N-acyl derivatives of 4-phenoxyaniline as neuroprotective agents.

Neuronal cell death is the main cause behind the progressive loss of brain function in age-related neurodegenerative disorders such as Alzheimer's and Parkinson's diseases. Despite the differing etiologies of these neurological diseases, the underlying neuronal damage is triggered by common mechanisms such as oxidative stress, impaired calcium homeostasis, and disrupted mitochondrial integrity and function. In particular, mitochondrial fragmentation, mitochondrial membrane permeability, and the release of death-promoting factors into the cytosol have been revealed as the "point of no return" in programmed cell death in neurons. Recent studies revealed a pivotal role for the pro-apoptotic Bcl-2-family protein Bid in models of neuronal cell death, which confirmed Bid as a potential drug target. Herein, we present N-acyl-substituted derivatives of 4-phenoxyaniline that were screened for their potential to attenuate Bid-mediated neurotoxicity. These compounds provided significant protection against glutamate- and Bid-induced toxicity in cultured neurons. Substitution of the amino group in the 4-phenoxyaniline scaffold with 4-piperidine carboxylic acid and N-hydroxyethyl-4-piperidine carboxylic acid yielded compounds that displayed significant neuroprotective activity at concentrations as low as 1 µM. Furthermore, findings of a tBid-overexpression assay and real-time measurements of cell impedance support the hypothesis that these compounds indeed address the Bid protein.

The human cytomegalovirus UL51 protein is essential for viral genome cleavage-packaging and interacts with the terminase subunits pUL56 and pUL89.

Cleavage of human cytomegalovirus (HCMV) genomes as well as their packaging into capsids is an enzymatic process mediated by viral proteins and therefore a promising target for antiviral therapy. The HCMV proteins pUL56 and pUL89 form the terminase and play a central role in cleavage-packaging, but several additional viral proteins, including pUL51, had been suggested to contribute to this process, although they remain largely uncharacterized. To study the function of pUL51 in infected cells, we constructed HCMV mutants encoding epitope-tagged versions of pUL51 and used a conditionally replicating virus (HCMV-UL51-ddFKBP), in which pUL51 levels could be regulated by a synthetic ligand. In cells infected with HCMV-UL51-ddFKBP, viral DNA replication was not affected when pUL51 was knocked down. However, no unit-length genomes and no DNA-filled C capsids were found, indicating that cleavage of concatemeric HCMV DNA and genome packaging into capsids did not occur in the absence of pUL51. pUL51 was expressed mainly with late kinetics and was targeted to nuclear replication compartments, where it colocalized with pUL56 and pUL89. Upon pUL51 knockdown, pUL56 and pUL89 were no longer detectable in replication compartments, suggesting that pUL51 is needed for their correct subnuclear localization. Moreover, pUL51 was found in a complex with the terminase subunits pUL56 and pUL89. Our data provide evidence that pUL51 is crucial for HCMV genome cleavage-packaging and may represent a third component of the viral terminase complex. Interference with the interactions between the terminase subunits by antiviral drugs could be a strategy to disrupt the HCMV replication cycle.