Your search keyword '"SeqCode"' showing total 33 results

1. Elusive marine Verrucomicrobiota: Seasonally abundant members of the novel genera Seribacter and Chordibacter specialize in degrading sulfated glycans

Author

Wilkie, Isabella and Orellana, Luis H.

Published

2025

2. Acidimicrobiia, the actinomycetota of coastal marine sediments: Abundance, taxonomy and genomic potential

Author

Silva-Solar, Sebastián, Viver, Tomeu, Wang, Yueqing, Orellana, Luis H., Knittel, Katrin, and Amann, Rudolf

Published

2024

3. Options and considerations for validation of prokaryotic names under the SeqCode

Author

Venter, Stephanus N., Rodriguez-R, Luis M., Chuvochina, Maria, Palmer, Marike, Hugenholtz, Philip, and Steenkamp, Emma T.

Published

2024

4. Тaxonomy of Cyanobacteria: The Era of Change.

Author

Pinevich, A. V. and Averina, S. G.

Subjects

*CYANOBACTERIA, *CELL nuclei, *MOLECULAR phylogeny, *DNA sequencing, *MICROBIOLOGY

Abstract

Until mid-1970s, cyanobacteria have been interpreted as algae despite they differed from other members of this taxonomic group by the absence of cell nucleus (that is currently considered among the characters of prokaryotic organization). However, when bacteria were interpreted as prokaryotes, blue-green algae became reattributed as cyanobacteria, and bacteriologists began to study their cultured strains with microbiology methods. But since these objects did not obey the provisions of bacteriological code (ICNB), development of their taxonomy had certain problems, especially regarding nomenclature, that could not be solved until early-2010s. Current changes in taxonomy of cyanobacteria result from the general progress in taxonomy of prokaryotes due to explosive accumulation of 16S rRNA gene sequencing data, particularly for uncultured objects. Advances in description of new cyanobacteral taxa are as follows: (I) based on polyphasic approach, new taxa ranging from species to order were published; (II) "dark" cyanobacteria demonstrating several types of non-photosynthetic metabolism were described; I(II) strains producing red-shifted chlorophylls d and f were published. Advances in nomenclature of cyanobacteria are: (IV) taxa validly published according to botanical code (ICN) are also considered valid under prokaryotic code (ICNP); (V) the category of phylum was introduced into ICNP, and due to valid publication of the type genus Cyanobacterium, phylum name Cyanobacteriota became legitimate; (VI) names of uncultured Candidatus objects could get a standing in nomenclature based on SeqCode in which type material is represented by genomic DNA sequences. Advances in classification of cyanobacteria are: (VII) evolutionary tree of oxygenic phototrophs and related phylotypes was construed; (VIII) phylogenomic system of orders and families was elaborated; (IX) ecogenomic system combining genomie analysis with genome distribution data was offered. A subject for future research is restriction of taxonomic redundancy in cyanobacteria, and further attempts to establish their species concept. [ABSTRACT FROM AUTHOR]

Published

2024

5. SeqCode: A Nomenclatural Code for Prokaryotes.

Author

Lata, Pushp, Bhargava, Vatsal, Gupta, Sonal, Singh, Ajaib, Bala, Kiran, and Lal, Rup

Subjects

*PROKARYOTES, *FACILITATED communication, *METADATA, *GENOMES, *MICROORGANISMS

Abstract

SeqCode is a nomenclatural code for naming prokaryotes based on genetic information. With the majority of prokaryotes being inaccessible as pure cultures, they are not eligible for naming under the International Code of Nomenclature of Prokaryotes. To address this challenge, a new concept that is SeqCode, which assign names to prokaryotes on the basis of genome sequence, has been announced in 2022. The valid publication of names for prokaryotes based on isolated genome, metagenome-assembled genomes, or single-amplified genome sequences. It operates through a registration portal, SeqCode Registry, where metadata is linked to names and nomenclatural types. This code provides a framework for reproducible nomenclature for all prokaryotes, either culturable or not and facilitates communication across all microbiological disciplines. Additionally, the SeqCode includes provisions for updating and revising names as new data becomes available. By providing a standardized system for naming and classifying these microorganisms based on their genetic information, the SeqCode will facilitate the discovery, understanding and comparison of these microorganisms, helping us to understand their role in the environment and how they contribute to the functioning of the Earth. [ABSTRACT FROM AUTHOR]

Published

2024

6. Use of gene sequences as type for naming prokaryotes: Recommendations of the international committee on the taxonomy of chlamydiae.

Author

Greub, Gilbert, Pillonel, Trestan, Bavoil, Patrik M, Borel, Nicole, Campbell, Lee Ann, Dean, Deborah, Hefty, Scott, Horn, Matthias, Morré, Servaas A, Ouellette, Scot P, Pannekoek, Yvonne, Puolakkainen, Mirja, Timms, Peter, Valdivia, Raphael, and Vanrompay, Daisy

Subjects

Chlamydia, Chlamydiales, Intracellular bacteria, SeqCode, Taxogenomics, Microbiology, Clinical Sciences

Abstract

The International Committee on Systematics of Prokaryotes (ICSP) discussed and rejected in 2020 a proposal to modify the International Code of Nomenclature of Prokaryotes to allow the use of gene sequences as type for naming prokaryotes. An alternative nomenclatural code, the Code of Nomenclature of Prokaryotes Described from Sequence Data (SeqCode), which considers genome sequences as type material for naming species, was published in 2022. Members of the ICSP subcommittee for the taxonomy of the phylum Chlamydiae (Chlamydiota) consider that the use of gene sequences as type would benefit the taxonomy of microorganisms that are difficult to culture such as the chlamydiae and other strictly intracellular bacteria. We recommend the registration of new names of uncultured prokaryotes in the SeqCode registry.

Published

2023

7. Description and Naming of Candidatus Taxa

Author

Oren, Aharon, Li, Wen-Jun, editor, Jiao, Jian-yu, editor, Salam, Nimaichand, editor, and Rao, Manik Prabhu Narsing, editor

Published

2024

8. Technologies Promoting Genome-Based Taxonomy

Author

Rekadwad, Bhagwan Narayan, Lian, Zheng-Han, Jiao, Jian-Yu, Li, Wen-Jun, Li, Wen-Jun, editor, Jiao, Jian-yu, editor, Salam, Nimaichand, editor, and Rao, Manik Prabhu Narsing, editor

Published

2024

9. Taxonomic Approaches for Uncultivated Prokaryotes

Author

Rekadwad, Bhagwan Narayan, Li, Wen-Jun, editor, Jiao, Jian-yu, editor, Salam, Nimaichand, editor, and Rao, Manik Prabhu Narsing, editor

Published

2024

10. Why and how to use the SeqCode

Author

William B. Whitman, Maria Chuvochina, Brian P. Hedlund, Konstantinos T. Konstantinidis, Marike Palmer, Luis M. Rodriguez‐R, Iain Sutcliffe, and Fengping Wang

Subjects

genome sequences, metagenome‐assembled genomes, nomenclature, SeqCode, Microbiology, QR1-502

Abstract

Abstract The SeqCode, formally called the Code of Nomenclature of Prokaryotes Described from Sequence Data, is a new code of nomenclature in which genome sequences are the nomenclatural types for the names of prokaryotic species. While similar to the International Code of Nomenclature of Prokaryotes (ICNP) in structure and rules of priority, it does not require the deposition of type strains in international culture collections. Thus, it allows for the formation of permanent names for uncultured prokaryotes whose nearly complete genome sequences have been obtained directly from environmental DNA as well as other prokaryotes that cannot be deposited in culture collections. Because the diversity of uncultured prokaryotes greatly exceeds that of readily culturable prokaryotes, the SeqCode is the only code suitable for naming the majority of prokaryotic species. The start date of the SeqCode was January 1, 2022, and the online Registry (https://seqco.de/) was created to ensure valid publication of names. The SeqCode recognizes all names validly published under the ICNP before 2022. After that date, names validly published under the SeqCode compete with ICNP names for priority. As a result, species can have only one name, either from the SeqCode or ICNP, enabling effective communication and the creation of unified taxonomies of uncultured and cultured prokaryotes. The SeqCode is administered by the SeqCode Committee, which is comprised of the SeqCode Community and elected administrative components. Anyone with an interest in the systematics of prokaryotes is encouraged to join the SeqCode Community and participate in the development of this resource.

