Metabolomics and Genomics Enable the Discovery of a New Class of Nonribosomal Peptidic Metallophores from a Marine Micromonospora

Although microbial genomes harbor an abundance of biosynthetic gene clusters, there remain substantial technological gaps that impair the direct correlation of newly discovered gene clusters and their corresponding secondary metabolite products. As an example of one approach designed to minimize or bridge such gaps, we employed hierarchical clustering analysis and principal component analysis (hcapca, whose sole input is MS data) to prioritize 109 marine Micromonospora strains and ultimately identify novel strain WMMB482 as a candidate for in-depth "metabologenomics" analysis following its prioritization. Highlighting the power of current MS-based technologies, not only did hcapca enable the discovery of one new, nonribosomal peptide bearing an incredible diversity of unique functional groups, but metabolomics for WMMB482 unveiled 16 additional congeners via the application of Global Natural Product Social molecular networking (GNPS), herein named ecteinamines A-Q (1-17). The ecteinamines possess an unprecedented skeleton housing a host of uncommon functionalities including a menaquinone pathway-derived 2-naphthoate moiety, 4-methyloxazoline, the first example of a naturally occurring Ψ[CH2NH] "reduced amide", a methylsulfinyl moiety, and a d-cysteinyl residue that appears to derive from a unique noncanonical epimerase domain. Extensive in silico analysis of the ecteinamine (ect) biosynthetic gene cluster and stable isotope-feeding experiments helped illuminate the novel enzymology driving ecteinamine assembly as well the role of cluster collaborations or "duets" in producing such structurally complex agents. Finally, ecteinamines were found to bind nickel, cobalt, zinc, and copper, suggesting a possible biological role as broad-spectrum metallophores.

Discovery of an Unexpected 1,4-Oxazepine-Linked seco-Fluostatin Heterodimer by Inactivation of the Oxidoreductase-Encoding Gene flsP

Fluostatins belong to the atypical angucyclinone aromatic polyketides featuring a distinctive tetracyclic benzo[a]fluorene skeleton. To understand the formation of the heavily oxidized A-ring in fluostatins, a flavin adenine dinucleotide-binding oxidoreductase-encoding gene flsP was inactivated, leading to the production of an unprecedented 1,4-oxazepine-linked seco-fluostatin heterodimer difluostatin I (7) and five new fluostatin-related derivatives, fluostatins T-X (8-12). Their structures were elucidated by mass spectrometry, nuclear magnetic resonance, X-ray diffraction analysis, and biosynthetic considerations. Difluostatin I (7) represents the first example with an A-ring-cleaved 3',4'-seco-fluostatin skeleton. The absolute configuration of fluostatin T (8) was determined by X-ray diffraction analysis. Fluostatin W (11) contains an uncommon isoxazolinone ring. These findings highlight the structural diversity of fluostatins.

C-N-Coupled Metabolites Yield Insights into Dynemicin A Biosynthesis

The biosynthesis of the three structural subclasses of enediyne antitumor antibiotics remains largely unknown beyond a common C16 -hexaene precursor. For the anthraquinone-fused subtype, however, an unexpected iodoanthracene γ-thiolactone was established to be a mid-pathway intermediate to dynemicin A. Having deleted a putative flavin-dependent oxidoreductase from the dynemicin biosynthetic gene cluster, we can now report four metabolites that incorporate the iodoanthracene and reveal the formation of the C-N bond linking the anthraquinone and enediyne halves emblematic of this structural subclass. The coupling of an aryl iodide and an amine is familiar from organometallic chemistry, but has little or no precedent in natural product biosynthesis. These metabolites suggest further that enediyne formation occurs early in the overall biosynthesis, and that even earlier events might convert the C16 -hexaene to a common C15 intermediate that partitions to enediyne and anthraquinone building blocks for the heterodimerization.

Genome Sequence of Micromonospora terminaliae TMS7T, a New Endophytic Actinobacterium Isolated from the Medicinal Plant Terminalia mucronata

Micromonospora terminaliae sp. nov., type strain TMS7^T, is a gram-positive nonmotile aerobic actinobacterium that was recently isolated from a surface-sterilized stem of the medicinal plant Terminalia mucronata. This strain was described as a novel species in the Micromonospora genus. To elucidate the application potential of this species, its genome was completely sequenced, using the PacBio SMRT cell platform, and was compared with selected complete genome sequences of other Micromonospora species. Genomic analysis revealed that the genome of TMS7^T consists of one circular DNA chromosome of 6,717,200 bp with a GC content of 73.35% and one plasmid of 24,912 bp with a GC content of 65.39%. The entire genome contains 6,311 predicted coding genes, 57 transfer RNAs, and nine ribosomal RNA genes. The genome contains a type III polyketide biosynthesis gene cluster, which encodes enzymes that catalyze the production of alkyl-O-dihydrogeranyl-methoxyhydroquinone. This information combined with the previous report that this strain can grow well on pH 10 medium with 4% NaCl (wt/vol) indicates that this strain may have potential biocontrol applications for economic plants cultivated on alkaline soil.

Complete Genome of Micromonospora sp. Strain B006 Reveals Biosynthetic Potential of a Lake Michigan Actinomycete

Actinomycete bacteria isolated from freshwater environments are an unexplored source of natural products. Here we report the complete genome of the Great Lakes-derived Micromonospora sp. strain B006, revealing its potential for natural product biosynthesis. The 7-megabase pair chromosome of strain B006 was sequenced using Illumina and Oxford Nanopore technologies followed by Sanger sequencing to close remaining gaps. All identified biosynthetic gene clusters (BGCs) were manually curated. Five known BGCs were identified encoding desferrioxamine, alkyl- O-dihydrogeranylmethoxyhydroquinone, a spore pigment, sioxanthin, and diazepinomicin, which is currently in phase II clinical trials to treat Phelan-McDermid syndrome and co-morbid epilepsy. We report here that strain B006 is indeed a producer of diazepinomicin and at yields higher than previously reported. Moreover, 11 of the 16 identified BGCs are orphan, eight of which were transcriptionally active under the culture condition tested. Orphan BGCs include an enediyne polyketide synthase and an uncharacteristically large, 36-module polyketide synthase-nonribosomal peptide synthetase BGC. We developed a genetics system for Micromonospora sp. B006 that will contribute to deorphaning BGCs in the future. This study is one of the few attempts to report the biosynthetic capacity of a freshwater-derived actinomycete and highlights this resource as a potential reservoir for new natural products.

Genome-based classification of micromonosporae with a focus on their biotechnological and ecological potential

There is a need to clarify relationships within the actinobacterial genus Micromonospora, the type genus of the family Micromonosporaceae, given its biotechnological and ecological importance. Here, draft genomes of 40 Micromonospora type strains and two non-type strains are made available through the Genomic Encyclopedia of Bacteria and Archaea project and used to generate a phylogenomic tree which showed they could be assigned to well supported phyletic lines that were not evident in corresponding trees based on single and concatenated sequences of conserved genes. DNA G+C ratios derived from genome sequences showed that corresponding data from species descriptions were imprecise. Emended descriptions include precise base composition data and approximate genome sizes of the type strains. antiSMASH analyses of the draft genomes show that micromonosporae have a previously unrealised potential to synthesize novel specialized metabolites. Close to one thousand biosynthetic gene clusters were detected, including NRPS, PKS, terpenes and siderophores clusters that were discontinuously distributed thereby opening up the prospect of prioritising gifted strains for natural product discovery. The distribution of key stress related genes provide an insight into how micromonosporae adapt to key environmental variables. Genes associated with plant interactions highlight the potential use of micromonosporae in agriculture and biotechnology.

