SeqCode Registry

Lists of names of prokaryotic Candidatus taxa

Citation: Oren et al. (2020). International Journal of Systematic and Evolutionary Microbiology 70 (7)
Names: “Huberarchaeum crystalense” “Huberarchaeum” Ca. Allofontibacter Ca. Allofontibacter communis “Fermentibacteria” Ca. Fermentibacter danicus Ca. Fermentibacter Ca. Fermentibacteraceae “Fermentibacterales” “Methanofastidiosia” Ca. Methanofastidiosum Ca. Methanofastidiosum methylothiophilum Ca. Carsonella Ca. Carsonella ruddii “Altiarchaeum” Ca. Methylumidiphilus alinenensis Ca. Caldarchaeum Kryptonium thompsonii ^Ts “Sulfuripaludibacter” “Sulfuritelmatobacter” Sulfuritelmatomonas “Izemoplasma acidinucleici” Cloacimonas acidaminivorans ^Ts Cloacimonas Ca. Methanomethylicia Ca. Methanomethylicus Ca. Methanomethylicus mesodigestus Ca. Methanomethylicus oleisabuli “Methanosuratincola petrocarbonis” “Methanosuratincola” Ca. Branchiomonas cystocola Kapaibacterium Kapaibacterium thiocyanatum ^Ts Muiribacterium halophilum ^Ts Promineifilum Promineifilum breve ^Ts “Accumulibacter aalborgensis” “Acetithermum autotrophicum” “Aciduliprofundum boonei” “Actinochlamydia clariatis” “Actinochlamydia pangasianodontis” “Actinomarina minuta” “Adiacens aphidicola” “Aenigmatarchaeum subterraneum” “Aerophobus profundus” “Allobeggiatoa salina” “Allocryptoplasma californiense” “Allospironema culicis” “Altiarchaeum hamiconexum” “Altimarinus pacificus” “Aminicenans sakinawicola” “Amoebinatus massiliensis” “Amoebophilus asiaticus” “Amphibiichlamydia ranarum” “Amphibiichlamydia salamandrae” “Anammoxiglobus propionicus” “Anammoximicrobium moscoviense” “Aquiluna rubra” “Atelocyanobacterium thalassae” “Bandiella euplotis” “Blochmanniella camponoti” “Blochmanniella floridana” “Blochmanniella myrmotrichis” “Blochmanniella pennsylvanica” “Blochmanniella vafra” “Brevifilum fermentans” “Brocadia anammoxidans” “Brocadia sapporonensis” “Caenarcanum bioreactoricola” “Caldarchaeum subterraneum” “Caldatribacterium californiense” “Caldatribacterium saccharofermentans” “Calditenuis aerorheumatis” “Calescibacterium nevadense” “Captivus acidiprotistae” “Carbonibacillus altaicus” “Cardinium hertigii” “Catenimonas italica” “Cenarchaeum symbiosum” “Chloranaerofilum corporosum” “Chloroploca asiatica” “Chlorotrichoides halophilum” “Chryseopegocella kryptomonas” “Clavichlamydia salmonicola” “Cochliopodiiphilus cryoturris” “Combothrix italica” “Competibacter denitrificans” “Competibacter phosphatis” “Consessor aphidicola” “Contendibacter odensensis” “Contubernalis alkaliaceticus” “Criblamydia sequanensis” “Criblamydia” “Cryptoprodota polytropus” “Curculioniphilus buchneri” “Cyrtobacter comes” “Dactylopiibacterium carminicum” “Desulfofervidus auxilii” “Desulfonatronobulbus propionicus” “Doolittlea endobia” “Ecksteinia adelgidicola” “Electronema nielsenii” “Electronema palustre” Electrothrix arhusiensis Electrothrix communis ^Ts “Electrothrix japonica” “Electrothrix marina” “Endecteinascidia fromenterensis” “Endobugula glebosa” “Endobugula sertula” “Endolissoclinum faulkneri” “Endonucleibacter bathymodioli” “Endoriftia persephonae” “Endowatersipora glebosa” “Entotheonella factor” “Entotheonella palauensis” “Entotheonella serta” “Epixenosoma ejectans” “Epulonipiscioides gigas” “Epulonipiscioides saccharophilum” “Epulonipiscium fischelsonii” Fervidibacter sacchari ^Ts “Finniella inopinata” “Finniella lucida” “Finniella” “Flaviluna lacus” “Fodinibacter communicans” “Fokinia crypta” “Fokinia solitaria” “Fritschea bemisiae” “Fritschea eriococci” “Fukatsuia symbiotica” “Galacturonatibacter soehngenii” “Mariprofundia” “Moduliflexia” “Thermofontia” “Vecturitrichia” “Actinomarinales” “Altiarchaeales” “Gastranaerophilales” “Moduliflexales” “Nitrosocaldales” “Vecturitrichales” “Accumulibacter phosphatis” Sulfuritelmatomonas gaucii ^Ts Electronema aureum ^Ts Electronema Electrothrix Fervidibacter
Abstract: We here present annotated lists of names ofCandidatustaxa of prokaryotes with ranks between subspecies and class, proposed between the mid-1990s, when the provisional status ofCandidatustaxa was first established, and the end of 2018. Where necessary, corrected names are proposed that comply with the current provisions of the International Code of Nomenclature of Prokaryotes and its Orthography appendix. These lists, as well as updated lists of newly published names ofCandidatustaxa with additio

Comparison of the performance of the main real-time and conventional PCR detection tests for ‘Candidatus Liberibacter’ spp., plant pathogenic bacteria causing the Huanglongbing disease in Citrus spp

Citation: Cellier et al. (2020). European Journal of Plant Pathology 157 (4)
Names: Liberibacter
Abstract

