CORE Downloaded from orbit.dtu.dk on: Dec 20, 2017 Metadata, citation and similar papers at core.ac.uk Provided by Online Research Database In Technology Fungal Origins of the Bicyclo[2.2.2]diazaoctane Ring System of Prenylated Indole Alkaloids Finefield, Jennifer M.; Frisvad, Jens Christian; Sherman, David H.; Williams, Robert M. Pub lished in: Journal of Natural Products Link to article, DOI: 10.1021/np200954v Pub lication date: 2012 Document Version Early version, also known as pre-print Link back to DTU Orbit Citation (APA): Finefield, J. M., Frisvad, J. C., Sherman, D. H., & Williams, R. M. (2012). Fungal Origins of the Bicyclo[2.2.2]diazaoctane Ring System of Prenylated Indole Alkaloids. Journal of Natural Products, 75(4), 812- 833. DOI: 10.1021/np200954v General rights Copyright and moral rights for the publications made accessible in the public portal are retained by the authors and/or other copyright owners and it is a condition of accessing publications that users recognise and abide by the legal requirements associated with these rights. • Users may download and print one copy of any publication from the public portal for the purpose of private study or research. • You may not further distribute the material or use it for any profit-making activity or commercial gain • You may freely distribute the URL identifying the publication in the public portal If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. Review pubs.acs.org/jnp Fungal Origins of the Bicyclo[2.2.2]diazaoctane Ring System of Prenylated Indole Alkaloids Jennifer M. Finefield,† Jens C. Frisvad,‡ David H. Sherman,§ and Robert M. Williams*,†,⊥ † Department of Chemistry, Colorado State University, Fort Collins, Colorado 80523, United States ‡ Department of Systems Biology, Building 221, Technical University of Denmark, DK-2800 Kgs. Lyngby, Denmark § Life Sciences Institute and Departments of Medicinal Chemistry, Microbiology & Immunology, and Chemistry, University of Michigan, Ann Arbor, Michigan 48109, United States ⊥ University of Colorado Cancer Center, Aurora, Colorado 80045, United States ABSTRACT: Overeightdifferentfamiliesofnaturalproducts consisting of nearly 70 secondary metabolites that contain the bicyclo[2.2.2]diazaoctane ring system have been isolated from various Aspergillus, Penicillium, and Malbranchea species. Since 1968, these secondary metabolites have been the focus of numerous biogenetic, synthetic, taxonomic, and biological studies and, as such, have made a lasting impact across multiple scientific disciplines. Thisreview covers the isolation, biosynthesis, and biological activity of these unique secondary metabolites containing the bridging bicyclo[2.2.2]diazaoctane ringsystem.Furthermore,thediversefungaloriginofthesenaturalproductsiscloselyexaminedand,inmanycases,updatedto reflect the currently accepted fungal taxonomy. ■ INTRODUCTION known to produce metabolites containing the bridging bicycle. SpecificincorporationofintactC units,combinedwiththe13C Naturalproductsderivedfromfungalsourceshavebeenanarea 2 coupling patterns observed by 13CNMR spectroscopy, demon- of intense research for decades due to the vast structural strated that the isoprene units found in these metabolites arise diversity and biological activity of these secondary metabolites. from dimethylallyl pyrophosphate (DMAPP), a product of the Numerous fungal-derived natural products serve as clinical mevalonic acid pathway (Scheme 1).11,12 therapeutics for both human and animal diseases, and thus the Of the natural products containing the unusual bridging search for new classes of bioactive secondary metabolites from bicycle, two distinct stereochemical configurations have been terrestrial and marine fungal sources has garnered additional interest.1 Natural products containing a unique bicyclo[2.2.2]- noted with respect to the relative configuration at the C-19 position (brevianamide numbering). The rare anti-configuration diazaoctaneringsystemarepartofadiverseclassofbiologically (1)andthemorecommonsyn-configuration(2)aredetermined