posted on 2022-05-27, 16:33authored byDevi Prasanna, Ashish Runthala
Terpenoids form a
large pool of highly diverse organic compounds
possessing several economically important properties, including nutritional,
aromatic, and pharmacological properties. The 1-deoxy-d-xylulose
5-phosphate (DXP) pathway’s end enzyme, nuclear distribution
protein (NudF), interacting with isopentenyl pyrophosphate (IPP) and
dimethylallyl pyrophosphate (DMAPP), is critical for the synthesis
of isoprenol/prenol/downstream compounds. The enzyme is yet to be
thoroughly investigated to increase the overall yield of terpenoids
in the Bacillus subtilis, which is widely used in
industry and is generally regarded as a safe (GRAS) bacterium. The
study aims to analyze the evolutionary conservation across the active
site for mapping the key residues for mutagenesis studies. The 37-sequence
data set, extracted from 103 Bacillus subtilis entries,
shows a high phylogenetic divergence, and only six one-motif sequences
ASB92783.1, ASB69297.1, ASB56714.1, AOR97677.1, AOL97023.1, and OAZ71765.1
show a monophyly relationship, unlike a complete polyphyly relationship
between the other 31 three-motif sequences. Furthermore, only 47 of
179 residues of the representative sequence CUB50584.1 are observed
to be significantly conserved. Docking analysis suggests a preferential
bias of adenosine diphosphate (ADP)-ribose pyrophosphatase toward
IPP, and a nearly threefold energetic difference is observed between
IPP and DMAPP. The loops are hereby shown to play a regulatory role
in guiding the promiscuity of NudF toward a specific ligand. Computational
saturation mutagenesis of the seven hotspot residues identifies two
key positions LYS78 and PHE116, orderly encoded within loop1 and loop7,
majorly interacting with the ligands DMAPP and IPP, and their mutants
K78I/K78L and PHE116D/PHE116E are found to stabilize the overall conformation.
Molecular dynamics analysis shows that the IPP complex is significantly
more stable than the DMAPP complex, and the NudF structure is very
unstable. Besides showing a promiscuous binding of NudF with ligands,
the analysis suggests its rate-limiting nature. The study would allow
us to customize the metabolic load toward the synthesis of any of
the downstream molecules. The findings would pave the way for the
development of catalytically improved NudF mutants for the large-scale
production of specific terpenoids with significant nutraceutical or
commercial value.