Gene Expression Analysis Reveals Inhibition of Radiation-Induced TGFβ-Signaling by Hyperbaric Oxygen Therapy in Mouse Salivary Glands

A side effect of radiation therapy in the head and neck region is injury to surrounding healthy tissues such as irreversible impaired function of the salivary glands. Hyperbaric oxygen therapy (HBOT) is clinically used to treat radiation-induced damage but its mechanism of action is largely unknown. In this study, we investigated the molecular pathways that are affected by HBOT in mouse salivary glands two weeks after radiation therapy by microarray analysis. Interestingly, HBOT led to significant attenuation of the radiation-induced expression of a set of genes and upstream regulators that are involved in processes such as fibrosis and tissue regeneration. Our data suggest that the TGFβ-pathway, which is involved in radiation-induced fibrosis and chronic loss of function after radiation therapy, is affected by HBOT. On the longer term, HBOT reduced the expression of the fibrosis-associated factor α-smooth muscle actin in irradiated salivary glands. This study highlights the potential of HBOT to inhibit the TGFβ-pathway in irradiated salivary glands and to restrain consequential radiation induced tissue injury.     

Inhibition of dopamine-β-hydroxylase by cytokinins

The activity of cell-free preparations of dopamine--hydroxylase from a mammalian source was inhibited by a number of N⁶-substituted adenine derivatives that are hormonally active as cytokinins in plant systems. The synthetic cytokinin N⁶-cyclohexylmethyladenine exhibited inhibitory activity equivalent to that of 1-phenyl-3-(2-thiazolyl)-2-thiourea (PTTU), a compound known to be a potent inhibitor of dopamine--hydroxylase activity. PTTU itself was found to exhibit cytokinin activity in the tobacco callus bioassay and to inhibit the activity of the plant enzyme, cytokinin oxidase. The possible significance of these observations is discussed in relation to known effects of cytokinins on phenethylamine metabolism.     

Activation of AMPK by Bitter Melon Triterpenoids Involves CaMKKβ

We recently showed that bitter melon-derived triterpenoids (BMTs) activate AMPK and increase GLUT4 translocation to the plasma membrane in vitro, and improve glucose disposal in insulin resistant models in vivo. Here we interrogated the mechanism by which these novel compounds activate AMPK, a leading anti-diabetic drug target. BMTs did not activate AMPK directly in an allosteric manner as AMP or the Abbott compound (A-769662) does, nor did they activate AMPK by inhibiting cellular respiration like many commonly used anti-diabetic medications. BMTs increased AMPK activity in both L6 myotubes and LKB1-deficient HeLa cells by 20–35%. Incubation with the CaMKKβ inhibitor, STO-609, completely attenuated this effect suggesting a key role for CaMKKβ in this activation. Incubation of L6 myotubes with the calcium chelator EGTA-AM did not alter this activation suggesting that the BMT-dependent activation was Ca²⁺-independent. We therefore propose that CaMKKβ is a key upstream kinase for BMT-induced activation of AMPK.     

Inhibition of lipogenesis and induction of apoptosis by valproic acid in prostate cancer cells via the C/EBPα/SREBP-1 pathway

Lipid metabolism reprogramming is now accepted as a new hallmark of cancer.Hence,target-ing the lipogenesis pathway may be a potential avenue for cancer treatme...     

The Concept of ‘Minimally Modified’ Antisense Oligonucleotides for Specific Inhibition of Gene Expression

Abstract

The design and use of minimally modified oligonucleotides for specific inhibition of gene expression is discussed. The “minimal” protection strategy is a combination of the end-capping technique and the protection of internal pyrimidine positions which are the major sites of endonuclease degradation. By reducing the number of phosphorothioate modifications needed to make the oligonucleotide resistant to nuclease degradation, non-sequence-specific effects, which are frequently observed with uniformly phosphorothioate-modified oligonucleotides, can be reduced.