Published

2024

11. Metagenome-assembled genomes reveal greatly expanded taxonomic and functional diversification of the abundant marine Roseobacter RCA cluster

Author

Yanting Liu, Thorsten Brinkhoff, Martine Berger, Anja Poehlein, Sonja Voget, Lucas Paoli, Shinichi Sunagawa, Rudolf Amann, and Meinhard Simon

Subjects

RCA cluster, Roseobacteraceae, Rhodobacteraceae, Metagenome-assembled genomes, SeqCode, Phylogenomics, Microbial ecology, QR100-130

Abstract

Abstract Background The RCA (Roseobacter clade affiliated) cluster belongs to the family Roseobacteracea and represents a major Roseobacter lineage in temperate to polar oceans. Despite its prevalence and abundance, only a few genomes and one described species, Planktomarina temperata, exist. To gain more insights into our limited understanding of this cluster and its taxonomic and functional diversity and biogeography, we screened metagenomic datasets from the global oceans and reconstructed metagenome-assembled genomes (MAG) affiliated to this cluster. Results The total of 82 MAGs, plus five genomes of isolates, reveal an unexpected diversity and novel insights into the genomic features, the functional diversity, and greatly refined biogeographic patterns of the RCA cluster. This cluster is subdivided into three genera: Planktomarina, Pseudoplanktomarina, and the most deeply branching Candidatus Paraplanktomarina. Six of the eight Planktomarina species have larger genome sizes (2.44–3.12 Mbp) and higher G + C contents (46.36–53.70%) than the four Pseudoplanktomarina species (2.26–2.72 Mbp, 42.22–43.72 G + C%). Cand. Paraplanktomarina is represented only by one species with a genome size of 2.40 Mbp and a G + C content of 45.85%. Three novel species of the genera Planktomarina and Pseudoplanktomarina are validly described according to the SeqCode nomenclature for prokaryotic genomes. Aerobic anoxygenic photosynthesis (AAP) is encoded in three Planktomarina species. Unexpectedly, proteorhodopsin (PR) is encoded in the other Planktomarina and all Pseudoplanktomarina species, suggesting that this light-driven proton pump is the most important mode of acquiring complementary energy of the RCA cluster. The Pseudoplanktomarina species exhibit differences in functional traits compared to Planktomarina species and adaptations to more resource-limited conditions. An assessment of the global biogeography of the different species greatly expands the range of occurrence and shows that the different species exhibit distinct biogeographic patterns. They partially reflect the genomic features of the species. Conclusions Our detailed MAG-based analyses shed new light on the diversification, environmental adaptation, and global biogeography of a major lineage of pelagic bacteria. The taxonomic delineation and validation by the SeqCode nomenclature of prominent genera and species of the RCA cluster may be a promising way for a refined taxonomic identification of major prokaryotic lineages and sublineages in marine and other prokaryotic communities assessed by metagenomics approaches. Video Abstract

Published

2023

12. Metagenome-assembled genomes reveal greatly expanded taxonomic and functional diversification of the abundant marine Roseobacter RCA cluster.

Author

Liu, Yanting, Brinkhoff, Thorsten, Berger, Martine, Poehlein, Anja, Voget, Sonja, Paoli, Lucas, Sunagawa, Shinichi, Amann, Rudolf, and Simon, Meinhard

Subjects

METAGENOMICS, PROKARYOTIC genomes, GENOMES, GENOME size, HORIZONTAL gene transfer, BIOGEOGRAPHY

Abstract

Background: The RCA (Roseobacter clade affiliated) cluster belongs to the family Roseobacteracea and represents a major Roseobacter lineage in temperate to polar oceans. Despite its prevalence and abundance, only a few genomes and one described species, Planktomarina temperata, exist. To gain more insights into our limited understanding of this cluster and its taxonomic and functional diversity and biogeography, we screened metagenomic datasets from the global oceans and reconstructed metagenome-assembled genomes (MAG) affiliated to this cluster. Results: The total of 82 MAGs, plus five genomes of isolates, reveal an unexpected diversity and novel insights into the genomic features, the functional diversity, and greatly refined biogeographic patterns of the RCA cluster. This cluster is subdivided into three genera: Planktomarina, Pseudoplanktomarina, and the most deeply branching Candidatus Paraplanktomarina. Six of the eight Planktomarina species have larger genome sizes (2.44–3.12 Mbp) and higher G + C contents (46.36–53.70%) than the four Pseudoplanktomarina species (2.26–2.72 Mbp, 42.22–43.72 G + C%). Cand. Paraplanktomarina is represented only by one species with a genome size of 2.40 Mbp and a G + C content of 45.85%. Three novel species of the genera Planktomarina and Pseudoplanktomarina are validly described according to the SeqCode nomenclature for prokaryotic genomes. Aerobic anoxygenic photosynthesis (AAP) is encoded in three Planktomarina species. Unexpectedly, proteorhodopsin (PR) is encoded in the other Planktomarina and all Pseudoplanktomarina species, suggesting that this light-driven proton pump is the most important mode of acquiring complementary energy of the RCA cluster. The Pseudoplanktomarina species exhibit differences in functional traits compared to Planktomarina species and adaptations to more resource-limited conditions. An assessment of the global biogeography of the different species greatly expands the range of occurrence and shows that the different species exhibit distinct biogeographic patterns. They partially reflect the genomic features of the species. Conclusions: Our detailed MAG-based analyses shed new light on the diversification, environmental adaptation, and global biogeography of a major lineage of pelagic bacteria. The taxonomic delineation and validation by the SeqCode nomenclature of prominent genera and species of the RCA cluster may be a promising way for a refined taxonomic identification of major prokaryotic lineages and sublineages in marine and other prokaryotic communities assessed by metagenomics approaches. 4nWA41D1uUohyPVze8XWvD Video Abstract [ABSTRACT FROM AUTHOR]

Published

2023

13. Use of gene sequences as type for naming prokaryotes: Recommendations of the international committee on the taxonomy of chlamydiae

Author

Gilbert Greub, Trestan Pillonel, Patrik M. Bavoil, Nicole Borel, Lee Ann Campbell, Deborah Dean, Scott Hefty, Matthias Horn, Servaas A. Morré, Scot P. Ouellette, Yvonne Pannekoek, Mirja Puolakkainen, Peter Timms, Raphael Valdivia, and Daisy Vanrompay

Subjects

SeqCode, Taxogenomics, Chlamydiales, Intracellular bacteria, Chlamydia, Infectious and parasitic diseases, RC109-216

Abstract

The International Committee on Systematics of Prokaryotes (ICSP) discussed and rejected in 2020 a proposal to modify the International Code of Nomenclature of Prokaryotes to allow the use of gene sequences as type for naming prokaryotes. An alternative nomenclatural code, the Code of Nomenclature of Prokaryotes Described from Sequence Data (SeqCode), which considers genome sequences as type material for naming species, was published in 2022. Members of the ICSP subcommittee for the taxonomy of the phylum Chlamydiae (Chlamydiota) consider that the use of gene sequences as type would benefit the taxonomy of microorganisms that are difficult to culture such as the chlamydiae and other strictly intracellular bacteria. We recommend the registration of new names of uncultured prokaryotes in the SeqCode registry.