Sequence Analysis of New Tuf Molecular Types of ‘Candidatus Phytoplasma Solani’ in Iranian Vineyards

Citation: Jamshidi et al. (2020). Pathogens 9 (6)
Names: Ca. Phytoplasma Ca. Phytoplasma solani
Abstract: Grapevine Bois noir (BN) is caused by ‘Candidatus Phytoplasma solani’ (‘Ca. P. solani’) and is one of the most important phytoplasma diseases in the Euro-Mediterranean viticultural areas. The epidemiology of BN can include grapevine as a plant host and is usually transmitted via sap-sucking insects that inhabit herbaceous host plants. Tracking the spread of ‘Ca. P. solani’ strains is of great help for the identification of plant reservoirs and insect vectors involved in local BN outbreaks. The m

Impact of HLB on the physiological quality of citrus rootstock seeds and non-vertical ‘Candidatus Liberibacter asiaticus’ transmission

Citation: Morelli et al. (2020). Tropical Plant Pathology 45 (6)
Names: Ca. Liberibacter asiaticus
Abstract

“Candidatus Mystax nordicus” Aggregates with Mitochondria of Its Host, the Ciliate Paramecium nephridiatum

Citation: Korotaev et al. (2020). Diversity 12 (6)
Names: Ca. Gortzia Ca. Hafkinia Ca. Megaira venefica Ca. Mystax Ca. Mystax nordicus Ca. Paraholospora
Abstract: Extensive search for new endosymbiotic systems in ciliates occasionally reverts us to the endosymbiotic bacteria described in the pre-molecular biology era and, hence, lacking molecular characterization. A pool of these endosymbionts has been referred to as a hidden bacterial biodiversity from the past. Here, we provide a description of one of such endosymbionts, retrieved from the ciliate Paramecium nephridiatum. This curve-shaped endosymbiont (CS), which shared the host cytoplasm with recently

Pontiella desulfatans gen. nov., sp. nov., and Pontiella sulfatireligans sp. nov., Two Marine Anaerobes of the Pontiellaceae fam. nov. Producing Sulfated Glycosaminoglycan-like Exopolymers

Citation: van Vliet et al. (2020). Microorganisms 8 (6)
Names: Pontiellaceae
Abstract: Recently, we isolated two marine strains, F1T and F21T, which together with Kiritimatiella glycovorans L21-Fru-ABT are the only pure cultures of the class Kiritimatiellae within the phylum Verrucomicrobiota. Here, we present an in-depth genome-guided characterization of both isolates with emphasis on their exopolysaccharide synthesis. The strains only grew fermentatively on simple carbohydrates and sulfated polysaccharides. Strains F1T, F21T and K. glycovorans reduced elemental sulfur, ferric ci

Isolation of Candidatus Bartonella rousetti and Other Bat-associated Bartonellae from Bats and Their Flies in Zambia

Citation: Qiu et al. (2020). Pathogens 9 (6)
Names: Ca. Bartonella rousetti
Abstract: Bat-associated bartonellae, including Bartonella mayotimonensis and Candidatus Bartonella rousetti, were recently identified as emerging and potential zoonotic agents, respectively. However, there is no report of bat-associated bartonellae in Zambia. Thus, we aimed to isolate and characterize Bartonella spp. from bats and bat flies captured in Zambia by culturing and PCR. Overall, Bartonella spp. were isolated from six out of 36 bats (16.7%), while Bartonella DNA was detected in nine out of 19 b

Single-Cell Genomics of Novel Actinobacteria With the Wood–Ljungdahl Pathway Discovered in a Serpentinizing System

Citation: Merino et al. (2020). Frontiers in Microbiology 11
Names: “Hakubellales” “Hakubellaceae”
Abstract

Candidatus Amarolinea and Candidatus Microthrix Are Mainly Responsible for Filamentous Bulking in Danish Municipal Wastewater Treatment Plants

Citation: Nierychlo et al. (2020). Frontiers in Microbiology 11
Names: “Neomicrothrix”
Abstract

Synthesis of Deoxyradicinin, an Inhibitor of Xylella fastidiosa and Liberibacter crescens, a Culturable Surrogate for Candidatus Liberibacter asiaticus

Citation: Brandenburg et al. (2020). Journal of Natural Products 83 (6)
Names: Ca. Liberibacter asiaticus
Abstract

Publications 3843

Lists of names of prokaryotic Candidatus taxa

Comparison of the performance of the main real-time and conventional PCR detection tests for ‘Candidatus Liberibacter’ spp., plant pathogenic bacteria causing the Huanglongbing disease in Citrus spp

Sequence Analysis of New Tuf Molecular Types of ‘Candidatus Phytoplasma Solani’ in Iranian Vineyards

Impact of HLB on the physiological quality of citrus rootstock seeds and non-vertical ‘Candidatus Liberibacter asiaticus’ transmission

“Candidatus Mystax nordicus” Aggregates with Mitochondria of Its Host, the Ciliate Paramecium nephridiatum

Pontiella desulfatans gen. nov., sp. nov., and Pontiella sulfatireligans sp. nov., Two Marine Anaerobes of the Pontiellaceae fam. nov. Producing Sulfated Glycosaminoglycan-like Exopolymers

Isolation of Candidatus Bartonella rousetti and Other Bat-associated Bartonellae from Bats and Their Flies in Zambia

Single-Cell Genomics of Novel Actinobacteria With the Wood–Ljungdahl Pathway Discovered in a Serpentinizing System

Candidatus Amarolinea and Candidatus Microthrix Are Mainly Responsible for Filamentous Bulking in Danish Municipal Wastewater Treatment Plants

Synthesis of Deoxyradicinin, an Inhibitor of Xylella fastidiosa and Liberibacter crescens, a Culturable Surrogate for Candidatus Liberibacter asiaticus

Publications
3843