Micromonospora phytophila sp. nov. and Micromonospora luteiviridis sp. nov., isolated as natural inhabitants of plant nodules

Two actinobacterial isolates, strains SG15T and SGB14T, were recovered through a microbial diversity study of nitrogen fixing nodules from Pisum sativum plants collected in Salamanca (Spain). The taxonomic status of these isolates was determined using a polyphasic approach and both presented chemotaxonomic and morphological properties consistent with their classification in the genus Micromonospora. For strains SG15T and SGB14T, the highest 16S rRNA gene sequence similarities were observed with Micromonospora coxensis JCM 13248T (99.2 %) and Micromonospora purpureochromogenes DSM 43821T (99.4 %), respectively. However, strains SG15T and SGB14T were readily distinguished from their phylogenetic neighbours both genetically and phenotypically indicating that they represent two new Micromonospora species. The following names are proposed for these species: Micromonosporaphytophila sp. nov. type strain SG15T (=CECT 9369T; =DSM 105363T), and Micromonosporaluteiviridis sp. nov. type strain SGB14T (=CECT 9370T; =DSM 105362T).

Monitoring the colonization and infection of legume nodules by Micromonospora in co-inoculation experiments with rhizobia

The discovery that the actinobacterium Micromonospora inhabits nitrogen-fixing nodules raised questions as to its potential ecological role. The capacity of two Micromonospora strains to infect legumes other than their original host, Lupinus angustifolius, was investigated using Medicago and Trifolium as test plants. Compatible rhizobial strains were used for coinoculation of the plants because Micromonospora itself does not induce nodulation. Over 50% of nodules from each legume housed Micromonospora, and using 16S rRNA gene sequence identification, we verified that the reisolated strains corresponded to the microorganisms inoculated. Entry of the bacteria and colonization of the plant hosts were monitored using a GFP-tagged Lupac 08 mutant together with rhizobia, and by using immunogold labeling. Strain Lupac 08 was localized in plant tissues, confirming its capacity to enter and colonize all hosts. Based on studying three different plants, our results support a non-specific relationship between Micromonospora and legumes. Micromonospora Lupac 08, originally isolated from Lupinus re-enters root tissue, but only when coinoculated with the corresponding rhizobia. The ability of Micromonospora to infect and colonize different legume species and function as a potential plant-growth promoting bacterium is relevant because this microbe enhances the symbiosis without interfering with the host and its nodulating and nitrogen-fixing microbes.

Micromonospora fulva sp. nov., isolated from forest soil

A novel actinobacterium, designated strain UDF-1T, was isolated from forest soil in Chungnam, South Korea, and its taxonomic position was investigated using a polyphasic approach. Strain UDF-1T formed a branched brownish-orange substrate mycelium with spherical or oval spores. No aerial mycelium was formed. Comparative 16S rRNA gene sequence analysis indicated that strain UDF-1T belongs to the genus Micromonospora, showing the highest sequence similarity to Micromonospora palomenae NEAU-CX1T (99.2 % 16S rRNA gene sequence similarity), 'Micromonospora maoerensis' NEAU-MES19 (99.0 %), Micromonospora endolithica DSM 44398T (98.8 %) and Micromonospora matsumotoense IMSNU 22003T (98.8 %). The predominant menaquinones of strain UDF-1T were MK-10 (H4) and MK-10 (H6). The cell wall contained meso-diaminopimelic acid and the whole-cell sugars were arabinose and xylose. The major polar lipids were phosphatidylinositol, diphosphatidylglycerol and phosphatidylethanolamine. The major cellular fatty acids were iso-C16 : 0, anteiso-C15 : 0 and iso-C15 : 0. The genomic DNA G+C content was 73.1 mol%. DNA-DNA relatedness between strain UDF-1T and closely related type strains in the genus Micromonospora was below 30 %. On the basis of the polyphasic analysis conducted in this study, strain UDF-1T represents a novel species of the genus Micromonospora, for which the name Micromonospora fulva sp. nov. is proposed. The type strain is UDF-1T (=KACC 18696T=NBRC 111826T).

Micromonospora luteifusca sp. nov. isolated from cultivated Pisum sativum

Three novel actinobacterial strains, GUI2(T), GUI42 and CR21 isolated from nodular tissues and the rhizosphere of a sweet pea plant collected in Cañizal, Spain were identified according to their 16S rRNA gene sequences as new members of the genus Micromonospora. The closest phylogenetic members were found to be Micromonospora saelicesensis (99.2%) "Micromonospora zeae" (99.1%), "Micromonospora jinlongensis" (99%), Micromonospora lupini (98.9%) and Micromonospora zamorensis (98.8%). To resolve their full taxonomic position, four additional genes (atpD, gyrB, recA, rpoB) were partially sequenced and compared to available Micromonospora type strain sequences. DNA-DNA hybridization, BOX-PCR and ARDRA profiles confirmed that these strains represent a novel genomic species. All strains contained meso-diaminopimelic and hydroxy-diaminopimelic acids in their cell wall. Their fatty acid profiles comprised iso-C15:0, iso-C16:0 and anteiso-C15:0 as major components. The polar lipids diphosphatidylglycerol, phosphatidylethanolamine and phosphatidylinositol were found in the type strain GUI2(T) which also contained MK-10(H4) as the major menaquinone. Physiological and biochemical characteristics also differentiated the new isolates. Based on the integration of the above studies, strains GUI2(T), GUI42 and CR21 represent a novel Micromonospora species and we propose the name Micromonospora luteifusca sp. nov. The type strain is GUI2(T) (=CECT 8846(T); =DSM 100204(T)).

Genome features of the endophytic actinobacterium Micromonospora lupini strain Lupac 08: on the process of adaptation to an endophytic life style?

Endophytic microorganisms live inside plants for at least part of their life cycle. According to their life strategies, bacterial endophytes can be classified as “obligate” or “facultative”. Reports that members of the genus Micromonospora, Gram-positive Actinobacteria, are normal occupants of nitrogen-fixing nodules has opened up a question as to what is the ecological role of these bacteria in interactions with nitrogen-fixing plants and whether it is in a process of adaptation from a terrestrial to a facultative endophytic life. The aim of this work was to analyse the genome sequence of Micromonospora lupini Lupac 08 isolated from a nitrogen fixing nodule of the legume Lupinus angustifolius and to identify genomic traits that provide information on this new plant-microbe interaction. The genome of M. lupini contains a diverse array of genes that may help its survival in soil or in plant tissues, while the high number of putative plant degrading enzyme genes identified is quite surprising since this bacterium is not considered a plant-pathogen. Functionality of several of these genes was demonstrated in vitro, showing that Lupac 08 degraded carboxymethylcellulose, starch and xylan. In addition, the production of chitinases detected in vitro, indicates that strain Lupac 08 may also confer protection to the plant. Micromonospora species appears as new candidates in plant-microbe interactions with an important potential in agriculture and biotechnology. The current data strongly suggests that a beneficial effect is produced on the host-plant.

Genomics of sponge-associated Streptomyces spp. closely related to Streptomyces albus J1074: insights into marine adaptation and secondary metabolite biosynthesis potential

A total of 74 actinomycete isolates were cultivated from two marine sponges, Geodia barretti and Phakellia ventilabrum collected at the same spot at the bottom of the Trondheim fjord (Norway). Phylogenetic analyses of sponge-associated actinomycetes based on the 16S rRNA gene sequences demonstrated the presence of species belonging to the genera Streptomyces, Nocardiopsis, Rhodococcus, Pseudonocardia and Micromonospora. Most isolates required sea water for growth, suggesting them being adapted to the marine environment. Phylogenetic analysis of Streptomyces spp. revealed two isolates that originated from different sponges and had 99.7% identity in their 16S rRNA gene sequences, indicating that they represent very closely related strains. Sequencing, annotation, and analyses of the genomes of these Streptomyces isolates demonstrated that they are sister organisms closely related to terrestrial Streptomyces albus J1074. Unlike S. albus J1074, the two sponge streptomycetes grew and differentiated faster on the medium containing sea water. Comparative genomics revealed several genes presumably responsible for partial marine adaptation of these isolates. Genome mining targeted to secondary metabolite biosynthesis gene clusters identified several of those, which were not present in S. albus J1074, and likely to have been retained from a common ancestor, or acquired from other actinomycetes. Certain genes and gene clusters were shown to be differentially acquired or lost, supporting the hypothesis of divergent evolution of the two Streptomyces species in different sponge hosts.

