Comparative Genomics of Four Isosphaeraceae Planctomycetes: A Common Pool of Plasmids and Glycoside Hydrolase Genes Shared by Paludisphaera borealis PX4T, Isosphaera pallida IS1BT, Singulisphaera acidiphila DSM 18658T, and Strain SH-PL62

Ivanova, Anastasia A.; Naumoff, D. G.; Miroshnikov, Kirill K.; Liesack, Werner; Dedysh, Svetlana N.

doi:10.3389/fmicb.2017.00412

Cited by 46 publications

(34 citation statements)

References 70 publications

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“…However, Planctomycetes have recently been recognized as important producers of bioactive compounds by both in silico genome mining analyses and molecular screening approaches. These analyses revealed the presence of genes related to various pathways for the production of several bioactive molecules, including some antitumor compounds like epothilone (Donadio et al, 2007;Graça et al, 2013;Wang et al, 2014;Graça et al, 2016;Ivanova et al, 2017;Vollmers et al, 2017). It is therefore very promising that several of our Planctomycetes strains isolated from various ecosystems showed significant cytotoxic activity toward the MOLM-13 cells and the human prostatic PC3 cells.…”

Section: Discussionmentioning

confidence: 99%

Anticancer Activity in Planctomycetes

et al. 2019

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There is a strong need to develop new drugs against many severe diseases. Therapy resistance is a major problem, for instance, in infectious diseases and cancer. Drug discovery has again turned to nature to search for molecules that can become drug leads. Although many bacterial phyla are extensively studied, some, like the Planctomycetes, remain largely unexplored as potential sources of new leads. Planctomycetes form a diverse group of bacteria with peculiar characteristics such as division by polar budding and absence of the FtsZ gene. Furthermore, they exhibit large genomes up to 12.5 Mb, and possess a high number of secondary metabolites as assessed by in silico genomic analysis. These characteristics have also revealed the presence of potential anticancer activity. Based on these promising characteristics, we wanted to investigate Planctomycetes as a source for natural products with anticancer properties. Organic and aqueous extracts were obtained from cultivated Planctomycetes strains originated from a variety of habitats such as marine systems (free living or attached to marine algae), deep marine iron hydroxide deposits, brackish water and glacier ice system. The extracts were screened for ability to inhibit cell growth, or induce cell death on two cancer cell lines, the human prostatic cancer cell line PC3, and human acute myeloid leukaemia (AML) cell line MOLM-13, as well as normal rat kidney epithelial cell line (NRK). Out of 39 strains, five exhibited cytotoxicity toward NRK cells, whereas 32 of the strains were toxic to the AML cell line, and four were toxic to the PC3 cell line. Two strains showed high toxicity and selectivity toward both the cancer cell lines over the NRK-cells, and are potential producers of anti-cancer compounds. We found no correlation between bioactivity and strains habitat and geographic location but regarding phylogeny some Rhodopirellula spp. showed higher toxicity toward MOLM-13 cells. These results from the first anticancer screening with Planctomycetes showed that these peculiar microorganisms should be further explored for anti-cancer compounds, and that more effort must be put in providing culture collections for drug development purposes.

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Section: Discussionmentioning

confidence: 99%

Anticancer Activity in Planctomycetes

et al. 2019

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“…Recently, the gene encoding the key enzyme for synthesis of N-methylated phosphorus-free ornithine membrane lipids, N-methyltransferase (OlsG), was identified in the genome of Singulisphaera acidiphila DSM 18658 T (Sinac_1600) (24) and later detected in genomes of other members of the family Isosphaeraceae (11). Our analysis revealed that distant homologs of Sinac_1600 are also present in the genomes of Gemmataceae planctomycetes, including F. ruber SP5 T , Zavarzinella formosa A10 T , and Gemmata sp.…”

Section: Chitin As a Source Of C Chitin As A Source Of Nmentioning

confidence: 99%

“…Members of the family Isosphaeraceae are especially abundant in boreal peatlands (9,10). As revealed by recent comparative genomic analysis, these peat-inhabiting planctomycetes possess extremely high but partly hidden glycolytic potential (11) and are capable of degrading various heteropolysaccharides. The ability to degrade fibrous and microcrystalline cellulose, however, has so far been demonstrated only for a single, peat-inhabiting planctomycete from the family Gemmataceae, Telmatocola sphagniphila (12).…”

mentioning

confidence: 99%

Genome Analysis of Fimbriiglobus ruber SP5 ^T , a Planctomycete with Confirmed Chitinolytic Capability