active prenylated indole alkaloids isolated mainly from various Penicillium and Aspergillus species of fungi.2 The breviana- by the position of the C−H proton at the bridgehead of mides,3 paraherquamides,4 stephacidins,5 notoamides,6 asper- the bicyclic core in relation to the bridging secondary lactam paralines,7 marcfortines,8 chrysogenamides,9 and malbranchea- (Figure 2).13 The brevianamides are currently the only family mides10 exhibit a range of interesting structural features, such of secondary metabolites to display the anti-configuration about the bridging bicycle; however, it was recently discovered that as a bicyclo[2.2.2]diazaoctane nucleus and a complex, oxidized two novel metabolites chrysogenamide A and versicolamide B amino acid skeleton (Figure 1). Structurally, these natural alsodisplaytherareanti-stereochemistry.6f,9Contrarytothis,all products are comprised of tryptophan, a cyclic amino acid other known metabolites containing the core bridging bicycle (proline, pipecolic acid, or derivatives of proline or pipecolic display the syn-configuration. acid), and one or two isoprene units. In addition to their Since the first isolation of these bicyclo[2.2.2]diazaoctane- structuraldiversity,avarietyofbioactivitiesarealsopresentfor containing metabolites, substantial effort has focused on both these compounds, including but not limited to insecticidal, the synthetic and the biosynthetic aspects of this unique cytotoxic, anthelmintic, and antibacterial properties. ring system.14,15 However, although relatively little is known Initial characterization of these types of natural products led about the microbial assembly and modification of metabolites to the conclusion that two isoprene units are present in these containing this core bridging bicycle, new genomic and bio- alkaloid families, in which one of the two isoprene units is chemical approaches are beginning to clarify important aspects involved in the formation of the bicyclo[2.2.2]diazaoctane ring system.11 In order to determine the biosynthetic pathway fromwhichtheisopreneunitsoriginate,[13C ]-acetatehasbeen Received: December 8,2011 2 utilized in precursor incorporation studies with fungal cultures Published: April15, 2012 ©2012AmericanChemicalSocietyand AmericanSocietyofPharmacognosy 812 dx.doi.org/10.1021/np200954v|J.Nat.Prod.2012,75,812−833 Journal of Natural Products Review Figure 1. Structures ofseveral secondary metabolites that contain the core bicyclo[2.2.2]diazaoctane ringsystem. Scheme 1. Classical Mevalonic Acid Pathway Showing the Labeling Pattern via 1,2-Doubly Labeled Acetatea aNote the change in carbon numbering. Scheme 2. Proposed Biosynthetic Diels−Alder Reaction16 Figure 2. Anti- and syn-relationship of the bicyclo[2.2.2]diazaoctane core. biomimetic syntheses of several advanced metabolites.15−17 of these pathways. Originally proposed by Porter and Sammes Concurrently, substantial effort has been put forth to isolate in 1970, the biosynthetic formation of the bicyclo[2.2.2]- and characterize the putative Diels−Alderase enzyme respon- diazaoctane ring system is believed to arise via an intra- sible for this biosynthetic transformation, but, to date, no such molecular hetero Diels−Alder reaction (IMDA) of a 5-hydro- enzyme has been isolated. xypyrazine-2(1H)-one (Scheme 2).16 Extensive synthetic ThePenicilliumandAspergillusfungalproducersofsecondary research carried out by Williams and co-workers has aimed at metabolites containing the bicyclo[2.2.2]diazaoctane ring have supporting a biosynthetic Diels−Alder reaction via the beendefinedtaxonomicallybasedonearlyphenotypicmethods 813 dx.doi.org/10.1021/np200954v|J.Nat.Prod.2012,75,812−833 Journal of Natural Products Review Table 1. Culture Collection Strains Producing Secondary Metabolites with a Bicyclo[2.2.2]diazaoctane Unit and Related Compounds (new data: Frisvad, unpublished) secondarymetabolite fungalspecies producers:isolatesavailableininternationalculturecollections malbrancheamides Malbranchea (RRC1813)b(UCSC086937A) aurantiacaa M.graminicola chrysogenamide