Vision and change in undergraduate biology education: a call to action presentation to faculty for undergraduate neuroscience, july 2011.

The biology of the 21(st) century requires a revolution in teaching that corresponds to the revolution that the discipline experienced in the last decades of the 20(th) century. Consensus is not a tradition in the many disparate subdisciplines that constitute modern biology, but the demands of effective instruction prompted an unprecedented series of conversations among all the stakeholders of undergraduate biology education. A culminating conference resulted in consensus on both the form and substance of modern biology courses: They should emphasize repeatedly five core concepts and six core competencies in a student-centered, inquiry-driven pedagogy modeled on a number of "best practices." The conference report can serve as a guide to individual faculty members, departments, and institutions seeking to reform their teaching practices.

Genome Consortium for Active Teaching: meeting the goals of BIO2010.

The Genome Consortium for Active Teaching (GCAT) facilitates the use of modern genomics methods in undergraduate education. Initially focused on microarray technology, but with an eye toward diversification, GCAT is a community working to improve the education of tomorrow's life science professionals. GCAT participants have access to affordable microarrays, microarray scanners, free software for data analysis, and faculty workshops. Microarrays provided by GCAT have been used by 141 faculty on 134 campuses, including 21 faculty that serve large numbers of underrepresented minority students. An estimated 9480 undergraduates a year will have access to microarrays by 2009 as a direct result of GCAT faculty workshops. Gains for students include significantly improved comprehension of topics in functional genomics and increased interest in research. Faculty reported improved access to new technology and gains in understanding thanks to their involvement with GCAT. GCAT's network of supportive colleagues encourages faculty to explore genomics through student research and to learn a new and complex method with their undergraduates. GCAT is meeting important goals of BIO2010 by making research methods accessible to undergraduates, training faculty in genomics and bioinformatics, integrating mathematics into the biology curriculum, and increasing participation by underrepresented minority students.

Concentrations of ouabain that prevent intercellular communication do not affect free calcium levels in cultured fibroblasts.

To better understand inhibition of gap-junction-mediated cell communication among cultured fibroblasts treated with the sodium pump inhibitor ouabain, we tested whether such cells have higher calcium levels than normal. Using the calcium indicator dye fura-2 with fluorescence spectroscopy and digital imaging microscopy, we determined cell calcium levels during exposure of cells to ouabain. The concentration of ouabain was high enough to achieve maximum alterations of steady-state sodium and potassium content and cell communication. We found no consistent change in calcium levels in human fibroblasts as a result of this treatment. In mouse 3T3 fibroblasts, concentrations of ouabain that inhibit cell communication were associated with a significant reduction of cell calcium. It appears, therefore, that the inhibition of communication by ouabain cannot be attributed to elevated cytosolic free calcium in the treated cultures.

Glucose transport in cultured animal cells: an exercise for the undergraduate cell biology laboratory.

Membrane transport is a fundamental concept that undergraduate students of cell biology understand better with laboratory experience. Formal teaching exercises commonly used to illustrate this concept are unbiological, qualitative, or intricate and time consuming to prepare. We have developed an exercise that uses uptake of radiolabeled nutrient analogues by attachment-dependent animal cells cultured on multiwell trays. This system can readily be manipulated within a typical 3-h laboratory period to yield reproducible, biologically relevant, quantitative data regarding key aspects of membrane transport. Each 24-well tray of cultures allows a group of two to four students to compare eight conditions in triplicate. If different groups of students test different conditions or different types of cells, data can be shared for an even broader experience. The exercise is also readily adaptable for open-ended student projects. Here we illustrate the exercise measuring uptake of the nonmetabolizable glucose analogue [(3)H]-2-deoxy-D-glucose. Students successfully tested the effects of competing sugars, putative inhibitors of the GLUT1 transporter, and changes in cell physiology that might be expected to affect glucose transport in epithelial cells and fibroblasts. In this exercise students find the nutritional and medical implications of glucose transport and its regulation intriguing. They also learn to handle radioisotopes and cultured cells.