General Medicine


Publications
576

Extensive microbial diversity within the chicken gut microbiome revealed by metagenomics and culture

Citation
Gilroy et al. (2021). PeerJ 9
Names
“Ureaplasma intestinipullorum” “Ventrenecus stercoripullorum” “Ventrenecus” “Ventrenecus avicola” “Ventricola gallistercoris” “Ventricola” “Ventricola intestinavium” “Ventrimonas merdavium” “Ventrisoma” “Ventrisoma faecale” “Ventrousia” “Ventrousia excrementavium” “Yaniella excrementavium” “Yaniella excrementigallinarum” “Alectryocaccomicrobium” “Alectryocaccobium” “Galloscillospiraceae” “Limivivens” “Allolimicola stercorigallinarum” “Allolimicola” “Alectryobacillus merdavium” “Alectryobacillus” “Gemmiger faecavium” “Barnesiella excrementigallinarum” “Blautia stercoravium” “Desulfovibrio intestinigallinarum” “Limosilactobacillus merdigallinarum” “Acinetobacter avistercoris” “Anaerobiospirillum pullistercoris” “Gemmiger excrementipullorum” “Evtepia faecigallinarum” “Anaerofilum excrementigallinarum” “Acutalibacter pullistercoris” “Barnesiella excrementavium” “Evtepia faecavium” “Agathobaculum merdavium” “Eisenbergiella pullistercoris” “Tetragenococcus pullicola” “Alistipes intestinigallinarum” “Luteimonas excrementigallinarum” “Intestinimonas merdavium” “Sphingobacterium stercorigallinarum” “Rubneribacter avistercoris” “Rothia avicola” “Companilactobacillus pullicola” “Tidjanibacter faecipullorum” “Ruania gallistercoris” “Fournierella merdipullorum” “Gemmiger excrementavium” “Atopostipes pullistercoris” “Lactobacillus pullistercoris” “Janibacter merdipullorum” “Mucispirillum faecigallinarum” “Ligilactobacillus excrementavium” “Collinsella stercoripullorum” “Microbacterium stercoravium” “Mediterraneibacter merdipullorum” “Mediterraneibacter pullicola” “Fournierella merdigallinarum” “Mediterraneibacter merdigallinarum” “Limosilactobacillus excrementigallinarum” “Agathobaculum intestinipullorum” “Brevibacterium intestinavium” “Brachybacterium merdavium” “Desulfovibrio intestinavium” “Bariatricus faecipullorum” “Alistipes avicola” “Phocaeicola faecigallinarum” “Blautia merdipullorum” “Desulfovibrio gallistercoris” “Fournierella merdavium” “Fournierella excrementigallinarum” “Mailhella merdavium” “Nosocomiicoccus stercorigallinarum” “Eisenbergiella merdigallinarum” “Ligilactobacillus avistercoris” “Eisenbergiella merdavium” “Alistipes stercoravium” “Dietzia intestinipullorum” “Mediterraneibacter faecipullorum” “Mediterraneibacter faecigallinarum” “Dietzia intestinigallinarum” “Anaerostipes avistercoris” “Blautia merdavium” “Phocaeicola excrementigallinarum” “Corynebacterium faecigallinarum” “Mediterraneibacter excrementavium” “Acutalibacter stercorigallinarum” “Blautia stercorigallinarum” “Butyricicoccus avistercoris” “Eisenbergiella stercoravium” “Mediterraneibacter vanvlietii” “Acetatifactor stercoripullorum” “Borkfalkia faecipullorum” “Hungatella pullicola” “Blautia pullistercoris” “Anaerostipes excrementavium” “Fusicatenibacter merdavium” “Anaerotignum merdipullorum” “Mediterraneibacter stercoripullorum” “Borkfalkia excrementigallinarum” “Faecalibacterium gallistercoris” “Mediterraneibacter pullistercoris” “Limosilactobacillus intestinipullorum” “Intestinimonas stercoravium” “Merdibacter merdigallinarum” “Gemmiger stercoripullorum” “Borkfalkia stercoripullorum” “Enterocloster excrementipullorum” “Merdibacter merdavium” “Eisenbergiella intestinipullorum” “Gemmiger stercoravium” “Ruthenibacterium merdavium” “Mediterraneibacter excrementigallinarum”
Abstract
Background The chicken is the most abundant food animal in the world. However, despite its importance, the chicken gut microbiome remains largely undefined. Here, we exploit culture-independent and culture-dependent approaches to reveal extensive taxonomic diversity within this complex microbial community. Results We performed metagenomic sequencing of fifty chicken faecal samples from two breeds and analysed these, alongside all (n = 582) relevant publicly available chicken metagenomes, to c