P.chrysogenum (No.005)b brevianamides P.viridicatum IMI039755ii,cIMI351305,IMI351306,NRRL869,NRRL870,NRRL959,NRRL962,NRRL3586, NRRL3600,NRRLA-15402,NRRLA-18563,NRRLA-26909 P.brevicompactum CBS257.29,cCBS256.31,CBS316.59,CBS317.59,CBS480.84,CBS100068,CBS110069,NRRL867, NRRL32579 A.carlsbadensis CBS123894c deoxybrevianamides A.pseudoustus NRRL5856,cMRC096 P.italicum ATCC48952,CBS339.48,CBS278.58,CBS349.75,CBS489.84, P.ulaiense CBS136.41,CBS210.92,CBS722.92,CBS262.94 paraherquamides P.brasilianum CBS253.55,cCBS338.59 P.cluniae CBS276.89c P.glaucoroseum NRRL908c P.cf.canescens ATCC20841,IMI332995 paraherquamideE A.aculeatinus CBS204480 A.fijiensis CBS313.89,cIMI337664a asperparalines A.aculeatinus ATCC204480=JV-23,CBS101.43,CBS186.67,CBS610.78,CBS621.78,CBS116.80,CBS121060, CBS121875 A.fijiensis CBS313.89,cCBS119.49,IMI337664a notoamides(including A.bridgeri CBS350.81c (−)-versicolamide) A.melleus CBS546.65,cNRRL394 A.ochraceus CBS108.08,cCBS589.68,CBS624.78,NRRL6319,(CL41582) A.ostianus CBS103.07,cCBS101.23,CBS311.80,IMI177964b,IMI348937,NRRL422,NRRL5225,NRRLA-15156, (01F313) A.persii CBS112795c A.petrakii CBS105.57c A.sclerotiorum CBS549.65,cATCC18413,NRRL5167,(CNC358) A.westerdijkiae CBS112803c=NRRL3174,CBS112791,CBS112804,NRRL5175,NRRL5221,NRRL5228, notoamides(including A.protuberus CBS602.74,cCBS601.74 (+)-versicolamide) A.versicolor CBS118.50,CBS106.57,CBS599.65,IMI096225,NRRL35600 A.elongatus CBS387.75c austamide A.pseudoustus NRRL5856,cMRC096 citrinadins P.citrinum CBS139.45,c(N-059) PF1270citrinadins P.westlingii (PF1270) talathermophilins Talaromyces CBS116.72,(YM1−3) thermophilus aPossiblemisidentification. bStrain unavailable. cType strain. of Raper and Thom18 for Penicillium and Raper and Fennell19 inacaveinMexico(Table2).10Shortlyfollowingtheisolation for Aspergillus. However, several of these species have since of malbrancheamide and malbrancheamide B, Mata and co- been reclassified based on modern molecular methods. workersreportedthepresenceofthenonhalogenatedprecursor Extensive taxonomical research carried out by Frisvad and malbrancheamide C, which was later named premalbranchea- co-workershasprovidednewphylogeneticinformationforeach mide.10c This unique family of halogenated secondary fungal culture known to produce the bicyclo[2.2.2]diazaoctane metabolites has expanded recently with the isolation of two ring system described in this review, and both the original and newchlorinatedmetabolites,(−)-spiromalbramideand(+)-iso- updated fungal strain nomenclature will be mentioned when malbrancheamideB,fromMalbrancheagraminicola,asreported applicable. Furthermore, numerous strains of these fungal by Crews and co-workers.10d Furthermore, two brominated cultures have been determined to produce the same sets of analogues, (+)-malbrancheamide C (hereafter referred to as secondary metabolites (Table 1). Taxonomic revisions of (+)-malbrancheamide “C”) and (+)-isomalbrancheamide C, species and reidentifications of the strains are based on a were obtained from M. graminicola when the growth medium polyphasic approach, including morphological, physiological, was enriched with bromine salts. chemical, and DNA sequence data. Mostly sequences from This family of natural products represents the only bicyclo- β-tubulinandcalmodulingeneshavebeenvaluableinassigning [2.2.2]diazaoctane-containing metabolites to be reported from s■trains to new or known species. a fungal source outside the genera Penicillium and Aspergillus. Taxonomically, the strain of M. aurantiaca (RRC1813) may MALBRANCHEAMIDES either be that species or represent the species M. graminicola, First identified in 2006 by Mata and co-workers, malbranchea- since three strains of M. aurantiaca from the CBS collection mide and malbrancheamide B were isolated from Malbranchea (CBS 127.77, Utah, ex culture contaminant, type strain; CBS aurantiaca RRC1813, a fungus obtained from bat guano found 759.74 and CBS 309.76, both ex soil, India) did not produce 814 dx.doi.org/10.1021/np200954v|J.Nat.Prod.2012,75,812−833 Journal of Natural Products