CYANIDE AND THIOCYANATE-BASED BIOSYNTHESIS IN TROPICAL MARINE SPONGES JAMIE S. SIMPSON AND MARY J. GARSON Simpson, J.S. & Garson, M.J. 1999 06 30: Cyanide and thiocyanate-based biosynthesis in tropical marinesponees. MemoirsoftheQueenslandMuseum44: 559-567. Brisbane. ISSN 0079-8835. The sponge Axinyssa n.sp. incorporates both sodium l4C] cyanide and sodium 14C] [ [ thiocyanateinto2-thiocyanatoneopupukeananeaswellas into9-isothiocyanatopupukeanane, however these 2 precursors were not incorporated into 9-isocyanopupukeanane. The specificity of incorporation into the thiocyanate carbon was confirmed by chemical degradation. Stylotella aurantium incorporates sodium 14C] cyanide and sodium l4C] thiocyanate intothedichloroiminefunctionalityofthestyl|otellanesAand B,aswell as[ into farnesy isothiocyanate.Thespecificityofincorporationintothedichloroiminecarbonatom I was confirmed by chemical degradation. These experiments represent the first detailed studyofthebiosyntheticoriginoforganicthiocyanatesanddichtoroimines, andextendthe range of functionality known to be biosynthesised from cyanide and thiocyanate. Our results raise the interesting question of the interconversion of inorganic cyanide and thiocyanate and/or the interconversion of the resulting organic metabolites in marine sponges. An isothiocyanate-isocyanide conversion was demonstrated in Amphimedon terpenensis by incorporation of a l4C-labelled sample of diisothiocyanatoadociane into diisocyanoadociane.OPorifera, Amphimedonterpenensis,Axinyssa, Stylotellaaurantium, biosynthesis, cyanide, dichloroimines. isocyanides, isothiocyanates,secondarymetabolites, terpenes, thiocyanates. JamieS. Simpson& MatyJ. Garson(email:[email protected]). Departmentof Chemistry, UniversityofQueensland, StLucia4072, Australia; 30November 1998. Marine sponges of the order Axinellida, Furthermore inorganic thiocyanate was shown Halichondrida and Haplosclerida often contain also to be a precursorto both the isocyanide and bioactive terpenes with isocyanide, isothio- the isothiocyanate metabolites in this sponge. cyanate and formamide functionality; the rarer From these experimental results a biosynthetic isocyanate and thiocyanate substituents are also link was inferred between the two inorganic known (Scheuer, 1992; Chang & Scheuer, 1993; precursors or between the two metabolite types Garson et al., 1998). These unique metabolites (Dumdei et al., 1997). have been novel targets for study with ,4C- and The origin ofthe thiocyanato group has been l3C-labelled precursors to determine the bio- the subject of much biosynthetic speculation saytnotmhe(tiGcarsoorni,gin19o8f9;thCehannogn-&terSpcehneouiedr,ca1r9b9o0n; (Garson, 1993). Pham et ai. (1991)suggested the cyanation of a thiol, which appears to be a Garson, 1993; Garson et al., 1999). Workby our reasonable pathway to the amino acid-derived research group on the sponge Amphimedon psammaplin thiocyanate (Jimenez & Crews, terpenensis has shown that marine isocyanides 1991). In contrast, in those sponges in which suchasdiisocyanoadociane(Fig. 1A)arederived thiocyanates co-occur with isocyanides or with by functionalisation ofa terpene precursor with isothiocyanates,theinvolvementoftheambidenl i1n9o8r8g)a.niKcarcuysaonid&e S(cGahresuoenr,(11998869;)Fsouobkseesqueetntall.y, t1h9i9o2c;vaWnaaltkeerio&nhBaustlbeere,n1i9n96v)o.keTdhe(Hdeicehtlaol.r,o1i9m8i9n;e showed that both diterpene (eg. Fig. IB) and (= carbonimidic dichloride) moiety represents a sesquiterpene (eg. Fig. 1C) isocyanides are rare example of a functional group containing cyanide-derived, and further demonstrated the both nitrogen and carbon which has previously intact incorporation oftheNpCi unit. Ourrecent been found in terpene metabolites ofthe Indo- work with Acanthella cavernosa has shown the Pacific sponge Pseudaxinvssa pitvs (Wratten & utilisationofcyanide forthebiosynthesisofboth Faulkner, 1977; 1978a; 1978b). Thecoocurrence a sesquiterpene isocyanide (Fig. ID) and an ofan isothiocyanatetogetherwith dichloroimines isothiocyanate (Fig. 1E) inthis axinellid sponge. in P. pitys suggested to us the involvement of . 