Unravelling the Carbohydrate-Binding Preferences of the Carbohydrate-Binding Modules of AMP-Activated Protein Kinase.

The ß subunit of adenosine monophosphate (AMP)-activated protein kinase (AMPK), which exists as two isoforms (ß1 and ß2) in humans, has a carbohydrate-binding module (CBM) that interacts with glycogen. Although the ß1- and ß2-CBMs are structurally similar, with strictly conserved ligand-contact residues, they show different carbohydrate affinities. ß2-CBM shows the strongest affinity for both branched and unbranched oligosaccharides and it has recently been shown that a Thr insertion into ß2-CBM (Thr101) forms a pocket to accommodate branches. This insertion does not explain why ß2-CBM binds all carbohydrates with stronger affinity. Herein, it is shown that residue 134 (Val for ß2 and Thr for ß1), which does not come into contact with a carbohydrate, appears to account for the affinity difference. Characterisation by NMR spectroscopy, however, suggests that mutant ß2-Thr101Δ/Val134Thr differs from that of ß1-CBM, and mutant ß1-Thr101ins/Thr134Val differs from that of ß2-CBM. Furthermore, these mutants are less stable to chemical denaturation, relative to that of wild-type ß-CBMs, which confounds the affinity analyses. To support the importance of Thr101 and Val134, the ancestral CBM has been constructed. This CBM retains Thr101 and Val134, which suggests that the extant ß1-CBM has a modest loss of function in carbohydrate binding. Because the ancestor bound carbohydrate with equal affinity to that of ß2-CBM, it is concluded that residue 134 plays an indirect role in carbohydrate binding.

Determinants of oligosaccharide specificity of the carbohydrate-binding modules of AMP-activated protein kinase.

AMP-activated protein kinase (AMPK) is an αßγ heterotrimer that is important in regulating energy metabolism in all eukaryotes. The ß-subunit exists in two isoforms (ß1 and ß2) and contains a carbohydrate-binding module (CBM) that interacts with glycogen. The two CBM isoforms (ß1- and ß2-CBM) are near identical in sequence and structure, yet show differences in carbohydrate-binding affinity. ß2-CBM binds linear carbohydrates with 4-fold greater affinity than ß1-CBM and binds single α1,6-branched carbohydrates up to 30-fold tighter. To understand these affinity differences, especially for branched carbohydrates, we determined the NMR solution structure of ß2-CBM in complex with the single α1,6-branched carbohydrate glucosyl-ß-cyclodextrin (gBCD) which supported the dynamic nature of the binding site, but resonance broadening prevented defining where the α1,6 branch bound. We therefore solved the X-ray crystal structures of ß1- and ß2-CBM, in complex with gBCD, to 1.7 and 2.0 Å (1 Å=0.1 nm) respectively. The additional threonine (Thr101) of ß2-CBM expands the size of the surrounding loop, creating a pocket that accommodates the α1,6 branch. Hydrogen bonds are formed between the α1,6 branch and the backbone of Trp99 and Lys102 side chain of ß2-CBM. In contrast, the α1,6 branch could not be observed in the ß1-CBM structure, suggesting that it does not form a specific interaction. The orientation of gBCD bound to ß1- and ß2-CBM is supported by thermodynamic and kinetic data obtained through isothermal titration calorimetry (ITC) and NMR. These results suggest that AMPK containing the muscle-specific ß2-isoform may have greater affinity for partially degraded glycogen.