A multi-omic survey of black cottonwood tissues highlights coordinated transcriptomic and metabolomic mechanisms for plant adaptation to phosphorus deficiency.

Introduction: Phosphorus (P) deficiency in plants creates a variety of metabolic perturbations that decrease photosynthesis and growth. Phosphorus deficiency is especially challenging for the production of bioenergy feedstock plantation species, such as poplars (Populus spp.), where fertilization may not be practically or economically feasible. While the phenotypic effects of P deficiency are well known, the molecular mechanisms underlying whole-plant and tissue-specific responses to P deficiency, and in particular the responses of commercially valuable hardwoods, are less studied. Methods: We used a multi-tissue and multi-omics approach using transcriptomic, proteomic, and metabolomic analyses of the leaves and roots of black cottonwood (Populus trichocarpa) seedlings grown under P-deficient (5 µM P) and replete (100 µM P) conditions to assess this knowledge gap and to identify potential gene targets for selection for P efficiency. Results: In comparison to seedlings grown at 100 µM P, P-deficient seedlings exhibited reduced dry biomass, altered chlorophyll fluorescence, and reduced tissue P concentrations. In line with these observations, growth, C metabolism, and photosynthesis pathways were downregulated in the transcriptome of the P-deficient plants. Additionally, we found evidence of strong lipid remodeling in the leaves. Metabolomic data showed that the roots of P-deficient plants had a greater relative abundance of phosphate ion, which may reflect extensive degradation of P-rich metabolites in plants exposed to long-term P-deficiency. With the notable exception of the KEGG pathway for Starch and Sucrose Metabolism (map00500), the responses of the transcriptome and the metabolome to P deficiency were consistent with one another. No significant changes in the proteome were detected in response to P deficiency. Discussion and conclusion: Collectively, our multi-omic and multi-tissue approach enabled the identification of important metabolic and regulatory pathways regulated across tissues at the molecular level that will be important avenues to further evaluate for P efficiency. These included stress-mediating systems associated with reactive oxygen species maintenance, lipid remodeling within tissues, and systems involved in P scavenging from the rhizosphere.

We Can't Fail Again: Arguments for Professional Development in the Wake of COVID-19.

The majority of academic institutions were underprepared for a global pandemic, leading to spikes in instructor anxiety and drops in student engagement with STEM courses. With many STEM professors teaching online for the first time, they independently sought out training in distance education and inclusive teaching practices. Had institutions been proactive in providing such professional development prior to the pandemic, the negative impacts of transitioning to online education would have been reduced. While recent events are still fresh in people's minds, we advocate for increased or maintained professional development opportunities for STEM instructors in order to protect this critical pedagogical support from budget cuts.

A combination of morphology and 28S rRNA gene sequences provide grouping and ranking criteria to merge eight into three Ambispora species (Ambisporaceae, Glomeromycota).

Ambispora, the only genus in Ambisporaceae and one of three deeply rooted families in Archaeosporales, Glomeromycetes, is amended. Analysis of the morphology of specimens from types and living cultures and 28S ribosomal DNA (rDNA; LSU) sequences resulted in two major changes that redefined Ambispora to include only species with the potential for spore dimorphism (acaulosporoid and glomoid). First, species described as producing only glomoid spores (Ambispora leptoticha, Ambispora fecundispora, and Ambispora callosa), only acaulosporoid spores (Ambispora jimgerdemannii), or both spore morphotypes (Ambispora appendicula) were synonymized with a redefined dimorphic species, A. leptoticha. LSU sequences and more conserved SSU gene data indicated little divergence between genotypes formerly classified as separate species. Second, Ambispora fennica was synonymized with Ambispora gerdemannii based on morphological and LSU sequence variation equivalent to that measured in the sister clade A. leptoticha. With this analysis, Ambispora was reduced to three species: A. leptoticha, A. gerdemannii, and Ambispora granatensis. Morphological and molecular characters were given equal treatment in this study, as each data set informed and clarified grouping and ranking decisions. The two inner layers of the acaulosporoid spore wall were the only structural characters uniquely defining each of these three species; all other characters were shared. Phenotypes of glomoid spores were indistinguishable between species, and thus were informative only at the genus level. Distinct subclade structure of the LSU gene tree suggests fixation of discrete variants typical of clonal reproduction and possible retention of polymorphisms in rDNA repeats, so that not all discrete genetic variants are indicative of speciation.