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In biochemistry and molecular biology, the TIM barrel is a conserved protein fold consisting of eight α-helices and eight parallel β-strands that alternate along the peptide backbone. The structure is named after triosephosphate isomerase, a conserved metabolic enzyme. TIM barrels are one of the most common protein folds. One of the most intriguing features among members of this class of proteins is although they all exhibit the same tertiary fold there is very little sequence similarity between them. At least 15 distinct enzyme families use this framework to generate the appropriate active site geometry, always at the C-terminal end of the eight parallel beta-strands of the barrel.

Aldolase-type TIM barrel
8tim TIM barrel topview.png
Top view of a triosephosphateisomerase (TIM) barrel (PDB accession code 8TIM), colored from blue (N-terminus) to red (C-terminus).
Identifiers
SymbolAldolase_TIM
Pfam clanCL0036
InterProIPR013785
CATH8tim
SCOPe8tim / SUPFAM

Contents

Structure and compositionEdit

TIM barrels are considered α/β protein folds because they include an alternating pattern of α-helices and β-strands in a single domain. In a TIM barrel the helices and strands (usually 8 of each) form a solenoid that curves around to close on itself in a doughnut shape, topologically known as a toroid. The parallel β-strands form the inner wall of the doughnut (hence, a β-barrel), whereas the α-helices form the outer wall of the doughnut. Each β-strand connects to the next adjacent strand in the barrel through a long right-handed loop that includes one of the helices, so that the ribbon N-to-C coloring in the top view proceeds in rainbow order around the barrel. The TIM barrel can also be thought of, then, as made up of 8 overlapping, right-handed β-α-β super-secondary structures.[1]

 
Side view of the same TIM barrel (PDB code 8TIM).

Although the ribbon diagram shows a hole in the protein's central core, the amino acid side chains are not shown in this representation. The protein's core is actually tightly packed, mostly with bulky hydrophobic amino acid residues although a few glycines are needed to allow wiggle room for the highly constrained center of the 8 approximate repeats to fit together. The packing interactions between the strands and helices are also dominated by hydrophobicity and the branched aliphatic residues valine, leucine, and isoleucine comprise about 40% of the total residues in the β-strands.[1]

Across many TIM proteins, the catalytic site and the beta-barrel parts are more rigid than the helical parts, the positions of which can vary frequently among specific proteins.[2] An ideal 4-fold symmetrical TIM barrel enzyme has been designed by the Rosetta@Home group using computational methods.[3]

Loop regionsEdit

Of the approximately 200 residues required to fully form a TIM barrel, about 160 are considered structurally equivalent between different proteins sharing this fold. The remaining residues are located on the loop regions that link the helices and strands; the loops at the C-terminal end of the strands tend to contain the active site, which is one reason this fold is so common: the residues required to maintain the structure and the residues that effect enzymatic catalysis are for the most part distinct subsets:[4] The linking loops can, in fact, be so long that they contain other protein domains. Recently, it has been demonstrated that catalytic loops can be exchanged between different TIM barrel enzymes as semiautonomous units of functional groups.[5]

See alsoEdit

ReferencesEdit

  1. ^ a b Branden C, Tooze J (1999). Introduction to Protein Structure (2nd ed.). New York, NY: Garland Publishing. pp. 47–50.
  2. ^ Tiwari SP, Reuter N (March 2016). "Similarity in Shape Dictates Signature Intrinsic Dynamics Despite No Functional Conservation in TIM Barrel Enzymes". PLoS Computational Biology. 12 (3): e1004834. Bibcode:2016PLSCB..12E4834T. doi:10.1371/journal.pcbi.1004834. PMC 4807811. PMID 27015412.
  3. ^ Huang PS, Feldmeier K, Parmeggiani F, Velasco DA, Höcker B, Baker D (January 2016). "De novo design of a four-fold symmetric TIM-barrel protein with atomic-level accuracy". Nature Chemical Biology. 12 (1): 29–34. doi:10.1038/nchembio.1966. PMC 4684731. PMID 26595462.
  4. ^ Ochoa-Leyva A, Soberón X, Sánchez F, Argüello M, Montero-Morán G, Saab-Rincón G (April 2009). "Protein design through systematic catalytic loop exchange in the (beta/alpha)8 fold". Journal of Molecular Biology. 387 (4): 949–64. doi:10.1016/j.jmb.2009.02.022. PMID 19233201.
  5. ^ Ochoa-Leyva A, Barona-Gómez F, Saab-Rincón G, Verdel-Aranda K, Sánchez F, Soberón X (August 2011). "Exploring the Structure-Function Loop Adaptability of a (β/α)(8)-Barrel Enzyme through Loop Swapping and Hinge Variability". Journal of Molecular Biology. 411 (1): 143–57. doi:10.1016/j.jmb.2011.05.027. PMID 21635898.

Further readingEdit

External linksEdit