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The family Staphylococcacae and genus Gemella contain several organisms of clinical or biotechnological importance. We report here comprehensive phylogenomic and comparative analyses on 112 available genomes from species in these taxa to clarify their evolutionary relationships and classification. In a phylogenomic tree based on 678 core proteins, Gemella species were separated from Staphylococcacae by a long branch indicating that they constitute a distinct family (Gemellaceae fam. nov.). In this tree, Staphylococcacae species formed two main clades, one encompassing the genera Aliicoccus, Jeotgalicoccus, Nosocomiicoccus and Salinicoccus (Family “Salinicoccaceae”), while the other clade consisted of the genera Macrococcus, Mammaliicoccus and Staphylococcus (Family Staphylococcaceae emend.). In this tree, species from the genera Gemella, Jeotgalicoccus, Macrococcus and Salinicoccus each formed two distinct clades. Two species clades for these genera are also observed in 16S rRNA gene trees and supported by average amino acid identity analysis. We also report here detailed analyses on protein sequences from Staphylococcaceae and Gemella genomes to identify conserved signature indels (CSIs) which are specific for different genus and family-level clades. These analyses have identified 120 novel CSIs robustly demarcating different proposed families and genera. The identified CSIs provide independent evidence that the genera Gemella, Jeotgalicoccus, Macrococcus and Salinicoccus consist of two distinct clades, which can be reliably distinguished based on multiple exclusively shared CSIs. We are proposing transfers of the species from the novel clades of the above four genera into the genera Gemelliphila gen. nov., Phocicoccus gen. nov., Macrococcoides gen. nov. and Lacicoccus gen. nov., respectively. The identified CSIs also provide strong evidence for division of Staphylococcaceae into an emended family Staphylococcaceae and two new families, Abyssicoccaceae fam. nov. and Salinicoccaceae fam. nov. All of these families can be reliably demarcated based on several exclusively shared CSIs.

Species descriptions of reptiles historically have relied exclusively on the use of morphological data; however, these external, phenotypic data do not always co-vary with lineage divergence. Consequently, it has become increasingly clear that species diversity has been underestimated in many evolutionary radiations. With the use of an integrative approach, we examined the genetic and morphological diversity present in a nearly endemic Philippine radiation of Eutropis. Results demonstrated that current taxonomy does not reflect evolutionary history and that in many cases, morphological divergence has become decoupled from genetic divergence. As a consequence, species diversity is significantly underestimated. Here, we rectify the major taxonomic problems present in Philippine Eutropis by providing formal descriptions for eight new species. Three of the four new species in the E. multicarinata species complex are sympatric with (and have long been confused with) previously described subspecies (which we also elevate to full species here). The fourth species is endemic to the Caroline Islands, clearly derived from a long-distance dispersal event from the Philippines. The new species in the E. indeprensa species complex are allopatrically or parapatrically distributed across the archipelago. In contrast to the last review of Philippine Eutropis, which suggested the endemic radiation was composed of five species (one of which was composed of two subspecies), we demonstrate that this group includes at least 14 distinct evolutionary lineages, with potential for additional diversity to be discovered pending further study.

Background Members of the family Roseobacteraceae are metabolically, phenotypically, and genotypically diverse and are widely distributed in global marine environments. This family comprises over 150 validly published genera and nearly 500 validly published species. Despite its widespread use, 16S rRNA gene sequence analysis has proven inadequate for accurately resolving taxonomic relationships within the Roseobacteraceae , resulting in significant inconsistencies in the current classification of this family. Notably, a significant proportion of Roseobacteraceae genera contain only one species, suggesting a potential for over-splitting. To address this issue, we investigated the taxonomic status of three genera, Antarctobacter , Mameliella , and Maliponia , which were originally delineated based on 16S rRNA data. Results Our phylogenomic analyses, based on single-copy orthologous clusters and a bacterial core gene set, revealed that species from these three genera form a robust and distinct clade. Furthermore, genome-wide similarity indices, including average amino acid identity (AAI), percentage of conserved proteins (POCP), genome-wide average nucleotide identity (gANI), and alignment fraction (AF), consistently indicated a close relatedness among these genera. Analysis of the available phenotypic features also revealed that species of the genera Antarctobacter , Mameliella and Maliponia are very closely related and lack distinct characteristics. Conclusions Our findings suggest that Antarctobacter , Mameliella , and Maliponia may represent a single genus. We therefore propose that Mameliella and Maliponia species should be reclassified as members of the genus Antarctobacter . This re-evaluation contributes to the ongoing effort to refine the taxonomy of the Roseobacteraceae , correct historical misclassifications, and reduce the proliferation of underpopulated genera within this ecologically important family. This reclassification provides a more accurate framework for studying the evolution, diversity, and ecological roles of these bacteria, and allows researchers to focus on more significant variations among species. Our results help establish a more reasonable taxonomy within the family Roseobacteraceae .

