Increasing Undergraduate Student Knowledge about Journal Peer Review Using Outside Reading and In-Class Discussion.

Peer review is an important part of the scientific publishing process that serves as a key quality control step. Learning that scientific publications go through peer review builds scientific literacy and may increase trust in published findings. Though the publication and peer review process is an established part of the practice of communicating science, this topic is not commonly taught at the undergraduate level, even in classes that regularly require students to read primary literature or author manuscripts. Often, undergraduate course lessons on peer review focus on the practice of performing peer review on other students' writing rather than explaining how this process works for independent scientists publishing their novel work as primary literature articles. As a result, there is a need for more resources related to teaching about publication and peer review. This work presents a plan for out-of-class reading and an in-class lesson on peer review practices in biology. In this module, students learn the order of events in scientific publishing and consider the relationship between peer review and public trust in science by analyzing survey data. Students completing this activity reported knowledge gains related to scientific publishing and peer review and demonstrated their knowledge on an in-class assessment. Though this activity was developed for a biochemistry course, it may be implemented in various life sciences classes from introductory to advanced levels to improve student scientific literacy.

Human CTP synthase filament structure reveals the active enzyme conformation.

The universally conserved enzyme CTP synthase (CTPS) forms filaments in bacteria and eukaryotes. In bacteria, polymerization inhibits CTPS activity and is required for nucleotide homeostasis. Here we show that for human CTPS, polymerization increases catalytic activity. The cryo-EM structures of bacterial and human CTPS filaments differ considerably in overall architecture and in the conformation of the CTPS protomer, explaining the divergent consequences of polymerization on activity. The structure of human CTPS filament, the first structure of the full-length human enzyme, reveals a novel active conformation. The filament structures elucidate allosteric mechanisms of assembly and regulation that rely on a conserved conformational equilibrium. The findings may provide a mechanism for increasing human CTPS activity in response to metabolic state and challenge the assumption that metabolic filaments are generally storage forms of inactive enzymes. Allosteric regulation of CTPS polymerization by ligands likely represents a fundamental mechanism underlying assembly of other metabolic filaments.

Large-scale filament formation inhibits the activity of CTP synthetase.

CTP Synthetase (CtpS) is a universally conserved and essential metabolic enzyme. While many enzymes form small oligomers, CtpS forms large-scale filamentous structures of unknown function in prokaryotes and eukaryotes. By simultaneously monitoring CtpS polymerization and enzymatic activity, we show that polymerization inhibits activity, and CtpS's product, CTP, induces assembly. To understand how assembly inhibits activity, we used electron microscopy to define the structure of CtpS polymers. This structure suggests that polymerization sterically hinders a conformational change necessary for CtpS activity. Structure-guided mutagenesis and mathematical modeling further indicate that coupling activity to polymerization promotes cooperative catalytic regulation. This previously uncharacterized regulatory mechanism is important for cellular function since a mutant that disrupts CtpS polymerization disrupts E. coli growth and metabolic regulation without reducing CTP levels. We propose that regulation by large-scale polymerization enables ultrasensitive control of enzymatic activity while storing an enzyme subpopulation in a conformationally restricted form that is readily activatable.

Self-assembling enzymes and the origins of the cytoskeleton.

The bacterial cytoskeleton is composed of a complex and diverse group of proteins that self-assemble into linear filaments. These filaments support and organize cellular architecture and provide a dynamic network controlling transport and localization within the cell. Here, we review recent discoveries related to a newly appreciated class of self-assembling proteins that expand our view of the bacterial cytoskeleton and provide potential explanations for its evolutionary origins. Specifically, several types of metabolic enzymes can form structures similar to established cytoskeletal filaments and, in some cases, these structures have been repurposed for structural uses independent of their normal roles. The behaviors of these enzymes suggest that some modern cytoskeletal proteins may have evolved from dual-role proteins with catalytic and structural functions.