560 MEMOIRS OF THE QUEENSLAND MUSEUM Island (23°27\S, 151°55'E) or at North Point (12-16m depth). Lizard Island (H^'S, 145°27'E) on the Great Barrier Reef, Australia Of under permit numbers G96/050, G97/097, G98/037andG98/227 issuedjointly bytheGreat Barrier Reef Marine Park Authority and the QueenslandNationalParksand WildlifeService. Sponge samples used in biosynthetic exper- iments were maintained in running seawatcr at ambienttemperatureandlightconditionspriorto use. Voucher specimens ofthe spongesAxittyssa n. sp., (accession number QMG312575), Stylo- tteelrlpaeanennrsainst,i(uAmM(ZQ4M9G7380;7Q1M33G)3an1d42A2m8)p,hiarmcehdeolnd Q R=NC at the Queensland Museum (QM), Brisbane or £ R NCS the Australian Museum (AM), Sydney. Isolationofmetabolites. I)Axinyssan. sp. Anor- FIG. 1. Structures of isocyanide and isothiocyanatc ganic extract was prepared from frozen sponge metabolites investigated in biosynihetic experi- (49.6g wet wt) and further purified by normal ments. A, diisocyanoadociane. B, kalihinol F. C, 2-isocyanopupukeanane. D, axisonitrile-3. E, phase flash chromatography (gradient elution with hexanes/EtOAc) and normal phase HPLC axisothiocyanate-3. using 0.25% EtOAc in hexanes to give cyanide/thiocyanate in the biosynthesis of the (-)-9-isocyanopupukeanane (Fig. 2A; 107.6mg), dichloroimine group. (-)-9-isothiocyanatopupukeanane (Fig. 2B; In this paper we present the results of bio- 3.5mg), and (-)-2-thiocyanatoneopupukeanane synthetic experiments with the sponge Axinyssa (Fig. 2C; 31.4mg)togetherwith smalleramounts n. sp. which provide evidence for a cyanide/ of other isocyanides and isothiocyanates as thiocyanate origin of the thiocyanato function- describedbySimpsonetal. (1997b).2)Stylotella ality. We test the possibility using Stylotella aurantium. Anorganicextractwaspreparedfrom auremtium that dichloroimine metabolites are frozensponge(204gwet wt) and furtherpurified biosynthesisedfromfarnesylpyrophosphateusing by normalphase flashchromatography (gradient cyanide or thiocyanate to supply the Ni-Cj elution with hexanes/EtOAc) and by normal moiety. The role ofinorganic thiocyanate and of phase HPLC using 0.2% EtOAc in hexanes to an organic isothiocyanatc in diisocyanoadociane givestylotellaneA(Fig.2E;9mg), stylotellaneB biosynthesis are also explored. (Fig. 2F; 75.6mg), and farnesyl isothiocyanate (Fig. 2G; 2mg) as described by Simpson et al. MATERIALS AND METHODS ( 1 997a). 3) Amphimedon terpenensis Diisocyanoadociane (Fig. 1A; 16mg) was Abbreviations.GC-MS,gaschromatography-mass isolated from frozen sponge (25g wet wt) as spectrometry; TLC, thin layer chromatography; describedby Fookes et al. (1988). NMR, nuclear magnetic resonance; HPLC, high Biosynthetic experiments. 1) Pieces ofAxinyssa performance liquid chromatography. n. sp. (approx. 80g wet wt) were placed in an Chemicals and biochemicals. Solvents used in aquarium containing 200ml aerated seawater at the extraction of compounds from sponge ambient temperature (20-23°C Sodium 14C] samples were glass distilled. All radioactive cyanide (100|iCi) or sodium |)4.C] thiocya[nate [ precursorswerepurchasedfromSiijmaChemical (25uCi) was added and the sponge allowed to Co. (St Louis, MO). assimilateradioactivityfor 12hr. Thespongewas Biologicalmaterials. Samples ofAxinyssa n. sp. keptinrunningseawaterina 1 litre aquarium at (Halichondrida: Halichondriidae), Stylotella ambient temperaUire for 16 days, then frozen for entrantium (Halichondrida: Halichondriidae), subsequent radiochemical analysis. Metabolites Kelly-Borges & Bergquist, 1988, and Amphi- were purified according to the above protocol. medon terpenensis (Haplosclerida: Niphatidae) The radioactivity content was monitored at each Fromont, 1993, were collected using SCUBA at stage ofthe purification sequence, and terpenes Coral Gardens, Experimental Gardens or Coral weresubjectedtorepeatedHPLCuntilthespecific Spawning dive sites (12-16m depth), Heron activitywasconstant.2)Stylotellaaurantium(24g d I BIOSYNTHESIS IN TROPICAL MARINE SPONGES wet wt) was placed in an aquarium containing 200ml aerated seawater at ambient temperature(20-2S°C Sodium ) I ' C] cyanide (50|lCi ) was F addedand thespongeallowedto assimilate radioactivity lor I2hr overnight. Thi was kept i ill running seawater in ;i 10L aquarium at ambient temp- R Hi I I erature for 9 days, then frozen m tJ t |i r r mi for subsequent radiochemical bis. Metabolites were pur- ified according to the above protocol.The radioactivity con- tentwasmonitoredat each oi the punlie. aience. A um *C] thiocyanate (UpCii; C)[ d' ays incorporation) PIG, i olated i .., experiment, used a 1Zg piece of 'Mm. lucts. -\, sponge. 