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<p style="text-align: center;"><span style="font-size:36px"><strong><Index of Chapter 10></strong></span></p>
<p> </p>
<p><span style="color:#0000CD"><strong>Introduction</strong></span></p>
<p><span style="color:#0000CD"><strong>Protein nature and types</strong></span></p>
<p><span style="color:#0000CD"><strong>Protein structure</strong></span></p>
<p>-The chemical structure of proteins </p>
<p>-Conformation of the polypeptide chain</p>
<p>-Protein folding patterns</p>
<p><span style="color:#0000CD"><strong>Post-translational modifications</strong></span></p>
<p>-Why is there a common genetic code with 20 canorical amino acids?</p>
<p><span style="color:#0000CD"><strong>Seperation and anylsis of proteins </strong></span></p>
<p>-Polyacrylamide gel electrophoresis (PAGE)</p>
<p>-Two-dimensional polyacrylamide gel electrophoresis (2D-PAGE)</p>
<p>-Mass spectrometry</p>
<p><span style="color:#0000CD"><strong>Classification of protein structures</strong></span></p>
<p>-SCOP</p>
<p>-Changes in folding patterns in protein evolution</p>
<p><span style="color:#0000CD"><strong>Many proteins change conformation as part of the mechanism of their function</strong></span></p>
<p>-Conformational change during enzymatic catalysis</p>
<p>-Motor proteins</p>
<p>-Allosteric regulation of protein function</p>
<p>-Conformational states of serine protease inhibitors (serpins)</p>
<p><span style="color:#0000CD"><strong>Protein structure prediction and modelling</strong></span></p>
<p>-Homology modelling</p>
<p>-Available protocols for protein structure prediction</p>
<p>-Structural genomics</p>
<p><span style="color:#0000CD"><strong>Directed evolution and protein design</strong></span></p>
<p>-Directed evolution of subtilisin E</p>
<p>-Enzyme design</p>
<p><span style="color:#0000CD"><strong>Protein complexes and aggregates</strong></span></p>
<p>-Protein aggregation diseases</p>
<p>-Properties of protein-protein complexes</p>
<p>-Multisubinit proteins</p>
<p> </p>
<p><span style="color:#0000CD"><strong>Introduction</strong></span></p>
<p><span style="color:#0000CD"><strong>Protein nature and types</strong></span></p>
<p><span style="color:#0000CD"><strong>Protein structure</strong></span></p>
<p>-The chemical structure of proteins </p>
<p>-Conformation of the polypeptide chain</p>
<p>-Protein folding patterns</p>
<p><span style="color:#0000CD"><strong>Post-translational modifications</strong></span></p>
<p>-Why is there a common genetic code with 20 canorical amino acids?</p>
<p><span style="color:#0000CD"><strong>Seperation and anylsis of proteins </strong></span></p>
<p>-Polyacrylamide gel electrophoresis (PAGE)</p>
<p>-Two-dimensional polyacrylamide gel electrophoresis (2D-PAGE)</p>
<p>-Mass spectrometry</p>
<p><span style="color:#0000CD"><strong>Classification of protein structures</strong></span></p>
<p>-SCOP</p>
<p>-Changes in folding patterns in protein evolution</p>
<p><span style="color:#0000CD"><strong>Many proteins change conformation as part of the mechanism of their function</strong></span></p>
<p>-Conformational change during enzymatic catalysis</p>
<p>-Motor proteins</p>
<p>-Allosteric regulation of protein function</p>
<p>-Conformational states of serine protease inhibitors (serpins)</p>
<p><span style="color:#0000CD"><strong>Protein structure prediction and modelling</strong></span></p>
<p>-Homology modelling</p>
<p>-Available protocols for protein structure prediction</p>
<p>-Structural genomics</p>
<p><span style="color:#0000CD"><strong>Directed evolution and protein design</strong></span></p>
<p>-Directed evolution of subtilisin E</p>
<p>-Enzyme design</p>
<p><span style="color:#0000CD"><strong>Protein complexes and aggregates</strong></span></p>
<p>-Protein aggregation diseases</p>
<p>-Properties of protein-protein complexes</p>
<p>-Multisubinit proteins</p>