Review Table 2. Fungal Origin of the Malbrancheamides Scheme 3. Proposed Biosynthesis of the Malbrancheamides themalbrancheamidesorpenicillicacid.10eHowever,theisola- Following the isolation of the malbrancheamides, interest tion of (+)-malbrancheamide, (+)-malbrancheamide B, wassparkedinelucidatingthebiosynthetictimingoftheindole (+)-premalbrancheamide, and (−)-spiromalbramide from chlorination. As shown in Scheme 3, the initially proposed M.graminicolaindicatesthatthesecompoundsarecommon biogenesis of the malbrancheamides begins with the con- in the genus Malbranchea. densation of tryptophan, proline, and dimethylallyl pyrophos- Structurally, the malbrancheamides are the first members of phatetoaffordtheknownnaturalproductdeoxybrevianamideE. this class of metabolites to display halogenation of the indole From here, two distinct biosynthetic pathways are possible to moiety. While malbrancheamide was determined to contain form the known metabolite premalbrancheamide. One chlorinationattheC-5andC-6positionoftheindole,theexact potential pathway involves oxidation of deoxybrevianamide E structure of malbrancheamide B was unclear. By synthesizing to yield the Diels−Alder precursor 5-hydroxypyrazin-2(1H)- both the C-5-chlorinated and C-6-chlorinated potential one (4a), which would undergo [4+2] cycloaddition to afford compounds,itwasestablishedthatmalbrancheamideBcontains keto-premalbrancheamide. Subsequent carbonyl reduction of C-6monochlorination.21Inconjunctionwiththeuniqueindole the tertiary amide would provide premalbrancheamide. On chlorination, the malbrancheamides are also characterized by the other hand, carbonyl reduction could occur prior to the the syn-configuration about the bridging bicycle, as well as the IMDA reaction, in which 4b would serve as the key achiral presence of a monoketopiperazine moiety in the core bicycle. intermediate and direct intermediate to premalbrancheamide. Biologically, the malbrancheamides were determined to display Two individual and concurrent halogenases would then lead calmodulin inhibitory activity of CaM-dependent phosphodies- from premalbrancheamide to malbrancheamide B and then to terase (PDE1).10c,f malbrancheamide. 815 dx.doi.org/10.1021/np200954v|J.Nat.Prod.2012,75,812−833 Journal of Natural Products Review To test whether premalbrancheamide and/or keto-premal- and pyran rings. Chrysogenamide A is the first and only brancheamide serve as biosynthetic precursors to the metabolite of these families of natural products to display halogenated metabolites, doubly 13C-labeled premalbranchea- ■neurocyteprotectionagainstoxidativestress-inducedcelldeath.9 mide and keto-premalbrancheamide were synthesized by Williams et al. and provided to M. aurantiaca in separate BREVIANAMIDES precursor incorporation studies (Scheme 4).10f Results from Between 1969 and 1972, Birch and co-workers isolated six novel secondary metabolites, brevianamides A−F (Figure 3), Scheme 4. Precursor Incorporation Studies with M. aurantiaca. thesefeedingstudiesshowedsignificantincorporationof[13C]- 2 premalbrancheamide into malbrancheamide B (5.5% incorpo- ration), but surprisingly, [13C ]-keto-premalbrancheamide did 2 not incorporate. The latter result suggests that the timing for the reduction of the tryptophan-derived amide carbonyl residue must occur prior to the [4+2] cycloaddition; thus the biosynthetic formation of premalbrancheamide most likely arises from the proposed intermediate 4b. Future genetic and biochemical analysis of the malbrancheamide biosynthetic Figure 3. Structures of the brevianamides and related metabolites. pathway will undoubtedly resolve the mechanism of mono- k■etopiperizine assembly by M. aurantiaca.1 fromPenicilliumbrevicompactum.3Ofthesesixmetabolites,four compounds were found to contain the unique bicyclo[2.2.2]- CHRYSOGENAMIDE diazaoctane core. Additional research revealed that breviana- midesAandBarediastereoisomers,whilebrevianamidesCand In 2008, Zhu and co-workers were interested in identifying