12: Bioinorganic Chemistry

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Metals play a wide range of important roles in biological systems. This chapter will give an overview of the roles metals can play in biochemical reactions and highlight a few metal containing proteins in greater detail.

Learning Objectives

Observe the different roles metals can play in biological systems
Apply inorganic chemistry principles (MO theory, CFT, HSAB, etc.) to metalloproteins

Thumbnail images is the structure of Cytochrome C (CC BY-SA; Vossman via Wikimedia Commons)

12.1: Biological Significance of Metals
The transition metals are among the least abundant metal ions in the sea water from which contemporary organisms are thought to have evolved. For many of the metals, the concentration in human blood plasma greatly exceeds that in sea water. Such data indicate the importance of mechanisms for accumulation, storage, and transport of transition metals in living organisms.
12.2: Introduction to Amino Acids and Proteins
Many amino acids have side chains which can act as ligands for metal centers in proteins. For your reference, this section illustrates the chemical structures of all the amino acids.
12.3: Biological Dioxygen Transport and Storage
Most organisms require molecular oxygen in order to survive. The oxygen is used in a host of biochemical transformations. A number of iron and copper metalloproteins have evolved to transport oxygen from the lungs or gills to where it is needed and to store it until it is needed.
12.4: Biological Metal Storage
12.5: Zinc as Lewis Acid and Template
Unlike most other biologically important metals, zinc is not redox active and does not directly participate in catalytic reaction. Zinc ions do play important biochemical roles. They can act as Lewis acids, to indirectly catalyse reactions such as the hydration of carbon dioxide in carbonic anhydrase. They can also act as templates or scaffolds for protein tertiary structures
12.6: Electron Transfer
Metalloproteins that function as electron transferases typically place their metal coordination sites in a hydrophobic environment and may provide hydrogen bonds (in addition to ligands) to assist in stabilizing both the oxidized and the reduced forms of the cofactor. Metal-ligand bonds remain intact upon electron transfer to minimize inner-sphere reorganization energy.

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