The orders Cellvibrionales , Oceanospirillales , and Pseudomonadales , as three major orders of the largest bacterial class, Gammaproteobacteria , play important roles in various ecosystems as the keystone taxa of microbiomes, but their evolutionary relationship is currently polyphyletic and chaotic. Here, we constructed a bac120 tree and core-genome tree and calculated the amino acid identity (AAI) value to explore their intrinsic evolutionary history. In this study, we proposed two novel orders and three novel families. This evolution study vastly reconstructed the taxonomic framework of class Gammaproteobacteria and could provide a more distinct perspective on global distribution and evolutionary patterns of these environmental microorganisms. Orders Oceanospirillales and Pseudomonadales play important roles in various ecosystems as the keystone taxa of microbiomes. However, the two orders present a close evolutionary relationship, which might have caused taxonomic misinterpretation and resulted in an incorrect understanding of their evolutionary history. In this study, first, we used the 16S rRNA gene sequences of 2,049 species of Gammaproteobacteria to build a phylogenetic tree, which demonstrated that reports regarding the evolutionary relationship of orders Cellvibrionales , Oceanospirillales , and Pseudomonadales based on a single conserved gene with a poor resolution have been conflicting; in particular, the major families Moraxellaceae and Pseudomonadaceae of order Pseudomonadales were separated from orders Cellvibrionales and Oceanospirillales . Subsequently, we constructed the bac120 trees of all representative reference genomes of class Gammaproteobacteria based on 120 ubiquitous single-copy proteins from bacteria and a phylogenomic tree based on the 119 core genes of 257 reference genomes obtained from orders Cellvibrionales , Oceanospirillales , and Pseudomonadales to cross validate and infer their intrinsic evolutionary relationships. These results indicated that two novel orders, Moraxellales ord. nov. and Kangiellales ord. nov., and three novel families, Marinobacteraceae fam. nov., Perlucidibacaceae fam. nov., and Zooshikellaceae fam. nov., should be proposed. Additionally, orders Cellvibrionales and Oceanospirillales were merged into the order Pseudomonadales except for families Moraxellaceae and Kangiellaceae in class Gammaproteobacteria , which currently includes 18 families. Our work sheds some light on the evolutionary history of class Gammaproteobacteria , which could facilitate the detection and taxonomic analysis of natural communities. IMPORTANCE The orders Cellvibrionales , Oceanospirillales , and Pseudomonadales , as three major orders of the largest bacterial class, Gammaproteobacteria , play important roles in various ecosystems as the keystone taxa of microbiomes, but their evolutionary relationship is currently polyphyletic and chaotic. Here, we constructed a bac120 tree and core-genome tree and calculated the amino acid identity (AAI) value to explore their intrinsic evolutionary history. In this study, we proposed two novel orders and three novel families. This evolution study vastly reconstructed the taxonomic framework of class Gammaproteobacteria and could provide a more distinct perspective on global distribution and evolutionary patterns of these environmental microorganisms.