3) Ampkimedon ter- thiol from 2-thioayanatunei opupuk!eauatii lo Hani penetfuis (26g wet wt) was ilellane B. 0, famesyl isothi liiyf cai w«ni ran placed in an aquarium nylotellane B. I, amine fVom stylot tontaining 4 ml., acrate seawateratambienttemperature 121)-_'3°CJ | ' 11- innci tissue contained high populai Diisothiocyanatoadocianei, 1 1 uCi)wasadded and diverse bacterial cell types ill addition t1 t1h2ehrsspoonvegrenaiglhlto.weTdhetosapsosnimgielawtaesrakedpitoaienfrnuintning mceelmlbsranAen-bAorucnhdaneuac-lleoiikde symbianl tIiers! seawater in a 20L aquarium at ambient er ai., this volume; Kierst ct al., L991 stuebmspeeqruaetnutreradii\o*rche1m9icdaalysa,naltyshiesn. MFrcotzaebn- Poi ipCi iSmoedniuoml A| 'x[iCn]ystxhaiocn.ysapn.atmeaiwnatsaisnuepdpliineda Twhereerapduiroiafciteidviatycccoorndtienngttwoasthemoanbiotvoeredpraottoecaoclh. . 98i)m.1 1AHlntenrdeiISetdaaLy,s19a9q7u;arSiaumps i of the purification sequence. A sodium bation. the sponge sample was fro/en and \]lC\ thiocyanate (50pCi; 19 days incorporation) : Mianc (Fig. 2CJ experiment used a 45g piece ofsponge. N ited and rigor: ou;sly purified by MPLC to Procedures used in the synthesis oi I CJ- constant specific radioactivity. The thu>e> edlisieswohtehrieoc(ySainmaptsooando&ciGaanresowni.llin bperepdatration). (iFniTga.b2lCe :I consistneinfftcawntiltnytrhaediuosaectoifvet,hiaoscsyianate for the biosynthesis ofthe thioeyanato group as RESULTS shown in Pig 3, To test the specificity oi n corporation, 2-thiocyana sIe)sqIuv/i't/ne.rvspYe/nne.smpetacbololleictteesdbayt HGeCr-oMnSI,. cTonLtCaiannedd . 2C) was degraded lo die thiol (J N\1K; the hc\anc-soluh|es were processed as using L1AIH4. The thiol product was not radio- tJ-purrpiubkeedainnanSeimpissoocnyaentiadle. 1is1o9t9h7ibo)cytaonaglievepdaiier eacxtcilvuesi(vTealbyleas2s)octihaetreefdorweitthhe t|he'V| label nato carbon, Incorporation of sodium C] (lag. 2A,H) and 2-thiocyanatoneopupukeanane f (Fig. 2Cy The GC-MS profile of the sesqui- into a second piece of sponge also gave radio- terpene fraction showed a number ofother peaks active 2-Lhiocvanaloncop" Lnfi (Tab including isoeyamdcs and isothiocyanates. Light Degradation resulted in unlabclled thiol product able 2) indicating the label was again and electron microscopic inspection ofAxinysso t I n.sp. revealed the presence of mieiohial syni- elusivelyassociated wiih Lb anatomoiety ^ bionts. The outer layers sponge tissue were Our experiments i1 monitor rich in cyanobactei ia ofa or] ically isocyanide/isothiocyanate biosynthesis in thia similar to Aphanocapsa feldmanm while the sponge When die isoc)anide/teothiocyanaie pair 562 MEMOIRS OF THE QUEENSLAND MUSEUM TABLE 1. Molarspecific activities ofAxinyssa n. sp. TABLE 2. Molarspecific activities ofAxinyssa n. sp. metabolites, a, published incorporation values were degradationproducts. notpercentage values (Simpson& Garson, 1998); b, incorporation of25uCi; c, <10~2%; d, incorporation Compound Molarspecific Radioactivity oflOO^Ci. (Fig.no.) Precursor (mCaic/timvMitoyle) (%) Compound Molarspecific Incorporation^ 2C Na[14qSCN 0.150 100.0 (Fig.no.) Precursor (mCaic/timvMitoyle) (%) 2D Na[l4C]SCN O.001 0.3 2C Na[,4C]CN 1.230 100.0 2A Na[l4C]SCNb 0.004 <= 2B Na[l4C]SCNb 2.630 0.08 2D Na[I4C]CN 0.001 0.1 2C Na[l4C]SCNb 0.150 0.02 shown in Table 3, consistent with the use of 2A Na[l4C]CNd 0.014 c cyanideforthebiosynthesisofthedichloroimine 2B Na[l4ClCNd 13.900 0.3 group(Fig.4,routenotation 'a'). Thepercentage 2( Na[l4C]CNd 1.230 0.2 incorporation levels measured were low as a result of loss ofvolatile metabolites during the (Fig. 2A,B) were isolated, the isothiocyanate purificationprocess combinedwiththe chemical samples were radioactive (>150,000dpm/mg), instabilityofthedichloroiminegroup.Totestthe whereas the isocyanide samples from both specificity of incorporation, stylotellane B was thiocyanate and cyanide feedings were not degraded to the methyl carbamate (Fig. 2H) and significantly labelled (<100dpm/mg). The theamine(Fig. 21) using0.INphosphoricacidin specificity of labelling of 9-isothiocyanato- 95% methanol. The carbamate product was pupukeanane is currently under investigation. radioactive, whereas the amine was devoid of 2) Extracts of the sponge Stylotella aurantium wraadsioaecxtcivliutsyiv(eTlaybleas4s),octihaetreedforweitthhe