Dareartifactsofisolationduetolightirradiation.3cStructurally, newneuroprotectivecompoundsfromendophyticfungionthe the brevianamides were found to display the anti-configuration parasitic plant Cistanche deserticola collected in northwest mainland China (Table 3).9 From the roots of C. deserticola, aboutthebicycliccore,aswellasthespiro-indoxylmoiety,and an unsubstituted indole ring. Furthermore, the brevianamides threeactivestrainswerescreenedforneuroprotectiveeffectson are a class of natural products that display modest biological SH-SY5Y cells, and the fungal culture Penicillium chrysogenum activities,inwhichbrevianamidesAandDhavebeenshownto No.005demonstratedsignificantactivity.FromP.chrysogenum, possess antifeedant and insecticidal effects.25 the novel metabolite chrysogenamide A was isolated. From a taxonomic perspective, even though the original culture was As shown in Table 4, the brevianamides have been isolated not available for examination, other secondary metabolites predominately from two Penicillium species. The two main characteristic of P. chrysogenum were also isolated,9 supporting producers of brevianamide A are P. brevicompactum3,22,23 and the identity.22−24 P. viridicatum,3e,22,23 of which both are consistent producers of From a structural point of view, this novel metabolite is brevianamide A.26 The isolate of P. ochraceum reported to closely related to the marcfortines (discussed below) in that produce brevianamide A3d was determined to be a brown- chrysogenamide A was found to contain a bicyclo[2.2.2]- spored mutant of P. viridicatum.26 Deoxybrevianamide E is diazaoctane ring system, a spiro-oxindole moiety, and a producedbyP.italicum,27d,eP.ulaiense,22andafungusidentified pipecolic acid unit with C-17 methylation. Additionally, asAspergillusustusNRRL5856.27a−cThelatterisolatehasbeen chrysogenamide A displays the rare anti-configuration about the basis for the description of a new species, Aspergillus the bridging bicycle and an isoprene unit at the C-7 indole pseudoustus;28however,A.pseudoustusistheonlyspeciesknown position,asopposedtothemorecommonlyobserveddioxepin to produce austamide (discussed below). The first biosynthetic Table 3. Fungal Origin and Bioactivity of Chrysogenamide A 816 dx.doi.org/10.1021/np200954v|J.Nat.Prod.2012,75,812−833 Journal of Natural Products Review Table 4. Fungal Origin of the Brevianamides system. Thus, it was proposed that deoxybrevianamide E is first convertedto3R-hydroxyindolenine(6)viaanR-selectiveindole compound fungalspecies bioactivity reference oxidase,whichcouldthenproceedalongoneofthreepathways. brevianamideA P.brevicompactum, antifeedant 3a−c,e, Following an irreversible nucleophilic addition, 6 could be P.viridicatum, insecticidal d,25 P.ochraceuma readily converted to brevianamide E, or 6 could undergo a brevianamideB P.brevicompactum 3a−c pinacol-typerearrangementtoindoxyl7.Asecondoxidation− brevianamideC P.brevicompactum 3a−c enolizationsequencewouldthenyieldthechiralandoptically brevianamideD P.brevicompactum insecticidal 3a−c,25 pure azadiene (3), followed by an IMDA reaction to directly brevianamideFb A.versicolor, antibacterial 6f,3c,30 give brevianamides A and B. It should be noted that efforts to P.brevicompactum substantiatethisalternativebiosyntheticpathwayremainelusive brevianamideE P.brevicompactum 3a−c duetocomplicationsregardingthesynthesisof7.Despiteexten- deoxybrevianamideE Aspergillussp.MF297-2,c 6a,22, sive synthetic efforts, 7 appears to be unstable and spontane- A.ustus,dP.ulaiense, 27 ously suffers a retro-Michael reaction to give the dehydroalanine P.italicum piperazinedione and the reverse-prenylated indoxyl. aMisidentified fungal culture; correct identification = Penicillium Alternatively, reordering these steps would involve the viridicatum. bWidely distributed biosynthetic precursor; thus only relevantfungaloriginsarelisted.cUndergoingreidentification(possibly 3R-hydroxyindolenine (6) undergoing two-electron oxidation Aspergillus sclerotiorum). dReclassified asAspergillus pseudoustus. and enolization to the corresponding azadiene followed by