Team science: A syllabus for success on big projects.

Interdisciplinary teams are on the rise as scientists attempt to address complex environmental issues. While the benefits of team science approaches are clear, researchers often struggle with its implementation, particularly for new team members. The challenges of large projects often weigh on the most vulnerable members of a team: trainees, including undergraduate students, graduate students, and post-doctoral researchers. Trainees on big projects have to navigate their role on the team, with learning project policies, procedures, and goals, all while also training in key scientific tasks such as co-authoring papers. To address these challenges, we created and participated in a project-specific, graduate-level team science course. The purposes of this course were to: (1) introduce students to the goals of the project, (2) build trainees' understanding of how big projects operate, and (3) allow trainees to explore how their research interests dovetailed with the overall project. Additionally, trainees received training regarding: (1) diversity, equity & inclusion, (2) giving and receiving feedback, and (3) effective communication. Onboarding through the team science course cultivated psychological safety and a collaborative student community across disciplines and institutions. Thus, we recommend a team science course for onboarding students to big projects to help students establish the skills necessary for collaborative research. Project-based team science classes can benefit student advancement, enhance the productivity of the project, and accelerate the discovery of solutions to ecological issues by building community, establishing a shared project vocabulary, and building a workforce with collaborative skills to better answer ecological research questions.

A blended model to support brief interventions in primary care: A qualitative study of usability and acceptability of HealthEir in community pharmacy.

BACKGROUND: Brief interventions for lifestyle behaviour change are effective health promotion interventions. Primary care settings, including pharmacies, are the most frequently visited healthcare facilities and are well placed to provide brief health interventions. However, despite the evidence-based and policy guidance, barriers to brief interventions have limited their implementation. OBJECTIVES: This study aimed to explore the usability and acceptability of HealthEir, a blended model with digital, print, and communication elements designed to support the delivery of brief health-promoting interventions in pharmacy practice. METHODS: Usability tests using a think aloud protocol and set tasks (to assess usability) and semi-structured interviews (to assess acceptability) were conducted with fifteen patients and twelve pharmacists. Usability data were analysed deductively using Nielsen's five quality components of usability as a framework. Acceptability data were analysed using inductive thematic analysis. FINDINGS: All participants found HealthEir straightforward to use and completed the required tasks without assistance. A small number of patient and pharmacist participants identified opportunity for improvement of the digital element. Acceptability was also high, with individual comments from participants identifying opportunity for improvements to HealthEir, and two patients identifying privacy or safety concerns. The majority of comments regarding acceptability reflected wider social and cultural challenges such as perceptions of the roles of pharmacists and pharmacies and the low priority of preventative health interventions. CONCLUSION: HealthEir has been demonstrated to be a usable and acceptable support that has the potential to overcome barriers to delivery of brief interventions in pharmacies. Usability and acceptability testing identified minor changes that may further improve its design prior to piloting and implementation.

Hyaluronan modulates growth factor induced mammary gland branching in a size dependent manner.

Mammary gland morphogenesis begins during fetal development but expansion of the mammary tree occurs postnatally in response to hormones, growth factors and extracellular matrix. Hyaluronan (HA) is an extracellular matrix polysaccharide that has been shown to modulate growth factor-induced branching in culture. Neither the physiological relevance of HA to mammary gland morphogenesis nor the role that HA receptors play in these responses are currently well understood. We show that HA synthase (HAS2) is expressed in both ductal epithelia and stromal cells but HA primarily accumulates in the stroma. HA accumulation and expression of the HA receptors CD44 and RHAMM are highest during gestation when gland remodeling, lateral branch infilling and lobulo-alveoli formation is active. Molecular weight analyses show that approximately 98% of HA at all stages of morphogenesis is >300kDa. Low levels of 7-114kDa HA fragments are also detected and in particular the accumulation of 7-21kDa HA fragments are significantly higher during gestation than other morphogenetic stages (p<0.05). Using these in vivo results as a guide, in culture analyses of mammary epithelial cell lines (EpH4 and NMuMG) were performed to determine the roles of high molecular weight, 7-21kDa (10kDa MWavg) and HA receptors in EGF-induced branching morphogenesis. Results of these assays show that while HA synthesis is required for branching and 10kDa HA fragments strongly stimulate branching, the activity of HA decreases with increasing molecular weight and 500kDa HA strongly inhibits this morphogenetic process. The response to 10kDa HA requires RHAMM function and genetic deletion of RHAMM transiently blunts lateral branching in vivo. Collectively, these results reveal distinct roles for HA polymer size in modulating growth factor induced mammary gland branching and implicates these polymers in both the expansion and sculpting of the mammary tree during gestation.

