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1. Towards a Systems Biology Approach to Understanding the Lichen Symbiosis: Opportunities and Challenges of Implementing Network Modelling

   https://doi.org/10.3389/fmicb.2021.667864  

   Nazem-Bokaee, Hadi; Hom, Erik F.; Warden, Andrew C.; Mathews, Sarah; Gueidan, Cécile (May 2021, Frontiers in Microbiology)

   null (Ed.)

   Lichen associations, a classic model for successful and sustainable interactions between micro-organisms, have been studied for many years. However, there are significant gaps in our understanding about how the lichen symbiosis operates at the molecular level. This review addresses opportunities for expanding current knowledge on signalling and metabolic interplays in the lichen symbiosis using the tools and approaches of systems biology, particularly network modelling. The largely unexplored nature of symbiont recognition and metabolic interdependency in lichens could benefit from applying a holistic approach to understand underlying molecular mechanisms and processes. Together with ‘omics’ approaches, the application of signalling and metabolic network modelling could provide predictive means to gain insights into lichen signalling and metabolic pathways. First, we review the major signalling and recognition modalities in the lichen symbioses studied to date, and then describe how modelling signalling networks could enhance our understanding of symbiont recognition, particularly leveraging omics techniques. Next, we highlight the current state of knowledge on lichen metabolism. We also discuss metabolic network modelling as a tool to simulate flux distribution in lichen metabolic pathways and to analyse the co-dependence between symbionts. This is especially important given the growing number of lichen genomes now available and improved computational tools for reconstructing such models. We highlight the benefits and possible bottlenecks for implementing different types of network models as applied to the study of lichens. 

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2. An Online CURE Taught at a Community College During the Pandemic Shows Mixed Results for Development of Research Self-Efficacy and In-class Relationships

   https://doi.org/10.1007/s10956-023-10078-5  

   Dunbar-Wallis, Amy; Katcher, Jennifer; Moore, Wendy; Corwin, Lisa A. (October 2023, Journal of Science Education and Technology)

   Abstract The Bee the CURE is a novel course-based undergraduate research experience (CURE) that engages introductory biology students in DNA barcoding (DNA extraction, amplification, and bioinformatics) in partnership with the Tucson Bee Collaborative and the University of Arizona. The first iteration of this CURE taught at Pima Community College (PCC) occurred during the Fall 2020 semester in which the course was taught online and students focused on bioinformatics. Due to the online format, students were unable to participate directly in the wet-lab components (extraction and amplification) of the course. These were approximated with videos of the instructor performing the tasks. A qualitative case study of this semester built from student interviews found that students were able to form positive relationships with instructors and peer mentors but that the online format of the class posed some challenges to relationship formation. Students reported developing self-efficacy in bioinformatics skills while online lab participation disrupted student’s gaining “hands-on experiences” and seldom led to development of science self-efficacy in wet lab skills. Our findings from a study of a synchronous online CURE allowed us to characterize a context in which online learning posed a challenge and perhaps even a threat to research self-efficacy, especially regarding skill development and self-efficacy in “hands-on” areas, such as wet-bench research skills. Yet optimistically, our study highlights the potential of online community college learning environments to provide mastery experiences in online science contexts (e.g., bioinformatics) and opportunities for relationship building. 

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3. Soil-atmosphere fluxes of CO2, CH4, and N2O across an experimentally-grown, successional gradient of biocrust community types

   https://doi.org/10.3389/fmicb.2022.979825  

   Richardson, Andrew D; Kong, Gary V; Taylor, Katrina M; Le_Moine, James M; Bowker, Matthew A; Barber, Jarrett J; Basler, David; Carbone, Mariah S; Hayer, Michaela; Koch, George W; et al (September 2022, Frontiers in Microbiology)