intramolecularDiels−Aldercycloadditionandfinalpinacol-type precursor is the common dioxopiperazine brevianamide F rearrangement of the Diels−Alder cycloadducts, each of which (cyclo-L-Trp-L-Pro).Thisalkaloidhasbeenshowntoserveasthe ■was constituted by a 3R-hydroxyindolenine. precursor for several related secondary metabolites, those MARCFORTINES lacking the bridging bicycle, such as the fumitremorgins and spirotryprostatins in Aspergillus fumigatus.29 In 1980, Polonsky and co-workers reported the isolation of Following the isolation of these unique natural products in threenewalkaloidsfromPenicilliumroqueforti(laterreclassified 1969, which were the first metabolites to be isolated to display as P. paneum), an essential fungus used in the production of theunusualbicyclo[2.2.2]diazaoctaneringsystem,Birchandco- many varieties of blue cheese that contain mold.8a,b From the workerscarriedoutseveralradiolabeledprecursorincorporation strainB26ofP.paneum,marcfortinesA,B,andCwereisolated studies in order to elucidate early stages of the biosynthetic (Figure 4). From a structural point of view, these metabolites pathway of the brevianamides.3a−c,31 Birch demonstrated that contain the bicyclo[2.2.2] ring system with the syn-config- the brevianamides are derived biogenetically from tryptophan, urationandamonoketopiperazinering.Structurallyresembling proline, and mevalonic acid and later showed that radiolabeled chrysogenamide A, the marcfortines contain a spiro-oxindole cyclo-L-Trp-L-Pro (brevianamide F) is also a precursor to moiety and an unsubstituted pipecolic acid unit. Furthermore, brevianamide A in cultures of P. brevicompactum. On the basis all three marcfortine natural products display substitution on oftheseresults,BirchproposedthatbrevianamideFarisesfrom the indole ring at the C-6 and C-7 positions; marcfortines A the condensation of tryptophan and proline, which is followed andBbothcontainadioxepinring,whereasmacfortineChasa by C-2 reverse prenylation to afford deoxybrevianamide E. pyran moiety. Oxidation and cyclization of deoxybrevianamide E would give As shown in Table 5, the marcfortines were originally rise to brevianamides A and B (Scheme 5). isolatedfromastrainidentifiedasP.roqueforti;8a,bhowever,this Williams later demonstrated through tracer incorporation species was subsequently subdivided into three distinct species, studies with P. brevicompactum that radiolabeled deoxybrevia- P.roqueforti,P.carneum,andP.paneum,33anditwasdetermined namide E incorporates into brevianamides A, B, and E in that only the latter can produce marcfortines.8d,e,22,23 Addition- significant radiochemical yields.32 At the same time, Williams ally, Aspergillus carneus has been reported to produce showed that neither tritium-labeled brevianamide E nor the marcfortine A;4c however, the isolate producing marcfortine A proposed racemic, 13C-labeled cycloadduct 5 incorporates into and acyl aszonalenin differed from the culture ex type of brevianamide A or B when provided to P. brevicompactum in A. carneus, which produced citrinin. Therefore, the identity of isotopically labeled precursor incorporation studies (Scheme 6). the marcfortine-producing Aspergillus is questionable. Theseresultsledtothecurrentlyproposedbiosyntheticpathway The biosynthesis of marcfortine A has been investigated by of brevianamides A and B, as shown in Scheme 6. Since Kuoetal.,and,asshowninScheme7,thismetaboliteisderived cycloadduct 5 does not incorporate into the brevianamides, it from L-tryptophan (oxindole moiety), L-methionine (via SAM was suggested that stereoselective indole oxidation must occur methylationofthemonoketopiperazineN),L-lysine(pipecolate prior to the formation of the bicyclo[2.2.2]diazaoctane ring residue), and acetate (isoprene units).34 On the basis of these Scheme 5. Birch’s Proposed Biosynthesis of the Brevianamides 817 dx.doi.org/10.1021/np200954v|J.Nat.Prod.2012,75,812−833 Journal of Natural Products Review Scheme 6. Alternative Biosynthetic Pathway for the Brevianamides Scheme 7. Biosynthetic Derivatives of Marcfortine A14 