Zhenjian Lin

Citrinin Dimers from the Halotolerant Fungus Penicillium citrinum B-57

In order to search for structurally novel and bioactive natural compounds from microorganisms, a halotolerant fungal strain, Penicillium citrinum B-57, which mainly produces citrinin derivatives, was isolated from sediments collected from the Jilantai salt field. From the ethyl acetate extract of P. citrinum B-57, two new citrinin dimers, pennicitrinone C ( 1) and penicitrinol B ( 2), and 11 known related compounds were isolated and identified by spectroscopic and chemical methods. These compounds showed antioxidative activity against DPPH radicals with IC 50 values ranging from 0.8 to 59 microM.

Novel open-chain cytochalsins from the marine-derived fungus Spicaria elegans.

Six novel open-chain cytochalasins (1-6) and one known [12]-cytochalasin (7) have been isolated from the fermentation broth of a marine-derived fungus, Spicaria elegans. Cytochalasins Z10-Z15 (1-6) are the first reported cytochalasins that contain an open chain to date. The structures of these new compounds were elucidated by spectroscopic methods. The cytotoxic effects on P388, A-549, HL-60, and BEL-7402 cell lines of all compounds were evaluated by the MTT method.

A Bacterial Source for Mollusk Pyrone Polyketides

In the oceans, secondary metabolites often protect otherwise poorly defended invertebrates, such as shell-less mollusks, from predation. The origins of these metabolites are largely unknown, but many of them are thought to be made by symbiotic bacteria. In contrast, mollusks with thick shells and toxic venoms are thought to lack these secondary metabolites because of reduced defensive needs. Here, we show that heavily defended cone snails also occasionally contain abundant secondary metabolites, γ-pyrones known as nocapyrones, which are synthesized by symbiotic bacteria. The bacteria, Nocardiopsis alba CR167, are related to widespread actinomycetes that we propose to be casual symbionts of invertebrates on land and in the sea. The natural roles of nocapyrones are unknown, but they are active in neurological assays, revealing that mollusks with external shells are an overlooked source of secondary metabolite diversity.

Pulicatins A−E, Neuroactive Thiazoline Metabolites from Cone Snail-Associated Bacteria

The cone snail Conus pulicarius from the Philippines provides a specific habitat for actinomycetes and other bacteria. A phenotypic screen using primary cultures of mouse dorsal root ganglion neurons revealed that one C. pulicarius associate, Streptomyces sp. CP32, produces a series of natural products that enhance or diminish whole-cell Ca(2+) flux. These compounds include known thiazoline compounds and a series of new derivatives, pulicatins A-E (6-10). Individual compounds were shown to bind to a series of human receptors, with selective binding to the human serotonin 5-HT(2B) receptor. Here, we report the structure elucidation of the new compounds and results of the neurological assays.

Modularity of RiPP Enzymes Enables Designed Synthesis of Decorated Peptides

Macrocyclases and other posttranslational enzymes afford derived peptides with improved properties for pharmaceutical and biotechnological applications. Here, we asked whether multiple posttranslational modifications could be simultaneously controlled and matched to rationally generate new peptide derivatives. We reconstituted the cyanobactin peptide natural products in vitro with up to five different posttranslational enzymes in a single tube. By manipulating the order of addition and identity of enzymes and exploiting their broad-substrate tolerance, we engineered the production of highly unnatural derivatives, including an N-C peptide macrocycle of 22 amino acids in length. In addition to engineering, this work better defines the macrocyclization mechanism, provides the first biochemical demonstration of Ser/Thr posttranslational prenylation, and is the first example of reconstitution of a native, multistep RiPP pathway with multiple enzymes in one pot. Overall, this work demonstrates how the modularity of posttranslational modification enzymes can be used to design and synthesize desirable peptide motifs.

Aestuaramides, a Natural Library of Cyanobactin Cyclic Peptides Resulting from Isoprene-Derived Claisen Rearrangements

We report 12 cyanobactin cyclic peptides, the aestuaramides, from the cultivated cyanobacterium Lyngbya aestuarii. We show that aestuaramides are synthesized enzymatically as reverse O-prenylated tyrosine ethers that subsequently undergo a Claisen rearrangement to produce forward C-prenylated tyrosine. These results reveal that a nonenzymatic Claisen rearrangement dictates isoprene regiochemistry in a natural system. They also reveal one of the mechanisms that organisms use to generate structurally diverse compound libraries starting from simple ribosomal peptide pathways (RiPPs).