Ravin

Rakitin

Ivanova

et al. 2018

Appl Environ Microbiol

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Members of the bacterial order have often been observed in associations with Crustacea. The ability to degrade chitin, however, has never been reported for any of the cultured planctomycetes although utilization of-acetylglucosamine (GlcNAc) as a sole carbon and nitrogen source is well recognized for these bacteria. Here, we demonstrate the chitinolytic capability of a member of the family , SP5, which was isolated from a peat bog. As revealed by metatranscriptomic analysis of chitin-amended peat, the pool of 16S rRNA reads from increased in response to chitin availability. Strain SP5 displayed only weak growth on amorphous chitin as a sole source of carbon but grew well with chitin as a source of nitrogen. The genome of SP5 is 12.364 Mb in size and is the largest among all currently determined planctomycete genomes. It encodes several enzymes putatively involved in chitin degradation, including two chitinases affiliated with the glycoside hydrolase (GH) family GH18, GH20 family β--acetylglucosaminidase, and the complete set of enzymes required for utilization of GlcNAc. The gene encoding one of the predicted chitinases was expressed in , and the endochitinase activity of the recombinant enzyme was confirmed. The genome also contains genes required for the assembly of type IV pili, which may be used to adhere to chitin and possibly other biopolymers. The ability to use chitin as a source of nitrogen is of special importance for planctomycetes that inhabit N-depleted ombrotrophic wetlands. Planctomycetes represent an important part of the microbial community in -dominated peatlands, but their potential functions in these ecosystems remain poorly understood. This study reports the presence of chitinolytic potential in one of the recently described peat-inhabiting members of the family, SP5 This planctomycete uses chitin, a major constituent of fungal cell walls and exoskeletons of peat-inhabiting arthropods, as a source of nitrogen in N-depleted ombrotrophic -dominated peatlands. This study reports the chitin-degrading capability of representatives of the order.

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“…Members of the order Phycisphaerales and genus Zavarzinella also responded to xylan, while group WD2101 were responsive to cellulose and chitin. Another study by Ivanova et al (2017b) further supported the high glycolytic potential of Planctomycetes. In that study, a comparative genomic analysis of 4 members of the family Isosphaeraceae, namely Isosphaera pallida, Singulisphaera acidiphila, Paludisphaera borealis and the uncharacterized strain SH-PL62S, identified several CAZYmes from major families (GH5, GH13, GH57) as well as potential α-mannosidase, α-rhamnosidase and glucuronyl hydrolase activities.…”

Section: Alpha and Beta Diversitymentioning

confidence: 84%

“…The most abundant bacterial genus in the "heavy" fraction, Singulisphaera, had mostly positive connections, especially with other groups of Planctomycetes, Actinobacteria and Verrucomicrobia, suggesting potential cooperation for metabolizing WH15EPS. Several studies demonstrate that those groups of bacteria have glycolytic and detoxifying capacities, producing several enzymes that could be involved in the degradation of the EPS and resource sharing (Martinez-Garcia et al, 2012;Uhlik et al, 2012;Ivanova et al, 2017b). In addition, no direct correlation was found between Singulisphaera and the EPS producer Granulicella, which suggests that the metabolism of WH15EPS by Singulisphaera and enrichment of the genus did not negatively impact the abundance of Granulicella.…”

Section: Co-occurrence and Active Potential Interactionsmentioning

confidence: 99%

Dynamics of active potential bacterial and fungal interactions in the assimilation of acidobacterial EPS in soil

Costa

Pijl

Kuramae

2020

Soil Biology and Biochemistry

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Acidobacteria are one of the most abundant and ubiquitous bacterial phyla in soil, but the mechanisms underpinning their ecological success remain unknown. Acidobacteria produce copious amounts of extracellular polymeric substances (EPS) with unique sugar composition that can be used as a nutrient source for other microorganisms. Here, we investigated the assembly and potential interactions of the active bacterial and fungal communities in soil treated with the EPS of the Acidobacteria Granulicella sp. strain WH15 (WH15EPS) as a carbon source by the stable isotope probing (SIP) approach during a 35-day period. WH15EPS was mainly assimilated by Planctomycetes, Verrucomicrobia, Ascomycota and Basidiomycota and analysis suggested overall relationships between the kingdoms. Our study revealed active potential interactions between microorganisms in their natural habitat. In addition, the structure of the co-occurrence network of active microorganisms able to metabolize WH15EPS differed from those of the control treatments, demonstrating that hidden potential interactions can be unraveled by more specific and targeted metabolism studies.

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Comparative Genomics of Four Isosphaeraceae Planctomycetes: A Common Pool of Plasmids and Glycoside Hydrolase Genes Shared by Paludisphaera borealis PX4T, Isosphaera pallida IS1BT, Singulisphaera acidiphila DSM 18658T, and Strain SH-PL62

Cited by 46 publications

References 70 publications

Anticancer Activity in Planctomycetes

Anticancer Activity in Planctomycetes

Genome Analysis of Fimbriiglobus ruber SP5 ^T , a Planctomycete with Confirmed Chitinolytic Capability

Dynamics of active potential bacterial and fungal interactions in the assimilation of acidobacterial EPS in soil

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Comparative Genomics of Four Isosphaeraceae Planctomycetes: A Common Pool of Plasmids and Glycoside Hydrolase Genes Shared by Paludisphaera borealis PX4T, Isosphaera pallida IS1BT, Singulisphaera acidiphila DSM 18658T, and Strain SH-PL62

Cited by 46 publications

References 70 publications

Anticancer Activity in Planctomycetes

Anticancer Activity in Planctomycetes

Genome Analysis of Fimbriiglobus ruber SP5 T , a Planctomycete with Confirmed Chitinolytic Capability

Dynamics of active potential bacterial and fungal interactions in the assimilation of acidobacterial EPS in soil

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Genome Analysis of Fimbriiglobus ruber SP5 ^T , a Planctomycete with Confirmed Chitinolytic Capability