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Substitution preferences:
All protein types:

Favoured	Val ( 3)	Leu ( 2)	Met ( 1)
Neutral	Phe ( 0)
Disfavoured	Ala (-1)	Tyr (-1)	Cys (-1)	Thr (-1)	Ser (-2)	His (-3)	Pro (-3)	Asn (-3)
	Gln (-3)	Arg (-3)	Lys (-3)	Trp (-3)	Asp (-3)	Glu (-3)	Gly (-4)

Intracellular proteins:

Favoured	Val ( 2)	Leu ( 2)	Met ( 1)
Neutral	Ala ( 0)	Cys ( 0)	Thr ( 0)	Phe ( 0)	Tyr ( 0)
Disfavoured	Trp (-1)	Arg (-1)	Lys (-1)	Gln (-2)	Ser (-2)	Glu (-2)	His (-2)	Pro (-2)
	Asn (-2)	Asp (-3)	Gly (-3)

Extracellular proteins:

Favoured	Val ( 2)	Leu ( 1)
Neutral	Ala ( 0)	Lys ( 0)	Met ( 0)	Arg ( 0)	Thr ( 0)	Phe ( 0)	Tyr ( 0)
Disfavoured	Asn (-1)	His (-1)	Trp (-1)	Glu (-1)	Pro (-1)	Gln (-1)	Ser (-1)	Asp (-2)
	Gly (-2)	Cys (-5)

Membrane proteins:

Favoured	Val ( 2)	Leu ( 1)	Met ( 1)
Neutral	Ala ( 0)	Thr ( 0)
Disfavoured	Phe (-1)	Cys (-1)	Ser (-1)	Gly (-2)	Trp (-3)	Asn (-3)	Pro (-3)	Arg (-3)
	Asp (-3)	Tyr (-4)	Glu (-4)	Lys (-4)	Gln (-4)	His (-4)

Role in structure: Being hydrophobic, Isoleucine prefers to be buried in protein hydrophobic cores. However, Isoleucine has an additional property that is frequently overlooked. Like Valine, and Threonine it is C-beta branched. Whereas most amino acids contain only one non-hydrogen substituent attached to their C-beta carbon, these three amino acids contain two. This means that there is a lot more bulkiness near to the protein backbone, and thus means that these amino acids are more restricted in the conformations the main-chain can adopt. Perhaps the most pronounced effect of this is that it is more difficult for these amino acids to adopt an alpha-helical conformation, though it is easy and even preferred for them to lie within beta-sheets.

Role in function: The Isoleucine side chain is very non-reactive, and is thus rarely directly involved in protein function, though it can play a role in substrate recognition. In particular, hydrophobic amino acids can be involved in binding/recognition of hydrophobic ligands such as lipids.