Published

2023

14. Naming new taxa of prokaryotes in the 21st century.

Author

Oren, Aharon

Subjects

*TWENTY-first century, *QUALITY control, *ARCHAEBACTERIA, *METAGENOMICS, *CANDIDATUS

Abstract

The nomenclature of prokaryotes is regulated by the rules of the International Code of Nomenclature of Prokaryotes (ICNP) and is based on the Linnaean binomial system. The current rules of the Code only cover the nomenclature of the cultivated minority. Proposals to incorporate the uncultivated majority of bacteria and archaea under the rules of the Code were recently rejected by the International Committee on Systematics of Prokaryotes. The provisional rank of Candidatus can be used to name uncultivated prokaryotes whose names cannot be validly published under the rules of the ICNP, but their names can now be validated under the Code of Nomenclature of Prokaryotes Described from Sequence Data (the SeqCode), which was recently established to cover the nomenclature of the uncultivated majority. Metagenomics, single-cell genomics, and high-throughput cultivation techniques have led to a flood of new organisms currently waiting to be named. Automated programs such as GAN and Protologger can assist researchers in naming and describing newly discovered prokaryotes, cultivated as well as uncultivated. However, Latin and Greek skills remain indispensable for proper quality control of names that must meet the standards set by the codes of nomenclature. [ABSTRACT FROM AUTHOR]

Published

2023

15. Proposal of names for 329 higher rank taxa defined in the Genome Taxonomy Database under two prokaryotic codes.

Author

Chuvochina, Maria, Mussig, Aaron J, Chaumeil, Pierre-Alain, Skarshewski, Adam, Rinke, Christian, Parks, Donovan H, and Hugenholtz, Philip

Subjects

*DATABASES, *TAXONOMY, *GENOMES, *CANDIDATUS, *CLASSIFICATION

Abstract

The Genome Taxonomy Database (GTDB) is a taxonomic framework that defines prokaryotic taxa as monophyletic groups in concatenated protein reference trees according to systematic criteria. This has resulted in a substantial number of changes to existing classifications (https://gtdb.ecogenomic.org). In the case of union of taxa, GTDB names were applied based on the priority of publication. The division of taxa or change in rank led to the formation of new Latin names above the rank of genus that were only made publicly available via the GTDB website without associated published taxonomic descriptions. This has sometimes led to confusion in the literature and databases. A number of the provisional GTDB names were later published in other studies, while many still lack authorships. To reduce further confusion, here we propose names and descriptions for 329 GTDB-defined prokaryotic taxa, 223 of which are suitable for validation under the International Code of Nomenclature of Prokaryotes (ICNP) and 49 under the Code of Nomenclature of Prokaryotes described from Sequence Data (SeqCode). For the latter, we designated 23 genomes as type material. An additional 57 taxa that do not currently satisfy the validation criteria of either code are proposed as Candidatus. [ABSTRACT FROM AUTHOR]

Published

2023

16. Description of Asgardarchaeum abyssi gen. nov. spec. nov., a novel species within the class Asgardarchaeia and phylum Asgardarchaeota in accordance with the SeqCode

Author

Tamarit, Daniel, Köstlbacher, Stephan, Appler, Kathryn E., Panagiotou, Kassiani, De Anda, Valerie, Rinke, Christian, Baker, Brett J., Ettema, Thijs J.G., Tamarit, Daniel, Köstlbacher, Stephan, Appler, Kathryn E., Panagiotou, Kassiani, De Anda, Valerie, Rinke, Christian, Baker, Brett J., and Ettema, Thijs J.G.

Abstract

Asgardarchaeota, commonly referred to as Asgard archaea, is a candidatus phylum-rank archaeal clade that includes the closest archaeal relatives of eukaryotes. Despite their prevalence in the scientific literature, the name Asgardarchaeota lacks nomenclatural validation. Here, we describe a novel high-quality metagenome-assembled genome (MAG), AB3033_2TS, proposed to serve as the nomenclatural type for the species Asgardarchaeum abyssiTS according to the rules of the SeqCode. Based on protein content and compositional features, we infer that A. abyssi AB3033_2TS is an acetogenic chemoheterotroph, possibly a facultative lithoautotroph, and is adapted to a thermophilic lifestyle. Utilizing genomes from Asgard archaea, TACK, and Euryarchaea, we perform phylogenomic reconstructions using the GTDB archaeal marker genes, the current reference set for taxonomic classification. Calibrating relative evolutionary divergence (RED) values for Asgardarchaeota using established Thermoproteota lineages in the GTDB r207 reference tree, we establish a robust classification and propose Asgardarchaeum as the type genus for the family Asgardarchaeaceae (fam. nov)., the order Asgardarchaeales (ord. nov.), the class Asgardarchaeia (class. nov.), and the phylum Asgardarchaeota (phyl. nov.). This effort aims to preserve taxonomic congruence in the scientific literature.

Published

2024

17. Metagenomics of two aquifers with thermal anomalies in Mallorca Island, and proposal of new uncultivated taxa named following the rules of SeqCode

Author

Deep Blue Sea Enterprise, Agencia Estatal de Investigación (España), Ministerio de Ciencia, Innovación y Universidades (España), Ministerio de Ciencia e Innovación (España), European Commission, Universitat de les Illes Balears, Viver, Tomeu [0000-0001-8868-9292], Urdiain, Mercedes [0000-0001-6834-0237], Rosselló-Mora, Ramón [0000-0001-8253-3107], Gago, Juan F., Viver, Tomeu, Urdiain, Mercedes, Ferreira, Elaine, Robledo Ardila, Pedro Agustín, Rosselló-Mora, Ramón, Deep Blue Sea Enterprise, Agencia Estatal de Investigación (España), Ministerio de Ciencia, Innovación y Universidades (España), Ministerio de Ciencia e Innovación (España), European Commission, Universitat de les Illes Balears, Viver, Tomeu [0000-0001-8868-9292], Urdiain, Mercedes [0000-0001-6834-0237], Rosselló-Mora, Ramón [0000-0001-8253-3107], Gago, Juan F., Viver, Tomeu, Urdiain, Mercedes, Ferreira, Elaine, Robledo Ardila, Pedro Agustín, and Rosselló-Mora, Ramón

Abstract

Groundwater offers an intriguing blend of distinctive physical and chemical conditions, constituting a challenge for microbial life. In Mallorca, the largest island of Balearic archipelago, harbours a variety of thermal anomalies (i.e., geothermal manifestation where surface aquifers exhibiting temperatures exceeding the regional average). The metagenomes of two aquifers in the centre and southern of the island showed Pseudomonadota to be the most represented phylum when using extracted 16S rRNA gene sequences. However, the microbial structures within and between aquifers were remarkably diverse but similar in their metabolic profiles as revealed by the metagenome-assembled genomes (MAGs) pointing to a prevalence of aerobic chemolithoautotrophic and heterotrophic metabolisms, especially in the Llucmajor aquifer. Also, some evidences of anaerobic lifestyles were detected, which would indicate that these environments either could suffer episodes of oxygen depletion or the anaerobes had been transported from deeper waters. We believe that the local environmental factors (temperature, external inputs or chemistry) seem to be more relevant than the connection and, eventually, transport of microbial cells within the aquifer in determining the highly divergent structures. Notably, most of the reconstructed genomes belonged to undescribed bacterial lineages and from them two high-quality MAGs could be classified as novel taxa named following the rules of the Code for Nomenclature of Prokaryotes Described from Sequence Data (SeqCode). Accordingly, we propose the new species and genus Costitxia debesea gen. nov., sp. nov., affiliated with the novel family Costitxiaceae fam. nov., order Costitxiales ord. nov. and class Costitxiia class. nov.; and the new new species and genus Lloretia debesea gen. nov. sp. nov. affiliated with the novel family Lloretiaceae fam. nov.