t[h14eC]imlaibneel weakly inhibited the growth of a P388 mouse carbon. Incorporation of sodium ,4C] thio- TleLuCkaaenmdiaNcMeRll.lTinheeaDnCdM-csonotlauibnleed cteormppeonneesnbtys cyanate into a secondpiece ofsponge[ also gave radioactivemetabolites (Table 3), howeverthere oaSfnidmtphseBone(xFettirgaac.l.t(2w1Ee9,9rF7e)a,)prttooocggeiesvtseheetdrheawssitytdlehostcefrlailrbaneneedssyiAln awtaison.inIsnufefiaccihenetxpmearteirmieanlt,fotrhecihseomliactaeld fdaergnreasdy-l isothiocyanate (Fig. 2G) was also radioactive. isothiocyanate (Fig. 2G). Light microscopic in- spectionofspongetissuerevealedthe absenceof 3) 50uGi Sodium 14C] thiocyanate was then [ microbial symbionts otherthan bacteria. supplied to a specimen of A. terpenensis 50uGi Sodium I4C] cyanidewas suppliedto a accordingtoourestablishedprotocols(Fookeset [ specimen of S. aurantium according to our al., 1988; Dumdei et al., 1997). After 19 days established protocols (Dumdei et al., 1997; aquarium incubation, the sponge sample was Simpson et al, 1997a). After 9 days aquarium frozen and diisocyanoadociane isolated and incubation, the sponge sample was frozen and rigorouslypurifiedby HPLC, thenrecrystallised stylotellanes A and B were isolated and to constant specific radioactivity. The sample rigorouslypurifiedbyHPLC toconstantspecific was significantly radioactive consistent with the radioactivity. The samples ofstylotellanesAand use of thiocyanate for the biosynthesis of the B (Fig. 2E,F) were significantly radioactive, as isocyanide group (Fig. 5). Degradative exper- iments are in progress to confirm the specific $ labelling. When a sample of sex. ^5 • diisothiocyanatoadociane, l4C-labelled in both isothio- CN- SCN- cyanate groups, was f provided to A. terpenensis, the diisocyanoadociane isolated was found to be radioactive. The specificity FIG 3. Incorporation into isothiocyanate and thiocyanate metabolites of °* labelling is under Axinyssan. sp investigation. BIOSYNTHESIS IN TROPICAL MARINE SPONGES 563 TABLE 3. Molar specific activities ofS. aurantium TABLE 4. Molar specific activities ofS. aurantium metabolites, a, incorporation of 50uCi; b, degradation products, a, after dilution with incorporation of13uCi. unlabelled metabolite. C(oFimgp.onuon.)d Precursor M(omlCaaicr/timsvpMieotcylifei)c Incor<p%or)ation C(oFmigp.onuon.)d Precursor M(omlCaaicrt/imsvpMietocylifei)c Radioactivity 2E Na[l4C]CNa 1.136 0.004 2F Na['V]CN 0.332a 100.0 2F Na[,4C]CNu 1.472 0.033 2H Na[uC]CN 0.326 98.2 2E Na[l4qSCNb 0.354 0.00034 21 Na[l4C]CN 0.004 1.2 2F Na['4C]SCNb 0.224 0.00056 utilisation ofthis ambident precursor. Likewise cyanide is utilised for both thiocyanate and iso- DISCUSSION thiocyanate biosynthesis. Our proposal is that cyanide is converted in Axinyssa n. sp. to thio- OurbiosynthelicexperimentswithAxinyssan. cyanate by the action of an enzyme similar to sp. and with S. aurantium, together with the rhodanese (Scheivelbein et al., 1969; Westley, earlierwork on A. terpenensis andA. cavernosa 1973) and then incorporated into either (Garson, l986;FookesetaL, 1988;DumdeietaL, 9-isothiocyanatopupukeanane or 2-thiocyanato- 1997), reveal that cyanide and thiocyanate are neopupukeanane. The alternative possibility that precursors involved in the biosynthesis of four cyanide is converted first to the isocyanide then NpCi functional groups found in marine ter- by sulphur insertion to an isothiocyanate is less penes, namely isocyanides, isothiocyanates, likely since cyanide was not utilised for the bio- thiocyanates and dichloroimines. synthesis of9-isocyanopupukeanane inthe same A number ofdifferent biosynthetic pathways specimen ofAxinyssa n. sp. can be invoked to explain the origin ofthe thio- Stylotella aurantium uses both cyanide and cyanate group. Pham et al. (1991) suggested the thiocyanate as precursors for the biosynthesis of cyanation of a terpene thiol, however this the dichloroimine and isothiocyanate groups. proposal does not adequately explain the co- Fig.4showstwoplausiblebiosynthetic routesto occurrence of thiocyanates and isothiocyanates the stylotellanes A and B, one route (a)using an inthe samesponge. The insertionofsulphurinto isonilrile intermediate andthe other(b) invoking an organic cyanide or isocyanide to give a an isothiocyanate intermediate. The isolation of thiocyanate is mechanistically unprecedented. farnesyl