Synthesis and Metabolism of BTN3A1 Ligands: Studies on Diene Modifications to the Phosphoantigen Scaffold.

Phosphoantigens (pAgs) are small organophosphorus compounds such as (E)-4-hydroxy-3-methyl-but-2-enyl diphosphate (HMBPP) that trigger an immune response. These molecules bind to butyrophilin 3A1 (part of the HMBPP receptor) and activate Vγ9Vδ2 T cells. To explore the structure-activity relationships underlying this process, we evaluated a series of novel diene analogs of HMBPP. Here we report that prodrug forms of [(1E)-4-methylpenta-1,3-dien-1-yl] phosphonic acid that lack the allylic alcohol of HMBPP but instead contained a diene scaffold exhibit mid-nanomolar potency for the activation of Vγ9Vδ2 T cells. The compounds also trigger the production of T-cell interferon γ upon exposure to loaded K562 cells. Although both the allylic alcohol and the diene scaffold boost pAg activity, the combination of the two decreases the activity and results in glutathione conjugation. Together, these data show that the diene scaffold results in intermediate pAgs that may have implications for the mechanisms regulating the HMBPP receptor.

Conjugate reduction of vinyl bisphosphonates.

Vinyl bisphosphonates can be readily prepared by condensation of an aromatic aldehyde with the tetraester of a methylenebisphosphonate, and reduction of the resulting olefin is an attractive strategy for the preparation of monoalkyl geminal bisphosphonates. Conjugate reduction through use of variations on the Stryker approach has proven to be an efficient method for that reduction, even in the presence of aromatic substituents that also could be reduced. Furthermore, remote olefins in an isoprenoid chain survive this conjugate reduction unaffected, allowing access to isoprenoid-substituted triazole bisphosphonates of interest as potential inhibitors of terpenoid biosynthesis.

Incorporation of a FRET pair within a phosphonate diester.

Cell-cleavable protecting groups are an effective tactic for construction of biological probes because such compounds can improve problems with instability, solubility, and cellular uptake. Incorporation of fluorescent groups in the protecting groups may afford useful probes of cellular functions, especially for payloads containing phosphonates that would be highly charged if not protected, but little is known about the steric or electronic factors that impede release of the payload. In this report we present a strategy for the synthesis of a coumarin fluorophore and a 4-((4-(dimethylamino)phenyl)diazenyl)benzoic acid (DABCYL) ester chromophore incorporated as a FRET pair within a single phosphonate. Such compounds were designed to deliver a BTN3A1 ligand payload to its intracellular receptor. Both final products and some synthetic intermediates were evaluated for their ability to undergo metabolic activation in γδ T cell functional assays, and for their photophysical properties by spectrophotometry. One phosphonate bearing a DABCYL acyloxyester and a novel tyramine-linked coumarin fluorophore exhibited strong, rapid, and potent cellular activity for γδ T cell stimulation and also showed FRET interactions. This strategy demonstrates that bioactivatable phosphonates containing FRET pairs can be utilized to develop probes to monitor cellular uptake of otherwise charged payloads.

Synthesis and Metabolism of BTN3A1 Ligands: Studies on Modifications of the Allylic Alcohol.

(E)-4-Hydroxy-3-methyl-but-2-enyl diphosphate (HMBPP) and its phosphonate analogs are potent phosphoantigens. HMBPP contains an (E)-allylic alcohol which interacts with the molecular target BTN3A1 giving an antigenic signal to activate Vγ9Vδ2 T cells. As probes of BTN3A1 function, we prepared prodrug derivatives of the HMBPP analog C-HMBP that lack the (E)-allylic alcohol or have modified it to an aldehyde or aldoxime and evaluated their biological activity. Removal of the alcohol completely abrogates phosphoantigenicity in these compounds while the aldoxime modification decreases potency relative to the (E)-allylic alcohol form. However, homoprenyl derivatives oxidized to an aldehyde stimulate Vγ9Vδ2 T cells at nanomolar concentrations. Selection of phosphonate protecting groups (i.e., prodrug forms) impacts the potency of phosphoantigen aldehydes, with mixed aryl acyloxyalkyl forms exhibiting superior activity relative to aryl amidate forms. The activity correlates with the cellular reduction of the aldehyde to the alcohol form. Thus, the functionality on this ligand framework can be altered concurrently with phosphonate protection to promote cellular transformation to highly potent phosphoantigens.

Potent double prodrug forms of synthetic phosphoantigens.

Phosphoantigens are ligands of BTN3A1 that stimulate anti-cancer functions of γδ T cells, yet the potency of natural phosphoantigens is limited by low cell permeability and low metabolic stability. Derivatives of BTN3A1 ligand prodrugs were synthesized that contain an acetate-protected allylic alcohol and act as doubly protected prodrugs. A novel set of phosphonates, phosphoramidates, and phosphonamidates has been prepared through a new route that simplifies synthesis and postpones the point of divergence into different prodrug forms. One of the new prodrugs, compound 11, potently stimulates γδ T cell proliferation (72 h EC50 = 0.12 nM) and interferon γ response to loaded leukemia cells (4 h EC50 = 19 nM). This phosphonamidate form was > 900x more potent than the corresponding phosphoramidate, and the phosphonamidate form was also significantly more stable in plasma following acetate hydrolysis. Therefore, prodrug modification of phosphonate butyrophilin ligands at the allylic alcohol can both facilitate chemical synthesis and improve potency of γδ T cell stimulation.