Acidification of the Oceans at the time of KPg event and Now part of IODP School of Rock 2020:Teaching Activities
This activity will engage students in researching the sequence of events and effects of the KPg event. Students will compare using data the acidification of oceans today to the acidification of the oceans after the ...

MCC: Malate Dehydrogenase CUREs Community part of CUREnet:CURE Collection
The Malate Dehydrogenase CUREs Community (MCC) project is designed to facilitate the adoption of effective, protein‐centric, Course Based Undergraduate Research Experiences (CUREs) into teaching labs at a wide variety of undergraduate serving institutions. (Primarily Undergraduate Institutions, Research Intensive Universities and Community Colleges) MCC coordinates and conducts pedagogical research into two major features of CUREs:1) their duration (whole semester versus 5‐6 week modules incorporated into a lab class), and 2) the impact of scientific collaboration between institutions (a key aspect of much modern research). Using validated assessment tools we seek to establish their effects on student confidence, persistence in STEM, and ability to design research experiments and interprete data. To facilitate faculty adoption of CURE approaches the project provides a number of resources. These focus on a variety of research areas related to Malate Dehydrogenase including mechanisms of catalysis and regulation, adaptation and evolution, cofactor specificity, folding and stability and interactions in metabolons. Resources include biologics, experimental protocols and assessment tools. The project also coordinates interactions between courses at different institutions to allow incorporation of scientific collaboration into CUREs. These collaborations also facilitate the use of more sophisticated experimental approaches and broaden the experimental scope of the CUREs.

The Sustainability Triangle: How Do We Apply Science to Decision Making? part of Curriculum for the Bioregion:Activities
This writing assignment uses the "Sustainable Development Triangle" as a framework to critically evaluate an environmental issue of the student's choice. This learning activity provides an opportunity for an introductory chemistry student to use the sustainability's "Triple Bottom Line" as a tool to use material learned in the classroom to look at how environmental science helps inform economic and social/cultural factors in the development of sustainable solutions to our environmental challenges.

Carbon Dioxide Birthday part of Curriculum for the Bioregion:Activities

The HICA project part of CUREnet:CURE Collection
In this CURE, inspired by the work of Hoffmann, et al., students prepare mutant Haemophilus influenzae carbonic anhydrase (HICA) proteins. Using PyMOL to visualize the three-dimensional structure of the HICA protein, students choose one or more surface amino acid residues to mutate to histidine residues in order to create a surface histidine cluster that will allow the mutant protein to bind to a nickel affinity column. Using site-directed mutagenesis, recombinant plasmids are constructed and are then used to transform an E. coli expression vector. The mutant HICA protein is overexpressed, cells are lysed, and students load the cell lysate onto Ni-NTA columns and determine the imidazole concentration required to elute the mutant protein. The construction of a library of mutant proteins will allow the development of a general method in which specific surface histidine residues of any protein can be mutated in order to facilitate affinity purification. The Haemophilus influenzae bacterium described herein is a respiratory pathogen that causes meningitis (in its encapsulated form) and mucosal infections such as otitis media, sinusitis and conjunctivitis (in its unencapsulated form). A recent study showed that the carbonic anhydrase enzyme is absolutely required for pathogenesis. Furthermore, expression of the HICA enzyme allows the pathogen to survive in host immune cells (Langereis, et al.). These observations make the study of HICA itself particularly attractive, in addition to the overall goal of contributing to a body of work that will allow the minimal histidine character required for nickel affinity to be ascertained.

Exploring eukaryotic protein structure and post-translational modifications. part of CUREnet:Institutes:Bowie State University:Examples
This CURE will provide opportunity for students to think and act as researchers by using computational, biochemical, and bioanalytical techniques to examine tick antigen proteins. The CURE is designed as a lab for upper-level students who are taking or have taken a one-semester introductory biochemistry course, but two semesters would be even better. It could also be adapted for cell/molecular biology or (bio) analytical chemistry instrumentational analysis labs. It has been taught for classes ranging from 12-24 students. Ticks are notorious vectors of viral, protozoan, and bacterial diseases, including Lyme disease. While an anti-vector vaccine capable of protecting people from diseases transmitted by a particular tick species is an alluring goal, only one such anti-tick vaccine is currently available. This vaccine targets Bm86, a protein from the midgut of Rhipicephalus microplus, a cattle tick. Not only does the vaccine limit parasitism of the cattle by ticks, data suggests that it can also prevent transmission of tick-borne diseases including bovine anaplasmosis and babesiosis. However, similar vaccination approaches have not succeeded thus far against ticks that transmit diseases to humans, and little is known about the antibody response to the antigen, or about the protein itself. Since the protein's structure and function are unknown, the research goal of this CURE is to purify Bm86 using an insect cell/baculovirus expression system and characterize it, including domain structure and post-translational modifications (glycosylation sites). There are homologs to Bm86 in every sequenced tick species examined, and future CUREs will characterize some of the homologs including those in Ixodes scapularis, the tick that is mainly responsible for transmitting Lyme in the eastern US, and Haemaphysalis longicornis, the Asian longhorned tick, a newly-discovered invasive species in the area that also has significant disease-transmitting potential. By understanding the structure and post-translational modifications of this protein, we hope to gain a better understanding of how to make effective anti-tick vaccines, including those for humans, that may prevent transmission of Lyme disease. Importantly, the basic parameters of this CURE can be used to examine other proteins besides tick antigens. For example, during the pandemic, the CURE pivoted from the tick antigen to the SARS-CoV-2 nucleocapsid protein, which was also expressed in an insect cell system. Instead of characterizing glycosylation sites, we characterized phosphorylation sites. It's therefore possible to use this same framework for many different eukaryotic proteins that may be of research interest.

Hurricanes and Heat Transfer part of EarthLabs for Educators:Hurricanes
The lab activity described here was created by John McDaris of SERC for the EarthLabs project. Summary and Learning Objectives In this activity students investigate how hurricanes transfer heat by conducting ...