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A Sec-dependent effector, CLIBASIA_04425, contributes to virulence in ‘Candidatus Liberibater asiaticus’

Citation
Zhang et al. (2023). Frontiers in Plant Science 14
Names
Ca. Liberibacter asiaticus
Abstract
Citrus Huanglongbing (HLB) is the most destructive citrus disease worldwide, mainly caused by ‘Candidatus Liberibacter asiaticus’ (CLas). It encodes a large number of Sec-dependent effectors that contribute to HLB progression. In this study, an elicitor triggering ROS burst and cell death in Nicotiana benthamiana, CLIBASIA_04425 (CLas4425), was identified. Of particular interest, its cell death-inducing activity is associated with its subcellular localization and the cytoplasmic receptor Botryti

Effects of Candidatus Liberibacter asiaticus infection on metagenome of Diaphorina citri gut endosymbiont

Citation
Pan et al. (2023). Scientific Data 10 (1)
Names
Ca. Liberibacter asiaticus
Abstract
AbstractAsian citrus psyllid (Diaphorina citri, D. citri) is the important vector of “Candidatus Liberibacter asiaticus” (CLas), associated with Huanglongbing, the most devastating citrus disease worldwide. CLas can affect endosymbiont abundance of D. citri. Here, we generated the high-quality gut endosymbiont metagenomes of Diaphorina citri on the condition of CLas infected and uninfected. The dataset comprised 6616.74 M and 6586.04 M raw reads, on overage, from CLas uninfected and infected psy

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

Citation
Chuvochina et al. (2023). FEMS Microbiology Letters
Names
Methyloligellaceae Rhodomicrobiaceae Leptospiria Alicyclobacillia Natranaerobiia Jeotgalibacillaceae Brevinematia Amphibacillaceae Chitinimonas Chitinimonadaceae Marinicellaceae Ahniellaceae Pseudohongiellaceae Methanoculleaceae Methanofollaceae Methanosphaerulaceae Methanocellia Methanosarcinia Methanonatronarchaeia Methanoliparia Halobacteriota Exiguobacteriales Exiguobacteriaceae Salinicoccaceae Staphylococcales Gemellaceae Thermicanales Thermicanaceae Neiellaceae Oceanococcaceae Wohlfahrtiimonadaceae Thermaerobacteria Thermaerobacterales Thermaerobacteraceae Sedimentibacteraceae Proteiniboraceae Monoglobaceae Monoglobales Lutisporaceae Lutisporales Lachnospirales Christensenellales Caldicoprobacterales Caldicellulosiruptoraceae Caldicellulosiruptorales Oxobacteraceae Caloramatoraceae Acetivibrionaceae Acetivibrio Acetivibrionales Clostridiisalibacter Clostridiisalibacteraceae Caldisalinibacter Dethiosulfatibacteraceae Thermincolales Thermincolia Carboxydocellales Carboxydocellaceae Tindalliaceae Thermotaleaceae Natronincolaceae Filifactoraceae Caminicellaceae Anaerovoracaceae Peptostreptococcales Acidaminobacteraceae Mahellales Mahellaceae Thermosulfidibacterota Thermosulfidibacteria Thermosulfidibacterales Thermosulfidibacteraceae Elainellaceae Elainellales Phormidesmidaceae Phormidesmidales Hydrogenothermales Desulfurobacteriia “Paceibacteria” Vampirovibrionaceae Vampirovibrionales Vampirovibrionia Binataceae Binatales Binatia Hydrothermia Hydrothermales Hydrothermaceae Azobacteroidaceae Bipolaricaulales Bipolaricaulaceae Bipolaricaulia Hepatobacteraceae Hepatoplasmataceae Johnevansiaceae Johnevansiales Kapaibacteriaceae Kapaibacteriales Magnetobacteriaceae Methylomirabilaceae Methylomirabilales Methylomirabilia Muiribacteriaceae Muiribacteriales Muiribacteriia Nucleicultricaceae Obscuribacteraceae Promineifilaceae Promineifilales Pseudothioglobaceae Puniceispirillaceae Puniceispirillales Saccharimonadaceae Saccharimonadales Tenderiaceae Tenderiales Thermobaculaceae Thermobaculales Desulforudaceae Methylomirabilota Cloacimonadia Cloacimonadales Cloacimonadaceae Kapaibacteriia “Poriferisulfidales” Leptolyngbyaceae
Abstract
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