Two Related Pyrrolidinedione Synthetase Loci in Fusarium heterosporum ATCC 74349 Produce Divergent Metabolites

Equisetin synthetase (EqiS), from the filamentous fungus Fusarium heterosporum ATCC 74349, was initially assigned on the basis of genetic knockout and expression analysis. Increasing inconsistencies in experimental results led us to question this assignment. Here, we sequenced the F. heterosporum genome, revealing two hybrid polyketide-peptide proteins that were candidates for the equisetin synthetase. The surrounding genes in both clusters had the needed auxiliary genes that might be responsible for producing equisetin. Genetic mutation, biochemical analysis, and recombinant expression in the fungus enabled us to show that the initially assigned EqiS does not produce equisetin but instead produces a related 2,4-pyrrolidinedione, fusaridione A, that was previously unknown. Fusaridione A is methylated in the 3-position of the pyrrolidinedione, which has not otherwise been found in natural products, leading to spontaneous reverse-Dieckmann reactions. A newly described gene cluster, eqx, is responsible for producing equisetin.

Combinatorialization of fungal polyketide synthase-peptide synthetase hybrid proteins.

The programming of the fungal polyketide synthase (PKS) is quite complex, with a simple domain architecture leading to elaborate products. An additional level of complexity has been found within PKS-based pathways where the PKS is fused to a single module nonribosomal peptide synthetase (NRPS) to synthesize polyketides conjugated to amino acids. Here, we sought to understand the communication between these modules that enable correct formation of polyketide-peptide hybrid products. To do so, we fused together the genes that are responsible for forming five highly chemically diverse fungal natural products in a total of 57 different combinations, comprising 34 distinct module swaps. Gene fusions were formed with the idea of testing the connection and compatibility of the PKS and NRPS modules mediated by the acyl carrier protein (ACP), condensation (C) and ketoreductase (KR) domains. The resulting recombinant gene fusions were analyzed in a high-yielding expression platform to avail six new compounds, including the first successful fusion between a PKS and NRPS that make highly divergent products, and four previously reported molecules. Our results show that C domains are highly selective for a subset of substrates. We discovered that within the highly reducing (hr) PKS class, noncognate ACPs of closely related members complement PKS function. We intercepted a pre-Diels-Alder intermediate in lovastatin synthesis for the first time, shedding light on this canonical fungal biochemical reaction. The results of these experiments provide a set of ground rules for the successful engineering of hr-PKS and PKS-NRPS products in fungi.

Nobilamides A–H, Long-Acting Transient Receptor Potential Vanilloid-1 (TRPV1) Antagonists from Mollusk-Associated Bacteria

New compounds nobilamides A-H and related known compounds A-3302-A and A-3302-B were isolated based upon their suppression of capsaicin-induced calcium uptake in a mouse dorsal root ganglion primary cell culture assay. Two of these compounds, nobilamide B and A-3302-A, were shown to be long-acting antagonists of mouse and human TRPV1 channels, abolishing activity for >1 h after removal of drug presumably via a covalent attachment. Other derivatives also inhibited the TRPV1 channel, albeit with low potency, affording a structure-activity profile to support the proposed mechanism of action. While the activities were modest, we propose a new mechanism of action and a new site of binding for these inhibitors that may spur development of related analogues for treatment of pain.

Chrysogenamide A from an endophytic fungus associated with Cistanche deserticola and its neuroprotective effect on SH-SY5Y cells.

Chrysogenamide A (1), a new member of the macfortine group of alkaloids, along with four known compounds (2~5) were identified from Penicillium chrysogenum No. 005, an endophytic fungus associated with Cistanche deserticola Y. C. Ma. The new structure was elucidated on the basis of comprehensive spectral analysis. 1 exhibited a neurocyte protection effect against oxidative stress-induced cell death in SH-SY5Y cells.