Unusual N-prenylation in diazepinomicin biosynthesis: the farnesylation of a benzodiazepine substrate is catalyzed by a new member of the ABBA prenyltransferase superfamily

The bacterium Micromonospora sp. RV115, isolated from a marine sponge, produces the unusual metabolite diazepinomicin, a prenylated benzodiazepine derivative. We have cloned the prenyltransferase gene dzmP from this organism, expressed it in Escherichia coli, and the resulting His₈-tagged protein was purified and investigated biochemically. It was found to catalyze the farnesylation of the amide nitrogen of dibenzodiazepinone. DzmP belongs to the ABBA prenyltransferases and is the first member of this superfamily which utilizes farnesyl diphosphate as genuine substrate. All previously discovered members utilize either dimethylallyl diphosphate (C₅) or geranyl diphosphate (C₁₀). Another putative diazepinomicin biosynthetic gene cluster was identified in the genome of Streptomyces griseoflavus Tü4000, suggesting that the formation of diazepinomicin is not restricted to the genus Micromonospora. The gene cluster contains a gene ssrg_00986 with 61.4% identity (amino acid level) to dzmP. The gene was expressed in E. coli, and the purified protein showed similar catalytic properties as DzmP. Both enzymes also accepted other phenolic or phenazine substrates. ABBA prenyltransferases are useful tools for chemoenzymatic synthesis, due to their nature as soluble, stable biocatalysts. The discovery of DzmP and Ssrg_00986 extends the isoprenoid substrate range of this superfamily. The observed prenylation of an amide nitrogen is an unusual biochemical reaction.

[Cloning and sequence characterization of replication region in plasmid pJTU112 from Micoromonospora sp. 40027]

Micoromonospora sp. 40027, the producer of fortimicin A, harbors two plasmids pJTU101 and pJTU112.

OBJECTIVE

Cloning and sequencing of replication region of pJTU12, analyzing replication region sequence of pJTU112.

METHODS

Different fragments of pJTU112 were cloned and introduced by conjugation into Micromonospora sp. LXH20. The replication region of pJTU112 was identified.

RESULTS

The replication region of pJTU112 was located in the 4.7 kb SacI-KpnI DNA fragment. DNA sequencing and analysis revealed that the 4.7 kb SacI-KpnI DNA fragment encoded five open reading frames. The pJTU112.1 and pJTU112.2 were related to plasmid conjugation, pJTU112.3, pJTU112.4 and pJTU112.5 were related to plasmid conjugation.

CONCLUSION

The replication region of pJTU112 was located in the 4.7kb SacI-KpnI DNA fragment.

Micromonospora halotolerans sp. nov., isolated from the rhizosphere of a Pisum sativum plant

A filamentous actinomycete strain designated CR18(T) was isolated on humic acid agar from the rhizosphere of a Pisum sativum plant collected in Spain. This isolate was observed to grow optimally at 28 °C, pH 7.0 and in the presence of 5 % NaCl. Phylogenetic analyses based on the 16S rRNA gene sequence indicated a close relationship with the type strains of Micromonospora chersina and Micromonospora endolithica. A further analysis based on a concatenated DNA sequence stretch of 4,523 bp that included partial sequences of the atpD, gyrB, recA, rpoB and 16S rRNA genes clearly differentiated the new strain from recognized Micromonospora species compared. DNA-DNA hybridization studies further supported the taxonomic position of strain CR18(T) as a novel genomic species. Chemotaxonomic analyses which included whole cell sugars, polar lipids, fatty acid profiles and menaquinone composition confirmed the affiliation of the new strain to the genus Micromonospora and also highlighted differences at the species level. These studies were finally complemented with an array of physiological tests to help differentiate between the new strain and its phylogenetic neighbours. Consequently, strain CR18(T) (= CECT 7890(T) = DSM 45598(T)) is proposed as the type strain of a novel species, Micromonospora halotolerans sp. nov.

An effective method based on wet-heat treatment for the selective isolation of Micromonospora from estuarine sediments

Several methods for the isolation of Micromonospora from soil samples have been developed; however, it is unclear whether these methods are optimal for estuarine samples. In this study, we optimized the conditions of a wet-heat method for the selective isolation of Micromonospora from estuarine sediments. Sediments were collected from the Arakawa River (estuarine sediments) and Tokyo Bay (marine sediments). Sediment samples were wet-heated at 45, 55, or 65 °C for 30 min and then incubated at 27 °C for 3 weeks. After incubation, most of the actinomycete colonies were macroscopically determined to be of the genus Micromonospora or Streptomyces. In contrast to the treatment at 55 °C, treatment at 65 °C drastically reduced the number of Streptomyces colonies but increased the number of Micromonospora colonies from the estuarine sediments. This procedure allowed us to grow cultures that were composed of more than 90 % Micromonospora. In addition, treatment at 65 °C did not affect the diversity of Micromonospora species compared with treatment at 55 °C. These results indicate that the wet-heat method, which involves pre-treating the sediment at 65 °C for 30 min, is a very simple and effective method for the selective enrichment of a large number of diverse Micromonospora from estuarine sediments. Our results may lead to the isolation of new Micromonospora species, which produce novel bioactive compounds, from different estuarine sediments.

Micromonospora cremea sp. nov. and Micromonospora zamorensis sp. nov., isolated from the rhizosphere of Pisum sativum

Three actinobacterial strains, CR30(T), CR36 and CR38(T), were isolated from rhizosphere soil of Pisum sativum plants collected in Spain. The strains were filamentous, Gram-stain-positive and produced single spores. Phylogenetic, chemotaxonomic and morphological analyses confirmed that the three strains belonged to the genus Micromonospora. 16S rRNA gene sequence analysis of strains CR30(T) and CR36 showed a close relationship to Micromonospora coriariae NAR01(T) (99.3% similarity) while strain CR38(T) had a similarity of 99.0% with Micromonospora saelicesensis Lupac 09(T). In addition, gyrB gene phylogeny clearly differentiated the novel isolates from recognized Micromonospora species. DNA-DNA hybridization, BOX-PCR and ARDRA profiles confirmed that these strains represent novel genomic species. The cell-wall peptidoglycan of strains CR30(T) and CR38(T) contained meso-diaminopimelic acid. Both strains had MK-10(H(4)) as the main menaquinone and a phospholipid type II pattern. An array of physiological tests also differentiated the isolates from their closest neighbours. Considering all the data obtained, it is proposed that strains CR30(T) and CR36 represent a novel species under the name Micromonospora cremea sp. nov. (type strain CR30(T) = CECT 7891(T) = DSM 45599(T)), whereas CR38(T) represents a second novel species, for which the name Micromonospora zamorensis sp. nov. is proposed, with CR38(T) ( = CECT 7892(T) = DSM 45600(T)) as the type strain.

Identification and characterization of novel catalytic bioscavengers of organophosphorus nerve agents

In an effort to discover novel catalytic bioscavengers of organophosphorus (OP) nerve agents, cell lysates from a diverse set of bacterial strains were screened for their capacity to hydrolyze the OP nerve agents VX, VR, and soman (GD). The library of bacterial strains was identified using both random and rational approaches. Specifically, two representative strains from eight categories of extremophiles were chosen at random. For the rational approach, the protein sequence of organophosphorus hydrolase (OPH) from Brevundimonas diminuta was searched against a non-redundant protein database using the Basic Local Alignment Search Tool to find regions of local similarity between sequences. Over 15 protein sequences with significant sequence similarity to OPH were identified from a variety of bacterial strains. Some of these matches were based on predicted protein structures derived from bacterial genome sequences rather than from bona fide proteins isolated from bacteria. Of the 25 strains selected for nerve agent testing, three bacterial strains had measurable levels of OP hydrolase activity. These strains are Ammoniphilus oxalaticus, Haloarcula sp., and Micromonospora aurantiaca. Lysates from A. oxalaticus had detectable hydrolysis of VR; Haloarcula sp. had appreciable hydrolysis of VX and VR, whereas lysates from M. aurantiaca had detectable hydrolysis of VR and GD.