isothiocyanate, but not of farnesyl Sulphur insertion into an isocyanide to give an isocyanide (Fig. 4A), from this sponge is con- isothiocyanate (Hagadone et al., 1984), perhaps sistent with the operation of path (b). The using an enzyme functionally equivalent to dichloroimine metabolites are among the most rhodanese (Westley, 1973), followed by iso- unusual ofthe cyanide and thiocyanate-derived merisation of the isothiocyanate to the terpenes. In the laboratory, isocyanide dihalides thiocyanate is a plausible biosynthetic pathway. can be synthesised by addition of chlorine to In the laboratory however, the isothiocyanate- isocyanidesorbychlorinationofisothiocyanates thiocyanate equilibrium usually favours an (Ktihleetal., 1967).Thebiosyntheticmechanisms isothiocyanate over a thiocyanate (Hughes, proposed invoke the use of a chloroperoxidase o1f975a)n.aAmbfiindaelntbiotshyinotchyeatniacteposasniiboilnittyoisattthaeckusea eWanlzkyemre, 1t9o93c;hlWoarilnkaetre&inBtuetrlmeerd,ia1t9e9s6).(Butler & terpene carbenium ion or its functional equiv- In A. terpenensis, our results are consistent & alent (He et al., 1989; 1992; Walker Butler, with the use ofboth thiocyanate and ofcyanide 1996). Thiocyanate either reacts through the for isocyanide biosynthesis. Thiocyanate may nitrogen centre generating an isothiocyanate perhaps be converted to cyanide by use of a derivative or through the sulphur generating a peroxidase enzyme, as hasbeen demonstrated in thiocyanate. some bacteria (Ohkawa et al., 1971; Pollock & Results on the biosynthesis ofthe thiocyanate Goff, 1992;Westley, 1981),whichisthenutilised moiety are particularly informative. The incorp- for isocyanide biosynthesis (Fig. 5). oration of inorganic thiocyanate into the We havepreviously suggestedthatA. cavernosa thiocyanate and isothiocyanatemetabolites (Fig. is able to interconvert inorganic cyanide and 2B,C) ofAxinyssa n. sp. is consistentwith direct thiocyanate (Dumdei et al., 1997). Our current 564 MEMOIRS OF THE QUEENSLAND MUSEUM sponge contains isothio- cyanates as minor met- abolites (unpublished results). When radiolabel- ed diisothiocyanatoadociane was supplied to samples of A. terpenensis, the diisocyanoadociane isolated was shown to be radioactive. Chemical degradation is currently in progress to confirm the specificity of labelling in this advanced precursor experiment. In view ofthe previous successful experiments with both diterpene isocyanides (Garson, 1986;FookesetaL, 1988; FIG. 4. Biosynthesis of dichloroimines in Stylotella aurantium. A, farnesyl Karuso & Scheuer, 1989) isocyanide. B, farnesyl isothiocyanate. C, stylotellaneA. D, stylotellane B. and sesquiterpene isonitriles (Karuso & results suggestAxinyssan. sp., & aurantium and Scheuer, 1989; Dumdei et al, 1997), it is quite A. terpenensis are able to interconvert these 2 extraordinarythat we have not demonstratedthe inorganic precursors. We have also speculated incorporation of cyanide into the major iso- that enzymic transformations which parallel the cyanide component (Fig. 6) ofAxinyssa n. sp. cyanide-thiocyanate interconversion may Likewise thiocyanate appears not to be used for transform organic isocyanides into isothio- isocyanide biosynthesis in this sponge, in cyanates, or the reverse, in marine sponges contrast toA. cavernosa in which thiocyanate is (Dumdei et al, 1997). Figure 6 illustrates these used for isocyanide biosynthesis (Dumdei et al., suggestedbiosyntheticrelationshipsforAxinyssa 1997) and also in contrast toA. terpenensis (this n.sp. Thiocyanate is used to make 9-isothio- paper). The lack ofincorporation ofthiocyanate cyanatopupukeanane which then undergoes into 9-isocyanopupukeanane (Fig. 6) suggests desulphurisation togive9-isocyanopupukeanane; that eitherthethiocyanate to cyanide conversion alternatively, cyanide is used forisocyanide bio- isinefficientinthisspongeorthattheconversion synthesis, then the isocyanide is converted into ofisothiocyanate into isocyanide does not occur. the isothiocyanate by an enzyme functionally We are currently isolating some of the other equivalent to rhodanese. minor isocyanide metabolites from Axinyssa In pioneering biosynthetic experiments, samples labelled by thiocyanate or cyanide in Hagadone et al. (1984) inferred the precursor order to investigate the role of cyanide and status of an isocyanide