An undergraduate biochemistry laboratory experiment is described that utilizes free online bioinformatics tools along with readily available exonucleases to study the effects of base stacking and hydrogen bonding on the UV absorbance of DNA samples. UV absorbance of double-stranded DNA at the λ max is decreased when the DNA bases are involved in hydrogen bonding and formation of secondary structure. When an exonuclease is added to the solution containing the DNA, the strand is digested and the interactions disappear, leading to an increase in the absorbance called hyperchromicity. This experiment utilizes exonuclease digestion of DNA to show students how base interactions and secondary structure can alter the spectroscopic properties of a sample and, by extension, how apparent concentration as calculated with Beer−Lambert's law is not necessarily representative of the true concentration of DNA in solution. Teaching applications of this laboratory experiment include enzyme kinetics and activity, secondary structure of single-stranded DNA (and its parallel to RNA structure), and an introduction to bioinformatics.
Calmodulin from Homo sapiens is an α-helical calcium-binding protein that expresses to high levels in E. coli. When the N-terminus of a calmodulin variant is bound to Ca 2+ , it undergoes a conformational change, exposing hydrophobic pockets. This property can be utilized for purification purposes, as these pockets bind to phenyl sepharose resin with high affinity. Washing with EDTA chelates the Ca 2+ ions from the protein, inducing a conformational change back to the more folded state and eluting the protein from the column. We describe herein the use of a protein expression and purification technique using the calmodulin variant and a short linker for proteolytic cleavage by the mutant NIa-Pro tobacco etch virus protease. We have shown this approach to be useful in obtaining purified quantities of various small proteins that could not be expressed using other methods, including high enough concentrations of a designed WW domain protein for NMR structural analysis. We have also obtained promising results on the usefulness of this procedure to express and purify zinc finger proteins without the addition of zinc ions or other cofactors.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.