Genome sequence of the plant-pathogenic bacterium Dickeya dadantii 3937.

Dickeya dadantii is a plant-pathogenic enterobacterium responsible for the soft rot disease of many plants of economic importance. We present here the sequence of strain 3937, a strain widely used as a model system for research on the molecular biology and pathogenicity of this group of bacteria.

Phylogeographic genomics of mitochondrial DNA: Highly-resolved patterns of intraspecific evolution and a multi-species, microarray-based DNA sequencing strategy for biodiversity studies.

Phylogeographic genomics, based on multiple complete mtDNA genome sequences from within individual vertebrate species, provides highly-resolved intraspecific trees for the detailed study of evolutionary biology. We describe new biogeographic and historical insights from our studies of the genomes of codfish, wolffish, and harp seal populations in the Northwest Atlantic, and from the descendants of the founding human population of Newfoundland. Population genomics by conventional sequencing methods remains laborious. A new biotechnology, iterative DNA "re-sequencing", uses a DNA microarray to recover 30-300 kb of contiguous DNA sequence in a single experiment. Experiments with a single-species mtDNA microarray show that the method is accurate and efficient, and sufficiently species-specific to discriminate mtDNA genomes of moderately-divergent taxa. Experiments with a multi-species DNA microarray (the "ArkChip") show that simultaneous sequencing of species in different orders and classes detects SNPs within each taxon with equal accuracy as single-species-specific experiments. Iterative DNA sequencing offers a practical method for high-throughput biodiversity genomics that will enable standardized, coordinated investigation of multiple species of interest to Species at Risk and conservation biologists.

Interspecies hybridization on DNA resequencing microarrays: efficiency of sequence recovery and accuracy of SNP detection in human, ape, and codfish mitochondrial DNA genomes sequenced on a human-specific MitoChip.

BACKGROUND: Iterative DNA "resequencing" on oligonucleotide microarrays offers a high-throughput method to measure intraspecific iodiversity, one that is especially suited to SNP-dense gene regions such as vertebrate mitochondrial (mtDNA) genomes. However, costs of single-species design and microarray fabrication are prohibitive. A cost-effective, multi-species strategy is to hybridize experimental DNAs from diverse species to a common microarray that is tiled with oligonucleotide sets from multiple, homologous reference genomes. Such a strategy requires that cross-hybridization between the experimental DNAs and reference oligos from the different species not interfere with the accurate recovery of species-specific data. To determine the pattern and limits of such interspecific hybridization, we compared the efficiency of sequence recovery and accuracy of SNP identification by a 15,452-base human-specific microarray challenged with human, chimpanzee, gorilla, and codfish mtDNA genomes. RESULTS: In the human genome, 99.67% of the sequence was recovered with 100.0% accuracy. Accuracy of SNP identification declines log-linearly with sequence divergence from the reference, from 0.067 to 0.247 errors per SNP in the chimpanzee and gorilla genomes, respectively. Efficiency of sequence recovery declines with the increase of the number of interspecific SNPs in the 25b interval tiled by the reference oligonucleotides. In the gorilla genome, which differs from the human reference by 10%, and in which 46% of these 25b regions contain 3 or more SNP differences from the reference, only 88% of the sequence is recoverable. In the codfish genome, which differs from the reference by > 30%, less than 4% of the sequence is recoverable, in short islands > or = 12b that are conserved between primates and fish. CONCLUSION: Experimental DNAs bind inefficiently to homologous reference oligonucleotide sets on a re-sequencing microarray when their sequences differ by more than a few percent. The data suggest that interspecific cross-hybridization will not interfere with the accurate recovery of species-specific data from multispecies microarrays, provided that the species' DNA sequences differ by > 20% (mean of 5b differences per 25b oligo). Recovery of DNA sequence data from multiple, distantly-related species on a single multiplex gene chip should be a practical, highly-parallel method for investigating genomic biodiversity.