terpene metabolite in thiocyanate in isocyanide biosynthesis in this isothiocyanate formation in Ciocalypta sp. sponge. A clearer picture ofthe complex meta- They explored the in vivo conversion of 2-iso- bolic interrelationships in Axinyssa n. sp. will cyanpupukeanane into the corresponding emerge when we test the utilisation of formamide and isothiocyanate metabolites. The natural product status offormamide metabolites CN has however been questioned by Tada et al. (1988). A second concern with the work of Hagadone et al. (1984) is their use of the relatively insensitive l C label in conjunction with mass spectrometric detection. SCN- Our preliminary results with A. terpenensis suggest that an isothiocyanate to isocyanide FIG. 5. Biosynthesis of diisocyanoadociane in A. transformationmayoccurinthis sponge.The terpenensis. BIOSYNTHESIS IN TROPICAL MARINE SPONGES 565 now exploring Nj-Cj biosynthesis provide us with additional candidates to study the cellular localisationofterpenemetabolitesandtoexplore the role ofsymbionts in biosynthesis. TAXONOMIC NOTE. The sponge which we have identified as 'Amphimedon'' terpenensis in this paper has a chequered taxonomic history. It was firstnamed in the literature as anAdocia sp. bytheRochegroup(Bakeretal., 1976). Fromont (1993)placed the sponge withinAmphimedon in hertaxonomicstudiesonhaploscleridspongesof the Great Barrier Reefand proposed the species Q-isocyanopupukeanane 9-isothiocyanatopupukeanunc name for the large proportion of terpene FIG. 6. Possible biosynthetic interconversions in metabolites. Van Soest et al. (1996) considered Axinyssa n. sp. Solid lines indicate incorporation the skeletal characteristics were too irregular to results or possible conversions, dotted lines indicate be compatible with Amphimedon. Based on non-incorporation. structural characteristics and spicule analysis, they proposed the combination Cymbastela l4C-labelled isocyanide and isothiocyanate terpenensis, but acknowledged howeverthat the precursors by this sponge. skeletalmorphology,growthformandtexturefor The origin of the cyanide or the thiocyanate tdheescsrpiboendgebyweHroeopnoetrt&ypiBcearlgqoufisCtym(b1a9s9t2e)l.a,Thaes used by marine sponges remains a tantalising documented secondary metabolite chemistry of mystery. Plants generate hydrogen cyanide by- Cymbastela spp. consists ofpyrrole metabolites hydrolysis of cyanogenic glycosides (Seigler, 1975). Some bacteria are known to produce from a New Caledonian species (Ahond et al., hydrogen cyanide (Knowles, 1976) orto convert 1988). SamplesofCymbastelasp.collected from the amino acid cysteine to thiocyanate (Voet & HmeetraobnolIi.teanpdrofLiilzeabrydNI.MdRo naontdhGaCv-eMSa,sebcuotnhdaavrey Voet, 1995),whilemethioninehasbeenimplicat- ed in the formation ofcyanide as a byproduct of been shown to contain 24-isopropyl-5:' sterols ethylene biosynthesis (Pirrung, 1985). To date (Stoilov et al., 1986), whereas A. terpenensis experiments to determine an amino acid origin contains8 ' -sterols(Garsonetal., 1988).A more for the isocyano group in diisocyanoadociane thorough taxonomic assessment of 'A/ ter- have been unsuccesful (Fookes et al., 1988). penensis (and the related C. hooperi), including consideration of live specimen characteristics, Two sponges used in our biosynthetic ex- growth form, texture and spongin content and periments have interesting symbiotic profiles. skeletal structure is required. It is possible that a Amphimedon terpenensis has previously been new genus is required for these species but this shown to contain high bacterial populations of requires substantially more corroborative eubacteria together with a cyanobacterial evidence than is presently available (e.g. genetic symbiont which morphologically resembles analyses).Forthepresentweretainthetaxon 'A.' Aphanocapsafeldmcmni (Garson et al., 1992). terpenensis, but acknowledge it does not belong Axinyssa n.sp. contains a cyanobacterial sym- with typical members ofAmphimedon (Haplo- biont together with numerous bacteria, in sclerida; Niphatidae). particular an archaeal-like bacteria which con- tainsahighlyunusualmembrane-boundnucleoid ACKNOWLEDGEMENTS (Fuerst,thisvolume;Fuerstetal., 1998).Wehave previously demonstrated that A. terpenensis We thank John Hooper, Queensland Museum, isocyanides are localised in sponge cells, for taxonomy, the Australian Research Council primarily archaeocytes and choanocytes, and forfundingandtheAustralianGovernmentforan infer that this is the site of synthesis of the APRA scholarship. The assistance ofthe staffof metabolites (Garson et al., 1992). Terpene HeronIslandandLizardIslandResearchStations metabolites in 2 other sponges have been shown in performing field work is gratefully acknow- to be localised in sponge cells rather than sym- ledged.Thisresearchwasperformedunderpermits biont cells (Uriz et al, 1996; Flowers et al., G96/050, G97/097, G98/037 andG98/227 issued 1998). The range ofsponges with which we are jointly by GBRMPA and QNPWS. 