Signaling Cross-Talk between Salicylic and Gentisic Acid in the ‘Candidatus Phytoplasma Solani’ Interaction with Sangiovese Vines

Citation
Nutricati et al. (2023). Plants 12 (14)
Names
Ca. Phytoplasma Ca. Phytoplasma solani
Abstract
“Bois noir” disease associated with ‘Candidatus Phytoplasma solani’ seriously compromises the production and survival of grapevines (Vitis vinifera L.) in Europe. Understanding the plant response to phytoplasmas should help to improve disease control strategies. Using a combined metabolomic and transcriptomic analysis, this work, therefore, investigated the phytoplasma–grapevine interaction in red cultivar Sangiovese in a vineyard over four seasonal growth stages (from late spring to late summer

Metabolic changes and potential biomarkers in "Candidatus Liberibacter solanacearum"-infected potato psyllids: implications for psyllid-pathogen interactions

Citation
Li et al. (2023). Frontiers in Plant Science 14
Names
“Liberibacter solanacearum”
Abstract
Psyllid yellows, vein-greening (VG), and zebra chip (ZC) diseases, which are primarily transmitted by potato psyllid (PoP) carrying Candidatus Liberibacter solanacearum (CLso), have caused significant losses in solanaceous crop production worldwide. Pathogens interact with their vectors at the organic and cellular levels, while the potential changes that may occur at the biochemical level are less well reported. In this study, the impact of CLso on the metabolism of PoP and the identification of

Draft Genome Sequence of “ Candidatus Liberibacter asiaticus” Strain GZQL4, from Guizhou, China

Citation
Liu et al. (2023). Microbiology Resource Announcements 12 (7)
Names
Ca. Liberibacter asiaticus
Abstract
Here, we announce the draft genome sequence of “ Candidatus Liberibacter asiaticus” strain GZQL4, which was collected from Guizhou, China. The GZQL4 strain has a genome size of 1,234,029 bp, a G+C content of 36.5%, 1,204 predicted open reading frames, and 53 RNA genes.

Complete Genome Sequence of “ Candidatus Phytoplasma aurantifolia” TB2022, a Plant Pathogen Associated with Sweet Potato Little Leaf Disease in China

Citation
Li et al. (2023). Microbiology Resource Announcements 12 (7)
Names
Ca. Phytoplasma aurantifolia
Abstract
The complete genome sequence of “ Candidatus Phytoplasma aurantifolia” TB2022, which consists of one 670,073-bp circular chromosome, is presented in this work. This bacterium is associated with sweet potato little leaf disease in Fujian Province, China.

Molecular identification of ‘Candidatus Phytoplasma palmicola’ associated with coconut lethal yellowing in Equatorial Guinea

Citation
Bertaccini et al. (2023). Annals of Applied Biology
Names
Ca. Phytoplasma palmicola
Abstract
AbstractDuring the past two decades, a high mortality of coconut palms was observed in the coastal areas of Equatorial Guinea. Reportedly, the palm population has been reduced by 60%–70%, and coconut production has decreased accordingly. To identify the cause of the mortality, a survey was carried out in April 2021 in various localities of the coconut belt. Molecular analyses carried out on 16S rRNA and secA genes detected phytoplasma presence in the majority of the samples. Sequencing and BLAST

Diversity Analysis and Function Prediction of Bacterial Communities in the Different Colored Pericarp of Citrus reticulata cv. ‘Shatangju’ Due to ‘Candidatus Liberibacter asiaticus’ Infection

Citation
Wang et al. (2023). International Journal of Molecular Sciences 24 (14)
Names
Liberibacter Ca. Liberibacter asiaticus
Abstract
Huanglongbing (HLB), caused by the Candidatus Liberibacter spp., is the most devastating disease in the citrus industry. HLB significantly affects and alters the microbial community structure or potential function of the microbial community of leaves and roots. However, it is unknown how the microbial community structure of the pericarp with different pigments is affected by Candidatus Liberibacter asiaticus (CLas). This study identified the enriched taxa of the microbial community in the citrus