibitor (20.1 kDa). (B) Analysis, by OHSS solution was examined. Active solutions that were SDS-PAGE. ofthe proteins ineach fraction (1-9)eluted from molecular- exposed for 15 min to temperatures between 4C and 80C smieemvebrcahnroemawthoigcrhapwhays.TsthaeinpeodlywaictrhylCaomoimdaessgeilewbarsilltiraanntsbblloutet.edThtoeamPaVrkDeFr showed virtually no decrease in OHSS activity. In contrast, proteins were glutamate dehydrogenase (55.6 kDa), aldolase (39.2 kDa), solutions exposed to 100C lost activity (Fig. 4A). triosephosphate isomerase (26.6 kDa), and lysozyme (14.3 kDa). The two Least-square regression lines fitted to the data (Fig. 4B) bandsthat appearin fractions6and7 (arrowstotheright) have molecular indicated that active solutions incubated at either 4C or masses of32 kDa and 30 kDa. room temperature (about 23C) for up to 70 h showed no significant decrease in activity, and that there was no sig- 180 M. SAIGUSA AND H IWASAKI B 1.5 h 2.0 h 100 r 100 r 55.6 I 80 - 80 - 39.2 I 40 26.6 60 - 23 40 40 14.3 -- kDa 12 kDa 20 20 abed abed Figure 3. Distribution of OHSS activity in a polyacrylamide gel divided into four equal segments after SDS-PAGE. (A)Thegel. Numbersattheleftofthesmall arrowsindicatethemolecularmassesofthestandards (see Fig. 2B). The molecular mass limits ofeach gel segment are indicated by the large arrows. (B) Bioassay with twoorthree ovigerous setal segments. Open bars indicate OHSS activity ofeach gel segment. Incubation periods for the bioassay: 1.5 h and 2.0 h. Stippled bars: controls; the ovigerous setal segments were incubated DW in for 1.5 h and 2.0 h. Error bars: standard deviation. nificant difference between the two experiments. Solutions bands on SDS-PAGE, and they appeared in fractions 6-8 maintained for longer times (100 and 120 h) decreased in (Fig. 5). These immunostained protein bands clearly corre- activity in both experiments. sponded to the peak of OHSS activity in Figure 2A. Figure 4C shows the pH dependency of OHSS activity. The antibodies that had stained the 32-kDa and 30-kDa Afteran assay incubation of 1 h, the pH optimum was quite protein bands were purified by immunochemical affinity to broad, about 7.0-11.0. determine the specificity of binding. As shown in Figure 6A, the antibodies eluted from the 32-kDa protein band on Specificity ofantibodies and affinity purification SDS-PAGE stained the 30-kDa protein as well; and the An antiserum raised from molecular-sieve chromatogra- antibodies eluted from the 30-kDa band similarly stained phy (fractions 6 and 7) detected only two strong protein both the 30-kDa and 32-kDa proteins. B 100- 100- 100-i 80- 80- 80- S 60^ 60- 60- w w f O 40- 40 -i 40- 20- 20- 20- * i i i i i i i 2i 4i 81012 20 40 60 80 100 20 40 60 8800 100 120 6 Temperature ( C) Time of incubation ( h ) pH Figure4. Characteristics ofOHSS activity. (A) Heat stability. Active solutions were incubated for 15 mm at each temperature, and OHSS activity was bioassayed for 1 h. (B) Effects ofprolonged incubation (up to 5 days). For each time, active solutions were maintained at either 4C (O) or 23C (A), and the activity was bioassayedfor 1 h. (C) Dependenceofactivityon pH. Buffers: 100mMNa-acetate(): 100mMTns-HCl(A); 100 mM Gly-NaOH (O). The activity was bioassayed for 1 h. Broken line in (C) indicates the least-square regression curve fitted to the data. Error bars: standard deviation ofthree experiments. ACTIVE SUBSTANCE IN CRAB HATCH WATER 181 234Frac5tion6num7ber89 B 34Fra5ctio6n nu7mber 2 8 9 556 392 * 266 143- kDa Figure 5. Specificity of the polyclonal antiserum raised against OHSS. (A) SDS-PAGE of fractions eluted from molecular-sieve chromatography. The polyacrylamide gel was transblotted onto a PVDF membrane and stained with Coomassie brilliant blue. (B) Immunostaining ofthe PVDF membrane with a polyclonal antiserum raised to OHSS. Numbers to the left show the molecular masses of the standards showninFigure 2B. The intensely immunostainedbandsin fractions6-8havemassesofabout32 kDaand 30 kDa (arrows to the right). In this experiment (Fig. 6A), however, the 32-kDa band ular sieve chromatography (6 and 7 in Fig. 2A) were elec- was at most 2 mm apart from the 30 kDa band on the gel. trophoresed for a longerperiod (9 h), which produced a gap In addition, the PVDF membrane was not stained with of5-6 mm between the upper and lower bands. The whole CBB, except the narrow stripthat had beencut on both sides membrane was stained by Ponceau S, and each protein band mm mm (5 in width), because the antibodies were not bound to (2 in width) was subjected to affinity purification. CBB-stained proteins. So these protein bands could have Again, the antibody raised from the 32-kDa band bound to been incompletely separated. the 30-kDa band as well; and the antibody produced from In Figure 6B, concentrated active fractions from molec- the 30-kDaband alsorecognizedthe 32-kDaband (Fig. 6B). B 55.6 55.6- 39.2- 39.2 i a 26.6 26.6 14.3- 14.3 kDa kDa Figure6. ImmunostainingwithantibodiesaffinitypurifiedfromSDS-PAGEbandsthathadOHSSactivity. SDS-PAGEoftheproteinsfrom molecular-sievefractions6and7(seeFig. 