Total syntheses of surugamides and thioamycolamides toward understanding their biosynthesis

1. Apostolopoulos V, Bojarska J, Chai TT, Elnagdy S, Kaczmarek

K, Matsoukas J, New R, Parang K, Lopez OP, Parhiz H, Perera

CO, Pickholz M, Remko M, Saviano M, Skwarczynski M, Tang

Y, Wolf WM, Yoshiya T, Zabrocki J, Zielenkiewicz P, AlKhazindar M, Barriga V, Kelaidonis K, Sarasia EM, Toth I (2021)

A global review on short peptides: frontiers and perspectives.

Molecules 26:430

2. Dang T, Sussmuth RD (2017) Bioactive peptide natural

products as lead structures for medicinal use. Acc Chem Res

50:1566–1576

3. Hemmerling F, Piel J (2022) Strategies to access biosynthetic novelty in bacterial genomes for drug discovery. Nat Rev Drug Discov

5:359–378

4. Nicolaou KC, Snyder SA (2005) Chasing molecules that were

never there: misassigned natural products and the role of chemical

synthesis in modern structure elucidation. Angew Chem Int Ed

44:1012–1044

5. Takada K, Ninomiya A, Naruse M, Sun Y, Miyazaki M, Nogi Y,

Okada S, Matsunaga S (2013) Surugamides A–E, cyclic octapeptides with four d-Amino acid residues, from a marine Streptomyces sp.: LC–MS-aided inspection of partial hydrolysates for the

distinction of d- and l-amino acid residues in the sequence. J Org

Chem 78:6746–6750

6. Ninomiya A, Katsuyama Y, Kuranaga T, Miyazaki M, Nogi Y,

Okada S, Wakimoto T, Ohnishi Y, Matsunaga S, Takada K (2016)

Biosynthetic gene cluster for surugamide A encompasses an unrelated decapeptide, surugamide F. ChemBioChem 17:1709–1712

7. Du L, Lou L (2010) PKS and NRPS release mechanisms. Nat Prod

Rep 27:255–278

8. Kuranaga T, Matsuda K, Sano A, Kobayashi M, Ninomiya A,

Takada K, Matsunaga S, Wakimoto T (2018) Total synthesis of

the non-ribosomal peptide surugamide B and identification of a

new offloading cyclase family. Angew Chem Int Ed 57:9447–9451

9. White CJ, Yudin AK (2011) Contemporary strategies for peptide

macrocyclization. Nat Chem 3:509–524

10. Albericio F, El-Faham A (2018) Choosing the right coupling

reagent for peptides: a 25-year journey. Org Process Res Dev

22:760–772

11. Kuranaga T, Enomoto A, Tan H, Fujita K, Wakimoto T (2017)

Total synthesis of theonellapeptolide Id. Org Lett 19:1366–1369

12. Yan H, Chen F-E (2022) Recent progress in solid-phase total

synthesis of naturally occurring small peptides. Adv Synth Catal

364:1–29

13. Subirós-Funosas R, Prohens R, Barbas R, El-Faham A, Albericio

F (2009) Oxyma: an efficient additive for peptide synthesis to

replace the benzotriazole-based HOBt and HOAt with a lower

risk of explosion. Chem Eur J 15:9394–9403

14. Coste J, Le-Nguyen D, Castro B (1990) P

­ yBOP®: a new peptide

coupling reagent devoid of toxic by-product. Tetrahedron Lett

31:205–208

15. Carpino LA (1993) 1-Hydroxy-7-azabenzotriazole. An efficient

peptide coupling additive. J Am Chem Soc 115:4397–4398

16. You YO, Khosla C, Cane DE (2013) Stereochemistry of reductions catalyzed by methyl-epimerizing ketoreductase domains of

polyketide synthases. J Am Chem Soc 135:7406–7409

13

10

17. Backes BJ, Ellman JA (1996) An alkanesulfonamide “safetycatch” linker for solid-phase synthesis. J Org Chem 64:2322–2330

18. Pratt RF (2008) Substrate specificity of bacterial DD-peptidases

(penicillin-binding proteins). Cell Mol Life Sci 65:2138–2155

19. Matsuda K, Kobayashi M, Kuranaga T, Takada K, Matsunaga S,

Ikeda H, Wakimoto T (2019) SurE is a trans-acting thioesterase

cyclizing two distinct non-ribosomal peptides. Org Biomol Chem

17:1058–1061

20. Matsuda K, Zhai R, Mori T, Kobayashi M, Sano A, Abe I, Wakimoto T (2020) Heterochiral coupling in non-ribosomal peptide

macrolactamization. Nat Catal 3:507–515

21. Magarvey NA, Haltli B, He M, Greenstein M, Hucul JA (2006)

Biosynthetic pathway for mannopeptimycins, lipoglycopeptide

antibiotics active against drug-resistant gram-positive pathogens.

