Spatial Clustering of Isozyme-specific Residues Reveals Unlikely Determinants of Isozyme Specificity in Fructose-1,6-bisphosphate Aldolase

Vertebrate fructose-1,6-bisphosphate aldolase exists as three isozymes (A, B, and C) that demonstrate kinetic properties that are consistent with their physiological role and tissue-specific expression. The isozymes demonstrate specific substrate cleavage efficiencies along with differences in the a...

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Bibliographic Details
Published inThe Journal of biological chemistry Vol. 278; no. 19; pp. 17307 - 17313
Main Authors Pezza, John A., Choi, Kyung H., Berardini, Tanya Z., Beernink, Peter T., Allen, Karen N., Tolan, Dean R.
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 09.05.2003
American Society for Biochemistry and Molecular Biology
Subjects
Amino Acid Sequence
Animals
Chickens
Enzyme Stability
Fructose-Bisphosphate Aldolase - chemistry
Fructose-Bisphosphate Aldolase - genetics
Fructose-Bisphosphate Aldolase - metabolism
Humans
Isoenzymes - chemistry
Isoenzymes - genetics
Isoenzymes - metabolism
Kinetics
Mice
Molecular Sequence Data
Organ Specificity
Protein Conformation
Rabbits
Rats
Recombinant Proteins - chemistry
Recombinant Proteins - genetics
Recombinant Proteins - metabolism
Sequence Alignment
Substrate Specificity
Xenopus
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Summary:Vertebrate fructose-1,6-bisphosphate aldolase exists as three isozymes (A, B, and C) that demonstrate kinetic properties that are consistent with their physiological role and tissue-specific expression. The isozymes demonstrate specific substrate cleavage efficiencies along with differences in the ability to interact with other proteins; however, it is unknown how these differences are conferred. An alignment of 21 known vertebrate aldolase sequences was used to identify all of the amino acids that are specific to each isozyme, or isozyme-specific residues (ISRs). The location of ISRs on the tertiary and quaternary structures of aldolase reveals that ISRs are found largely on the surface (24 out of 27) and are all outside of hydrogen bonding distance to any active site residue. Moreover, ISRs cluster into two patches on the surface of aldolase with one of these patches, the terminal surface patch, overlapping with the actin-binding site of aldolase A and overlapping an area of higher than average temperature factors derived from the x-ray crystal structures of the isozymes. The other patch, the distal surface patch, comprises an area with a different electrostatic surface potential when comparing isozymes. Despite their location distal to the active site, swapping ISRs between aldolase A and B by multiple site mutagenesis on recombinant expression plasmids is sufficient to convert the kinetic properties of aldolase A to those of aldolase B. This implies that ISRs influence catalysis via changes that alter the structure of the active site from a distance or via changes that alter the interaction of the mobile C-terminal portion with the active site. The methods used in the identification and analysis of ISRs discussed here can be applied to other protein families to reveal functionally relevant residue clusters not accessible by conventional primary sequence alignment methods.
ISSN:0021-9258
1083-351X
DOI:10.1074/jbc.M209185200