Published

2024

18. Commentary on the proposed Section 10 amendments to the International Code of Nomenclature of Prokaryotes regarding Candidatus names.

Author

Whitman, William B. and Venter, Stephanus N.

Subjects

CANDIDATUS, PLANT-fungus relationships, PHYTOPATHOGENIC fungi, CYANOBACTERIA

Abstract

Amendments were proposed to the International Code of Nomenclature of Prokaryotes (ICNP) in January [Arahal et al. (2024) Int. J Syst. Evol. Microbiol. 74: 006188] that would cause major changes in the treatment of Candidatus names. The amendments introduce Section 10 to name taxa whose names cannot be validly published under the ICNP because of the absence of type strains. This section creates a parallel 'pro-nomenclature' and formalizes alternative material which could serve as nomenclatural types. When conspecific isolates of taxa with Candidatus names are deposited in culture collections as type strains, the names can be validly published, and it is required that the same Candidatus name be used. While the amendments are promoted to provide stable names and rules of nomenclature for uncultivated taxa, the system is deeply flawed. It removes the permanent association between names and types, which will make the meaning of names imprecise and ambiguous. It creates 'pro-nomenclature', which is confusing and unnecessary. Since many taxa which cannot be validly named under the ICNP can already be named under the SeqCode, it duplicates and creates overlap with an established nomenclatural system without providing tangible benefits. As the SeqCode recognizes names formed under the ICNP, the ICNP should recognize names formed under the SeqCode as they have done for the Cyanobacteria named under the International Code of Nomenclature for algae, fungi and plants (ICN). For these reasons, we urge the members of the International Committee of Systematics of Prokaryotes (ICSP) to reject these amendments. [ABSTRACT FROM AUTHOR]

Published

2024

19. The strategy for naming fungal 'dark taxa' may involve a transition period and genomics.

Author

Zhou, Li-Wei

Abstract

Many unnamed fungi have been revealed from DNA sequences but cannot be formally named due to a lack of physical materials required for the description of a taxon by the International Code of Nomenclature for algae, fungi, and plants. While the mycological community generally discusses the necessity to amend the code to permit DNA sequence data as the nomenclatural type of these fungal 'dark taxa' (FDT), the standard of DNA sequences is mainly in debate. Here, I suggest to set an approximate fifteen years transition period. During that time, it is recommended to sequence the whole genomes of all known species and newly published species with available physical materials; meanwhile, the FDT can be provisionally named with priority using whole genome data as the type. After the transition period, these provisionally named FDT will become valid, provided no known species from physical materials with a priority can be proved to be conspecific. Moreover, in this new era of fungal taxonomy when the whole genome data will be commonly used as the crucial evidence to delimit fungal species, new taxa should be named along with the deposition of whole genome sequences in public databases, and the whole genome data may be the type of the FDT. [ABSTRACT FROM AUTHOR]

Published

2024

20. Genomic comparison of deep-sea hydrothermal genera related to Aeropyrum, Thermodiscus and Caldisphaera, and proposed emended description of the family Acidilobaceae.

Author

St. John, Emily and Reysenbach, Anna-Louise

Subjects

HYDROTHERMAL vents, POLYSULFIDES, SUBMARINE volcanoes, BACTERIAL communities, DATABASES, RECOMMENDER systems

Abstract

Deep-sea hydrothermal vents host archaeal and bacterial thermophilic communities, including taxonomically and functionally diverse Thermoproteota. Despite their prevalence in high-temperature submarine communities, Thermoproteota are chronically under-represented in genomic databases and issues have emerged regarding their nomenclature, particularly within the Aeropyrum–Thermodiscus–Caldisphaera. To resolve some of these problems, we identified 47 metagenome-assembled genomes (MAGs) within this clade, from 20 previously published deep-sea hydrothermal vent and submarine volcano metagenomes, and 24 MAGs from public databases. Using phylogenomic analysis, Genome Taxonomy Database Toolkit (GTDB-Tk) taxonomic assessment, 16S rRNA gene phylogeny, average amino acid identity (AAI) and functional gene patterns, we re-evaluated of the taxonomy of the Aeropyrum–Thermodiscus–Caldisphaera. At least nine genus-level clades were identified with two or more MAGs. In accordance with SeqCode requirements and recommendations, we propose names for three novel genera, viz. Tiamatella incendiivivens, Hestiella acidicharens and Calypsonella navitae. A fourth genus was also identified related to Thermodiscus maritimus, for which no available sequenced genome exists. We propose the novel species Thermodiscus eudorianus to describe our high-quality Thermodiscus MAG , which represents the type genome for the genus. All three novel genera and T. eudorianus are likely anaerobic heterotrophs, capable of fermenting protein-rich carbon sources, while some Tiamatella, Calypsonella and T. eudorianus may also reduce polysulfides, thiosulfate, sulfur and/or selenite, and the likely acidophile, Hestiella, may reduce nitrate and/or perchlorate. Based on phylogenomic evidence, we also propose the family Acidilobaceae be amended to include Caldisphaera, Aeropyrum, Thermodiscus and Stetteria and the novel genera described here. [ABSTRACT FROM AUTHOR]

Published

2024

21. Metagenomics of two aquifers with thermal anomalies in Mallorca Island, and proposal of new uncultivated taxa named following the rules of SeqCode.

Author

Gago, Juan F., Viver, Tomeu, Urdiain, Mercedes, Ferreira, Elaine, Robledo, Pedro, and Rossello-Mora, Ramon

Subjects

AQUIFERS, METAGENOMICS, MICROBIAL cells, ISLANDS, MICROORGANISMS, EOCENE Epoch, ARCHIPELAGOES

Abstract

Groundwater offers an intriguing blend of distinctive physical and chemical conditions, constituting a challenge for microbial life. In Mallorca, the largest island of Balearic archipelago, harbours a variety of thermal anomalies (i.e., geothermal manifestation where surface aquifers exhibiting temperatures exceeding the regional average). The metagenomes of two aquifers in the centre and southern of the island showed Pseudomonadota to be the most represented phylum when using extracted 16S rRNA gene sequences. However, the microbial structures within and between aquifers were remarkably diverse but similar in their metabolic profiles as revealed by the metagenome-assembled genomes (MAGs) pointing to a prevalence of aerobic chemolithoautotrophic and heterotrophic metabolisms, especially in the Llucmajor aquifer. Also, some evidences of anaerobic lifestyles were detected, which would indicate that these environments either could suffer episodes of oxygen depletion or the anaerobes had been transported from deeper waters. We believe that the local environmental factors (temperature, external inputs or chemistry) seem to be more relevant than the connection and, eventually, transport of microbial cells within the aquifer in determining the highly divergent structures. Notably, most of the reconstructed genomes belonged to undescribed bacterial lineages and from them two high-quality MAGs could be classified as novel taxa named following the rules of the Code for Nomenclature of Prokaryotes Described from Sequence Data (SeqCode). Accordingly, we propose the new species and genus Costitxia debesea gen. nov., sp. nov., affiliated with the novel family Costitxiaceae fam. nov. , order Costitxiales ord. nov. and class Costitxiia class. nov.; and the new new species and genus Lloretia debesea gen. nov. sp. nov. affiliated with the novel family Lloretiaceae fam. nov. [ABSTRACT FROM AUTHOR]

Published

2024

22. Quis custodiet ipsos custodes? A call for community participation in the governance of the SeqCode.

Author

Sutcliffe, Iain C., Rodriguez-R, Luis M., Venter, Stephanus N., and Whitman, William B.

