Data from: Novel microsatellite markers for epiphytic bromeliad Tillandsia recurvata L., in an urban landscape in South-eastern Brazil

The authors present seven novel microsatellite markers for Tillandsia recurvata L. The genome assemble sequences of T. recurvata were obtained from NCBI (7.2Gb) (Sayers et al. 2022). The BioProject Accession and accession numbers are PRJNA701548 and SRX10089449, respectively. The microsatellite identification software Krait (0.5.2) (Du et al. 2018) was used to detect suitable microsatellites, both genome-wide and in the noncoding regions of T. recurvata. The single sequence repeats (SSRs) were refined to a minimum number of seven repeats of di-, tri-, or tetra-nucleotide repeat motifs. These sequences were further limited to SSRs of more than 100bp in length and low GC content (<50%). Krait (0.5.2) (Du et al. 2018) was also used to design the primers for the selected SSR sequences, in conjunction with the integrated Primer3 software. The criteria for primer selection included: a primer length of 18-26bp, an optimal melting temperature (Tm) of 54-59°C and GC content of <50%. These designed primers were single-plexed and amplified using the following PCR cycle: initial denaturation (95°C for 3 min), 34 cycles of 95°C for 30s, annealing for 30s (JP01-JP12: 54°C, 4873TD + 35251TD: 56°C, 19286TD: 53°C, 5044TD + 186664TD + 214633TD: 58°C), 72°C for 1 min and a final extension of 72°C for 5 mins. The authors make this information available to other researchers, to continue the investigation of epiphyte genetics

Phylogenetic diversity and the structure of host-epiphyte interactions across the Neotropics

Understanding the mechanisms driving community assembly has been a major focus of ecological research for nearly a century, yet little is known about these mechanisms in commensal communities, particularly with respect to their historical/evolutionary components. Here, we use a large-scale dataset of 4,440 vascular plant species to explore the relationship between the evolutionary distinctiveness (ED) (as measured by the 'species evolutionary history' (SEH)) of host species and the phylogenetic diversity (PD) of their associated epiphyte species. Although there was considerable variation across hosts and their associated epiphyte species, they were largely unrelated to host SEH. Our results mostly support the idea that the determinants of epiphyte colonization success might involve host characteristics that are unrelated to host SEH (e.g., architectural differences between hosts). While determinants of PD of epiphyte assemblages are poorly known, they do not appear to be related to the evolutionary history of host species. Instead, they might be better explained by neutral processes of colonization and extinction. However, the high level of phylogenetic signal in epiphyte PD (independent of SEH) suggests it might still be influenced by yet unrecognized evolutionary determinants. This study highlights how little is still known about the phylogenetic determinants of epiphyte communities

Discovery of a single male Aedes aegypti (L.) in Merseyside, England

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Data from: Novel microsatellite markers for epiphytic bromeliad Tillandsia recurvata L., in an urban landscape in South-eastern Brazil

The authors present seven novel microsatellite markers for Tillandsia recurvata L. The genome assemble sequences of T. recurvata were obtained from NCBI (7.2Gb) (Sayers et al. 2022). The BioProject Accession and accession numbers are PRJNA701548 and SRX10089449, respectively. The microsatellite identification software Krait (0.5.2) (Du et al. 2018) was used to detect suitable microsatellites, both genome-wide and in the noncoding regions of T. recurvata. The single sequence repeats (SSRs) were refined to a minimum number of seven repeats of di-, tri-, or tetra-nucleotide repeat motifs. These sequences were further limited to SSRs of more than 100bp in length and low GC content (<50%). Krait (0.5.2) (Du et al. 2018) was also used to design the primers for the selected SSR sequences, in conjunction with the integrated Primer3 software. The criteria for primer selection included: a primer length of 18-26bp, an optimal melting temperature (Tm) of 54-59°C and GC content of <50%. These designed primers were single-plexed and amplified using the following PCR cycle: initial denaturation (95°C for 3 min), 34 cycles of 95°C for 30s, annealing for 30s (JP01-JP12: 54°C, 4873TD + 35251TD: 56°C, 19286TD: 53°C, 5044TD + 186664TD + 214633TD: 58°C), 72°C for 1 min and a final extension of 72°C for 5 mins. The authors make this information available to other researchers, to continue the investigation of epiphyte genetics