A simple strategy for retargeting lentiviral vectors to desired cell types via a disulfide-bond-forming protein-peptide pair.

Despite recent improvements in the engineering of viral envelope proteins, it remains a significant challenge to create lentiviral vectors that allow targeted transduction to specific cell populations of interest. In this study, we developed a simple 'plug and play' strategy to retarget lentiviral vectors to any desired cell types through in vitro covalent modification of the virions with specific cell-targeting proteins (CTPs). This strategy exploits a disulfide bond-forming protein-peptide pair PDZ1 and its pentapeptide ligand (ThrGluPheCysAla, TEFCA). PDZ1 was incorporated into an engineered Sindbis virus envelope protein (Sind-PDZ1) and displayed on lentiviral particles while the TEFCA pentapeptide ligand was genetically linked to the CTP. Her2/neu-binding designed ankyrin repeat proteins (DARPin) were used as our model CTPs. DARPin-functionalized unconcentrated lentiviral vectors harboring Sind-PDZ1 envelope protein (Sind-PDZ1-pp) exhibited >800-fold higher infectious titer in HER2+ cells than the unfunctionalized virions (8.5 × 106 vs. <104 IU/mL). Moreover, by virtue of the covalent disulfide bond interaction between PDZ1 and TEFCA, the association of the CTP with the virions is nonreversible under non-reducing conditions (e.g. serum), making these functionalized virions potentially stable in an in vivo setting.

Retargeting Lentiviruses via SpyCatcher-SpyTag Chemistry for Gene Delivery into Specific Cell Types.

We report a simple strategy for the creation of lentiviral vectors specific to any desired target cells. SpyTag is inserted into an engineered Sindbis virus envelope protein and displayed on the lentivirus surface to create Sindbis virus-SpyTag pseudoparticles (Sind-SpyTag-pp). The SpyTag serves as the covalent anchoring site for a target-cell-specific cell-binding protein (CBP) that is fused to a truncated SpyCatcher (SpyCatcherΔ). Target-cell-specific lentiviruses are created by mixing the Sind-SpyTag-pp and CBP-SpyCatcherΔ in vitro We first used a HER2-binding designed ankyrin repeat protein (DARPin.9.26) as the model CBP. The DARPin-conjugated lentivirus transduced HER2+ SKOV3 cells with an infectious titer of 5.2 × 106 IU/ml, >500-fold higher than the unfunctionalized "naked" virions (<104 IU/ml). The ability of the DARPin-conjugated lentivirus to transduce HER2+ cells correlated with the surface expression level of HER2. Furthermore, these lentiviruses preferentially transduced HER2+ cells in cocultures containing HER2+ and HER2- cells. To enable the use of commercially available monoclonal antibodies (MAbs) as the CBP, we developed a convenient click chemistry-based approach to conjugate MAb-derived Fab fragments to a variant SpyCatcherΔ protein containing a nonnatural amino acid, 4-azido-l-phenylalanine (AzF). Using the HER2-binding trastuzumab as a model cell-specific MAb, we created Fab-conjugated lentiviral vectors that transduced HER2+ SKOV3 cells with an infectious titer of 2.8 × 106 IU/ml, on par with the result achieved using the DARPin-SpyCatcherΔ fusion protein. The ability to create cell-specific lentiviral vectors through chemical conjugation of a CBP should make this approach generalizable to any antibody, giving it broad utility for a wide range of research and clinical applications.IMPORTANCE Lentiviral vectors hold great potential in gene therapy. However, it remains a major hurdle to robustly engineer cell-specific lentiviral vectors. This article reports a simple and effective strategy to functionalize lentiviral vectors with cell-binding proteins, thus retargeting these viruses to cells expressing the binding partner of the CBP. The CBP is genetically or chemically linked to the SpyCatcher. The SpyTag is displayed on the virion surface as a fusion to an engineered Sindbis virus envelope protein and is used as the anchorage site for SpyCatcher-linked CBP. Using this strategy, we created lentiviral vectors highly infectious toward HER2+ cancer cells. The ability to rapidly create cell-specific lentiviral vectors targeting a wide range of cell types should accelerate the development of custom lentiviral vectors for many research and clinical applications.

Pseudomonas aeruginosa, under DNA replication inhibition, tends to form biofilms via Arr.

Bacteria infecting eukaryotic hosts often encounter therapeutic antimicrobial and DNA damaging agents and respond by forming biofilms. While mechanisms of biofilm response are incompletely understood, they seem to involve bacterial second messenger bis-(3'-5')-cyclic dimeric guanosine monophosphate (c-di-GMP) signaling. We hypothesized that DNA replication inhibition induces bacterial biofilm formation via c-di-GMP signaling. Evidently, we found that Pseudomonas aeruginosa mounted a biofilm response to the subinhibitory DNA replication inhibitors hydroxyurea and nalidixic acid, but planktonic proliferation was inhibited. The biofilm response was suppressed either genetically by mutations causing planktonic resistance or biochemically by reversal of replication inhibition. Biofilms were induced by a mechanism of stimulated adhesion of planktonic filaments having impaired DNA replication, as examined under fluorescence microscopy. Induction was suppressed by either inhibition or mutation of Arr-a c-di-GMP phosphodiesterase. These results suggest that P. aeruginosa, under DNA replication stress, tends to form biofilms via Arr. The profound implications of the SOS response, planktonic-sessile and bacteria-cancer relationships are discussed.