Subjects

COMMUNITY involvement, ADMINISTRATIVE assistants, PROKARYOTES, ARCHAEBACTERIA, GENOMES

Abstract

Codes of nomenclature that provide well-regulated and stable frameworks for the naming of taxa are a fundamental underpinning of biological research. These Codes themselves require systems that govern their administration, interpretation and emendment. Here we review the provisions that have been made for the governance of the recently introduced Code of Nomenclature of Prokaryotes Described from Sequence Data (SeqCode), which provides a nomenclatural framework for the valid publication of names of Archaea and Bacteria using isolate genome, metagenome-assembled genome or single-amplified genome sequences as type material. The administrative structures supporting the SeqCode are designed to be open and inclusive. Direction is provided by the SeqCode Community, which we encourage those with an interest in prokaryotic systematics to join. [ABSTRACT FROM AUTHOR]

Published

2024

23. Description of Asgardarchaeum abyssi gen. nov. spec. nov., a novel species within the class Asgardarchaeia and phylum Asgardarchaeota in accordance with the SeqCode.

Author

Tamarit D, Köstlbacher S, Appler KE, Panagiotou K, De Anda V, Rinke C, Baker BJ, and Ettema TJG

Subjects

RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, DNA, Archaeal genetics, DNA, Archaeal chemistry, Metagenome, Phylogeny, Archaea classification, Archaea genetics, Archaea isolation & purification, Genome, Archaeal

Abstract

Asgardarchaeota, commonly referred to as Asgard archaea, is a candidatus phylum-rank archaeal clade that includes the closest archaeal relatives of eukaryotes. Despite their prevalence in the scientific literature, the name Asgardarchaeota lacks nomenclatural validation. Here, we describe a novel high-quality metagenome-assembled genome (MAG), AB3033_2 TS , proposed to serve as the nomenclatural type for the species Asgardarchaeum abyssi TS according to the rules of the SeqCode. Based on protein content and compositional features, we infer that A. abyssi AB3033_2 TS is an acetogenic chemoheterotroph, possibly a facultative lithoautotroph, and is adapted to a thermophilic lifestyle. Utilizing genomes from Asgard archaea, TACK, and Euryarchaea, we perform phylogenomic reconstructions using the GTDB archaeal marker genes, the current reference set for taxonomic classification. Calibrating relative evolutionary divergence (RED) values for Asgardarchaeota using established Thermoproteota lineages in the GTDB r207 reference tree, we establish a robust classification and propose Asgardarchaeum as the type genus for the family Asgardarchaeaceae (fam. nov)., the order Asgardarchaeales (ord. nov.), the class Asgardarchaeia (class. nov.), and the phylum Asgardarchaeota (phyl. nov.). This effort aims to preserve taxonomic congruence in the scientific literature., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Author(s). Published by Elsevier GmbH.. All rights reserved.)

Published

2024

24. Description of two cultivated and two uncultivated new Salinibacter species, one named following the rules of the bacteriological code: Salinibacter grassmerensis sp. nov.; and three named following the rules of the SeqCode: Salinibacter pepae sp. nov., Salinibacter abyssi sp. nov., and Salinibacter pampae sp. nov.

Author

Universidad de Alicante. Departamento de Fisiología, Genética y Microbiología, Viver, Tomeu, Conrad, Roth E., Lucio, Marianna, Harir, Mourad, Urdiain, Mercedes, Gago, Juan F., Suárez-Suárez, Ana, Bustos-Caparros, Esteban, Sanchez-Martinez, Rodrigo, Mayol, Eva, Fassetta, Federico, Pang, Jinfeng, Gridan, Ionuț Mădălin, Venter, Stephanus, Santos, Fernando, Baxter, Bonnie, Llames, María E., Cristea, Adorján, Banciu, Horia L., Hedlund, Brian P., Stott, Matthew B., Kämpfer, Peter, Amann, Rudolf, Schmitt-Kopplin, Philippe, Konstantinidis, Konstantinos T., Rossello-Mora, Ramon, Universidad de Alicante. Departamento de Fisiología, Genética y Microbiología, Viver, Tomeu, Conrad, Roth E., Lucio, Marianna, Harir, Mourad, Urdiain, Mercedes, Gago, Juan F., Suárez-Suárez, Ana, Bustos-Caparros, Esteban, Sanchez-Martinez, Rodrigo, Mayol, Eva, Fassetta, Federico, Pang, Jinfeng, Gridan, Ionuț Mădălin, Venter, Stephanus, Santos, Fernando, Baxter, Bonnie, Llames, María E., Cristea, Adorján, Banciu, Horia L., Hedlund, Brian P., Stott, Matthew B., Kämpfer, Peter, Amann, Rudolf, Schmitt-Kopplin, Philippe, Konstantinidis, Konstantinos T., and Rossello-Mora, Ramon

Abstract

Current -omics methods allow the collection of a large amount of information that helps in describing the microbial diversity in nature. Here, and as a result of a culturomic approach that rendered the collection of thousands of isolates from 5 different hypersaline sites (in Spain, USA and New Zealand), we obtained 21 strains that represent two new Salinibacter species. For these species we propose the names Salinibacter pepae sp. nov. and Salinibacter grassmerensis sp. nov. (showing average nucleotide identity (ANI) values < 95.09% and 87.08% with Sal. ruber M31T, respectively). Metabolomics revealed species-specific discriminative profiles. Sal. ruber strains were distinguished by a higher percentage of polyunsaturated fatty acids and specific N-functionalized fatty acids; and Sal. altiplanensis was distinguished by an increased number of glycosylated molecules. Based on sequence characteristics and inferred phenotype of metagenome-assembled genomes (MAGs), we describe two new members of the genus Salinibacter. These species dominated in different sites and always coexisted with Sal. ruber and Sal. pepae. Based on the MAGs from three Argentinian lakes in the Pampa region of Argentina and the MAG of the Romanian lake Fără Fund, we describe the species Salinibacter pampae sp. nov. and Salinibacter abyssi sp. nov. respectively (showing ANI values 90.94% and 91.48% with Sal. ruber M31T, respectively). Sal. grassmerensis sp. nov. name was formed according to the rules of the International Code for Nomenclature of Prokaryotes (ICNP), and Sal. pepae, Sal. pampae sp. nov. and Sal. abyssi sp. nov. are proposed following the rules of the newly published Code of Nomenclature of Prokaryotes Described from Sequence Data (SeqCode). This work constitutes an example on how classification under ICNP and SeqCode can coexist, and how the official naming a cultivated organism for which the deposit in public repositories is difficult finds an intermediate solution.

Published

2023

25. Description of two cultivated and two uncultivated new Salinibacter species, one named following the rules of the bacteriological code: Salinibacter grassmerensis sp. nov.; and three named following the rules of the SeqCode: Salinibacter pepae sp. nov., Salinibacter abyssi sp. nov., and Salinibacter pampae sp. nov

