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Chap 13. Specificity and Editing Mechanism

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1 Chap 13. Specificity and Editing Mechanism
The relative rate of reaction A function of both substrate binding and catalytic rate The kcat/KM: the important kinetic constant in determining specificity

2 A. Limits on Specificity
Larger substrates than the specific substrate: small active site to fit in Smaller substrates than the specific substrate: always able to bind, less binding energy Ex. aminoacyl tRNA synthethases isoleucyl-tRNA synthetase: Ile vs Val, 150 times tighter valyl-tRNA synthetase: Val vs. Thr, times tighter alanyl-tRNA synthetase: Ala vs Gly, 250 times tighter The maximum effect due to the additional binding: exp(-Gb/RT) (Gb, the binding energy of the enzyme and TS)

3 B. Editing or Proofreading Mechanisms
Proofreading exists In DNA replication the complementary base pairing: 1 part in error rate: 1 per In protein biosynthesis amino acid selection: 1 part in 102 error rate: 1 per Active site for synthesis and hydrolytic active site

4 There are Different Editing Mechanisms between Protein Synthesis and DNA Replication
each specific enzyme for selecting an amino acid error correction before polymerization DNA replication a single DNA polymerase the editing after polymerization

5 Three Rules of Proof may be Considered in Protein Synthesis
tRNA E + ATP + AA E•AA-AMP AA-tRNA + AMP + E PPi The valyl-tRNA synthetase: the mischarged tRNA Val vs. Thr, 600 times the hydrophobic acylating site and the hydrophilic deacylating site The isoleucyl-tRNA synthetase: the aminoacyl adenylate (E•AA-AMP) with existing tRNA, major editing process The methionyl-tRNA synthetase: the misactivated homocyteine without tRNA, before transfer to tRNA, the cyclized intermediate

6 Prokaryotic DNA Polymerases have a 3’→5’ Exonuclease Activity to Give the Postreplicative Repair Mechanism DNA synthesis: 5’→ 3’, Exonuclease activity: 3’→ 5’ The exonuclease activity is greatest for mismatched bases or ssDNA The mutation frequency correlates with the exonuclease activity: Table 13.1 Prokaryotic DNA polymerases (with exonuclease activity): higher accuracy Eukaryotic DNA polymerases (no exonuclease activity): expected accuracy The kinetics of error induction by prokaryotic DNA polymerases are consistent with the active participation of an editing mechanism

7 C. The Cost of Accuracy The editing hydrolysis costs energy:
energy wasteful hydrolysis of the correct substrate Cost: the fraction of correct substrate wastefully hydrolyzed The more efficient the editing, the more the cost In general, higher selectivity at lower cost: multistage editing

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