Synthesis and selection of de novo proteins that bind and impede cellular functions of an essential mycobacterial protein.

Recent advances in nonrational and part-rational approaches to de novo peptide/protein design have shown increasing potential for development of novel peptides and proteins of therapeutic use. We demonstrated earlier the usefulness of one such approach recently developed by us, called "codon shuffling," in creating stand-alone de novo protein libraries from which bioactive proteins could be isolated. Here, we report the synthesis and selection of codon-shuffled de novo proteins that bind to a selected Mycobacterium tuberculosis protein target, the histone-like protein HupB, believed to be essential for mycobacterial growth. Using a versatile bacterial two-hybrid system that entailed utilization of HupB and various codon-shuffled protein libraries as bait and prey, respectively, we were able to identify proteins that bound strongly to HupB. The observed interaction was also confirmed using an in vitro assay. One of the protein binders was expressed in Mycobacterium smegmatis and was shown to appreciably affect growth in the exponential phase, a period wherein HupB is selectively expressed. Furthermore, the transcription profile of hupB gene showed a significant reduction in the transcript quantity in mycobacterial strains expressing the protein binder. Electron microscopy of the affected mycobacteria elaborated on the extent of cell damage and hinted towards a cell division malfunction. It is our belief that a closer inspection of the obtained de novo proteins may bring about the generation of small-molecule analogs, peptidomimetics, or indeed the proteins themselves as realistic leads for drug candidates. Furthermore, our strategy is adaptable for large-scale targeting of the essential protein pool of Mycobacterium tuberculosis and other pathogens.