Scheme 8. Two Biogenetic Routes from L-Lysine to Pipecolic Acid34b Figure 4. Themarcfortine family ofnatural products. Table 5. Fungal Origin of the Marcfortines compound fungalspecies bioactivity references marcfortineA A.carneus,P.paneum, anthelmintic 8c−e,a,b,f P.roquefortia marcfortineB P.paneum,P.roquefortia 8d,e,a,b marcfortineC P.paneum,P.roquefortia 8d,e,a,b metabolizes L-lysine to the pipecolic acid unit, Kuo and co- aReclassified asPenicillium paneum. workers carried out separate feeding studies with [α-15N]- and [ε-15N]-L-lysine. NMR and MS analysis revealed that the results, it is clear that the isoprene residues originate from [α-15N]-L-lysinewasincorporatedattheα,β,andγnitrogenof mevalonic acid; however, there are two possible biosynthetic marcfortine A, with a rate of 1.8%, 13%, and 9%, respectively. routes for the formation of pipecolic acid from L-lysine, as Contrary to this result, [ε-15N]-L-lysine showed an incorpo- shown in Scheme 8.34b To determine which pathway ration rate of 54%, 2.7%, and 3.9% respectively, for the three 818 dx.doi.org/10.1021/np200954v|J.Nat.Prod.2012,75,812−833 Journal of Natural Products Review nitrogens, thus leading to the conclusion that the [ε-15N]-L- canescens, and P. cluniae, which are all soil fungi and the main lysine gave a more specific and higher incorporation at the producers of paraherquamides (Table 6). pipecolate nitrogen. On the basis of these data, pathway A is Structurally, all of the paraherquamides contain the the preferred method of L-lysine metabolism to the pipecolic bicyclo[2.2.2]diazaoctane core with the syn-configuration; acid moiety.34b however, the paraherquamide family displays a plethora of ■ skeletal diversity. For example, the paraherquamides exhibit PARAHERQUAMIDES varying substitution and oxygenation on not only the proline ring but also the spiro-oxindole moiety, in that several of the One of the largest groups of metabolites containing the paraherquamidescontainanunusualdioxepinring,whileothers bicyclo[2.2.2]diazaoctane ring system is the paraherquamides, contain a pyran moiety. Within this family of secondary which were first isolated from Penicillium paraherquei,4a a metabolites, VM55599 and pre-paraherquamide are the only synonym of P. brasilianum,35 and later from an isolate ATCC two compounds that do not contain either a spiro-oxindole 20841,originallyidentifiedasP.charlesii.4hHowever,P.charlesii functionality or an oxygenated indole ring system. was stated incorrectly36 to be a synonym of P. fellutanum by The paraherquamides have attracted considerable interest Pitt,37 andATCC 20841 has therefore been cited asbelonging due to their potent anthelmintic activity. Parasitic nematodes tooneofthesespeciesinlaterpublications.Consequently,this causeseverehealthproblemsinhumansanddomesticanimals, isolate and another similar isolate producing paraherquamides and the severity of this problem is increasing due to the (IMI 332995)4e represent a new species closely related to development of drug-resistant strains of parasites.38 Initial P. canescens and will be called hereafter P. cf. canescens. Other anthelmintic activity was detected in Trichostrongylus colubri- producers of paraherquamides include P. cluniae4d and formis,39 and subsequent investigations showed that para- Aspergillus aculeatinus.4j herquamide A is effective against strains of parasites that are Paraherquamide A (Figure 5) was the first member of this resistant to broad-spectrum anthelmintics.40 However, the family to be isolated by Yamazaki et al. from P. paraherquei toxicity of paraherquamide A was determined to be too great (=Penicilliumbrasilianum).4aAdecadelater,paraherquamideA for use as a broad-spectrum anthelmintic.41 To decrease the was isolated from a fungus identified as P. charlesii (= P. toxicity, but still maintain potency, several paraherquamide fellutanumsensu Pitt37)along withsix structurally relatednovel derivatives have been synthesized and tested for anthelmintic analogues, paraherquamides B−G.4b,c The original isolate activity.38 