Submitted by Kari Young / Centre College on Thu, 07/17/2014 - 16:23
Additional Authors
Arpita Saha / Georgia Southern University
Gerard Rowe / University of South Carolina Aiken
Copper / University of Central Arkansas
Nancy Williams / Scripps College, Pitzer College, Claremont McKenna College
Robert Holbrook / Northwestern University
Sibrina Collins / College of Arts and Sciences at Lawrence Technological University
My Notes
Categories
Prerequisites
General Chemistry
Organic Chemistry
Corequisites
Biology
Course Level
Upper Division/Graduate
Topics Covered
Acid-base chemistry
Bonding models: Discrete molecules
Chemical literature
Electronic spectroscopy
Electronic structure
Molecular structure
Physical methods / analytical techniques
Synthesis and reactivity
Subdiscipline
Bioinorganic Chemistry
Coordination Chemistry
Solid State and Materials Chemistry
Spectroscopy and Structural Methods
Description

In this literature discussion, students read a paper about a cobalt metallopeptide that imitates the active site of the enzyme nitrile hydratase.  Specifically, the model complex is oxidized by air to produce a coordination sphere with both cysteine thiolate and sulfinic acid ligands, much like the post-translationally oxidized cysteine ligands in the biological system.  This paper also provides an introduction to a variety of physical methods used to characterize the structure, including X-ray absorbance spectroscopy, magnetic susceptibility using the Evans method, IR spectroscopy, electronic absorbance spectroscopy, and electron paramagnetic resonance spectroscopy.  This LO was created for the 2014 TUES Viper Workshop on bioinorganic chemistry.

Attachment Size
Student reading guide 49.78 KB
Learning Goals

Students will be able to:

  • Identify the oxidation state, coordination number, and approximate geometry of the cobalt complexes presented in this paper

  • Give the overall reaction catalyzed by the enzyme

  • Identify sites of potential ligand coordination in an oligopeptide

  • Compare two cobalt metalloenzyme active sites using the Protein Data Bank

  • Explain how X-ray absorbance spectroscopy can be used to identify the oxidation state of an atom

  • Assign ligand field or LMCT electronic transitions based on molar absorptivity

  • Compare and contrast thiolate, sulfenate, and sulfinate ligands with respect to charge, donor ability, and oxidation state

  • Predict how Lewis basicity and redox potential change as the ligand becomes more oxidized

  • Evaluate the effectiveness of a model complex for reproducing a metalloenzyme active site
Related activities
Exploring Post-Translational Modification with DFT
Exploring Proteins as Ligands using the Protein Data Bank
X-ray absorption spectroscopy and its applications to LFT
Implementation Notes

Students should read the paper and complete the reading guide before the literature discussion.  


We hope that instructors will mix and match questions that are appropriate to their classes.  In particular, instructors may want to remove questions 9-12 depending on the desired emphasis on experimental methods. 

Web Resources
Sequential oxidation of thiolates and the cobalt metallocenter in a synthetic …
Evaluation
Evaluation Methods

Students will be assessed qualitatively based on whether they complete the reading guide and how they contribute to a class discussion.  Students can also be assessed using the DFT Post-translational modification activity based on the same paper.

Evaluation Results

This LO was created for the 2014 TUES workshop and has not yet been tested in the classroom.

Creative Commons License
Attribution, Non-Commercial, Share Alike CC BY-NC-SA