Disulfide-compatible phage-assisted continuous evolution in the periplasmic space.

The directed evolution of antibodies has yielded important research tools and human therapeutics. The dependence of many antibodies on disulfide bonds for stability has limited the application of continuous evolution technologies to antibodies and other disulfide-containing proteins. Here we describe periplasmic phage-assisted continuous evolution (pPACE), a system for continuous evolution of protein-protein interactions in the disulfide-compatible environment of the E. coli periplasm. We first apply pPACE to rapidly evolve novel noncovalent and covalent interactions between subunits of homodimeric YibK protein and to correct a binding-defective mutant of the anti-GCN4 Ω-graft antibody. We develop an intein-mediated system to select for soluble periplasmic expression in pPACE, leading to an eight-fold increase in soluble expression of the Ω-graft antibody. Finally, we evolve disulfide-containing trastuzumab antibody variants with improved binding to a Her2-like peptide and improved soluble expression. Together, these results demonstrate that pPACE can rapidly optimize proteins containing disulfide bonds, broadening the applicability of continuous evolution.

The Central Spike Complex of Bacteriophage T4 Contacts PpiD in the Periplasm of Escherichia coli.

Infecting bacteriophage T4 uses a contractile tail structure to breach the envelope of the Escherichia coli host cell. During contraction, the tail tube headed with the "central spike complex" is thought to mechanically puncture the outer membrane. We show here that a purified tip fragment of the central spike complex interacts with periplasmic chaperone PpiD, which is anchored to the cytoplasmic membrane. PpiD may be involved in the penetration of the inner membrane by the T4 injection machinery, resulting in a DNA-conducting channel to translocate the phage DNA into the interior of the cell. Host cells with the ppiD gene deleted showed partial reduction in the plating efficiency of T4, suggesting a supporting role of PpiD to improve the efficiency of the infection process.

Periplasmic Nanobody-APEX2 Fusions Enable Facile Visualization of Ebola, Marburg, and Menglà virus Nucleoproteins, Alluding to Similar Antigenic Landscapes among Marburgvirus and Dianlovirus.

We explore evolved soybean ascorbate peroxidase (APEX2) as a reporter when fused to the C-termini of llama nanobodies (single-domain antibodies, sdAb; variable domains of heavy chain-only antibodies, VHH) targeted to the E. coli periplasm. Periplasmic expression preserves authentic antibody N-termini, intra-domain disulphide bond(s), and capitalizes on efficient haem loading through the porous E. coli outer membrane. Using monomeric and dimeric anti-nucleoprotein (NP) sdAb cross-reactive within the Marburgvirus genus and cross-reactive within the Ebolavirus genus, we show that periplasmic sdAb-APEX2 fusion proteins are easily purified at multi-mg amounts. The fusions were used in Western blotting, ELISA, and microscopy to visualize NPs using colorimetric and fluorescent imaging. Dimeric sdAb-APEX2 fusions were superior at binding NPs from viruses that were evolutionarily distant to that originally used to select the sdAb. Partial conservation of the anti-Marburgvirus sdAb epitope enabled the recognition of a novel NP encoded by the recently discovered Menglà virus genome. Antibody-antigen interactions were rationalized using monovalent nanoluciferase titrations and contact mapping analysis of existing crystal structures, while molecular modelling was used to reveal the potential landscape of the Menglà NP C-terminal domain. The sdAb-APEX2 fusions also enabled live Marburgvirus and Ebolavirus detection 24 h post-infection of Vero E6 cells within a BSL-4 laboratory setting. The simple and inexpensive mining of large amounts of periplasmic sdAb-APEX2 fusion proteins should help advance studies of past, contemporary, and perhaps Filovirus species yet to be discovered.

The lambda spanin components Rz and Rz1 undergo tertiary and quaternary rearrangements upon complex formation.

Phage holins and endolysins have long been known to play key roles in lysis of the host cell, disrupting the cytoplasmic membrane and peptidoglycan (PG) layer, respectively. For phages of Gram-negative hosts, a third class of proteins, the spanins, are involved in disrupting the outer membrane (OM). Rz and Rz1, the components of the lambda spanin, are, respectively, a class II inner membrane protein and an OM lipoprotein, are thought to span the entire periplasm by virtue of C-terminal interactions of their soluble domains. Here, the periplasmic domains of Rz and Rz1 have been purified and shown to form dimeric and monomeric species, respectively, in solution. Circular dichroism analysis indicates that Rz has significant alpha-helical character, but much less than predicted, whereas Rz1, which is 25% proline, is unstructured. Mixture of the two proteins leads to complex formation and an increase in secondary structure, especially alpha-helical content. Moreover, transmission electron-microscopy reveals that Rz-Rz1 complexes form large rod-shaped structures which, although heterogeneous, exhibit periodicities that may reflect coiled-coil bundling as well as a long dimension that matches the width of the periplasm. A model is proposed suggesting that the formation of such bundles depends on the removal of the PG and underlies the Rz-Rz1 dependent disruption of the OM.

Involvement of SecDF and YidC in the membrane insertion of M13 procoat mutants.

The M13 phage Procoat protein is one of the best characterized substrates for the novel YidC pathway. It inserts into the membrane independent of the SecYEG complex but requires the 60 kDa YidC protein. Mutant Procoat proteins with alterations in the periplasmic region had been found to require SecYEG and YidC. In this report, we show that the membrane insertion of these mutants also strongly depends on SecDF that bridges SecYEG to YidC. In a cold-sensitive mutant of YidC, the Sec-dependent function of YidC is strongly impaired. We find that specifically the SecDF-dependent mutants are inhibited in the cold-sensitive YidC strain. Finally, we find that subtle changes in the periplasmic loop such as the number and location of negatively charged residues and the length of the periplasmic loop can make the Procoat strictly Sec-dependent. In addition, we successfully converted Sec-independent Pf3 coat into a Sec-dependent protein by changing the location of a negatively charged residue in the periplasmic tail. Protease mapping of Pf3 coat shows that the insertion-arrested proteins that accumulate in the YidC- or in the SecDF-deficient strains are not translocated. Taken together, the data suggest that the Sec-dependent mutants insert at the interface of YidC and the translocon with SecDF assisting in the translocation step in vivo.

The pI and pXI assembly proteins serve separate and essential roles in filamentous phage assembly.

Three non-capsid, phage-encoded proteins, pI, pIV and pXI, are required for assembly of the filamentous bacteriophage at the envelope of Escherichia coli. pIV forms the outer membrane component of the assembly site, and pI and pXI are predicted to form the cytoplasmic membrane component. pXI is the result of an in-frame internal translational initiation event in gene I and is identical with the carboxyl-terminal third of pI in amino acid sequence, membrane localization and topology. The two proteins share a cytoplasmic domain predicted to be an amphipathic helix, a transmembrane domain, and a periplasmic domain. By mutating the initiation site for pXI, a phage was made that produced only pI and was shown to absolutely require functional plasmid-encoded pXI for growth. Further mutational analysis was done to examine the functional determinants of the amphipathic helix and periplasmic domains of the pI and pXI proteins. The results show that the amphipathic helix region is very important for pI function but not for pXI function. Mutational analysis of the periplasmic domains of pI and pXI implies that these domains also perform separate functions, and suggests that the interaction between pI and pIV in the periplasm is critical for assembly. The results are discussed with regard to the separate roles that the pI and pXI proteins play in the overall process of phage assembly.