Functional gene-guided discovery of type II polyketides from culturable actinomycetes associated with soft coral Scleronephthya sp

Compared with the actinomycetes in stone corals, the phylogenetic diversity of soft coral-associated culturable actinomycetes is essentially unexplored. Meanwhile, the knowledge of the natural products from coral-associated actinomycetes is very limited. In this study, thirty-two strains were isolated from the tissue of the soft coral Scleronephthya sp. in the East China Sea, which were grouped into eight genera by 16S rDNA phylogenetic analysis: Micromonospora, Gordonia, Mycobacterium, Nocardioides, Streptomyces, Cellulomonas, Dietzia and Rhodococcus. 6 Micromonospora strains and 4 Streptomyces strains were found to be with the potential for producing aromatic polyketides based on the analysis of KS_α (ketoacyl-synthase) gene in the PKS II (type II polyketides synthase) gene cluster. Among the 6 Micromonospora strains, angucycline cyclase gene was amplified in 2 strains (A5-1 and A6-2), suggesting their potential in synthesizing angucyclines e.g. jadomycin. Under the guidance of functional gene prediction, one jadomycin B analogue (7b, 13-dihydro-7-O-methyl jadomycin B) was detected in the fermentation broth of Micromonospora sp. strain A5-1. This study highlights the phylogenetically diverse culturable actinomycetes associated with the tissue of soft coral Scleronephthya sp. and the potential of coral-derived actinomycetes especially Micromonospora in producing aromatic polyketides.

Probing the catalytic mechanism of a C-3'-methyltransferase involved in the biosynthesis of D-tetronitrose

D-Tetronitrose is a nitro-containing tetradeoxysugar found attached to the antitumor and antibacterial agent tetrocarcin A. The biosynthesis of this highly unusual sugar in Micromonospora chalcea requires 10 enzymes. The fifth step in the pathway involves the transfer of a methyl group from S-adenosyl-L-methionine (SAM) to the C-3' carbon of dTDP-3-amino-2,3,6-trideoxy-4-keto-D-glucose. The enzyme responsible for this transformation is referred to as TcaB9. It is a monomeric enzyme with a molecular architecture based around three domains. The N-terminal motif contains a binding site for a structural zinc ion. The middle- and C-terminal domains serve to anchor the SAM and dTDP-sugar ligands, respectively, to the protein, and the active site of TcaB9 is wedged between these two regions. For this investigation, the roles of Tyr 76, His 181, Tyr 222, Glu 224, and His 225, which form the active site of TcaB9, were probed by site-directed mutagenesis, kinetic analyses, and X-ray structural studies. In addition, two ternary complexes of the enzyme with bound S-adenosyl-L-homocysteine and either dTDP-3-amino-2,3,6-trideoxy-4-keto-D-glucose or dTDP-3-amino-2,3,6-trideoxy-D-galactose were determined to 1.5 or 1.6 Å resolution, respectively. Taken together, these investigations highlight the important role of His 225 in methyl transfer. In addition, the structural data suggest that the methylation reaction occurs via retention of configuration about the C-3' carbon of the sugar.

Micromonospora sediminicola sp. nov., isolated from marine sediment

An actinomycete strain, designated strain SH2-13(T), was isolated from a marine sediment sample collected from the Andaman Sea of Thailand. Applying a polyphasic approach, the isolate was identified as a member of the genus Micromonospora using morphological and chemotaxonomic characteristics, including the presence of meso-diaminopimelic acid in the peptidoglycan. Whole-cell sugars were arabinose, galactose, glucose, rhamnose, ribose and xylose. Diagnostic polar lipids were phosphatidylethanolamine, phosphatidylglycerol, diphosphatidylglycerol, phosphatidylinositol, phosphatidylinositol mannosides and phosphoglycolipids. The major menaquinones were MK-10(H(2)), MK-10(H(4)) and MK-10(H(6)). 16S rRNA gene sequence analysis revealed similarity to Micromonospora marina JSM1-1(T) (99.1 %), Micromonospora coxensis 2-30-b(28)(T) (99.1 %), Micromonospora aurantiaca DSM 43813(T) (98.8 %) and Micromonospora chalcea DSM 43026(T) (98.7 %). However, a combination of DNA-DNA hybridization results and phenotypic properties indicated that strain SH2-13(T) ( = NBRC 107934(T) = BCC 45601(T)) should be classified as the type strain of a novel species, with the proposed name Micromonospora sediminicola sp. nov.

Diversity of Micromonospora strains isolated from nitrogen fixing nodules and rhizosphere of Pisum sativum analyzed by multilocus sequence analysis

It was recently reported that Micromonospora inhabits the intracellular tissues of nitrogen fixing nodules of the wild legume Lupinus angustifolius. To determine if Micromonospora populations are also present in nitrogen fixing nodules of cultivated legumes such as Pisum sativum, we carried out the isolation of this actinobacterium from P. sativum plants collected in two man-managed fields in the region of Castilla and León (Spain). In this work, we describe the isolation of 93 Micromonospora strains recovered from nitrogen fixing nodules and the rhizosphere of P. sativum. The genomic diversity of the strains was analyzed by amplified ribosomal DNA restriction analysis (ARDRA). Forty-six isolates and 34 reference strains were further analyzed using a multilocus sequence analysis scheme developed to address the phylogeny of the genus Micromonospora and to evaluate the species distribution in the two studied habitats. The MLSA results were evaluated by DNA-DNA hybridization to determine their usefulness for the delineation of Micromonospora at the species level. In most cases, DDH values below 70% were obtained with strains that shared a sequence similarity of 98.5% or less. Thus, MLSA studies clearly supported the established taxonomy of the genus Micromonospora and indicated that genomic species could be delineated as groups of strains that share > 98.5% sequence similarity based on the 5 genes selected. The species diversity of the strains isolated from both the rhizosphere and nodules was very high and in many cases the new strains could not be related to any of the currently described species.

Micromonospora tulbaghiae sp. nov., isolated from the leaves of wild garlic, Tulbaghia violacea

A novel actinomycete, strain TVU1(T), was isolated from leaves of the indigenous South African plant Tulbaghia violacea. Applying a polyphasic approach, the isolate was identified as a member of the genus Micromonospora. Phylogenetic analysis of the 16S rRNA gene sequence showed that strain TVU1(T) was most closely related to Micromonospora echinospora DSM 43816(T). However, phylogenetic analysis based on gyrB gene sequences showed that strain TVU1(T) was most closely related to the type strains of Micromonospora aurantiaca and Micromonospora chalcea. DNA-DNA relatedness values between strain TVU1(T) and the type strains of M. echinospora, M. aurantiaca and M. chalcea were 7.6+/-4.5, 45.9+/-2.0 and 60.9+/-4.5 %, respectively. Strain TVU1(T) could be distinguished from the type strains of all three of these species by several physiological characteristics, such as colony colour, NaCl tolerance, growth temperature range and sole carbon source utilization pattern. Strain TVU1(T) (=DSM 45142(T)=NRRL B-24576(T)) therefore represents a novel species for which the name Micromonospora tulbaghiae sp. nov. is proposed.

Micromonospora pisi sp. nov., isolated from root nodules of Pisum sativum

A novel actinomycete, designated strain GUI 15(T), isolated from the root nodules of a Pisum sativum plant was characterized taxonomically by using a polyphasic approach. The 16S rRNA gene sequence of strain GUI 15(T) showed highest similarity to Micromonospora pattaloongensis TJ2-2(T) (98.7 %) and Polymorphospora rubra TT 97-42(T) (98.5 %). Phylogenetic analysis based on the gyrase B gene also supported the close relationship of these three strains, but indicated that strain GUI 15(T) should be assigned to the genus Micromonospora. Chemotaxonomic results confirmed the position of the isolate in the genus Micromonospora, but revealed differences at the species level. The novel strain could be distinguished from recognized Micromonospora species by using a combination of physiological and biochemical tests. Based on these observations, strain GUI 15(T) is considered to represent a novel species of the genus Micromonospora, for which the name Micromonospora pisi sp. nov. is proposed. The type strain is GUI 15(T) (=DSM 45175(T)=LMG 24546(T)).

