Publications

3806

Abstract A new distribution map is provided for Candidatus Phytoplasma cynodontis Marcone et al. Mollicutes: Acholeplasmatales: Acholeplasmataceae. Main host: Bermuda grass ( Cynodon dactylon ). Information is given on the geographical distribution in Africa (Ethiopia, Kenya, Sudan, Tanzania, Uganda), Asia (China, India, Karnataka, Kerala, Madhya Pradesh, Tamil Nadu, Uttar Pradesh, Indonesia, Iran, Iraq, Israel, Malaysia, Myanmar, Pakistan, Saudi Arabia, Singapore, Sri Lanka, Taiwan, Thailand, Turkey, Vietnam), Europe (Albania, Italy, Serbia), North America (Cuba), Oceania (Australia, Northern Territory, Western Australia).

Grapevine Bois noir (BN) is associated with ‘Candidatus Phytoplasma solani’. It has been recorded in vineyards throughout Europe as well as in different countries in Asia, where it now constitutes a threat to Iranian viticulture. BN is strictly dependent on ‘Ca. P. solani’ strains, wild host plants, and insect vectors. The molecular typing of ‘Ca. P. solani’, based on the nonribosomal gene tuf and the two hypervariable markers vmp1 and stamp, is valuable for the reconstruction and clarification of the pathways of BN spread. In this study, an RFLP analysis was performed on the vmp1 gene, and a single-nucleotide polymorphism analysis confirmed new vmp types in ‘Ca. P. solani’. A stamp gene phylogenetic analysis allowed us to distinguish between the new genotype infections in the grapevines and the ‘weeds’ Convolvulus arvensis and Erigeron bonariensis in Iranian vineyards, highlighting the close genetic relatedness of the strains of ‘Ca. P. solani’ found in Iran and Azerbaijan. The most common genotype in the grapevines was tuf b/V24/stamp III, which was associated with C. arvensis. This information contributes toward the identification of further routes of introduction of ‘Ca. P. solani’ in Iran to sustain the control measures for the management of BN.

‘Candidatus Liberibacter solanacearum’ (CaLsol) is an uncultured bacterium, transmitted by psyllids and associated with several diseases in Solanaceae and Apiaceae crops. CaLsol detection in psyllids often requires insect destruction, preventing a subsequent morphological identification. In this work, we have assessed the influence on the detection of CaLsol by PCR in Bactericera trigonica (Hemiptera: Psyllidae), of four specimen preparations (entire body, ground, cut-off head, and punctured abdomen) and seven DNA extraction methods (PBS suspension, squashing on membrane, CTAB, Chelex, TRIsureTM, HotSHOT, and DNeasy®). DNA yield and purity ratios, time consumption, cost, and residues generated were also evaluated. Optimum results were obtained through grinding, but it is suggested that destructive procedures are not essential in order to detect CaLsol. Although CaLsol was detected by qPCR with DNA obtained by the different procedures, HotSHOT was the most sensitive method. In terms of time consumption and cost, squashed on membrane, HotSHOT, and PBS were the fastest, while HotSHOT and PBS were the cheapest. In summary, HotSHOT was accurate, fast, simple, and sufficiently sensitive to detect this bacterium within the vector. Additionally, cross-contamination with CaLsol was assessed in the ethanol solutions where B. trigonica specimens were usually collected and preserved. CaLsol-free psyllids were CaLsol-positive after incubation with CaLsol-positive specimens. This work provides a valuable guide when choosing a method to detect CaLsol in vectors according to the purpose of the study.

AbstractThe phylum “Candidatus Nanohaloarchaeota” is a representative halophilic lineage within DPANN superphylum. They are characterized by their nanosized cells and symbiotic lifestyle with Halobacteria. However, the development of the symbiosis remains unclear for the lack of genomes located at the transition stage. Here, we performed a comparative genomic analysis of “Ca. Nanohaloarchaeota”. We propose a novel family “Candidatus Nanoanaerosalinaceae” represented by five de-replicated metagenome-assembled genomes obtained from hypersaline sediments and the enrichment cultures of soda-saline lakes. Phylogeny analysis reveals that the novel family are placed at the root of the family “Candidatus Nanosalinaceae” including the well-researched taxa. Most members of “Ca. Nanoanaerosalinaceae” contain lower proportion of putative horizontal gene transfers from Halobacteria than “Ca. Nanosalinaceae”, while they maintain moderately acidic proteomes for hypersaline adaptation of “salt-in” strategy, suggesting that “Ca. Nanoanaerosalinaceae” have not established an intimate association with Halobacteria, and may descend from an intermediate stage. Functional prediction discloses that they exhibit divergent potentials in carbohydrate and organic acids metabolism, and environmental responses. Historical events reconstruction illustrates that the involved genes acquired at the putative ancestors possibly drive the evolutionary and symbiotic divergences. Globally, this research on the new family “Ca. Nanoanaerosalinaceae” enriches the taxonomic and functional diversity of “Ca. Nanohaloarchaeota”, and provides insights into the evolutionary process of “Ca. Nanohaloarchaeota” and their Halobacteria-associated symbiosis.ImportanceDPANN superphylum is a group of archaea widely distributing in various habitats. They generally have small cells, and perform a symbiotic lifestyle with other archaea. The archaeal symbiotic interaction is important to understand microbial community. However, the formation and evolution of the symbiosis between the DPANN lineages and other diverse archaea remain unclear. Based on phylogeny, hypersaline adaptation, functional potentials, and historical events of “Ca. Nanohaloarchaeota”, a representative phylum within the DPANN superphylum, we report a novel family descending from an intermediate stage, and we illustrate the evolutionary process of “Ca. Nanohaloarchaeota” and their Halobacteria-associated symbiosis. Furthermore, we find the acquired genes involved in carbohydrate and organic acids metabolism and environmental responses possibly drive the evolutionary and symbiotic divergences. Altogether, this research helps in understanding the evolution of the archaeal symbiosis, and provides a model for the evolution of the other DPANN lineages.

