Myelin Basic Protein Attenuates Furin-Mediated Bri2 Cleavage and Postpones Its Membrane Trafficking.

Myelin basic protein (MBP) is the second most abundant protein in the central nervous system and is responsible for structural maintenance of the myelin sheath covering axons. Previously, we showed that MBP has a more proactive role in the oligodendrocyte homeostasis, interacting with membrane-associated proteins, including integral membrane protein 2B (ITM2B or Bri2) that is associated with familial dementias. Here, we report that the molecular dynamics of the in silico-generated MBP-Bri2 complex revealed that MBP covers a significant portion of the Bri2 ectodomain, assumingly trapping the furin cleavage site, while the surface of the BRICHOS domain, which is responsible for the multimerization and activation of the Bri2 high-molecular-weight oligomer chaperone function, remains unmasked. These observations were supported by the co-expression of MBP with Bri2, its mature form, and disease-associated mutants, which showed that in mammalian cells, MBP indeed modulates the post-translational processing of Bri2 by restriction of the furin-catalyzed release of its C-terminal peptide. Moreover, we showed that the co-expression of MBP and Bri2 also leads to an altered cellular localization of Bri2, restricting its membrane trafficking independently of the MBP-mediated suppression of the Bri2 C-terminal peptide release. Further investigations should elucidate if these observations have physiological meaning in terms of Bri2 as a MBP chaperone activated by the MBP-dependent postponement of Bri2 membrane trafficking.

Two independent routes of post-translational chemistry in fluorescent protein FusionRed.

The crystal structure of monomeric red fluorescent protein FusionRed (λex/λem 580/608 mn) has been determined at 1.09 Å resolution and revealed two alternative routes of post-translational chemistry, resulting in distinctly different products. The refinement occupancies suggest the 60:40 ratio of the mature Met63-Tyr64-Gly65 chromophore and uncyclized chromophore-forming tripeptide with the protein backbone cleaved between Met63 and the preceding Phe62 and oxidized Cα-Cß bond of Tyr64. We analyzed the structures of FusionRed and several related red fluorescent proteins, identified structural elements causing hydrolysis of the peptide bond, and verified their impact by single point mutagenesis. These findings advance the understanding of the post-translational chemistry of GFP-like fluorescent proteins beyond the canonical cyclization-dehydration-oxidation mechanism. They also show that impaired cyclization does not prevent chromophore-forming tripeptide from further transformations enabled by the same set of catalytic residues. Our mutagenesis efforts resulted in inhibition of the peptide backbone cleavage, and a FusionRed variant with ~30% improved effective brightness.

Diaminopelargonic acid transaminase from Psychrobacter cryohalolentis is active towards (S)-(-)-1-phenylethylamine, aldehydes and α-diketones.

Substrate and reaction promiscuity is a remarkable property of some enzymes and facilitates the adaptation to new metabolic demands in the evolutionary process. Substrate promiscuity is also a basis for protein engineering for biocatalysis. However, molecular principles of enzyme promiscuity are not well understood. Even for the widely studied PLP-dependent transaminases of class III, the reliable prediction of the biocatalytically important amine transaminase activity is still difficult if the desired activity is unrelated to the natural activity. Here, we show that 7,8-diaminopelargonic acid transaminase (synthase), previously considered to be highly specific, is able to convert (S)-(-)-1-phenylethylamine and a number of aldehydes and diketones. We were able to characterize the (S)-amine transaminase activity of 7,8-diaminopelargonic acid transaminase from Psychrobacter cryohalolentis (Pcryo361) and analyzed the three-dimensional structure of the enzyme. New substrate specificity for α-diketones was observed, though only a weak activity towards pyruvate was found. We examined the organization of the active site and binding modes of S-adenosyl-L-methionine and (S)-(-)-1-phenylethylamine using X-ray analysis and molecular docking. We suggest that the Pcryo361 affinity towards (S)-(-)-1-phenylethylamine arises from the recognition of the hydrophobic parts of the specific substrates, S-adenosyl-L-methionine and 7-keto-8-aminopelargonic acid, and from the flexibility of the active site. Our results support the observation that the conversion of amines is a promiscuous activity of many transaminases of class III and is independent from their natural function. The analysis of amine transaminase activity from among various transaminases will help to make the sequence-function prediction for biocatalysis more reliable.

Inhibition of G1/S transition potentiates oxaliplatin-induced cell death in colon cancer cell lines.

In a series of colorectal cancer cell lines, both necrosis and apoptosis were induced upon exposure to oxaliplatin, and enhanced by co-administration of the Hsp90 inhibitor 17-AAG. We analyzed the effects of these interventions on the cell cycle, and found that oxaliplatin treatment caused G1 and G2 arrest in HCT116 cells, and S-phase accumulation in two p53-deficient cell lines (HT29 and DLD1). Addition of 17-AAG enhanced cell cycle effects of oxaliplatin in HCT116, and induced G1 arrest and decrease in S-phase population in the other cell lines. Analysis of cell cycle proteins revealed that the major difference between the cell lines was that in HCT116, 17-AAG resulted in profound inhibition of expression and phosphorylation of late G1 proteins cyclin E and cdk2, with no effect on p21/WAF1 induction. Consistent with these, an HCT116 p53(-/-) line, lacking p21, showed resistance to oxaliplatin, failure to enter apoptosis, and an accumulation of cells in S-phase. Introduction of p21 in these cells caused reversal of that phenotype, including restoration of the G1 block and re-sensitization to oxaliplatin. Inhibition of G1/S progression using cdk2 inhibitor also enhanced oxaliplatin cytotoxicity. We conclude that in colon cancer cells with impaired p53 function, interventions directed to cycle arrest in G1 may potentiate oxaliplatin activity.

