Nikolai A Löhr, Malik Rakhmanov, Jacob M Wurlitzer, Gerald Lackner, Markus Gressler, Dirk Hoffmeister
{"title":"担子菌非还原性多酮合成酶独立于SAT结构域起作用。","authors":"Nikolai A Löhr, Malik Rakhmanov, Jacob M Wurlitzer, Gerald Lackner, Markus Gressler, Dirk Hoffmeister","doi":"10.1186/s40694-023-00164-z","DOIUrl":null,"url":null,"abstract":"<p><strong>Background: </strong>Non-reducing polyketide synthases (NR-PKSs) account for a major share of natural product diversity produced by both Asco- and Basidiomycota. The present evolutionary diversification into eleven clades further underscores the relevance of these multi-domain enzymes. Following current knowledge, NR-PKSs initiate polyketide assembly by an N-terminal starter unit:acyl transferase (SAT) domain that catalyzes the transfer of an acetyl starter from the acetyl-CoA thioester onto the acyl carrier protein (ACP).</p><p><strong>Results: </strong>A comprehensive phylogenetic analysis of NR-PKSs established a twelfth clade from which three representatives, enzymes CrPKS1-3 of the webcap mushroom Cortinarius rufoolivaceus, were biochemically characterized. These basidiomycete synthases lack a SAT domain yet are fully functional hepta- and octaketide synthases in vivo. Three members of the other clade of basidiomycete NR-PKSs (clade VIII) were produced as SAT-domainless versions and analyzed in vivo and in vitro. They retained full activity, thus corroborating the notion that the SAT domain is dispensable for many basidiomycete NR-PKSs. For comparison, the ascomycete octaketide synthase atrochrysone carboxylic acid synthase (ACAS) was produced as a SAT-domainless enzyme as well, but turned out completely inactive. However, a literature survey revealed that some NR-PKSs of ascomycetes carry mutations within the catalytic motif of the SAT domain. In these cases, the role of the domain and the origin of the formal acetate unit remains open.</p><p><strong>Conclusions: </strong>The role of SAT domains differs between asco- and basidiomycete NR-PKSs. For the latter, it is not part of the minimal set of NR-PKS domains and not required for function. This knowledge may help engineer compact NR-PKSs for more resource-efficient routes. From the genomic standpoint, seemingly incomplete or corrupted genes encoding SAT-domainless NR-PKSs should not automatically be dismissed as non-functional pseudogenes, but considered during genome analysis to decipher the potential arsenal of natural products of a given fungus.</p>","PeriodicalId":52292,"journal":{"name":"Fungal Biology and Biotechnology","volume":"10 1","pages":"17"},"PeriodicalIF":0.0000,"publicationDate":"2023-08-04","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10401856/pdf/","citationCount":"0","resultStr":"{\"title\":\"Basidiomycete non-reducing polyketide synthases function independently of SAT domains.\",\"authors\":\"Nikolai A Löhr, Malik Rakhmanov, Jacob M Wurlitzer, Gerald Lackner, Markus Gressler, Dirk Hoffmeister\",\"doi\":\"10.1186/s40694-023-00164-z\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><strong>Background: </strong>Non-reducing polyketide synthases (NR-PKSs) account for a major share of natural product diversity produced by both Asco- and Basidiomycota. The present evolutionary diversification into eleven clades further underscores the relevance of these multi-domain enzymes. Following current knowledge, NR-PKSs initiate polyketide assembly by an N-terminal starter unit:acyl transferase (SAT) domain that catalyzes the transfer of an acetyl starter from the acetyl-CoA thioester onto the acyl carrier protein (ACP).