566 MEMOIRS OF THE QUEENSLAND MUSEUM LITERATURE CITED 1993. Thebiosynthesisofmarine natural products. Chemical Reviews 93: 1699-1733. AIIONCD.D,,,PLAO.AU,BPZOAUUTRT,IETC,A,,PP.M,UBSL.SA,EVTCE,OLLLMI.EN,,&RVTI,.H,LOFAIIUSZORANEM,NETSD,,. GARS&iOnNSa,TmOMaI.rJLi.On,eVP,sApRIo.TLnA.gLe1I9,8o8fV..t.hIesLoIApArmeApnEhoiNidm-eJbdiEooNsnSynEgtNehn.eussiS.s. 1988. A new antitumoural compound isolated Incorporationstudieswith[l-l4C]acetate, [4-l4C] from the sponge Pseudaxinyssa cantharella sp. cholesterol and [2-14C] mevalonate.Comparative nov. (Axinellidae). Comptes Rendus de Biochemistry and Physiology91B(2): 293-300. BAKE[R',AcJa.Td.e,mWicELdeLsSS,ciRe.Jn.c,esOBSeErRieHAII.N3S0L7I:,14W5.-E1.48&. GARSBOANT,TME.RJ.S,HTIHLOLM,PSCOMN.,,J.ME.U,RLPAHRSYE,N,P.RT..M.&, HAWES,G.B. 1976.Anewdiisocyanideofnovel BERGQUIST, P.R. 1992.Terpenes inspongecell ring structure from a sponge. Journal of the membranes: cell separation and membrane American Chemical Society 98(13): 4010-4012. fractionation studies with the tropical marine BUTLER, A. & WALKER, J.V. 1993. Marine hab- spongeAmphimedonsp. Lipids 27: 378-388. peroxidases. Chemical Reviews93: 1937-1944. GARSON, M.J., SIMPSON, J.S., FLOWERS. A.E. & CHANG,C.W.J.&SCHEUER,P.J. 1990.Biosynthesis DUMDEI E.J. 1999. Cyanide and thiocyanatc- of marine isocyanoterpenoids in sponges. derived functionality in marine organisms - Comparative Biochemistry and Physiology 97B: structure, biosynthesis and ecology. Studies in 227-233. Natural Products, inpress. 1993. Marine isocyano compounds. Pp. 34-75. In HAGADONE, M.R., SCHEUER, P.J., & HOLM, A. Scheuer, P.J. (ed.) Marine Natural Products. 1984. On the origin ofthe isocyano function in Diversity and Biosynthesis: Topics in Current marine sponges. Journal of the American Chemistry. Volume 167. (Springer-Verlag: Chemical Societv 106: 2447-2448. Berlin and New York). HE, H.-Y., FAULKNER, D.J., SHUMSKY, J.S., DUMDEI, E.J., FLOWERS, A.L.. GAKSON, M.J. & HONG,K.&CLARDY,J. 1989.Asesquiterpene MOORE, CJ. 1997. The biosynthesis ofsesqui- thiocyanate and three sesquiterpene isothio- terpene isocyanides and isothiocyanates in the cyanates from the sponge Traehyopsis marine sponge Acanthella cavernosa (Dendy); aplvsinoides. Journal ofOrganic Chemistrv 54: evidence for dietary transfer to the dorid nudi- 2511-2514. branch PhyUidiella pustulosa. Comparative HE, H.-Y., SALVA, J., CATALOS, R.F. & FAULK- Biochemistryand Physiology 1ISA: 1385-1392. NER, D.J. 1992. Sesquiterpenethiocyanates and FLOWERS, A.E., GARSON^M.J., WEBB, R.I.. isothiocvanates from Axinvssa aplvsinoides. DUMDEI, E.J.&CIIARAN, RD. 1998.Cellular Journal ofOrganic Chemistry 57: 3191-3194. origin of chlorinated diketopiperazines in the HOOPER, J.N.A. & BERGQUIST, P.R. 1992. dictyoceratid spongeDvsideaherbacea (Keller). Cymbastela, a new genus oflamellate coral reef Cell and Tissue Research 292: 597-607. sponges. Memoirs of the Queensland Museum FOOKES, C.J.R., GARSON, M.J., MACLEOD, J.K., 32(1): 99-137. SKELTON, B.W. & WHITE, A. H. 1988. HUGHES, M.N. 1975. Generalchemistry. Pp. 3-67.In Biosynthesis of diisocyanoadociane, a novel Newman,A.A. (ed.)Chemistryandbiochemistry diterpene from the marine sponge Amphimedon ofthiocyanic acid and itsderivatives. (Academic sp.: crystal structure ofa monoamide derivative. Press: London). Journal of the Chemical Society Perkin Trans- JIMENEZ, C. & CREWS, P. 1991. Novel marine actions I: 1003-1011. sponge derived amino acids. 13. Additional I ROMONT,J. 1993.DescriptionsofthcHaplosclerida psammaplysin derivatives from Psammaplysilia (Porifera: Demospongiae) occurring in tropical purpurea. Tetrahedron 47: 2097-3102. waters of the Great Barrier Reef. The Beagle, KARUSO, P.