Production of rosamicin derivatives in Micromonospora rosaria by introduction of D-mycinose biosynthetic gene with PhiC31-derived integration vector pSET152

Some of the polyketide-derived bioactive compounds contain sugars attached to the aglycone core, and these sugars often impart specific biological activity to the molecule or enhance this activity. Mycinamicin II, a 16-member macrolide antibiotic produced by Micromonospora griseorubida A11725, contains a branched lactone and two different deoxyhexose sugars, D-desosamine and D-mycinose, at the C-5 and C-21 positions, respectively. The D-mycinose biosynthesis genes, mycCI, mycCII, mycD, mycE, mycF, mydH, and mydI, present in the M. griseorubida A11725 chromosome were introduced into pSET152 under the regulation of the promoter of the apramycin-resistance gene aac(3)IV. The resulting plasmid pSETmycinose was introduced into Micromonospora rosaria IFO13697 cells, which produce the 16-membered macrolide antibiotic rosamicin containing a branched lactone and D-desosamine at the C-5 position. Although the M. rosaria TPMA0001 transconjugant exhibited low rosamicin productivity, two new compounds, IZI and IZII, were detected in the ethylacetate extract from the culture broth. IZI was identified as a mycinosyl rosamicin derivative, 23-O-mycinosyl-20-deoxo-20-dihydro-12,13-deepoxyrosamicin (MW 741), which has previously been synthesized by a bioconversion technique. This is the first report on production of mycinosyl rosamicin-derivatives by a engineered biosynthesis approach. The integration site PhiC31attB was identified on M. rosaria IFO13697 chromosome, and the site lay within an ORF coding a pirin homolog protein. The pSETmycinose could be useful for stimulating the production of "unnatural" natural mycinosyl compounds by various actinomycete strains using the bacteriophage PhiC31 att/int system.

Biosynthesis of diazepinomicin/ECO-4601, a Micromonospora secondary metabolite with a novel ring system

The novel microbial metabolite diazepinomicin/ECO-4601 (1) has a unique tricyclic dibenzodiazepinone core, which was unprecedented among microbial metabolites. Labeled feeding experiments indicated that the carbocyclic ring and the ring nitrogen of tryptophan could be incorporated via degradation to the 3-hydroxyanthranilic acid, forming ring A and the nonamide nitrogen of 1. Genomic analysis of the biosynthetic locus indicated that the farnesyl side chain was mevalonate derived, the 3-hydroxyanthranilic acid moiety could be formed directly from chorismate, and the third ring was constructed via 3-amino-5-hydroxybenzoic acid. Successful incorporation of 4,6-D2-3-hydroxyanthranilic acid into ring A of 1 via feeding experiments supports the genetic analysis and the allocation of the locus to this biosynthesis. These studies highlight the enzymatic complexity needed to produce this structural type, which is rare in nature.

Genetic dissection of the biosynthetic route to gentamicin A2 by heterologous expression of its minimal gene set

Since the first use of streptomycin as an effective antibiotic drug in the treatment of tuberculosis, aminoglycoside antibiotics have been widely used against a variety of bacterial infections for over six decades. However, the pathways for aminoglycoside biosynthesis still remain unclear, mainly because of difficulty in genetic manipulation of actinomycetes producing this class of antibiotics. Gentamicin belongs to the group of 4,6-disubstituted aminoglycosides containing a characteristic core aminocyclitol moiety, 2-deoxystreptamine (2-DOS), and the recent discovery of its biosynthetic gene cluster in Micromonospora echinospora has enabled us to decipher its biosynthetic pathway. To determine the minimal set of genes and their functions for the generation of gentamicin A(2), the first pseudotrisaccharide intermediate in the biosynthetic pathway for the gentamicin complex, various sets of candidate genes from M. echinospora and other related aminoglycoside-producing strains were introduced into a nonaminoglycoside producing strain of Streptomyces venezuelae. Heterologous expression of different combinations of putative 2-DOS biosynthetic genes revealed that a subset, gtmB-gtmA-gacH, is responsible for the biosynthesis of this core aminocyclitol moiety of gentamicin. Expression of gtmG together with gtmB-gtmA-gacH led to production of 2'-N-acetylparomamine, demonstrating that GtmG acts as a glycosyltransferase that adds N-acetyl-d-glucosamine (GLcNA) to 2-DOS. Expression of gtmM in a 2'-N-acetylparomamine-producing recombinant S. venezuelae strain generated paromamine. Expression of gtmE in an engineered paromamine-producing strain of S. venezuelae successfully generated gentamicin A(2), indicating that GtmE is another glycosyltransferase that attaches d-xylose to paromamine. These results represent in vivo evidence elucidating the complete biosynthetic pathway of the pseudotrisaccharide aminoglycoside.

Characterisation of micromonosporae from aquatic environments using molecular taxonomic methods

Large numbers of strains assigned to the genus Micromonospora on the basis of typical colonial and pigmentation features were isolated from diverse aquatic sediments using a standard selective isolation procedure. Two hundred and six isolates and eight representatives of the genus Micromonospora were assigned to 24 multimembered groups based on a numerical analysis of banding patterns generated using BOX and ERIC primers. Representatives of multimembered groups encompassing isolated micromonosporae were the subject of 16S rRNA gene sequencing analyses. Good congruence was found between the molecular fingerprinting and 16S rRNA sequence data indicating that the groups based upon the former are taxonomically meaningful. Nearly all of the isolates that were chosen for the 16S rRNA gene sequencing analyses showed that the ecosystems studied are a rich source of novel micromonosporae. These findings have implications for high throughput screening for novel micromonosporae as BOX and ERIC fingerprinting, which is rapid and reproducible, can be applied as a robust dereplication procedure to indicate which environmental isolates have been cultured previously.

Use of phage battery to investigate the actinofloral layers of termite gut microflora

AIMS

The termite gut microbiota can include a variety of micro-organisms from the three domains: Bacteria, Archaea and Eucarya. The bacterial groups from the gut systems are mainly affiliated to the proteobacteria, the Gram-positive groups Bacterioiodes/Flavobacterium branch and the spirochetes, Firmicutes and Actinobacteria. However, culture independent molecular studies have revealed that the majority of these microbial gut symbionts have not yet been cultured, including actinobacterial clusters associated with termite guts. Accordingly, the aim of this study was to selectively isolate the actinofloral layers of gut associated microflora of the Coptotermes lacteus (Froggatt) species located at the Sunshine Coast Region of Queensland, Australia to increase our knowledge on the diversity of actinobacterial taxa present in the termite guts.

METHODS AND RESULTS

Actinofloral layers associated with the guts of the wood-eating subterranean termite C. lacteus were investigated by exploiting the phage susceptibility of different gut associated bacteria which impede the growth of actinomycetes on isolation plates. These unwanted microbial taxa were removed by exposing the gut contents to polyvalent bacteriophages specifically targeting different background bacterial taxa and after their removal from the isolation plates previously undetected and novel actinomycetes were successfully cultured from the gut samples.

CONCLUSIONS

Use of bacteriophages as a means of selective pressure successfully revealed the presence of novel actinomycete species within the guts of C. lacteus.

SIGNIFICANCE AND IMPACT OF THE STUDY

Molecular ecology has undoubtedly revealed the fascinating diversity of micro-organisms, which cannot be cultured. However, these advances in the field still have not provided the ability to detect and isolate micro-organisms effectively from their ecological niches. Accordingly, studies like the one described here have importance in increasing the chances of uncultured taxa to be isolated to complement molecular microbial ecological efforts towards the establishment of an understanding on the diversity of termite gut microflora.