</p><p><strong>Results: </strong>A comprehensive phylogenetic analysis of NR-PKSs established a twelfth clade from which three representatives, enzymes CrPKS1-3 of the webcap mushroom Cortinarius rufoolivaceus, were biochemically characterized. These basidiomycete synthases lack a SAT domain yet are fully functional hepta- and octaketide synthases in vivo. Three members of the other clade of basidiomycete NR-PKSs (clade VIII) were produced as SAT-domainless versions and analyzed in vivo and in vitro. They retained full activity, thus corroborating the notion that the SAT domain is dispensable for many basidiomycete NR-PKSs. For comparison, the ascomycete octaketide synthase atrochrysone carboxylic acid synthase (ACAS) was produced as a SAT-domainless enzyme as well, but turned out completely inactive. However, a literature survey revealed that some NR-PKSs of ascomycetes carry mutations within the catalytic motif of the SAT domain. In these cases, the role of the domain and the origin of the formal acetate unit remains open.</p><p><strong>Conclusions: </strong>The role of SAT domains differs between asco- and basidiomycete NR-PKSs. For the latter, it is not part of the minimal set of NR-PKS domains and not required for function. This knowledge may help engineer compact NR-PKSs for more resource-efficient routes. 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引用次数: 0
摘要
背景:非还原性聚酮合成酶(NR-PKSs)在Asco-和担子菌科产生的天然产物多样性中占主要份额。目前进化多样化为11支进一步强调了这些多结构域酶的相关性。根据目前的知识,NR-PKSs通过n端起始单元:酰基转移酶(SAT)结构域启动聚酮组装,催化乙酰基起始物从乙酰辅酶a硫酯转移到酰基载体蛋白(ACP)上。结果:通过对NR-PKSs的综合系统发育分析,建立了第12枝,并从该枝中鉴定了3个代表性的CrPKS1-3酶。这些担子菌合成酶缺乏SAT结构域,但在体内是功能齐全的七肽和八肽合成酶。对担子菌nr - pks的另一个分支(分支VIII)的三个成员进行了无sat结构域版本的制备,并在体内和体外进行了分析。它们保留了充分的活性,从而证实了SAT结构域对于许多担子菌nr - pks是必不可少的。相比之下,子囊菌八肽合成酶atrochrysone羧酸合成酶(ACAS)也作为无sat结构域的酶被生产出来,但被证明是完全无活性的。然而,一项文献调查显示,子囊菌的一些NR-PKSs在SAT结构域的催化基序中携带突变。在这些情况下,结构域的作用和正式醋酸酯单元的起源仍然是开放的。结论:在asco-和担子菌NR-PKSs中,SAT结构域的作用是不同的。对于后者,它不是NR-PKS结构域最小集的一部分,也不是功能所必需的。这一知识可能有助于设计更紧凑的NR-PKSs,以获得更有效的资源。从基因组的角度来看,编码sat -domain - less nr - pks的看似不完整或损坏的基因不应被自动视为非功能假基因,而应在基因组分析中考虑,以破译给定真菌的潜在天然产物库。
Basidiomycete non-reducing polyketide synthases function independently of SAT domains.
Background: Non-reducing polyketide synthases (NR-PKSs) account for a major share of natural product diversity produced by both Asco- and Basidiomycota. The present evolutionary diversification into eleven clades further underscores the relevance of these multi-domain enzymes. Following current knowledge, NR-PKSs initiate polyketide assembly by an N-terminal starter unit:acyl transferase (SAT) domain that catalyzes the transfer of an acetyl starter from the acetyl-CoA thioester onto the acyl carrier protein (ACP).
Results: A comprehensive phylogenetic analysis of NR-PKSs established a twelfth clade from which three representatives, enzymes CrPKS1-3 of the webcap mushroom Cortinarius rufoolivaceus, were biochemically characterized. These basidiomycete synthases lack a SAT domain yet are fully functional hepta- and octaketide synthases in vivo. Three members of the other clade of basidiomycete NR-PKSs (clade VIII) were produced as SAT-domainless versions and analyzed in vivo and in vitro. They retained full activity, thus corroborating the notion that the SAT domain is dispensable for many basidiomycete NR-PKSs. For comparison, the ascomycete octaketide synthase atrochrysone carboxylic acid synthase (ACAS) was produced as a SAT-domainless enzyme as well, but turned out completely inactive. However, a literature survey revealed that some NR-PKSs of ascomycetes carry mutations within the catalytic motif of the SAT domain. In these cases, the role of the domain and the origin of the formal acetate unit remains open.
Conclusions: The role of SAT domains differs between asco- and basidiomycete NR-PKSs. For the latter, it is not part of the minimal set of NR-PKS domains and not required for function. This knowledge may help engineer compact NR-PKSs for more resource-efficient routes. From the genomic standpoint, seemingly incomplete or corrupted genes encoding SAT-domainless NR-PKSs should not automatically be dismissed as non-functional pseudogenes, but considered during genome analysis to decipher the potential arsenal of natural products of a given fungus.