Three novel facultatively methylotrophic bacteria, strains 3CT, 1A, 8P, were isolated from activated sludges. The isolates were aerobic, Gram-stain-negative, non-motile, non-spore forming rods multiplying by binary fission. The predominant polar lipids were phosphatidylcholine, phosphatidylglycerol, phosphatidylethylethanolamine, phosphatidylmonomethylethanolamine, and diphosphatidylglycerol. The major fatty acids of cells were С18:1ω7c, C19:0ω8c cyclo and C16:0. Levels of 16S rRNA gene similarity indicates that the closely relatives are representatives of the genera Starkeya, Ancylobacter, Angulomicrobium and Methylorhabdus (96.4–99.4%). Genomic comparisons of 3CT and its closest relatives, S. novella DSM 506T and S. koreensis Jip08T, shared 87.3 and 86.8% nucleotide identity and 28.3 and 26.8% digital DNA–DNA hybridization values, respectively. The average amino acid identities between the strain 3CT and representatives of Starkeya, Ancylobacter and Angulomicrobium were in the range of 75.6–84.3%, which combines these strains into a single genus and gives rise to their reclassification. Based on polyphasic analyses, the strains 3CT, 1A, 8P represents a novel species of the genus Ancylobacter, for which the name Ancylobacter moscoviensis sp. nov. is proposed. The type strain is 3CT (= VKM B-3218T = KCTC 62336T). Furthermore, we also suggested the reclassification of Starkeya novella as Ancylobacter novellus comb. nov., Starkeya koreensis as Ancylobacter koreensis comb. nov., Angulomicrobium tetraedrale as Ancylobacter tetraedralis comb. nov., Angulomicrobium amanitiforme as Ancylobacter amanitiformis comb. nov. and Methylorhabdus multivorans as Ancylobacter multivorans comb. nov. with the emended description of the genus Ancylobacter.

The literature on the geography of subjective well-being largely converges in pointing out the occurrence, at least in developed countries, of an urban/rural divide: people living in the most urbanized regions tend to be significantly less satisfied than those living in rural areas. This paper aims at reassessing this statement by taking into consideration an important aspect, frequently overlooked in the literature, i.e. people-based characteristics. Individuals are not alike and may differently experience and appreciate the advantages and disadvantages of urbanisation. Characteristics such as the level of education, the type of occupation and, more generally, the income level can mediate the capacity to reap urbanisation advantages (as the accessibility to advanced services and diversified job markets) and mitigate urbanization disadvantages (such as cost of living and congestion). Additionally, but based on the same reasoning, more educated and affluent individuals (negatively) value distance from top rank centres more than less educated and affluent ones. We test and prove these propositions in a study on the subjective well-being of more than 250,000 individuals living in European cities, defined as NUTS3 regions, in the period 2004–2010.

Seven new species of Cichlidogyrus Paperna, 1960 (Monogenea: Dactylogyridae) isolated from the gills of six cichlid host species belonging to four tribes and sampled from the Congolese coastline of Lake Tanganyika (LT) are described: Cichlidogyrus adkoningsi sp. nov. from Cyphotilapia frontosa (tribe Cyphotilapiini); C. koblmuelleri sp. nov. from Cardiopharynx schoutedeni (Ectodini); C. habluetzeli sp. nov. from C. schoutedeni and C. frontosa ; C. antoineparisellei sp. nov. from Interochromis loocki (Tropheini); C. masilyai sp. nov. from Petrochromis orthognathus (Tropheini); C. salzburgeri sp. nov. from P. trewavasae , and C. sergemorandi sp. nov. from Tylochromis polylepis (Tylochromini). This study represents the first parasitological examination of cyphotilapiine cichlid hosts. Representatives of the Tanganyikan ectodine, tropheine, and tylochromine cichlids previously sampled from various localities in the lake yielded nine, twelve, and two described species of Cichlidogyrus , respectively. The study further includes a morphological characterization of the male copulatory organ of six undescribed species of Cichlidogyrus found on the gills of the tropheines I. loocki and P. orthognathus, and on those of Callochromis melanostigma and Xenotilapia flavipinnis (both Ectodini). Geographical variation in the monogenean fauna of I. loocki was observed. The most closely related cichlid species investigated in this study harboured Cichlidogyrus spp. exhibiting some similarities in their sclerotized structures. Thus, our paper provides additional evidence of the high species richness of Cichlidogyrus and the link with their hosts’s phylogenetic affinities in LT.