[Study on electroporation of rare Actinomycete Micromonospora sp. 40027 with Streptomyces plasmid pSET152]

Electroporation of Micromonospora sp. 40027 isolated from soil was studied with Streptomyces plasmid pSET152, an integrative vector commonly used in Streptomyces genetic manipulation. Transformant was not obtained by electroporation with germinated spores of Micromonospora sp. 40027 as recipient, but plasmid pSET152 can be electroporated into the fresh mycelium of Micromonospora sp. 40027, and the highest electroporation efficiency was yielded under the electric field strength of 13kV/cm. Plasmid stability experiment and southern blot showed that pSET152 could stably exist in the Micromonospora sp. 40027, and was integrated into its chromosome via the attP site, originated from Streptomyces phage phiC31. These data suggested that plasmid pSET152 was successfully electroporated into Micromonospora, and that the integrase gene and attP site of Streptomyces phage phiC31 could play the same role in Micromonospora.

Phylogenetic Analysis of Antibiotic Glycosyltransferases

Catalyzed by a family of enzymes called glycosyltransferases, glycosylation reactions are essential for the bioactivities of secondary metabolites such as antibiotics. Due to the special characters of antibiotic glycosyltransferases (AGts), antibiotics can function by attaching some unusual deoxy-sugars to their aglycons. Comprehensive similarity searches on the amino acid sequences of AGts have been performed. We reconstructed the molecular phylogeny of AGts with neighbor-joining, maximum-likelihood, and Bayesian methods of phylogenetic inference. The phylogenetic trees show a distinct separation of polyene macrolide (PEM) AGts and other polyketide AGts. The former are more like eukaryotic glycosyltransferases and were deduced to be the results of horizontal gene transfer from eukaryotes. Protein tertiary structural comparison also indicated that some glycopeptide AGts (Gtf-proteins) have a close evolutionary relationship with MurGs, essential glycosyltransferases involved in maturation of bacterial cell walls. The evolutionary relationship of glycopeptide antibiotic biosynthetic gene clusters was speculated according to the phylogenetic analysis of Gtf-proteins. Considering the fact that polyketide AGts and Gtf-proteins are all GT Family 1 members and their aglycon acceptor biosynthetic patterns are very similar, we deduced that AGts and the synthases of their aglycon acceptors have some evolutionary relevance. Finally, the evolutionary origins of AGts that do not fall into GT Family 1 are discussed, suggesting that their ancestral proteins appear to be derived from various proteins responsible for primary metabolism.

Two new species of the genus Micromonospora: Micromonospora chokoriensis sp. nov. and Micromonospora coxensis sp. nov., isolated from sandy soil

Two actinomycete strains, 2-19(6)(T) and 2-30-b(28)(T), which produced single, non-motile noduler to warty spore surfaces, were isolated from sandy soil in Chokoria, Cox's Bazar, Bangladesh. A polyphasic study was carried out to establish the taxonomic position of these strains. Morphological and chemotaxonomic characteristics of these strains coincided with those of the genus Micromonospora. Phylogenetic analysis using 16S rDNA sequences indicated that these strains should be classified in the genus Micromonospora. The 16S rDNA sequence of strain 2-19(6)(T )showed closest similarity to the type strains of M. mirobrigensis (98.9%) and M. carbonacea (98.8%), and the strain 2-30-b(28)(T) to the type strains of M. purpureochromogenes (99.4%), M. halophytica (99.3%) and M. aurantiaca (99.2%). Furthermore, a combination of DNA-DNA hybridization results and some differential physiological and biochemical properties indicated that these strains were distinguished from the phylogenetically closest relatives. These strains therefore represent two novel species, for which the name Micromonospora chokoriensis sp. nov. and Micromonospora coxensis sp. nov. are proposed. The type strains are 2-19(6)(T) (=JCM 13247(T) =MTCC 8535(T)) and 2-30-b(28)(T) (=JCM 13248(T)=MTCC 8093(T)).

Micromonospora coriariae sp. nov., isolated from root nodules of Coriaria myrtifolia

An actinomycete strain, NAR01T, was isolated from root nodules of a Coriaria plant. The 16S rRNA gene sequence of strain NAR01T showed most similarity to the type strains of Micromonospora endolithica (98.94 %) and Micromonospora chersina (98.4 %). The chemotaxonomic results obtained confirmed the taxonomic position of the isolate within the genus Micromonospora, and revealed differences at the species level. Physiological and biochemical tests showed that strain NAR01T could be clearly distinguished from its closest phylogenetic neighbours, while DNA–DNA hybridization results indicated that the isolate represents a novel species. On the basis of these results, strain NAR01T (=DSM 44875T=LMG 23557T) is proposed as the type strain of the novel species Micromonospora coriariae sp. nov.

Exploiting the reversibility of natural product glycosyltransferase-catalyzed reactions

Glycosyltransferases (GTs), an essential class of ubiquitous enzymes, are generally perceived as unidirectional catalysts. In contrast, we report that four glycosyltransferases from two distinct natural product biosynthetic pathways-calicheamicin and vancomycin-readily catalyze reversible reactions, allowing sugars and aglycons to be exchanged with ease. As proof of the broader applicability of these new reactions, more than 70 differentially glycosylated calicheamicin and vancomycin variants are reported. This study suggests the reversibility of GT-catalyzed reactions may be general and useful for generating exotic nucleotide sugars, establishing in vitro GT activity in complex systems, and enhancing natural product diversity.

In vivo characterization of the dTDP-D-desosamine pathway of the megalomicin gene cluster from Micromonospora megalomicea

In vivo reconstitution of the dTDP-D-desosamine pathway of the megalomicin gene cluster from Micromonospora megalomicea was achieved by expression of the genes in Escherichia coli. LC/MS/MS analysis of the dTDP-sugar intermediates produced by operons containing different sets of genes showed that production of dTDP-D-desosamine from dtdp-4-keto-6-deoxy-D-glucose requires only four biosynthetic steps, catalysed by MegCIV, MegCV, MegDII and MegDIII, and that MegCII is not involved. Instead, bioconversion studies demonstrated that MegCII is needed together with MegCIII to catalyse transfer of D-desosamine to 3-alpha-mycarosylerythronolide B.

Two Nucleophilic Mutants of the Micromonospora viridifaciens Sialidase Operate with Retention of Configuration by Two Different Mechanisms

Mutants of the Micromonospora viridifaciens sialidase, Y370E and Y370F, are catalytically active retaining enzymes that operate by different mechanisms. Previous substitutions with smaller amino acids, including Y370D, yielded inverting sialidases. At least one water molecule can fit into the active-site cavity of this mutant and act as a nucleophile from the face opposite the leaving group (Biochemistry 2003, 42, 12 682). Thus, addition of a CH(2) unit (Asp versus Glu) changes the mechanism from inversion back to retention of configuration. Based on Brønsted beta(lg) values, it is proposed that the Y370E mutant reacts by a double-displacement mechanism (beta(lg) on k(cat)/K(m) -0.36+/-0.04) with Glu370 acting as the nucleophile. However, the Y370F mutant (beta(lg) on k(cat)/K(m) -0.79+/-0.12) reacts via a dissociative transition state. The crystal structure of the Y370F mutant complexed with 2-deoxy-2,3-dehydro-N-acetylneuraminic acid shows no significant active-site perturbation relative to the wild-type enzyme.

Eight new species of the genus Micromonospora, Micromonospora citrea sp. nov., Micromonospora echinaurantiaca sp. nov., Micromonospora echinofusca sp. nov. Micromonospora fulviviridis sp. nov., Micromonospora inyonensis sp. nov., Micromonospora peucetia sp. nov., Micromonospora sagamiensis sp. nov., and Micromonospora viridifaciens sp. nov

A previous phylogenetic study on type strains of the genus Micromonospora and Micromonospora species bearing non-validly published names has pointed towards the species status of several of latter strains. Subsequent studies on morphological, cultural, chemotaxonomic, metabolic, and genomic properties, and on whole cell mass spectrometric analyses by matrix adsorbed laser desorption/ionization time-of-flight (MALDI-TOF) confirmed the species status, leading to the proposal of eight new Micromonospora species: Micromonospora citrea sp. nov., type strain DSM 43903T, Micromonospora echinaurantiaca sp. nov., type strain DSM 43904T, Micromonospora echinofusca sp. nov., type strain DSM 43913T, Micromonospora fulviviridis sp. nov., type strain DSM 43906T, Micromonospora inyonensis sp. nov., type strain DSM 46123T, Micromonospora peucetia sp. nov., type strain DSM 43363T, Micromonospora sagamiensis sp. nov., type strain DSM 43912T and Micromonospora viridifaciens sp. nov., type strain DSM 43909T.

