Browsing by Author "Maldonado, Jonathan E."
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- ItemDNA sequencing in the classroom: complete genome sequence of two earwig (Dermaptera; Insecta) species(2023) Kobayashi, Sanae; Maldonado, Jonathan E.; Gaete, Alexis; Araya, Ingrid; Aguado-Norese, Constanza; Cumplido, Nicolás; Díaz, Sebastián; Espinoza, Alonso; Fernández, Edelmira; Gajardo, Felipe; González-Ordenes, Felipe; Hauyon, Khantati; Maldonado, Piedad; Maldonado, Rodrigo; Pochet, Isabel; Riveros, Aníbal; Sandoval, Paula; Sepúlveda-González, Ailynne; Stuardo, Camila; Tapia-Reyes, Patricio; Thornton, Carolina; Undurraga, Soledad; Varas, Macarena; Valdivieso, Camilo; Gutiérrez Ilabaca, Rodrigo Antonio; Orellana, Ariel; Montecino, Martín; Maass, Alejandro; González, Mauricio; Allende, Miguel L.; Hodar, Christian; Irles, PaulaBackground Despite representing the largest fraction of animal life, the number of insect species whose genome has been sequenced is barely in the hundreds. The order Dermaptera (the earwigs) suffers from a lack of genomic information despite its unique position as one of the basally derived insect groups and its importance in agroecosystems. As part of a national educational and outreach program in genomics, a plan was formulated to engage the participation of high school students in a genome sequencing project. Students from twelve schools across Chile were instructed to capture earwig specimens in their geographical area, to identify them and to provide material for genome sequencing to be carried out by themselves in their schools. Results The school students collected specimens from two cosmopolitan earwig species: Euborellia annulipes (Fam. Anisolabididae) and Forficula auricularia (Fam. Forficulidae). Genomic DNA was extracted and, with the help of scientific teams that traveled to the schools, was sequenced using nanopore sequencers. The sequence data obtained for both species was assembled and annotated. We obtained genome sizes of 1.18 Gb (F. auricularia) and 0.94 Gb (E. annulipes) with the number of predicted protein coding genes being 31,800 and 40,000, respectively. Our analysis showed that we were able to capture a high percentage (≥ 93%) of conserved proteins indicating genomes that are useful for comparative and functional analysis. We were also able to characterize structural elements such as repetitive sequences and non-coding RNA genes. Finally, functional categories of genes that are overrepresented in each species suggest important differences in the process underlying the formation of germ cells, and modes of reproduction between them, features that are one of the distinguishing biological properties that characterize these two distant families of Dermaptera. Conclusions This work represents an unprecedented instance where the scientific and lay community have come together to collaborate in a genome sequencing project. The versatility and accessibility of nanopore sequencers was key to the success of the initiative. We were able to obtain full genome sequences of two important and widely distributed species of insects which had not been analyzed at this level previously. The data made available by the project should illuminate future studies on the Dermaptera.
- ItemPartners to survive: Hoffmannseggia doellii root‐associated microbiome at the Atacama Desert(2022) Maldonado, Jonathan E.; Gaete, Alexis; Mandakovic, Dinka; Aguado‐Norese, Constanza; Aguilar, Melissa; Gutiérrez Ilabaca, Rodrigo Antonio; González, Mauricio
- ItemTesting the stress gradient hypothesis in soil bacterial communities associated with vegetation belts in the Andean Atacama Desert(2023) Mandakovic, Dinka; Aguado-Norese, Constanza; García-Jiménez, Beatriz; Hodar, Christian; Maldonado, Jonathan E.; Gaete, Alexis; Latorre, Mauricio; Wilkinson, Mark D.; Gutiérrez Ilabaca, Rodrigo Antonio; Cavieres, Lohengrin A.; Medina, Joaquín; Cambiazo, Verónica; Gonzalez, MauricioBackground Soil microorganisms are in constant interaction with plants, and these interactions shape the composition of soil bacterial communities by modifying their environment. However, little is known about the relationship between microorganisms and native plants present in extreme environments that are not affected by human intervention. Using high-throughput sequencing in combination with random forest and co-occurrence network analyses, we compared soil bacterial communities inhabiting the rhizosphere surrounding soil (RSS) and the corresponding bulk soil (BS) of 21 native plant species organized into three vegetation belts along the altitudinal gradient (2400–4500 m a.s.l.) of the Talabre–Lejía transect (TLT) in the slopes of the Andes in the Atacama Desert. We assessed how each plant community influenced the taxa, potential functions, and ecological interactions of the soil bacterial communities in this extreme natural ecosystem. We tested the ability of the stress gradient hypothesis, which predicts that positive species interactions become increasingly important as stressful conditions increase, to explain the interactions among members of TLT soil microbial communities. Results Our comparison of RSS and BS compartments along the TLT provided evidence of plant-specific microbial community composition in the RSS and showed that bacterial communities modify their ecological interactions, in particular, their positive:negative connection ratios in the presence of plant roots at each vegetation belt. We also identified the taxa driving the transition of the BS to the RSS, which appear to be indicators of key host-microbial relationships in the rhizosphere of plants in response to different abiotic conditions. Finally, the potential functions of the bacterial communities also diverge between the BS and the RSS compartments, particularly in the extreme and harshest belts of the TLT. Conclusions In this study, we identified taxa of bacterial communities that establish species-specific relationships with native plants and showed that over a gradient of changing abiotic conditions, these relationships may also be plant community specific. These findings also reveal that the interactions among members of the soil microbial communities do not support the stress gradient hypothesis. However, through the RSS compartment, each plant community appears to moderate the abiotic stress gradient and increase the efficiency of the soil microbial community, suggesting that positive interactions may be context dependent.