& SCHEUER, P.J. 1989. Biosynthesisof Records of the Northern Territory Museum of isocyanoterpenes in sponges. Journal ofOrganic Artsand Science 10(1): 7-40. Chemistry 54: 2092-2095. I I ERLS.T,&J.RAE.,ISWWEIBGB,,H.R.MI...G19A9R8.SMOeNm,brMa.Jn.e,-HboAuRnDdYe,d KELLSYp-oBnOgResGEfSr,omM.M,ot&upBoEreRGIQsUlaInSd,T,PaPp.Ru.a 1N9e88w. nucleoids in microbial symbionts of marine Guinea. Indo-MalayanZoology 5: 121-159. sponges.FEMSMicrobiologyLetters 166:29-34. KNOWLES, C.J. 1976. Microorganisms and cyanide. GARSON, M.J. 1986. Biosynthesis of the novel Bacteriological Reviews40(3): 652-680. diterpene isonitrile diisocyanoadociane by a KOHLE,E.,ANDERS,B.&ZUMACH,G. 1967.New marine sponge o\~ the Amphimedon genus: methods of preparative organic chemistry IV. Incorporation studies with sodium ! C] cyanide Syntheses ofisocyanide dihalides. Angewandtc [ and sodium [2- C] acetate. Journal of the Chemie International Edition 6: 649-653. Chemical Society Chemical Communications OHKAWA, H & CASIDA, J.E. 1971. Glutathione- 35-36. s-transferases liberate hydrogen cyanide from 1989. Biosynthetic studies on marine natural oraanicthioevanates.Biochemical Phannacolosv products. Natural Product Reports 6: 143-170. 20:1708-1711. BIOSYNTHESIS IN TROPICAL MARINE SPONGES 567 PHAM,A.T., ICHIBA,T, YOSHIDA, W., SCHEUER, Australia. Bulletin de Nnstitut Royal des P.J., UCHIDA, T, TANAKA, J., & HIGA, T. SciencesNaturelles de Belgique66: 103-108. 1991. Two marine sesquiterpene thiocyanates. STOILOV I.L., THOMPSON, J.E. & DJERASSI, C. Tetrahedron Letters 32: 4843-4846. 1986. Biosynthetic studies of marine lipids 7. PIRRUNG, M.C. 1985. Ethylene biosynthesis. 3. Experimental demonstration of a double Evidence concerning the fate of Ci-Ni of alkylation at C-28 in the biosynthesis of24-iso- 1-aminocyclopropanecarboxylicacid.Bioorganic propylcholesterols in a sponge. Tetrahedron Chemistry 13:219-226. 42(15): 4147-4160. POLLOCK, J.R. & GOFF, H.M. 1992. Lactoper- TADA, H., TOZYO, T & SHIRO, M. 1988. A new oxidase-catalysedoxidationofthiocyanateion.A isocyanide from a sponge. Is the formamide a carbon-13 nuclear magnetic resonance study of natural product? Journal of Organic Chemistry the oxidation products. Biochimica Biophysica 53:3366-3368. Acta 1159: 279-285. URIZ, M.J., TURON, X., GALERA, J. & TUR, J.M. SCHEUER, PJ. 1992. Isocyanides and cyanides as 1996. New light on the cell location of avarol naturalproducts.AccountsofChemicalResearch within the sponge Dysidea avara (Dendro- 25: 433-439. ceratida).CellandTissueResearch285:519-527. SCHIEVELBEIN, H.,BAUMEISTER, H.&VOGEL, VOET D. & VOET J.G. 1995. Biochemistry. 2nd R. 1969. Comparative investigations on the Edition (Wiley: NewYork). activity of thiosulphate-sulphur transferase. WALKER, J.V. & BUTLER, A. 1996. Vanadium Naturwissenschaften 56: 416-417. bromoperoxidase-catalysed oxidation of SEIGLER, D.S. 1975. Isolationandcharacterisationof thiocyanate by hvdrogen peroxide. Inorganica naturally occurring cyanogenic compounds. ChimicaActa243": 201-206. Phytochemistry 14: 9-29. WESTLEY, J. 1973. Rhodanese. Advances in Enzym- SIMPSON,J.S.,RANIGA,P.&GARSON,M.J. 1997a. ology 39: 327-368. Biosynthesis of dichloroimines in the tropical 1981. Cyanide and sulfane sulfur. Pp. 61-75. In marinespongeStvlotellaaurantium. Tetrahedron Vennesland, B., Conn, E.E., Knowles, C.J., Letters38(45): 7947-7950. Westley, J. & Wissing, J. (eds) Cyanide in SIMPSON, J.S. GARSON, M.J., HOOPER, J.N.A., Biology. (Academic Press: London). CLINE, E.I. & ANGERHOFER, C.K. 1997b. WRATTEN, S.J. & FAULKNER, D.J. 1977. Carbo- Terpene metabolites from the tropical marine nimidic dichlorides from the marine sponge sponge Axinyssa sp. nov. Australian Journal of Pseudaxinyssa pitys. Journal of the American Chemistry 50:1123-1127. Chemical Society 99: 7367-7368. SIMPSON, J.S. & GARSON, MJ. 1998. Thiocyanate WRATTEN,S.J.,FAULKNER,D.J.,VANENGEN,D. biosynthesis in the tropical marine sponge & CLARDY, J. 1978a. A vinyl carbonimidic Axinyssa n. sp. Tetrahedron Letters 39: 5819- dichloridefromthemarinespongePseudaxinyssa 5822. pitys. Tetrahedron Letters 16: 1391-1394. SOEST, R.W.M. VAN, DESQUEYROUX- FAUNDEZ, WRATTEN, S.J. & FAULKNER, D.J. 1978b. Minor R., WRIGHT, A.D. & KONIG, G.M. 1996. carbonimidicdichloridesfromthemarinesponge Cymbastela hooperi sp. nov. (Halichondrida: Pseudaxinyssa pitys. Tetrahedron Letters 16: Axinellidae) from the Great Barrier Reef, 1395-1398.