Characterization of the Micromonospora rosaria pMR2 plasmid and development of a high G+C codon optimized integrase for site-specific integration

pMR2, an 11.1 kb plasmid was isolated from Micromonospora rosaria SCC2095, NRRL3718, and its complete nucleotide sequence determined. Analysis revealed 13 ORFs including homologs of a KorSA regulatory protein and TraB plasmid transfer protein found on other actinomycete plasmids. pMR2 contains att/int functions consisting of an integrase, an excisionase, and a putative plasmid attachment site (attP). The integrase gene contained a high frequency of codons rarely used in high G+C actinomycete coding regions. The gene was codon optimized for actinomycete codon usage to create the synthetic gene int-OPT. pSPRX740, containing an rpsL promoter and the att/int-OPT region, was introduced into Micromonospora halophytica var. nigra ATCC33088. Analysis of DNA flanking the pSPRX740 integration site confirmed site-specific integration into a tRNA(Phe) gene in the M. halopytica var. nigra chromosome. The pMR2 attP element and chromosomal attachment (attB) site contain a 63 bp region of sequence identity overlapping the 3' end of the tRNA(Phe) gene. Plasmids comprising the site-specific att/int-OPT functions of pMR2 can be used to integrate genes into the chromosome of actinomycetes with an appropriate tRNA gene. The development of an integrative system for Micromonospora will expand our ability to study antibiotic biosynthesis in this important actinomycete genus.

Structure and Mechanism of Action of an Inverting Mutant Sialidase

Mutagenesis of the conserved tyrosine (Y370) of the Micromonospora viridifaciens sialidase to small amino acids changes the mechanism of catalysis from retention of anomeric configuration to inversion [Watson, J. N., et al. (2003) Biochemistry 42, 12682-12690]. For the Y370G mutant enzyme-catalyzed hydrolysis of a series of aryl sialosides and 3'-sialyllactose, the derived Brønsted parameters (beta(lg)) on k(cat) and k(cat)/K(m) are -0.63 +/- 0.05 and -0.80 +/- 0.08, respectively. Thus, for the Y370G enzyme, glycosidic C-O bond cleavage is rate-determining. Analysis of the activity of the Y370G mutant and wild-type enzymes against a substrate [3,4-dihydro-2H-pyrano[3,2-c]pyridinium alpha-d-N-acetylneuraminide (DHP-alphaNeu5Ac)] whose hydrolysis cannot be accelerated by acid catalysis is consistent with these reactions proceeding via S(N)1 and S(N)2 mechanisms, respectively. The overall structure of the Y370G mutant sialidase active site is very similar to the previously reported wild-type structure [Gaskell, A., et al. (1995) Structure 3, 1197-1205], although removal of the tyrosine residue creates two significant changes to the active site. First, the anomeric oxygen atom of the hydrolysis product (beta-N-acetylneuraminic acid) and four water molecules bind in the large cavity created by the Y370G mutation. Second, the side chain of Asn310 moves to make a strong hydrogen bond to one of the bound water molecules.

Micromonospora mirobrigensis sp. nov

An actinomycete strain was recovered from a pond where radon is known to be dissolved. A polyphasic study was undertaken to identify the new isolate. The 16S rRNA gene sequence of strain WA201T showed closest similarity to the type strains of Micromonospora carbonacea (98·5 %) and Micromonospora matsumotoense (98·1 %). The chemotaxonomic results confirmed the taxonomic position of the isolate in the genus Micromonospora. DNA–DNA relatedness values supported the classification of this isolate as a novel species. A number of physiological and biochemical tests were able to distinguish strain WA201T from its closest phylogenetic neighbours. Therefore, it is proposed that isolate WA201T (=DSM 44830T=LMG 22229T) be considered the type strain representing a novel species, Micromonospora mirobrigensis sp. nov.

Characterization of tylM3/tylM2 and mydC/mycB pairs required for efficient glycosyltransfer in macrolide antibiotic biosynthesis

The heterologous expression of tylM3 and mydC, two homologous genes of previously unknown function, along with genes encoding their respective partner glycosyltransferases, tylM2 and mycB, and the necessary sugar biosynthesis genes significantly enhances the glycosyltransferase activity in the engineered Streptomyces venezuelae host in which the native glycosyltransferase, desVII, has been inactivated. Both glycosyltransferases accept the endogenous 12-membered macrolide, 10-deoxymethynolide, or the exogenously fed 16-membered macrolide, tylactone. Five new compounds were generated using this expression system. This work suggests that the 13 other known TylM3/MydC/DesVIII homologues found in macrolide and anthracycline antibiotic clusters likely function as glycosyltransferase auxiliary proteins as well. These findings will greatly assist endeavors to generate new natural products in these pathways in a combinatorial fashion.

The targeted inactivation of polyketide synthase mycAV in the mycinamicin producer, Micromonospora griseorubida, and a complementation study

Mycinamicin is a 16-membered macrolide antibiotic produced by Micromonospora griseorubida A11725, which shows strong antimicrobial activity against gram-positive bacteria. Recently, the nucleotide sequences of the mycinamicn biosynthetic gene cluster in M. griseorubida have been completely determined. Mycinamicin non-producer M7A21 was isolated by mycAV inactivation, which encodes the module 7 of mycinamicin polyketide synthase (PKS) required for the biosynthesis of the mycinamicin biosynthetic intermediate protomycinolide-IV (PML-IV). When the bioconversion to mycinamicin II (M-II) from PML-IV was performed using M7A21 and the feeding culture method, the productivity of M-II was the same as that of M-II in wild-type strain A11725. p446M7 containing mycAV was constructed using the Escherichia coli-Streptomyces shuttle vector pGM446. The mycinamicin productivity of M7A21 was restored by the introduction of p446M7 into the M7A21 cell, but almost all p446M7 was integrated into the chromosome of M7A21 because the plasmid was unstable in M7A21. The feeding culture and the introduction of the complement gene for M7A21 would be powerful tools to perform combinatorial biosynthesis for the production of new macrolide antibiotics.

Micromonospora siamensis sp. nov., isolated from Thai peat swamp forest

Morphological and chemotaxonomic characterization of actinomycete strain TT2-4T isolated from peat swamp forest soil in Pattaloong Province, Thailand, clearly demonstrated that this strain belongs to the genus Micromonospora. 16S rDNA sequence analysis for the strain supported the assignment of the strain to the genus Micromonospora and the similarity value of sequences between this strain and the closely related species, Micromonospora mirobrigensis was 99.1%, and M. carbonacea and M. matsumotoense were 98.8%. The DNA-DNA hybridization result and some physiological and biochemical properties indicated that strain TT2-4T was distinguished from the phylogenetically closest relatives. Based on these genotypic and phenotypic data, strain TT2-4T merits a new species in the genus Micromonospora and the name Micromonospora siamensis sp. nov. is proposed for the strain. The type strain is strain TT2-4T (=JCM 12769T =PCU 266T =TISTR 1554T).

Micromonospora eburnea sp. nov., isolated from a Thai peat swamp forest

Two actinomycete strains, LK2-10T and LK2-5, which produced single, non-motile spores, were isolated from peat swamp forest soil in Yala Province, Thailand. A polyphasic study was carried out to establish the taxonomic position of these strains. Morphological and chemotaxonomic characteristics of these strains coincided with those of the genus Micromonospora. Phylogenetic analysis using 16S rRNA gene sequences also indicated that these strains should be classified in the genus Micromonospora and clearly separated from their closest relative, Micromonospora nigra DSM 43818T. Furthermore, a combination of DNA–DNA hybridization results and physiological and biochemical properties indicated that these strains were distinguished from all recognized Micromonospora species. These strains therefore represent a novel species, for which the name Micromonospora eburnea sp. nov. is proposed. The type strain is LK2-10T (=JCM 12345T=PCU 238T=DSM 44814T=TISTR 1531T).

