Binding of boswellic acids to functional proteins of the SARS-CoV-2 virus: Bioinformatic studies.

Boswellic acids (BAs) have been shown to possess antiviral activity. Using bioinformatic methods, it was tested whether or not acetyl-11-keto-ß-boswellic acid (AKBA), 11-keto-ß-boswellic acid (KBA), ß-boswellic acid (BBA), and the phosphorylated active metabolite of Remdesivir® (RGS-P3) bind to functional proteins of SARS-CoV-2, that is, the replicase polyprotein P0DTD1, the spike glycoprotein P0DTC2, and the nucleoprotein P0DTC9. Using P0DTD1, AKBA and KBA showed micromolar binding affinity to the RNA-dependent RNA polymerase (RdRp) and to the main proteinase complex Mpro . Phosphorylated BAs even bond in the nanomolar range. Due to their positive and negative charges, BAs and RGS-P3 bond to corresponding negative and positive areas of the protein. BAs and RGS-P3 docked in the tunnel-like cavity of RdRp. BAs also docked into the elongated surface rim of viral Mpro . In both cases, binding occurred with active site amino acids in the lower micromolecular to upper nanomolar range. KBA, BBA, and RGS-P3 also bond to P0DTC2 and P0DTC9. The binding energies for BAs were in the range of -5.8 to -6.3 kcal/mol. RGS-P3 and BAs occluded the centrally located pore of the donut-like protein structure of P0DTC9 and, in the case of P0DTC2, RGS-P3 and BAs impacted the double-wing-like protein structure. The data of this bioinformatics study clearly show that BAs bind to three functional proteins of the SARS-CoV-2 virus responsible for adhesion and replication, as does RGS-P3, a drug on the market to treat this disease. The binding effectiveness of BAs can be increased through phosphate esterification. Whether or not BAs are druggable against the SARS-CoV-2 disease remains to be established.

11-Keto-ß-Boswellic Acid Inhibits Lymphocyte (CD3) Infiltration Into Pancreatic Islets of Young None Obese Diabetic (NOD) Mice.

11-Keto-ß-Boswellic acid (KBA) has been shown to prevent infiltration of lymphocytes into pancreatic islets and appearance of peri-insular apoptotic cells in an animal model of autoimmune diabetes caused by injection of Multiple Low Doses of Streptozotocin (MLD-STZ), which is a chemical compound belonging to the class of nitrososureas. The aim of this work was to study whether or not KBA can also prevent/attenuate infiltration of lymphocytes into pancreatic islets and appearance of peri-insular apoptotic cells in an animal model of autoimmune diabetes caused by genetic dysfunction resembling human type 1 diabetes in several important features. Four weeks old female NOD mice received daily i.p. injections of 7.5 mg/kg of KBA over a period of 3 weeks. Compared to 4 weeks old animals there was significant infiltration of lymphocytes (CD3) into pancreatic islets and appearance of peri-insular apoptotic cells in the period between 4 and 7 weeks. During this time plasma glucose dropped significantly and body weight did not increase. As far as pro-inflammatory cytokines are concerned, except a small increase of IFN-γ, there was no change in the blood. In mice that had been treated with KBA between 4 and 7 weeks after birth no significant infiltration of lymphocytes into pancreatic islets and appearance of peri-insular apoptotic cells was observed, when compared to 4 weeks old mice. Moreover, there was no drop of blood glucose and the animals gained body weight. It is concluded that - similar to the model of MLD-STZ-diabetes - also in the NOD mouse model KBA is able to attenuate or even prevent development of insulitis, suggesting that KBA protects islets from autoimmune reaction regardless whether the signal is provided by a chemical compound or by genetic dysfunction. Whether this also holds for human type 1 diabetes remains to be established.

Interference of boswellic acids with the ligand binding domain of the glucocorticoid receptor.