Antimicrob Agents Chemother 50:2167–2177

22. Li Q, Song Y, Qin X, Zhang X, Sun A, Ju J (2015) Identification

of the biosynthetic gene cluster for the anti-infective desotamides

and production of a new analogue in a heterologous host. J Nat

Prod 78:944–948

23. Son S, Hong YS, Jang M, Heo KT, Lee B, Jang JP, Kim JW,

Ryoo IJ, Kim WG, Ko SK, Kim BY, Jang JH, Ahn JS (2017)

Genomics-driven discovery of chlorinated cyclic hexapeptides

ulleungmycins A and B from a Streptomyces species. J Nat Prod

80:3025–3031

24. Mudalungu CM, Von Törne WJ, Voigt K, Rückert C, Schmitz S,

Sekurova ON, Zotchev SB, Süssmuth RD (2019) Noursamycins,

chlorinated cyclohexapeptides identified from molecular networking of Streptomyces noursei NTR-SR4. J Nat Prod 82:1478–1486

25. Zhou X, Huang H, Li J, Song Y, Jiang R, Liu J, Zhang S, Hua Y,

Ju J (2014) New anti-infective cycloheptadepsipeptide congeners

and absolute stereochemistry from the deep sea-derived Streptomyces drozdowiczii SCSIO 10141. Tetrahedron 70:7795–7801

26. Li Q, Qin X, Liu J, Gui C, Wang B, Li J, Ju J (2016) Deciphering the biosynthetic origin of l-allo-isoleucine. J Am Chem Soc

138:408–415

27. Matsuda K, Kuranaga T, Sano A, Ninomiya A, Takada K, Wakimoto T (2019) The revised structure of the cyclic octapeptide

surugamide A. Chem Pharm Bull 67:476–480

28. Nimura N, Toyama A, Kinoshita T (1984) Optical resolution of

amino acid enantiomers by high-performance liquid chromatography. J Chromatogr A 316:547–552

29. Hess S, Gustafson KR, Milanowski DJ, Alvira E, Lipton MA,

Pannell LK (2004) Chirality determination of unusual amino

acids using precolumn derivatization and liquid chromatography–electrospray ionization mass spectrometry. J Chromatogr A

1035:211–219

30. Dunbar KL, Scharf DH, Litomska A, Hertweck C (2017) Enzymatic carbon–sulfur bond formation in natural product biosynthesis. Chem Rev 117:5521–5577

31. Wang N, Saidhareddy P, Jiang X (2020) Construction of sulfurcontaining moieties in the total synthesis of natural products. Nat

Prod Rep 37:246–275

32. Schwalen CJ, Hudson GA, Kille B, Mitchell DA (2018) Bioinformatic expansion and discovery of thiopeptide antibiotics. J Am

Chem Soc 140:9494–9501

33. Pan C, Kuranaga T, Liu C, Lu S, Shinzato N, Kakeya H (2020)

Thioamycolamides A–E, sulfur-containing cycliclipopeptides

produced by the rare actinomycete Amycolatopsis sp. Org Lett

22:3014–3017

34. Liu H, Liu Y, Wang Z, Xing X, Maguire AR, Luesch H, Ye T

(2013) Total synthesis and biological evaluation of grassypeptolide A. Chem Eur J 19:6774–6784

35. Wipf P, Fritch PC (1996) Total synthesis and assignment of configuration of lissoclinamide 7. J Am Chem Soc 118:12358–12367

36. Yamashita T, Kuranaga T, Inoue M (2015) Solid-phase total

synthesis of bogorol A: stereocontrolled construction of

13

Journal of Natural Medicines (2023) 77:1–11

37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52. 53. 54. 55. 56. 57. thermodynamically unfavored (E)-2-amino-2-butenamide. Org

Lett 17:2170–2173

Pan C, Kuranaga T, Kakeya H (2020) Total synthesis of thioamycolamide A via a biomimetic route. Org Biomol Chem

18:8366–8370

Boden CDJ, Pattenden G, Ye T (1995) The synthesis of optically

active thiazoline and thiazole derived peptides from N-protected

α-amino acids. Synlett 1995:417–419

Konigsberg W, Hill RH, Craig LC (1961) The oxidation and acid

isomerization of bacitracin A. J Org Chem 26:3867–3871

Hirotsu Y, Shiba T, Kaneko T (1970) Synthetic studies on bacitracin. VII. Isomerization of amino acid components of thiazoline

peptides. Bull Chem Soc Jpn 43:1870–1873

Yonetani K, Hirotsu Y, Shiba T (1975) Racemization of amino

acid residues fused in thiazoline, oxazoline, and imidazoline

rings. Bull Chem Soc Jpn 48:3302–3305

Wipf P, Fritch PC (1994) Synthesis of peptide thiazolines from

β-hydroxythioamides. An investigation of racemization in

cyclodehydration protocols. Tetrahedron Lett 35:5397–5400

Thomsen I, Clausen K, Scheibye S, Lawesson S-O (1984) Thiation with 2,4-bis(4-methoxyphenyl)-1,3,2,4-dithiadiphosphetane 2,4-disulfide: N-methylthiopyrrolidone. Org Synth 62:158