[Study on cloning of sisomicin-resistant gene (sisR) from Micromonospora inyoensis]

A new sisomicin resistance gene sisR was cloned from sisomicin-producing Micromonospora inyoensis. The sisR fragment was obtained by PCR amplification. The primer pairs were designed based on grm gene sequence from gentamicin-producing Micromonospora purpurea. The template DNA was isolated from Micromonospora inyoensis. A series of different DNA fragments were amplified by PCR, which were sub-cloned to vector pUC19 for further identification. It was found that five specific transformants containing target DNA fragments could resist high concentrations of sisomicin (over 1000 microg/mL sisomicin). One of them designated as sisR, was then sequenced and the alignment among sisR and other related genes showed that sisR gene differs from any known genes. It was concluded that sisR gene is a sequence that has not been reported so far.

Differentiation of Micromonospora isolates from a coastal sediment in Wales on the basis of Fourier transform infrared spectroscopy, 16S rRNA sequence analysis, and the amplified fragment length polymorphism technique

A number of actinomycetes isolates were recovered from coastal sediments in Aberystwyth (Wales, United Kingdom) with standard isolation techniques. Most of them were putatively assigned to the genera Streptomyces and Micromonospora on the basis of their morphological characteristics, and there appeared to be no difference whether the isolation media contained distilled water or seawater. A group of 20 Micromonospora isolates was selected to undergo further polyphasic taxonomic investigation. Three approaches were used to analyze the diversity of these isolates, 16S rDNA sequencing, fluorescent amplified fragment length polymorphism (AFLP), and Fourier transform infrared spectroscopy (FT-IR). The 16S rDNA sequence analysis confirmed that all of these isolates should be classified to the genus Micromonospora, and they were analyzed with a group of other Micromonospora 16S rDNA sequences available from the Ribosomal Database Project. The relationships of the 20 isolates were observed after hierarchical clustering, and almost identical clusters were obtained with these three techniques. This has obvious implications for high-throughput screening for novel actinomycetes because FT-IR spectroscopy, which is a rapid and reliable whole-organism fingerprinting method, can be applied as a very useful dereplication tool to indicate which environmental isolates have been cultured previously.

An approach for cloning biosynthetic genes of 2-deoxystreptamine-containing aminocyclitol antibiotics: isolation of a biosynthetic gene cluster of tobramycin from Streptomyces tenebrarius

Genes homologous to 2-deoxystreptamine (DOS) biosynthetic genes were isolated from aminoglycoside producers, Micromonospora and Streptomyces spp., using PCR primers based on the core sequences of 2-deoxy-scyllo-inosose (DOI) synthase and L-glutamine: scyllo-inosose aminotransferase (GIA). Identities of 40-45% were observed for DOI synthases, and 65-75% were observed for GIAs. The gene cluster of tobramycin biosynthesis was isolated from the genomic library of Streptomyces tenebrarius using DOI synthase as a probe. Sequencing of 33.9 kb revealed 24 putative open reading frames including the tobramycin biosynthetic gene cluster (13.8 kb) and a transport protein. This cluster encodes proteins homologous to 2-deoxystreptamine biosynthetic enzymes, glycosyltransferase and other aminocyclitols biosynthetic enzymes. Sequence analysis revealed the evolution of DOI synthases from 3-dehydroquinate (DHQ) synthases in actinomycetes. DOI synthases and GIA are therefore useful for cloning biosynthetic genes of DOS-containing aminocyclitol antibiotics or for screening such metabolites producers.

Molecular cloning and characterization of a 2-deoxystreptamine biosynthetic gene cluster in gentamicin-producing Micromonospora echinospora ATCC15835

The organization of the 2-deoxystreptamine (DOS) biosynthetic gene cluster of Micromonospora echinospora has been determined. Sequencing of a 14.04 kb-region revealed twelve open reading frames (ORFs): four putative DOS biosynthetic genes (gtmA, B, C, and D), five amino sugars biosynthetic genes (gtmE, G, H, I, and gacB), two aminoglycoside resistance genes (gtmF and J) as well as a hypothetical ORF (gacA). One of the putative DOS biosynthetic genes, gtmA, was expressed in Escherichia coli, and the purified protein was shown to convert glucose-6-phosphate (G-6-P) to 2-deoxy-scyllo-inosose (DOI), a key step in DOS biosynthesis. In addition gtmJ was expressed in Streptomyces lividans and shown to confer gentamicin resistance. Thus gtmA and gtmJ are implicated in the biosynthesis of gentamicin and in resistance to it, respectively.

Gene Cluster in Micromonospora echinospora ATCC15835 for the Biosynthesis of the Gentamicin C Complex

Gentamicin is a 4,6-disubstituted aminocyclitol antibiotic complex synthesised by some members of the actinomycete genus Micromonospora. In a search for the gentamicin biosynthetic gene cluster we identified, using a cosmid library approach, a region of the M. echinospora ATCC15835 chromosome that encodes homologues of aminoglycoside biosynthesis genes including gntB-a close homologue of the 2-deoxy-scyllo-inosose synthase gene (btrC) from butirosin-producing Bacillus circulans. Insertional inactivation was achieved by homologous recombination with an internal gntB fragment-containing suicide plasmid, delivered by conjugal transfer from Escherichia coli. gntB disruptants were gentamicin nonproducing mutants as assayed by an ELISA antibiotic detection system, proving the association of gntB (or a downstream region) with gentamicin biosynthesis. The function of some open reading frames within the cluster, predicted by nucleotide database homology searching, is discussed with regards to their potential roles in gentamicin biosynthesis. The discovery of this genetic region represents the first report of a gene cluster involved in the biosynthesis of a 4,6-disubstituted aminocyclitol antibiotic.

Cryptoendolithic Actinomycetes from Antarctic Sandstone Rock Samples: Micromonospora endolithica sp. nov. and two Isolates Related to Micromonospora coerulea Jensen 1932

Three cryptoendolithic, aerobic actinomycetes (AA-459T, AA-319 and AA-321) from antarctic sandstone were characterised phenotypically and by molecular taxonomic methods. The isolates had single spores on substrate mycelium, meso-diaminopimelic acid (m-DAP) and glycine (cell wall type II), a whole cell sugar pattern D (galactose, xylose, arabinose, glucose or rhamnose) and phospholipids of type PII (diphosphatidylglycerol, phosphatidylethanolamine, phosphatidylinositol). Their predominant fatty acids were iso-16:0 and iso-15:0 or 17:1omega8c, the menaquinone profile was complex with mainly MK10 (H4) and MK10 (H6). A wide variety of sugars and several acids were utilised for growth. The isolates were sensitive to a few antibiotics, but formation and excretion of antibiotics was not observed. Phenotypically, isolates AA-319 and AA-321 were similar. Phylogenetic analysis of 16S rRNA gene sequences revealed close relationship of strains AA-319 and AA-321 with each other (99.5%) and clustering (98.5%) with Micromonospora coerulea DSM 43143T. DNA-DNA hybridisation showed both strains to be genomically highly similar to strain DSM 43143T. Phenotypically they could be viewed as separate taxa, but presently they will be considered as strains of Micromonospora coerulea. Strain AA-459T was phylogenetically close to Micromonospora chersina DSM 44151T (99.1%) and to Micromonospora rosaria DSM 803T, but DNA-DNA similarity with M. chersina DSM 44151T was low with 28.9/33.5 %, indicating the presence of a different and new species. Consequently, isolate AA-459T (DSM 44398T NRRL B-24248T) is described as the type strain of Micromonospora endolithica sp. nov.