Abstract
The β1α1 loop in the tryptophan biosynthetic enzyme indole-3-glycerol phosphate synthase (IGPS) is important for substrate binding, product release and chemical catalysis. IGPS catalyzes the ring closure of the substrate 1-(o-carboxyphenylamine)-1-dexoyribulose 5-phosphate to form indole-3-glycerol phosphate, involving distinct decarboxylation and dehydration steps. The ring closure step is rate-determining in the thermophilic Sulfolobus sulfataricus enzyme (ssIGPS) at high temperatures. The β1α1 loop is especially important in the dehydration step as it houses the general acid Lys53. We propose that loop dynamics are governed by competing interactions on the N- and C-terminal sides of the loop. We had previously shown that disrupting interactions with the N-terminal side of the loop through the N90A substitution decreases catalytic efficiency, slows down the dehydration step and quenches loop dynamics on the picosecond to millisecond timescales. Here, we show that disrupting interactions on the C-terminal side of the loop through the R64A/D65A substitutions likewise decreases catalytic efficiency, slows down the dehydration step and quenches loop dynamics. Interestingly, the triple substitution R64A/D65A/N90A leads to new μs–ms timescale loop dynamics and makes the ring-closure step rate-determining once again. These results are consistent with a model in which the β1α1 loop is maintained in a structurally dynamic state by these competing interactions, which is important for the dehydration step of catalysis. Competing interactions in other enzymes may likewise keep their loops and other structural elements appropriately mobile.
Highlights
Enzymes often undergo conformational changes as they bind substrate, perform chemical catalysis and release product
We proposed that competing interactions on the N-terminal and C-terminal sides of the β1α1 loop help to govern its structural dynamics (Figure 1b), affecting its many roles in ssIGPS catalysis
We demonstrate that severing the interactions with the α1/α8’ helices through the R64A/D65A double substitution decreases β1α1 loop motions and changes the identity of the rate-determining step of ssIGPS catalysis, similar to the N90A substitution
Summary
Enzymes often undergo conformational changes as they bind substrate, perform chemical catalysis and release product. We have proposed a revised chemical mechanism for IGPS [28], which overall catalyzes the ring closure of 1-(o-carboxyphenylamine)-1-dexoyribulose 5-phosphate (CdRP) into indole-3-glycerol phosphate (IGP) in the fifth step of the tryptophan biosynthetic pathway In this revised mechanism (Figure 1c), Lys110 (numbering according to ssIGPS) acts a general acid to protonate the C20 carbonyl of. We proposed that competing interactions on the N-terminal (e.g., the interaction between Arg54-Asn90) and C-terminal (e.g., interactions between Arg64/Asp and residues on the α1 and α8’ helices) sides of the β1α1 loop help to govern its structural dynamics (Figure 1b), affecting its many roles in ssIGPS catalysis. The structural dynamics of catalytically important active site loops in other enzymes may likewise be governed by competing interactions to keep these loops in conformationally “frustrated” states [30]
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