Ozturk T, Ertas E, Mert O (2007) Use of Lawesson’s reagent in

organic syntheses. Chem Rev 107:5210–5278

Sakaitani M, Ohfune Y (1990) Syntheses and reactions of silyl

carbamates. 1. Chemoselective transformation of amino protecting groups via tert-butyldimethylsilyl carbamates. J Org Chem

55:870–876

Burkhart JL, Kazmaier U (2011) A straightforward approach to

protected (S)-dolaphenine (Doe), the unusual amino acid component of dolastatin 10. Synthesis 2011:4033–4036

Yamashita T, Matoba H, Kuranaga T, Inoue M (2014) Total

syntheses of nobilamides B and D: application of traceless

Staudinger ligation. Tetrahedron 70:7746–7752

Nicolaou KC, Estrada AA, Zak M, Lee SH, Safina BS (2005)

A mild and selective method for the hydrolysis of esters with

trimethyltin hydroxide. Angew Chem Int Ed 44:1378–1382

Burns JA, Butler JC, Moran J, Whitesides GM (1991) Selective

reduction of disulfides by tris(2-carboxyethyl)phosphine. J Org

Chem 56:2648–2650

Zou B, Long K, Ma D (2005) Total synthesis and cytotoxicity studies of a cyclic depsipeptide with proposed structure of

palau’amide. Org Lett 7:4237–4240

Sugiyama H, Watanabe A, Teruya T, Suenaga K (2009) Synthesis of palau’amide and its diastereomers: confirmation of its

stereostructure. Tetrahedron Lett 50:7343–7345

Ma B, Litvinov DN, He L, Banerjee B, Castle SL (2009) Total

synthesis of celogentin C. Angew Chem Int Ed 48:6104–6107

Ma B, Banerjee B, Litvinov DN, He L, Castle SL (2010) Total

synthesis of the antimitotic bicyclic peptide celogentin C. J Am

Chem Soc 132:1159–1171

Kuranaga T, Minote M, Morimoto R, Pan C, Ogawa H, Kakeya

H (2020) Highly sensitive labeling reagents for scarce natural

products. ACS Chem Biol 15:2499–2506

Kuranaga T, Sesoko Y, Sakata K, Maeda N, Hayata A, Inoue M

(2013) Total synthesis and complete structural assignment of

yaku’amide A. J Am Chem Soc 135:5467–5474

Kuranaga T, Mutoh H, Sesoko Y, Goto T, Matsunaga S, Inoue

M (2015) Elucidation and total synthesis of the correct structures of tridecapeptides yaku’amides A and B. Synthesis-driven

stereochemical reassignment of the four amino acid residues. J

Am Chem Soc 137:9443–9451

Jiang Y, Matsumoto T, Kuranaga T, Lu S, Wang W, Onaka

H, Kakeya H (2021) Longicatenamides A–D, two diastereomeric pairs of antimicrobials cyclic hexapeptides produced

Journal of Natural Medicines (2023) 77:1–11 by combined-culture of Streptomyces sp. KUSC_F05 and Tsukamurella pulmonis TP-B0596. J Antibiot 74:307–316

58. Pan C, Kuranaga T, Cao X, Suzuki T, Dohmae N, Shinzato N,

Onaka H, Kakeya H (2021) Amycolapeptins A and B, cyclic

nonadepsipeptides produced by combined-culture of Amycolatopsis sp. and Tsukamurella pulmonis TP-B0596. J Org Chem

86:1843–1849

5 9. Kuranaga T, Tamura M, Ikeda H, Terada S, Nakagawa Y,

Kakeya H (2021) Identification and total synthesis of an unstable anticancer macrolide presaccharothriolide Z. Org Lett

23:7106–7111

60. Pan C, Kuranaga T, Kakeya H (2021) Application of the highly

sensitive labeling reagent to the structural confirmation of readily

isomerizable peptides. J Nat Med 75:339–343

11

61. Vagstad AL, Kuranaga T, Püntener S, Pattabiraman V, Bode JW,

Piel J (2019) Introduction of d-amino acids in minimalistic peptide substrates by an S-adenosyl-l-methionine radical epimerase.

Angew Chem Int Ed 58:2246–2250

62. Shirai T, Kuranaga T, Wright JLC, Baden DG, Satake M, Tachibana K (2010) Synthesis of a proposed biosynthetic intermediate

of a marine cyclic ether brevisamide for study on biosynthesis of

marine ladder-frame polyethers. Tetrahedron Lett 51:1394–1396

Publisher's Note Springer Nature remains neutral with regard to

jurisdictional claims in published maps and institutional affiliations.

13

...