Boswellic acids (BAs) possess anti-inflammatory properties in various biological models with similar features to those of glucocorticoids (GCs), such as suppression of the release of pro-inflammatory cytokines. Hence, the molecular mechanism of BAs responsible for their anti-inflammatory features might be attributable to interference with the human glucocorticoid receptor (GR). Due to obvious structural similarities with GCs, we conducted pharmacophore studies as well as molecular docking simulations of BAs as putative ligands at the ligand binding site (LBS) of the GR in distinct functional states. In order to verify receptor binding and functional activation of the GR by BAs, radiometric binding assays as well as GR response element-dependent luciferase reporter assay were performed with dexamethasone (DEX) as a functional positive control. With respect to the observed position of GCs in GR crystal complexes in the active antagonist state, BAs docked in a flipped orientation with estimated binding constants reflecting nanomolar affinities. For validation, DEX and other steroids were successfully redocked into their crystal poses in similar ranges as reported in the literature. In line with the pharmacophore and docking models, the BAs were strong GR binders (radiometric binding assay), albeit none of the BAs activated the GR in the reporter gene assay, when compared to the GC agonist DEX. The flipped scaffolds of all BAs dislodge the known C-11 function from its receiving amino acid (Asn564), which may explain the silencing effects of receptor-bound BAs in the reporter gene assay. Together, our results constitute a compelling example of rigid keys acting in an adaptable lock qualifying as a reversed induced fit mechanism, thereby extending the hitherto published knowledge about molecular target interactions of BAs.

[Cinnamon in type 2 diabetics]. / Zimt bei Typ-2-Diabetikern Diätetisches Lebensmittel oder Arzneimittel?

At present numerous preparations containing cinnamon are in the market. And it is claimed that they are suitable as dietetic food or food additive to regulate glucose metabolism in patients with type 2 diabetes. Background for this proposition are the results of some pharmacological and clinical studies, showing improvement of glucose tolerance in streptozotocin-diabetic animals, stimulation of insulin secretion in vitro and lowering blood glucose in type 2 diabetic patients during simultaneous treatment with oral antidiabetics. This led to a controversy between producers of food additives on the one side and scientists in the field of pharmacology and diabetology on the other. In this connection in a scientific statement the German Diabetes Association (DDG) and the German Pharmaceutical Society (DPhG) kept on distance from the use of cinnamon as a dietetic food/food supplement. The point is the interpretation of what is considered to be a food and what is a drug for medical purposes. Since cinnamon has been used for long as a spice, the nutrition site claims cinnamon as a food. In contrary the medical site in this case claims cinnamon as a drug because of its pharmacological effects on glucose tolerance, insulin resistance, insulin release and blood-sugar. In the meantime this is a case of jurisdiction.

K-ATP channel independent effects of pinacidil on ATP production in isolated cardiomyocyte or pancreatic beta-cell mitochondria.

Evidence has been presented that mitochondria contain ATP sensitive potassium channels (mK-ATP channels), which may confer tissue protection upon activation. It is, however, not known whether activation of mK-ATP channels has a direct effect on mitochondrial ATP production. This study was performed to define the effect of pinacidil (PIN) on ATP production by oxidative phosphorylation in isolated cardiomyocyte or pancreatic beta-cell mitochondria. Cardiomyocyte mitochondria produced seven times more ATP than beta-cell mitochondria in the presence of pyruvate/malate. PIN inhibited pyruvate/malate-induced mitochondrial ATP production with half maximal effect at 360 microM in both cell types. The inclusion of 5-hydroxydecanoate (5-HD) did not prevent this inhibition. Succinate induced a similar ATP production in cardiomyocyte or beta-cell mitochondria. In beta-cell mitochondria succinate-induced ATP production was inhibited by PIN with half maximal effects at 500 microM PIN. However, in cardiomyocyte mitochondria PIN stimulated succinate-induced ATP production 3-fold with half maximal effect at 100 microM and maximal effect at 200 microM. This PIN-dependent stimulation was mimicked by rotenone. The inclusion of 5-HD could not prevent these PIN effects. In conclusion, PIN may inhibit complex 1 of the respiratory chain without indications of opening mK-ATP channels. In cardiomyocytes with metabolically inhibited succinate dehydrogenase this results in a stimulation of ATP production conferring tissue protection. In beta-cells without a metabolically inhibited succinate dehydrogenase, there is no stimulation by PIN and tissue protection by PIN is not to be expected.