Author

Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), European Commission, National Science Foundation (US), Ministry of Research, Innovation and Digitization (Romania), Consejo Federal de Ciencia y Tecnología (Argentina), Ministerio de Universidades (España), Govern de les Illes Balears, Viver, Tomeu [0000-0001-8868-], Viver, Tomeu, Conrad, Roth E., Lucio, Marianna, Harir, Mourad, Urdiain, Mercedes, Gago, Juan F., Suárez-Suárez, Ana, Bustos, Esteban, Sánchez-Martínez, Rodrigo, Mayol, Eva, Fassetta, Federico, Pang, Jinfeng, Mădălin Gridan, Ionuț, Venter, Stephanus, Santos, Fernando, Baxter, Bonnie, Llames, María E., Cristea, Adorján, Banciu, Horia L, Hedlund, Brian P., Stott, Matthew B., Kämpfer, Peter, Amann, Rudolf, Schmitt-Kopplin, Philippe, Konstantinidis, Konstantinos T., Rosselló-Mora, Ramón, Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), European Commission, National Science Foundation (US), Ministry of Research, Innovation and Digitization (Romania), Consejo Federal de Ciencia y Tecnología (Argentina), Ministerio de Universidades (España), Govern de les Illes Balears, Viver, Tomeu [0000-0001-8868-], Viver, Tomeu, Conrad, Roth E., Lucio, Marianna, Harir, Mourad, Urdiain, Mercedes, Gago, Juan F., Suárez-Suárez, Ana, Bustos, Esteban, Sánchez-Martínez, Rodrigo, Mayol, Eva, Fassetta, Federico, Pang, Jinfeng, Mădălin Gridan, Ionuț, Venter, Stephanus, Santos, Fernando, Baxter, Bonnie, Llames, María E., Cristea, Adorján, Banciu, Horia L, Hedlund, Brian P., Stott, Matthew B., Kämpfer, Peter, Amann, Rudolf, Schmitt-Kopplin, Philippe, Konstantinidis, Konstantinos T., and Rosselló-Mora, Ramón

Abstract

Current -omics methods allow the collection of a large amount of information that helps in describing the microbial diversity in nature. Here, and as a result of a culturomic approach that rendered the collection of thousands of isolates from 5 different hypersaline sites (in Spain, USA and New Zealand), we obtained 21 strains that represent two new Salinibacter species. For these species we propose the names Salinibacter pepae sp. nov. and Salinibacter grassmerensis sp. nov. (showing average nucleotide identity (ANI) values < 95.09% and 87.08% with Sal. ruber M31T, respectively). Metabolomics revealed species-specific discriminative profiles. Sal. ruber strains were distinguished by a higher percentage of polyunsaturated fatty acids and specific N-functionalized fatty acids; and Sal. altiplanensis was distinguished by an increased number of glycosylated molecules. Based on sequence characteristics and inferred phenotype of metagenome-assembled genomes (MAGs), we describe two new members of the genus Salinibacter. These species dominated in different sites and always coexisted with Sal. ruber and Sal. pepae. Based on the MAGs from three Argentinian lakes in the Pampa region of Argentina and the MAG of the Romanian lake Fără Fund, we describe the species Salinibacter pampae sp. nov. and Salinibacter abyssi sp. nov. respectively (showing ANI values 90.94% and 91.48% with Sal. ruber M31T, respectively). Sal. grassmerensis sp. nov. name was formed according to the rules of the International Code for Nomenclature of Prokaryotes (ICNP), and Sal. pepae, Sal. pampae sp. nov. and Sal. abyssi sp. nov. are proposed following the rules of the newly published Code of Nomenclature of Prokaryotes Described from Sequence Data (SeqCode). This work constitutes an example on how classification under ICNP and SeqCode can coexist, and how the official naming a cultivated organism for which the deposit in public repositories is difficult finds an intermediate solution.

Published

2023

26. First single-strain enrichments of Electrothrix cable bacteria, description of E. aestuarii sp. nov. and E. rattekaaiensis sp. nov., and proposal of a cable bacteria taxonomy following the rules of the SeqCode.

Author

Plum-Jensen, Lea E., Schramm, Andreas, and Marshall, Ian P.G.

Subjects

BACTERIA classification, BACTERIA, CANDIDATUS, MARINE sediments, PROKARYOTES

Abstract

Cable bacteria are electrically conductive, filamentous Desulfobulbaceae, which are morphologically, functionally, and phylogenetically distinct from the other members of this family. Cable bacteria have not been obtained in pure culture and were therefore previously described as candidate genera, Candidatus Electrothrix and Ca. Electronema; a representative of the latter is available as single-strain sediment enrichment. Here we present an improved workflow to obtain the first single-strain enrichments of Ca. Electrothrix and report their metagenome-assembled genomes (MAGs) and morphology. Based on these results and on previously published high-quality MAGs and morphological data of cable bacteria from both candidate genera, we propose to adopt the genus names Electrothrix and Electronema following the rules of the Code of Nomenclature of Prokaryotes Described from Sequence Data (SeqCode), with Electrothrix communis RBTS and Electronema aureum GSTS, respectively, as the nomenclatural types of the genera. Furthermore, based on average nucleotide identity (ANI) values < 95 % with any described species, we propose two of our three single-strain enrichment cultures as novel species of the genus Electrothrix , with the names E. aestuarii sp. nov. and E. rattekaaiensis sp. nov., according to the SeqCode. [ABSTRACT FROM AUTHOR]

Published

2024

27. Andean soil-derived lignocellulolytic bacterial consortium as a source of novel taxa and putative plastic-active enzymes.

Author

Díaz-García, Laura, Chuvochina, Maria, Feuerriegel, Golo, Bunk, Boyke, Spröer, Cathrin, Streit, Wolfgang R., Rodriguez-R, Luis M., Overmann, Jörg, and Jiménez, Diego Javier

Subjects

POLYETHYLENE terephthalate, ENZYMES, BACTERIAL diversity, HYDROLASES, MICROBIAL communities, LIGNOCELLULOSE

Abstract

An easy and straightforward way to engineer microbial environmental communities is by setting up liquid enrichment cultures containing a specific substrate as the sole source of carbon. Here, we analyzed twenty single-contig high-quality metagenome-assembled genomes (MAGs) retrieved from a microbial consortium (T6) that was selected by the dilution-to-stimulation approach using Andean soil as inoculum and lignocellulose as a selection pressure. Based on genomic metrics (e.g., average nucleotide and amino acid identities) and phylogenomic analyses, 15 out of 20 MAGs were found to represent novel bacterial species, with one of those (MAG_26) belonging to a novel genus closely related to Caenibius spp. (Sphingomonadaceae). Following the rules and requirements of the SeqCode, we propose the name Andeanibacterium colombiense gen. nov., sp. nov. for this taxon. A subsequent functional annotation of all MAGs revealed that MAG_7 (Pseudobacter hemicellulosilyticus sp. nov.) contains 20, 19 and 16 predicted genes from carbohydrate-active enzymes families GH43, GH2 and GH92, respectively. Its lignocellulolytic gene profile resembles that of MAG_2 (the most abundant member) and MAG_3858, both of which belong to the Sphingobacteriaceae family. Using a database that contains experimentally verified plastic-active enzymes (PAZymes), twenty-seven putative bacterial polyethylene terephthalate (PET)-active enzymes (i.e., alpha/beta-fold hydrolases) were detected in all MAGs. A maximum of five putative PETases were found in MAG_3858, and two PETases were found to be encoded by A. colombiense. In conclusion, we demonstrate that lignocellulose-enriched liquid cultures coupled with genome-resolved metagenomics are suitable approaches to unveil the hidden bacterial diversity and its polymer-degrading potential in Andean soil ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

28. Description of two cultivated and two uncultivated new Salinibacter species, one named following the rules of the bacteriological code: Salinibacter grassmerensis sp. nov.; and three named following the rules of the SeqCode: Salinibacter pepae sp. nov., Salinibacter abyssi sp. nov., and Salinibacter pampae sp. nov

Author

Tomeu Viver, Roth E. Conrad, Marianna Lucio, Mourad Harir, Mercedes Urdiain, Juan F. Gago, Ana Suárez-Suárez, Esteban Bustos-Caparros, Rodrigo Sanchez-Martinez, Eva Mayol, Federico Fassetta, Jinfeng Pang, Ionuț Mădălin Gridan, Stephanus Venter, Fernando Santos, Bonnie Baxter, María E. Llames, Adorján Cristea, Horia L. Banciu, Brian P. Hedlund, Matthew B. Stott, Peter Kämpfer, Rudolf Amann, Philippe Schmitt-Kopplin, Konstantinos T. Konstantinidis, Ramon Rossello-Mora, Universidad de Alicante. Departamento de Fisiología, Genética y Microbiología, and Ecología Microbiana Molecular

