E7766, a Macrocycle-Bridged Stimulator of Interferon Genes (STING) Agonist with Potent Pan-Genotypic Activity.

A strategy for creating potent and pan-genotypic stimulator of interferon genes (STING) agonists is described. Locking a bioactive U-shaped conformation of cyclic dinucleotides by introducing a transannular macrocyclic bridge between the nucleic acid bases leads to a topologically novel macrocycle-bridged STING agonist (MBSA). In addition to substantially enhanced potency, the newly designed MBSAs, exemplified by clinical candidate E7766, exhibit broad pan-genotypic activity in all major human STING variants. E7766 is shown to have potent antitumor activity with long lasting immune memory response in a mouse liver metastatic tumor model. Two complementary stereoselective synthetic routes to E7766 are also described.

The ATP-mediated regulation of KaiB-KaiC interaction in the cyanobacterial circadian clock.

The cyanobacterial circadian clock oscillator is composed of three clock proteins--KaiA, KaiB, and KaiC, and interactions among the three Kai proteins generate clock oscillation in vitro. However, the regulation of these interactions remains to be solved. Here, we demonstrated that ATP regulates formation of the KaiB-KaiC complex. In the absence of ATP, KaiC was monomeric (KaiC(1mer)) and formed a complex with KaiB. The addition of ATP plus Mg(2+) (Mg-ATP), but not that of ATP only, to the KaiB-KaiC(1mer) complex induced the hexamerization of KaiC and the concomitant release of KaiB from the KaiB-KaiC(1mer) complex, indicating that Mg-ATP and KaiB compete each other for KaiC. In the presence of ATP and Mg(2+) (Mg-ATP), KaiC became a homohexameric ATPase (KaiC(6mer)) with bound Mg-ATP and formed a complex with KaiB, but KaiC hexamerized by unhydrolyzable substrates such as ATP and Mg-ATP analogs, did not. A KaiC N-terminal domain protein, but not its C-terminal one, formed a complex with KaiB, indicating that KaiC associates with KaiB via its N-terminal domain. A mutant KaiC(6mer) lacking N-terminal ATPase activity did not form a complex with KaiB whereas a mutant lacking C-terminal ATPase activity did. Thus, the N-terminal domain of KaiC is responsible for formation of the KaiB-KaiC complex, and the hydrolysis of the ATP bound to N-terminal ATPase motifs on KaiC(6mer) is required for formation of the KaiB-KaiC(6mer) complex. KaiC(6mer) that had been hexamerized with ADP plus aluminum fluoride, which are considered to mimic ADP-Pi state, formed a complex with KaiB, suggesting that KaiB is able to associate with KaiC(6mer) with bound ADP-Pi.

The roles of the dimeric and tetrameric structures of the clock protein KaiB in the generation of circadian oscillations in cyanobacteria.

The molecular machinery of the cyanobacterial circadian clock consists of three proteins, KaiA, KaiB, and KaiC. The three Kai proteins interact with each other and generate circadian oscillations in vitro in the presence of ATP (an in vitro KaiABC clock system). KaiB consists of four subunits organized as a dimer of dimers, and its overall shape is that of an elongated hexagonal plate with a positively charged cleft flanked by two negatively charged ridges. We found that a mutant KaiB with a C-terminal deletion (KaiB(1-94)), which lacks the negatively charged ridges, was a dimer. Despite its dimeric structure, KaiB(1-94) interacted with KaiC and generated normal circadian oscillations in the in vitro KaiABC clock system. KaiB(1-94) also generated circadian oscillations in cyanobacterial cells, but they were weak, indicating that the C-terminal region and tetrameric structure of KaiB are necessary for the generation of normal gene expression rhythms in vivo. KaiB(1-94) showed the highest affinity for KaiC among the KaiC-binding proteins we examined and inhibited KaiC from forming a complex with SasA, which is involved in the main output pathway from the KaiABC clock oscillator in transcription regulation. This defect explains the mechanism underlying the lack of normal gene expression rhythms in cells expressing KaiB(1-94).