As the causal agent of the grapevine yellows disease Bois noir, ‘Candidatus Phytoplasma solani' has a major economic impact on grapevines. To improve the control of Bois noir, it is critical to understand the very complex epidemiological cycles that involve the multiple “Ca. P. solani” host plants and insect vectors, of which Hyalesthes obsoletus is the most important. In the present study, multiple genotyping of the tuf, secY, stamp, and vmp1 genes was performed. This involved archived grapevine samples that were collected during an official survey of grapevine yellows throughout the wine-growing regions of Slovenia (from 2003 to 2016), plus samples from Austrian grapevines, stinging nettle, field bindweed, and insect samples (collected from 2012 to 2019). The data show that the tuf-b2 type of the tuf gene has been present in eastern Slovenia since at least 2003. The hypotheses that the occurrence of the haplotypes varies due to the geographical position of Slovenia on the Italian–Slovenian Karst divide and that the haplotypes are similar between Slovenian and Austrian Styria were confirmed. The data also show haplotype changes for host plants and H. obsoletus associated with ‘Ca. P. solani,' which might be linked to new epidemiological cycles of this phytoplasma that involve not just new plant sources and new insect vectors, but also climate and land-use changes.

Objetivo. Informe sobre especies de garrapatas que parasitan a los humanos en un área del bioma semiárido de Caatinga, noreste de Brasil, con nota de infección por rickettsias. Materiales y métodos. Todas las garrapatas se identificaron morfológicamente con estereomicroscopio. Algunas de las garrapatas recolectadas se analizaron molecularmente para detectar la presencia de ADN de bacterias del género Rickettsia. Las garrapatas se sometieron individualmente a la extracción de ADN (gen de la citrato sintasa [gltA] y gen de la proteína de la membrana externa [ompA]). Resultados. Se recolectaron un total de 78 garrapatas en humanos, identificadas como adultos de Amblyomma parvum (62 hembras y 16 machos). De estas, 15 mujeres fueron infectadas por ‘Candidatus Rickettsia andeanae’. Conclusiones. El presente estudio confirma una zona más de riesgo humano de picaduras de garrapatas en Brasil, también de la rickettsia no patógena 'Ca. Rickettsia andeanae'

AbstractMembers of the bacterial genusRickettsiawere originally identified as causative agents of vector-borne diseases in mammals. However, manyRickettsiaspecies are arthropod symbionts and close relatives of ‘CandidatusMegaira’, which are symbiotic associates of microeukaryotes. Here, we clarify the evolutionary relationships between these organisms by assembling 26 genomes ofRickettsiaspecies from understudied groups, including the Torix group, and two genomes of ‘Ca. Megaira’ from various insects and microeukaryotes. Our analyses of the new genomes, in comparison with previously described ones, indicate that the accessory genome diversity and broad host range of TorixRickettsiaare comparable to those of all otherRickettsiacombined. Therefore, the Torix clade may play unrecognized roles in invertebrate biology and physiology. We argue this clade should be given its own genus status, for which we propose the name ‘CandidatusTisiphia’.

Abstract Microbes are the most abundant form of life on Earth and play crucial roles in carbon and nutrient cycling. Despite their crucial role, our understanding of microbial diversity and physiology on the ocean floor is limited. To address this gap in knowledge, we obtained 55 novel bacterial metagenome-assembled genomes (MAGs) from coastal and deep sea sediments. Phylogenomic analyses revealed they belong to four new and one poorly described bacterial phyla. Comparison of their rRNA genes with public databases revealed they are all globally distributed. These novel bacteria are capable of the anaerobic degradation of polysaccharides and proteins, and the respiration of sulfur and nitrogen. These genomes code for an unusually high proportion (~ 9, and up to 20% per genome) of protein families lacking representatives in public databases. Hundreds of these protein families are predicted to be co-localized with genes for sulfur reduction, nitrogen cycling, energy conservation, and the degradation of organic compounds. These findings expand our understanding of microbial diversity and link previously overlooked gene families with key metabolic processes in the oceans.