Abstract
Controlling unmodified serotonin levels in brain synapses is a primary objective when treating major depressive disorder—a disease that afflicts ∼20% of the world’s population. Roughly 60% of patients respond poorly to first-line treatments and thus new therapeutic strategies are sought. To this end, we have constructed isoform-specific inhibitors of the human cytosolic sulfotransferase 1A3 (SULT1A3)—the isoform responsible for sulfonating ∼80% of the serotonin in the extracellular brain fluid. The inhibitor design includes a core ring structure, which anchors the inhibitor into a SULT1A3-specific binding pocket located outside the active site, and a side chain crafted to act as a latch to inhibit turnover by fastening down the SULT1A3 active-site cap. The inhibitors are allosteric, they bind with nanomolar affinity and are highly specific for the 1A3 isoform. The cap-stabilizing effects of the latch can be accurately calculated and are predicted to extend throughout the cap and into the surrounding protein. A free-energy correlation demonstrates that the percent inhibition at saturating inhibitor varies linearly with cap stabilization — the correlation is linear because the rate-limiting step of the catalytic cycle, nucleotide release, scales linearly with the fraction of enzyme in the cap-open form. Inhibitor efficacy in cultured cells was studied using a human mammary epithelial cell line that expresses SULT1A3 at levels comparable with those found in neurons. The inhibitors perform similarly in ex vivo and in vitro studies; consequently, SULT1A3 turnover can now be potently suppressed in an isoform-specific manner in human cells.
Highlights
Spurred extensive efforts in academia and industry to identify new and potentially more effective therapeutic strategies [4,5,6]
In microdialysates from human brain, serotonin is nearly completely oxidized by monoamine oxidase, and 80% of the oxidized metabolite is sulfonated [8]; monoamine oxidase and sulfotransferase (SULT) inhibitors are expected to act synergistically to increase the levels of unmodified serotonin
In previous work [15], we discovered CMP8 (Fig. 1), which binds tightly (Ki = 34 nM) to Sulfotransferase 1A3 (SULT1A3) and allosterically inhibits its turnover
Summary
Spurred extensive efforts in academia and industry to identify new and potentially more effective therapeutic strategies [4,5,6]. In microdialysates from human brain, serotonin is nearly completely oxidized by monoamine oxidase, and 80% of the oxidized metabolite is sulfonated [8]; monoamine oxidase and sulfotransferase (SULT) inhibitors are expected to act synergistically to increase the levels of unmodified serotonin. Sulfotransferase 1A3 (SULT1A3) is responsible for the majority of neurotransmitter sulfonation in the central nervous system [9, 10] It is one of thirteen human SULT isoforms, each of which has had its catalytic efficiency (kcat/Km) “tuned” by evolution [10] toward a different area of metabolism [11]. Using CMP8 as a template, we develop high-affinity, allosteric inhibitors that are specific for SULT1A3 and can virtually completely inhibit the isoform in cultured human cells
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