   Biological soil crusts (biocrusts) are critical components of dryland and other ecosystems worldwide, and are increasingly recognized as novel model ecosystems from which more general principles of ecology can be elucidated. Biocrusts are often diverse communities, comprised of both eukaryotic and prokaryotic organisms with a range of metabolic lifestyles that enable the fixation of atmospheric carbon and nitrogen. However, how the function of these biocrust communities varies with succession is incompletely characterized, especially in comparison to more familiar terrestrial ecosystem types such as forests. We conducted a greenhouse experiment to investigate how community composition and soil-atmosphere trace gas fluxes of CO₂, CH₄, and N₂O varied from early-successional light cyanobacterial biocrusts to mid-successional dark cyanobacteria biocrusts and late-successional moss-lichen biocrusts and as biocrusts of each successional stage matured. Cover type richness increased as biocrusts developed, and richness was generally highest in the late-successional moss-lichen biocrusts. Microbial community composition varied in relation to successional stage, but microbial diversity did not differ significantly among stages. Net photosynthetic uptake of CO₂by each biocrust type also increased as biocrusts developed but tended to be moderately greater (by up to ≈25%) for the mid-successional dark cyanobacteria biocrusts than the light cyanobacterial biocrusts or the moss-lichen biocrusts. Rates of soil C accumulation were highest for the dark cyanobacteria biocrusts and light cyanobacteria biocrusts, and lowest for the moss-lichen biocrusts and bare soil controls. Biocrust CH₄and N₂O fluxes were not consistently distinguishable from the same fluxes measured from bare soil controls; the measured rates were also substantially lower than have been reported in previous biocrust studies. Our experiment, which uniquely used greenhouse-grown biocrusts to manipulate community composition and accelerate biocrust development, shows how biocrust function varies along a dynamic gradient of biocrust successional stages. 

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4. Hubbard Brook Experimental Forest: Gastropod lichen feeding trials

   https://doi.org/10.6073/pasta/a89248c1594cf0384e299ac19e3403da  

   Cleavitt, Natalie; Clyne, Ailis (January 2021, Environmental Data Initiative)

   Herbivory by terrestrial gastropods, particularly Arion sp., can alter lichen communities; however, little is known about this interaction in forests of North America. This data set reports the results of two feeding trials with slugs and snails from Hubbard Brook on seven lichen species. In feeding trials two common lichens, Hypogymnia physodes and Platismatia glauca, were grazed more heavily by both native and non-native slugs than other lichen species. 

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5. Design and implementation of an asynchronous online course-based undergraduate research experience (CURE) in computational genomics

   https://doi.org/10.1371/journal.pcbi.1012384  

   Plaisier, Seema B; Alarid, Danielle O; Denning, Joelle A; Brownell, Sara E; Buetow, Kenneth H; Cooper, Katelyn M; Wilson, Melissa A (September 2024, PLOS Computational Biology)

   Palagi, Patricia M (Ed.)

   As genomics technologies advance, there is a growing demand for computational biologists trained for genomics analysis but instructors face significant hurdles in providing formal training in computer programming, statistics, and genomics to biology students. Fully online learners represent a significant and growing community that can contribute to meet this need, but they are frequently excluded from valuable research opportunities which mostly do not offer the flexibility they need. To address these opportunity gaps, we developed an asynchronous course-based undergraduate research experience (CURE) for computational genomics specifically for fully online biology students. We generated custom learning materials and leveraged remotely accessible computational tools to address 2 novel research questions over 2 iterations of the genomics CURE, one testing bioinformatics approaches and one mining cancer genomics data. Here, we present how the instructional team distributed analysis needed to address these questions between students over a 7.5-week CURE and provided concurrent training in biology and statistics, computer programming, and professional development. Scores from identical learning assessments administered before and after completion of each CURE showed significant learning gains across biology and coding course objectives. Open-response progress reports were submitted weekly and identified self-reported adaptive coping strategies for challenges encountered throughout the course. Progress reports identified problems that could be resolved through collaboration with instructors and peers via messaging platforms and virtual meetings. We implemented asynchronous communication using the Slack messaging platform and an asynchronous journal club where students discussed relevant publications using the Perusall social annotation platform. The online genomics CURE resulted in unanticipated positive outcomes, including students voluntarily discussing plans to continue research after the course. These outcomes underscore the effectiveness of this genomics CURE for scientific training, recruitment and student-mentor relationships, and student successes. Asynchronous genomics CUREs can contribute to a more skilled, diverse, and inclusive workforce for the advancement of biomedical science. 

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