Subjects

ICNP, Genomics, SeqCode, Salinibacter, Applied Microbiology and Biotechnology, Microbiology, Phylogeny, Ecology, Evolution, Behavior and Systematics, Taxonomy

Abstract

Current -omics methods allow the collection of a large amount of information that helps in describing the microbial diversity in nature. Here, and as a result of a culturomic approach that rendered the collection of thousands of isolates from 5 different hypersaline sites (in Spain, USA and New Zealand), we obtained 21 strains that represent two new Salinibacter species. For these species we propose the names Salinibacter pepae sp. nov. and Salinibacter grassmerensis sp. nov. (showing average nucleotide identity (ANI) values < 95.09% and 87.08% with Sal. ruber M31T, respectively). Metabolomics revealed species-specific discriminative profiles. Sal. ruber strains were distinguished by a higher percentage of polyunsaturated fatty acids and specific N-functionalized fatty acids; and Sal. altiplanensis was distinguished by an increased number of glycosylated molecules. Based on sequence characteristics and inferred phenotype of metagenome-assembled genomes (MAGs), we describe two new members of the genus Salinibacter. These species dominated in different sites and always coexisted with Sal. ruber and Sal. pepae. Based on the MAGs from three Argentinian lakes in the Pampa region of Argentina and the MAG of the Romanian lake Fără Fund, we describe the species Salinibacter pampae sp. nov. and Salinibacter abyssi sp. nov. respectively (showing ANI values 90.94% and 91.48% with Sal. ruber M31T, respectively). Sal. grassmerensis sp. nov. name was formed according to the rules of the International Code for Nomenclature of Prokaryotes (ICNP), and Sal. pepae, Sal. pampae sp. nov. and Sal. abyssi sp. nov. are proposed following the rules of the newly published Code of Nomenclature of Prokaryotes Described from Sequence Data (SeqCode). This work constitutes an example on how classification under ICNP and SeqCode can coexist, and how the official naming a cultivated organism for which the deposit in public repositories is difficult finds an intermediate solution. This study was funded by the Spanish Ministry of Science, Innovation and Universities projects PGC2018-096956-B-C41, RTC-2017-6405-1 and PID2021-126114NB-C42, which were also supported by the European Regional Development Fund (FEDER). RRM acknowledges the financial support of the sabbatical stay at Georgia Tech and HelmholzZentrum München by the grants PRX18/00048 and PRX21/00043 respectively also from the Spanish Ministry of Science, Innovation and Universities. This research was carried out within the framework of the activities of the Spanish Government through the “Maria de Maeztu Centre of Excellence” accreditation to IMEDEA (CSIC-UIB) (CEX2021-001198). KTK’s research was supported, in part, by the U.S. National Science Foundation (Award No. 1831582 and No. 2129823). IMG. AC and HLB were financially supported by a grant of the Ministry of Research, Innovation and Digitization, CNCS/CCCDI – UEFISCDI, project number PN-III-P4-ID-PCE-2020-1559, within PNCDI III. HLB acknowledges Ocna Sibiului City Hall (Sibiu County, Romania) for granting the access to Fără Fund Lake and A. Baricz and D.F. Bogdan for technical support during sampling and sample preparation. MBS thanks Dominion Salt for their assistance in sample Lake Grassmere. MELL acknowledges the financial support of the Argentinian National Scientific and Technical Research Council (Grant CONICET-NSFC 2017 N° IF-2018-10102222-APN-GDCT-CONICET) and the National Geographic Society (Grant # NGS 357R-18). BPH was supported by NASA (award 80NSSC18M0027). TV acknowledges the “Margarita Salas” postdoctoral grant, funded by the Spanish Ministry of Universities, within the framework of Recovery, Transformation and Resilience Plan, and funded by the European Union (NextGenerationEU), with the participation of the University of Balearic Islands (UIB).

Published

2023

29. Development of the SeqCode: A proposed nomenclatural code for uncultivated prokaryotes with DNA sequences as type

Author

National Science Foundation (US), National Institute of General Medical Sciences (US), National Institutes of Health (US), Ministerio de Ciencia e Innovación (España), Agencia Estatal de Investigación (España), Australian Research Council, German Research Foundation, European Commission, International Society for Microbial Ecology, Whitman, William B., Chuvochina, Maria, Hedlund, Brian P., Hugenholtz, Philip, Konstantinidis, Konstantinos T., Murray, Alison, Palmer, Marike, Parks, Donovan H., Probst, Alexander J., Reysenbach, A. L., Rodriguez-R, Luis M., Rosselló-Mora, Ramón, Sutcliffe, Iain, Venter, Stephanus N., National Science Foundation (US), National Institute of General Medical Sciences (US), National Institutes of Health (US), Ministerio de Ciencia e Innovación (España), Agencia Estatal de Investigación (España), Australian Research Council, German Research Foundation, European Commission, International Society for Microbial Ecology, Whitman, William B., Chuvochina, Maria, Hedlund, Brian P., Hugenholtz, Philip, Konstantinidis, Konstantinos T., Murray, Alison, Palmer, Marike, Parks, Donovan H., Probst, Alexander J., Reysenbach, A. L., Rodriguez-R, Luis M., Rosselló-Mora, Ramón, Sutcliffe, Iain, and Venter, Stephanus N.

Abstract

Over the last fifteen years, genomics has become fully integrated into prokaryotic systematics. The genomes of most type strains have been sequenced, genome sequence similarity is widely used for delineation of species, and phylogenomic methods are commonly used for classification of higher taxonomic ranks. Additionally, environmental genomics has revealed a vast diversity of as-yet-uncultivated taxa. In response to these developments, a new code of nomenclature, the Code of Nomenclature of Prokaryotes Described from Sequence Data (SeqCode), has been developed over the last two years to allow naming of Archaea and Bacteria using DNA sequences as the nomenclatural types. The SeqCode also allows naming of cultured organisms, including fastidious prokaryotes that cannot be deposited into culture collections. Several simplifications relative to the International Code of Nomenclature of Prokaryotes (ICNP) are implemented to make nomenclature more accessible, easier to apply and more readily communicated. By simplifying nomenclature with the goal of a unified classification, inclusive of both cultured and uncultured taxa, the SeqCode will facilitate the naming of taxa in every biome on Earth, encourage the isolation and characterization of as-yet-uncultivated taxa, and promote synergies between the ecological, environmental, physiological, biochemical, and molecular biological disciplines to more fully describe prokaryotes.

Published

2022

30. Description of two cultivated and two uncultivated new Salinibacter species, one named following the rules of the bacteriological code: Salinibacter grassmerensis sp. nov.; and three named following the rules of the SeqCode: Salinibacter pepae sp....

Author

Viver, Tomeu, Conrad, Roth E., Lucio, Marianna, Harir, Mourad, Urdiain, Mercedes, Gago, Juan F., Suárez-Suárez, Ana, Bustos-Caparros, Esteban, Sanchez-Martinez, Rodrigo, Mayol, Eva, Fassetta, Federico, Pang, Jinfeng, Mădălin Gridan, Ionuț, Venter, Stephanus, Santos, Fernando, Baxter, Bonnie, Llames, María E., Cristea, Adorján, Banciu, Horia L., and Hedlund, Brian P.

