RESUMO
Synthetic biology applications would benefit from protein modules of reduced complexity that function orthogonally to cellular components. As many subcellular processes depend on peptide-protein or protein-protein interactions, de novo designed polypeptides that can bring together other proteins controllably are particularly useful. Thanks to established sequence-to-structure relationships, helical bundles provide good starting points for such designs. Typically, however, such designs are tested in vitro and function in cells is not guaranteed. Here, we describe the design, characterization, and application of de novo helical hairpins that heterodimerize to form 4-helix bundles in cells. Starting from a rationally designed homodimer, we construct a library of helical hairpins and identify complementary pairs using bimolecular fluorescence complementation in E. coli. We characterize some of the pairs using biophysics and X-ray crystallography to confirm heterodimeric 4-helix bundles. Finally, we demonstrate the function of an exemplar pair in regulating transcription in both E. coli and mammalian cells.
Assuntos
Escherichia coli , Biologia Sintética , Animais , Escherichia coli/genética , Peptídeos/química , Proteínas/química , MamíferosRESUMO
Francisella tularensis, the causative agent of tularemia, is classified as Tier 1 Select Agent with bioterrorism potential. The efficacy of the only available vaccine, LVS, is uncertain and it is not licensed in the U.S. Previously, by using an approach generally applicable to intracellular pathogens, we identified working correlates that predict successful vaccination in rodents. Here, we applied these correlates to evaluate a panel of SchuS4-derived live attenuated vaccines, namely SchuS4-ΔclpB, ΔclpB-ΔfupA, ΔclpB-ΔcapB, and ΔclpB-ΔwbtC. We combined in vitro co-cultures to quantify rodent T-cell functions and multivariate regression analyses to predict relative vaccine strength. The predictions were tested by rat vaccination and challenge studies, which demonstrated a clear relationship between the hierarchy of in vitro measurements and in vivo vaccine protection. Thus, these studies demonstrated the potential power a panel of correlates to screen and predict the efficacy of Francisella vaccine candidates, and in vivo studies in Fischer 344 rats confirmed that SchuS4-ΔclpB and ΔclpB-ΔcapB may be better vaccine candidates than LVS.
RESUMO
Methods used to prepare bone marrow-derived macrophages (BMDMs) may influence the outcomes of immunological assays in which they are used. Supernatant conditioned by growth of L929 cells has often been used to generate mouse macrophages from bone marrow in vitro but is subject to lot-to-lot variability. To reduce experimental variability and to standardize techniques across laboratories, we investigated recombinant M-CSF (rM-CSF) as an alternative supplement for BMDM maturation in the context of macrophage infection, using the intracellular bacterium Live Vaccine Strain (LVS) of Francisella tularensis as a prototype. We compared rM-CSF with L929 supernatant in terms of their effects on mouse and rat macrophage growth, maturation patterns, surface marker expression, and the expression of selected genes. Further, we compared macrophage infectivity and bacterial replication using LVS. Finally, we compared the in vitro function of BMDMs co-cultured with splenocytes from vaccinated animals in terms of their control of intramacrophage bacterial replication, as well as production of cytokines and nitric oxide. We demonstrated that rM-CSF produced BMDMs with similar, or minimal, phenotypic and gene expression outcomes compared to those generated with media containing L929 supernatant. Most importantly, functional outcomes were similar. Taken together, our data support the use of the rM-CSF in cell culture media as an alternative to L929-supplemented media for functional bioassays that use C57BL/6J mouse or Fischer 344 rat BMDMs to study intracellular infections. This comparison therefore facilitates future protocol standardization.