2A) wascarriedoutforeither3.5h (A) or9h (B), the longerelectrophoresis producing the greater separation between the active bands at 32 kDa and 30kDa. Thebands werecutoutofthe PVDFmembranes, incubated with apolyclonal antiserum raisedto OHSS,andtheboundantibodieswereeluted(seeMethods).Theseantibodies,obtainedfromthe shortandlong electrophoresis,wereappliedtotwonewSDS-PAGEruns,bothof3.5h;thesefinalrunsareshowninthisfigure. Immunostaining was effected by antibodies bound (a) to protein in the upper band (32 kDa), and (b) to the proteininthelowerband(30kDa).ThestripstotheleftofthetwopanelswerestainedwithCoomassiebrilliant blue (A) and Ponceau S (B); the numbers (with arrow) are the molecular masses of the standard molecules (identified in Fig. 2B). 182 M. SAIGUSA AND H. IWASAKI OHSS activity in the post-hatching remnants ofthe during development, these activities would appear. Immu- embryo attachment system nochemical and biological observations were made. After hatching, the broken egg cases, funiculus, and in- Immunochemistry. Embryo clusters (one-third of an vestment coat remain attached to the ovigerous hairs. The ovigerous seta) were taken at successive times from a single female picks these remnant attachment structures off the female and crushed; the suspensions were denatured with ovigeroushairs, but this must occurafterthe OHSS released the lysis bufferbefore centrifugation. As shown in Figure 8, with the hatch water has been greatly diluted in the estuary. the 32- and 30-kDa proteins became noticeable at least 2 We therefore examined the possibility that at least some weeks before hatching. The 30-kDa band was the stronger OHSS is present in the remnant attachment structures them- of the two bands at 10 and 6 days before hatching; but its selves. intensity declined and became very faint in embryos 4 h The remnants were collected and stained with FITC- before hatching; and it disappeared completely in post- conjugated, OHSS antiserum (Fig. 7). OHSS was clearly hatched zoeas. In contrast, the 32-kDa band appeared later detected all over the remnants, including the prezoeal cuti- than the 30-kDa band, but it was still quite clear in embryos cles. In contrast, the egg capsule, funiculus, and investment 4 h before hatching, and again was not detected in the coat did not react to the FITC-conjugated OHSS antiserum post-hatched zoeas. In addition to the two bands of OHSS- when the embryos were squeezed in the egg cases (not related protein, an immunoreactive band appeared at about shown). 55 kDa, from 14 to about 2 days before hatching (Fig. 8). When samples for electrophoresis and immunoblotting In another female, the supernatant and the sediment were were prepared from remnants that had been crushed and denatured separately by the lysis buffer after the embryo denatured, only the 32-kDa band was detected (Fig. 7, clusters had been crushed and centrifuged. In the superna- right). tant (Fig. 9A). OHSS first appeared as a weak 32-kDa band Remnants storedat 20C were thawed andcrushed, and 14 days before hatching. The 30-kDa band was noticeable suspensions of this material (not centrifuged) were bioas- 10 days before hatching, and the amount increased abruptly sayedfor 1.5 h and 2.0h. As shown inTable I, strong OHSS in the embryos collected 6 days before. This protein de- was detected in this solution. In another experiment, the creased markedly just before hatching, but was still visible remnants were thawed and crushed, and then treated with 4 h before hatching. 5%, 10%, and 20% Triton-X. After centrifugation for 20 On the other hand, the sediment contained broken egg min (15,000 rpm), the supernatant was bioassayed for 1.5 h cases, funiculi, the investment coat, ovigerous hairs, and 2.2 h and showed strong OHSS activity, particularly at prezoeal cuticles, and probably only a portion of the em- the longer incubation (Table II). bryos. When this material was centrifuged and the superna- Appearance ofOHSS in the developing embryos tkaDnta wbaasndexaamppienaerdedonwtehaeklsyameinftehmealelan(eFisg.de9rBi)v,edthefr3o0m- Because OHSS immunoreactivity and biological activity embryos collected 10, 6, and 4 days before hatching; but it occur in the remnants after hatching, we determined when. was absent at other times. In contrast, the 32-kDa band 55.6 39.2 32 kDa 26.6 Figure7. Immunochemica] stainingofthestructuresremaining attached toafemale'sovigeroushairsafter hatching. Left: the iminunoblot of an extract of the remnants subjected to SDS-PAGE. Arrowhead: 32-kDa protein band. Numbers to the left show the molecular masses ofthe standard molecules (as in Fig. 2B). Right: the remnants stained with polyclonal FITC-conjugated OHSS antiserum. ci1: broken eggcase:/: funiculus;pc: prezoeal cuticle; oh: female ovigerous hair (see fig. 2 in Saigusa. 1994). Scale: 100 /nl. ACTIVE SUBSTANCE IN CRAB HATCH WATER 183 Table I iatissiiv iffsuspensions ofcrushedattachment slniciu ificr hatching Incubation*

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