Multi-omics Comparison Reveals Landscape of Citrus limon and Citrus sinensis Response to ‘Candidatus Liberibacter asiaticus’

Citation
Chin et al. (2021). PhytoFrontiers™ 1 (2)
Names
Ca. Liberibacter asiaticus
Abstract
Comparison of the metabolic changes prior to symptom development upon infection with Candidatus Liberibacter asiaticus (CLas), the bacterium associated with citrus greening disease, between citrus hosts with different tolerances is lacking. The objective of this study was to compare the early response of Lisbon lemon (Citrus limon) and Washington navel orange (Citrus sinensis [L.] Osbeck), two citrus species commercially important to California, to CLas through graft inoculation. Here, we compa

Production of nonulosonic acids in the extracellular polymeric substances of “Candidatus Accumulibacter phosphatis”

Citation
Tomás-Martínez et al. (2021). Applied Microbiology and Biotechnology 105 (8)
Names
“Accumulibacter” “Accumulibacter phosphatis”
Abstract
Abstract Nonulosonic acids (NulOs) are a family of acidic carbohydrates with a nine-carbon backbone, which include different related structures, such as sialic acids. They have mainly been studied for their relevance in animal cells and pathogenic bacteria. Recently, sialic acids have been discovered as an important compound in the extracellular matrix of virtually all microbial life and in “Candidatus Accumulibacter phosphatis”, a well-studied polyphosphate-accu

A new method for early detection of latent infection by ‘Candidatus Liberibacter asiaticus’ in citrus trees

Citation
Fujiwara et al. (2021). F1000Research 10
Names
Ca. Liberibacter asiaticus
Abstract
Background: ‘Candidatus Liberibacter asiaticus’ (CLas) is a major causal agent of citrus greening disease. The disease primarily involves an asymptomatic, often latent infection of CLas. However, there is no effective technique to distinguish latent-infected trees from healthy ones. This study describes the development of a new detection method for latent CLas infection using cuttings. Methods: Root tissues regenerated from cuttings using symptomatic and asymptomatic citrus trees were prepared f

Differential Response of Grapevine to Infection with ‘Candidatus Phytoplasma solani’ in Early and Late Growing Season through Complex Regulation of mRNA and Small RNA Transcriptomes

Citation
Dermastia et al. (2021). International Journal of Molecular Sciences 22 (7)
Names
Ca. Phytoplasma solani
Abstract
Bois noir is the most widespread phytoplasma grapevine disease in Europe. It is associated with ‘Candidatus Phytoplasma solani’, but molecular interactions between the causal pathogen and its host plant are not well understood. In this work, we combined the analysis of high-throughput RNA-Seq and sRNA-Seq data with interaction network analysis for finding new cross-talks among pathways involved in infection of grapevine cv. Zweigelt with ‘Ca. P. solani’ in early and late growing seasons. While t

Multiplex detection of “Candidatus Liberibacter asiaticus” and Spiroplasma citri by qPCR and droplet digital PCR

Citation
Maheshwari et al. (2021). PLOS ONE 16 (3)
Names
Ca. Liberibacter asiaticus
Abstract
“Candidatus Liberibacter asiaticus” (CLas) and Spiroplasma citri are phloem-limited bacteria that infect citrus and are transmitted by insect vectors. S. citri causes citrus stubborn disease (CSD) and is vectored by the beet leafhopper in California. CLas is associated with the devastating citrus disease, Huanglongbing (HLB), and is vectored by the Asian citrus psyllid. CLas is a regulatory pathogen spreading in citrus on residential properties in southern California and is an imminent threat to

Stably inherited transfer of the bacterial symbiont Candidatus Erwinia dacicola from wild olive fruit flies Bactrocera oleae to a laboratory strain

Citation
Livadaras et al. (2021). Bulletin of Entomological Research 111 (3)
Names
Ca. Erwinia dacicola
Abstract
AbstractThe olive fruit fly, Bactrocera oleae, the most serious pest of olives, requires the endosymbiotic bacteria Candidatus Erwinia dacicola in order to complete its development in unripe green olives. Hence a better understanding of the symbiosis of Ca. E. dacicola and its insect host may lead to new strategies for reduction of B. oleae and thus minimize its economic impact on olive production. Studies of this symbiosis are hampered as the bacterium cannot be grown in vitro and the establish