A number of 2,6-disubstituted analogues of disoxaril, a broad spectrum antipicornavirus agent, have been prepared and evaluated against several rhinovirus serotypes. A QSAR study revealed that the mean MIC (MIC) against five rhinovirus serotypes correlated well with log P. The 2,6-dichloro analogue, 15, was highly effective in vitro against rhinoviruses with an MIC80 of 0.3 microM, as well as against several enteroviruses, and was also effective in preventing paralysis in mice infected with coxsackievirus A-9.
A CoMFA analysis of eight compounds related to disoxaril whose X-ray structures bound to HRV-14 had been determined resulted in a strong positive correlation of activity with steric effects of the compounds, particularly toward the pore end of the compound binding site, and no correlation with electrostatic effects. These results confirm what had been previously found, that the activity of these compounds was highly dependent upon their hydrophobic nature as expressed by log p. The CoMFA study also confirmed the results from the comparison of a series of active and inactive compounds using volume maps which showed that bulk at the pore end of the molecule was conducive to high levels of antiviral activity while excessive bulk around the ring led to poor activity.
A number of (oxazolinylphenyl)isoxazoles have been synthesized and tested against human rhinovirus-14 (HRV-14). Several of the more active compounds have been examined by X-ray crystallography and their orientation in the compound binding site on the capsid protein of HRV-14 has been determined. Based on the minimum inhibitory concentration against HRV-14 and the X-ray conformation of the compounds, a model has been developed which distinguishes between the space-filling properties of the active and inactive compounds in this series. The model was generated by overlaying composite structures and comparing the van der Waals generated volume maps. The results of this study indicate that inactive compounds display areas of excessive bulk particularly around the phenyl ring, while the active compounds occupy space below the pore area of the compound binding site.
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