Subjects

UNSATURATED fatty acids, PERSONAL names, SPECIES, MICROBIAL diversity, FATTY acids

Abstract

Current -omics methods allow the collection of a large amount of information that helps in describing the microbial diversity in nature. Here, and as a result of a culturomic approach that rendered the collection of thousands of isolates from 5 different hypersaline sites (in Spain, USA and New Zealand), we obtained 21 strains that represent two new Salinibacter species. For these species we propose the names Salinibacter pepae sp. nov. and Salinibacter grassmerensis sp. nov. (showing average nucleotide identity (ANI) values < 95.09% and 87.08% with Sal. ruber M31T, respectively). Metabolomics revealed species-specific discriminative profiles. Sal. ruber strains were distinguished by a higher percentage of polyunsaturated fatty acids and specific N-functionalized fatty acids; and Sal. altiplanensis was distinguished by an increased number of glycosylated molecules. Based on sequence characteristics and inferred phenotype of metagenome-assembled genomes (MAGs), we describe two new members of the genus Salinibacter. These species dominated in different sites and always coexisted with Sal. ruber and Sal. pepae. Based on the MAGs from three Argentinian lakes in the Pampa region of Argentina and the MAG of the Romanian lake Fără Fund, we describe the species Salinibacter pampae sp. nov. and Salinibacter abyssi sp. nov. respectively (showing ANI values 90.94% and 91.48% with Sal. ruber M31T, respectively). Sal. grassmerensis sp. nov. name was formed according to the rules of the International Code for Nomenclature of Prokaryotes (ICNP), and Sal. pepae , Sal. pampae sp. nov. and Sal. abyssi sp. nov. are proposed following the rules of the newly published Code of Nomenclature of Prokaryotes Described from Sequence Data (SeqCode). This work constitutes an example on how classification under ICNP and SeqCode can coexist, and how the official naming a cultivated organism for which the deposit in public repositories is difficult finds an intermediate solution. [ABSTRACT FROM AUTHOR]

Published

2023

31. Development of the SeqCode: A proposed nomenclatural code for uncultivated prokaryotes with DNA sequences as type

Author

William B. Whitman, Maria Chuvochina, Brian P. Hedlund, Philip Hugenholtz, Konstantinos T. Konstantinidis, Alison E. Murray, Marike Palmer, Donovan H. Parks, Alexander J. Probst, Anna-Louise Reysenbach, Luis M. Rodriguez-R, Ramon Rossello-Mora, Iain Sutcliffe, Stephanus N. Venter, National Science Foundation (US), National Institute of General Medical Sciences (US), National Institutes of Health (US), Ministerio de Ciencia e Innovación (España), Agencia Estatal de Investigación (España), Australian Research Council, German Research Foundation, European Commission, and International Society for Microbial Ecology

Subjects

Nomenclatural type, Bacteria, Base Sequence, C100, Candidatus, C500, SeqCode, Archaea, Applied Microbiology and Biotechnology, Microbiology, C900, RNA, Ribosomal, 16S, Metagenome, Nomenclatural code, Phylogeny, Ecology, Evolution, Behavior and Systematics

Abstract

Over the last fifteen years, genomics has become fully integrated into prokaryotic systematics. The genomes of most type strains have been sequenced, genome sequence similarity is widely used for delineation of species, and phylogenomic methods are commonly used for classification of higher taxonomic ranks. Additionally, environmental genomics has revealed a vast diversity of as-yet-uncultivated taxa. In response to these developments, a new code of nomenclature, the Code of Nomenclature of Prokaryotes Described from Sequence Data (SeqCode), has been developed over the last two years to allow naming of Archaea and Bacteria using DNA sequences as the nomenclatural types. The SeqCode also allows naming of cultured organisms, including fastidious prokaryotes that cannot be deposited into culture collections. Several simplifications relative to the International Code of Nomenclature of Prokaryotes (ICNP) are implemented to make nomenclature more accessible, easier to apply and more readily communicated. By simplifying nomenclature with the goal of a unified classification, inclusive of both cultured and uncultured taxa, the SeqCode will facilitate the naming of taxa in every biome on Earth, encourage the isolation and characterization of as-yet-uncultivated taxa, and promote synergies between the ecological, environmental, physiological, biochemical, and molecular biological disciplines to more fully describe prokaryotes., Funding was provided by the US National Science Foundation (DEB 1841658 and EAR 1516680), the US National Institute of General Medical Sciences (P20 GM103440) from the National Institutes of Health, the Spanish Ministry of Science, Innovation and Universities (PID2021-126114NB-C42), the Australian Research Council (FL150100038), the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation, SFB 1439/1 2021 – 426547801) also supported with European Regional Development Funds (FEDER), and the International Society for Microbial Ecology (ISME)

Published

2022

32. Development of the SeqCode: A proposed nomenclatural code for uncultivated prokaryotes with DNA sequences as type.

Author

Whitman, William B., Chuvochina, Maria, Hedlund, Brian P., Hugenholtz, Philip, Konstantinidis, Konstantinos T., Murray, Alison E., Palmer, Marike, Parks, Donovan H., Probst, Alexander J., Reysenbach, Anna-Louise, Rodriguez-R, Luis M., Rossello-Mora, Ramon, Sutcliffe, Iain, and Venter, Stephanus N.

Subjects

DNA sequencing, PROKARYOTES, BACTERIAL DNA, ARCHAEBACTERIA, GENOMICS

Abstract

Over the last fifteen years, genomics has become fully integrated into prokaryotic systematics. The genomes of most type strains have been sequenced, genome sequence similarity is widely used for delineation of species, and phylogenomic methods are commonly used for classification of higher taxonomic ranks. Additionally, environmental genomics has revealed a vast diversity of as-yet-uncultivated taxa. In response to these developments, a new code of nomenclature, the Code of Nomenclature of Prokaryotes Described from Sequence Data (SeqCode), has been developed over the last two years to allow naming of Archaea and Bacteria using DNA sequences as the nomenclatural types. The SeqCode also allows naming of cultured organisms, including fastidious prokaryotes that cannot be deposited into culture collections. Several simplifications relative to the International Code of Nomenclature of Prokaryotes (ICNP) are implemented to make nomenclature more accessible, easier to apply and more readily communicated. By simplifying nomenclature with the goal of a unified classification, inclusive of both cultured and uncultured taxa, the SeqCode will facilitate the naming of taxa in every biome on Earth, encourage the isolation and characterization of as-yet-uncultivated taxa, and promote synergies between the ecological, environmental, physiological, biochemical, and molecular biological disciplines to more fully describe prokaryotes. [ABSTRACT FROM AUTHOR]

Published

2022

33. It is time for a new type of type to facilitate naming the microbial world.

Author

Palmer, M., Sutcliffe, I., Venter, S.N., and Hedlund, B.P.

Subjects

*MICROBIAL diversity, *SCIENTIFIC community, *MICROBIOLOGY, *GENOMES, *ARCHAEBACTERIA

Abstract

Since January 1, 2001, the only acceptable nomenclatural type for species under the International Code of Nomenclature of Prokaryotes (ICNP) has been pure cultures. Here, we argue that this requirement is discordant with the more inclusive nature of nomenclatural types accepted under other codes of nomenclature and posit that the unique rigidity of the ICNP has failed to serve the broad research community and has stifled progress. This case is based on the axiom that many archaea and bacteria are interdependent in nature and therefore difficult, if not impossible, to grow, preserve, and distribute as pure cultures. As such, a large proportion of Earth's biodiversity cannot be named under the current system, which limits our ability to communicate about microbial diversity within and beyond the microbiology research community. Genome sequence data are now encouraged for valid publication of new taxa in microbial systematics journals, and metagenome-assembled genomes and single cell-amplified genomes are being generated rapidly from every biome on Earth. Thus, genome sequences are available for both cultivated and uncultivated microorganisms and can readily serve as a new category of nomenclatural type, allowing for a unified nomenclature for all archaea and bacteria, whether or not they are available as pure cultures. Ideally this would be under a single code of nomenclature but, as we review here, the newly established SeqCode will operate in parallel with the ICNP as a first step toward this goal. [ABSTRACT FROM AUTHOR]

Published

2022