Of these derivatives, 2-deoxyparaherquamide A (ATCC20841)andanewisolate(IMI332995)bothrepresent (Figure6),laternamedderquantel(Pfizer),displayedexcellent a new species, provisionally called P. cf. canescens. In the activity in models of Hemonchus contortus, T. colubriformis, and followingyears,theparaherquamidefamilyofprenylatedindole Ostertagia ostertagi, while maintaining a safe level of toxicity. alkaloids continued to expand with the isolation of para- Manufacturing of 2-deoxyparaherquamide relies on a semi- herquamides H and I and several related compounds being synthetic procedure wherein paraherquamide is isolated from reported, including VM55595, VM55596, VM55597, large-scale fermentation of P. simplicissimum, purified, and VM55599,SB200437,andSB203105.4Morerecently,Sherman, chemically converted to the 2-deoxyparaherquamide ana- Williams, and co-workers reported the occurrence of pre- logue.38 This new spiroindole was released in July 2010 as a paraherquamideinculturesoftheparaherquamideA-producing combination treatment with abamectin and is currently P. cf. canescens, as well as in the asperparaline A-producing marketed under the brand name Startect for use as an fungus Aspergillus japonicus (later identified as A. aculeatinus).4j anthelmintic in sheep.42 Furthermore,itwasdeterminedthatparaherquamidesAandB Elucidating thebiosynthesisofparaherquamideAhasbeenan are also produced by A. aculeatinus. P. brasilianum, P. cf. areaofintenseresearchforseveralyears,largelybyWilliamsetal. Figure 5. Structures ofthe paraherquamides and relatedcompounds. 819 dx.doi.org/10.1021/np200954v|J.Nat.Prod.2012,75,812−833 Journal of Natural Products Review Table 6. Fungal Origin of the Paraherquamides compound fungalspecies bioactivity references paraherquamideA P.charlesii,aP.cluniae,P.brasilianum(=P.paraherquei),Penicilliumsp.IMI332995,a anthelmintic 4b−d,a,e,g, Penicilliumspecies antinematodal 38−42 paraherquamideB P.charlesii,aP.cluniae antinematodal 4b−d paraherquamideC P.charlesiia antinematodal 4b,c,h paraherquamideD P.charlesiia antinematodal 4b,c,h paraherquamideE Aspergillussp.IMI337664,A.aculeatus,P.charlesii,aP.cluniae, antinematodal 4f,b,c,h,k,d,e,g Penicilliumsp.IMI332995,aPenicilliumspecies paraherquamideF P.charlesii,aPenicilliumsp.IMI332995,Penicilliumspecies antinematodal 4b,c,h,e,g paraherquamideG P.charlesii,aPenicilliumsp.IMI332995,aPenicilliumspecies antinematodal 4b,c,h,e,g paraherquamideH P.cluniae 4d paraherquamideI P.cluniae 4d VM55595 Penicilliumsp.IMI332995a 4e VM55596 P.cluniae insecticidal 4d VM55597 P.cluniae,Penicilliumsp.IMI332995a insecticidal 4d,e VM55599 P.paneum,Penicilliumsp.IMI332995,aA.japonicus,bP.charlesiia 4i,k,e,j SB200437 Aspergillussp.IMI337664c anthelmintic 4f SB203105 Aspergillussp.IMI337664c anthelmintic 4f pre-paraherquamide A.japonicus,bP.charlesiia 4j aReclassified asa newspecies relatedto Penicillium canescens.bReclassified as Aspergillus aculeatinus.cReclassified as Aspergillus fijiensis. that the structurally similar paraherquamides follow a com- parable biosynthetic pathway. To determine which amino acid residues are incorporated into paraherquamide A, feeding experimentswereperformedwithP.cf.canescensusing[1-13C]- L-tryptophan, [methyl-13C]-L-methionine, [1-13C]-L-proline, and [1-13C]-L-isoleucine (Scheme 9).43 Through 13CNMR spectroscopy and electrospray mass spectrometry, the position Figure 6. Structure of 2-deoxyparaherquamide A (derquantel). and percentage of 13C incorporation were analyzed, and as expected, [1-13C]-L-tryptophan incorporated at the C-12 On the basis of the results obtained from the precursor incor- (paraherquamide numbering) position of the oxindole ring poration studies of the brevianamides, this group postulated with 2.5% incorporation. Moreover, similar to results obtained Scheme 9. (A) 13C-Labeled Amino Acid Incorporation into Paraherquamide A in Penicillium cf. canescens; (B) Proposed Biosynthetic Pathway for the Conversion of L-Isoleucine to 3(S)-Methyl-L-proline43 820 dx.doi.org/10.1021/np200954v|J.Nat.Prod.2012,75,812−833