Quantitative effects on c-Jun N-terminal protein kinase signaling determine synergistic interaction of cisplatin and 17-allylamino-17-demethoxygeldanamycin in colon cancer cell lines.

We investigated the effects of cisplatin and the hsp90 inhibitor 17-allylamino-17-demethoxygeldanamycin (17-AAG) in combination in a panel of human colon adenocarcinoma cell lines that differ in their p53 and mismatch repair status. Analysis of cytotoxicity after combined treatment revealed additive effects of cisplatin and 17-AAG in the HCT 116, DLD1, and SW480 cell lines and antagonism in HT-29 cells. Clonogenic assays demonstrated antagonism in HT-29, an additive effect in SW480, and synergism in HCT 116 and DLD1 cell lines. Analysis of signaling pathways revealed that cisplatin-induced activation of c-Jun N-terminal kinase (JNK) was fully blocked by 17-AAG in HT-29 and SW480 cells, whereas in HCT 116 and DLD1 cells it was inhibited only partially. The activation of caspases was also more pronounced in DLD1 and HCT 116 cell lines. These data suggested that a minimal level of apoptotic signaling through JNK was required for synergism with this combination. To test this hypothesis, we used the specific JNK inhibitor SP600125; when JNK was inhibited pharmacologically in HCT 116 and DLD1 cells, they demonstrated increased survival in clonogenic assays. Alternatively, sustained activation of JNK pathway led to an increase of the cytotoxicity of the cisplatin/17-AAG combination in HT-29 cells. Taken together, these data suggest that the synergistic interaction of this combination in colon cancer cell lines depends on the effect exerted by 17-AAG on cisplatin-induced signaling through JNK and associated pathways leading to cell death. An implication of that finding is that quantitative effects of signaling inhibitors may be critical for their ability to reverse cisplatin resistance.

Additive interaction of oxaliplatin and 17-allylamino-17-demethoxygeldanamycin in colon cancer cell lines results from inhibition of nuclear factor kappaB signaling.

Elucidation of the mechanism by which oxaliplatin induces cell death is essential to enhancing its action. We investigated the effects of oxaliplatin and 17-allylamino-17-demethoxygeldanamycin (17-AAG) in a panel of four colon adenocarcinoma cell lines. Cytotoxicity assays demonstrated at least additivity in three of the cell lines. Activation of the c-Jun NH(2)-terminal kinase pathway by oxaliplatin does not determine cytotoxicity. Activation of p38 was shown to be a key proapoptotic mediator of oxaliplatin-induced cell death. Modulation of extracellular signal-regulated kinase and AKT signaling had no impact on oxaliplatin toxicity in these cells. Nuclear factor (NF)-kappaB was constitutively active in all of the cell lines and was inhibited by 17-AAG. Down-regulation of NF-kappaB transactivation by pharmacological inhibitors enhanced oxaliplatin cytotoxicity. These data support an interaction between 17-AAG and components of the NF-kappaB pathway in the modulation of oxaliplatin sensitivity in colon cancer cells.

Geldanamycin and its 17-allylamino-17-demethoxy analogue antagonize the action of Cisplatin in human colon adenocarcinoma cells: differential caspase activation as a basis for interaction.

Several chaperone-binding drugs based on geldanamycin (GA) have been synthesized, and one of them, 17-allylamino-17-demethoxygeldanamycin (17-AAG), is being developed in the clinic. Interest in the use of 17-AAG in combination with cytotoxic drugs led us to study both GA and 17-AAG with cisplatin (DDP) in the human colon adenocarcinoma cell lines HT29 and HCT116. We performed isobologram analysis of combinations of DDP with GA or 17-AAG in these cell lines using the standard 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay to evaluate cell survival. In HCT116, the effects of GA and 17-AAG with DDP were additive and schedule dependent. In HT29 both GA and 17-AAG antagonized DDP effects resulting in cytotoxicity less than expected. We hypothesized that the antagonism in HT29 cells might be a consequence of altered p53 function in this cell line. Accordingly, we tested GA/17-AAG and DDP in combination in the HCTp5.2 cell line, which expresses a dominant-negative form of p53. In these cells too, the GA analogues antagonized DDP, suggesting a role for p53 in the observed effects. Investigation of the DDP-induced signaling pathways revealed that ansamycins block the activation of mitogen-activated protein kinase and c-Jun NH(2)-terminal kinase pathways and c-Jun expression in HT29 cells while exerting incomplete inhibitory effects in HCT116 and HCTp5.2 cell lines. Therefore, effects on signaling are thought not to underlay the antagonism in the latter model. The ansamycins inhibited DDP-induced activation of caspases 8 and 3 in HT29 and HCTp5.2 but not in HCT116 cells, which we postulate to be the basis for higher survival of p53-deficient cells when treated with combinations of the two drugs.