Nadine S. Henderson

Blue Native electrophoresis to study mitochondrial and other protein complexes

The biogenesis and maintenance of mitochondria relies on a sizable number of proteins. Many of these proteins are organized into complexes, which are located in the mitochondrial inner membrane. Blue Native polyacrylamide gel electrophoresis (BN-PAGE) is a method for the isolation of intact protein complexes. Although it was initially used to study mitochondrial respiratory chain enzymes, it can also be applied to other protein complexes. The use of BN-PAGE has increased exponentially over the past few years and new applications have been developed. Here we review how to set up the basic system and outline modifications that can be applied to address specific research questions. Increasing the upper mass limit of complexes that can be separated by BN-PAGE can be achieved by using agarose instead of acrylamide. BN-PAGE can also be used to study assembly of mitochondrial protein complexes. Other applications include in-gel measurements of enzyme activity by histochemical staining and preparative native electrophoresis to isolate a protein complex. Finally, new ways of identifying protein spots in Blue Native gels using mass spectrometry are briefly discussed.

Fiber Formation across the Bacterial Outer Membrane by the Chaperone/Usher Pathway

Gram-negative pathogens commonly exhibit adhesive pili on their surfaces that mediate specific attachment to the host. A major class of pili is assembled via the chaperone/usher pathway. Here, the structural basis for pilus fiber assembly and secretion performed by the outer membrane assembly platform--the usher--is revealed by the crystal structure of the translocation domain of the P pilus usher PapC and single particle cryo-electron microscopy imaging of the FimD usher bound to a translocating type 1 pilus assembly intermediate. These structures provide molecular snapshots of a twinned-pore translocation machinery in action. Unexpectedly, only one pore is used for secretion, while both usher protomers are used for chaperone-subunit complex recruitment. The translocating pore itself comprises 24 beta strands and is occluded by a folded plug domain, likely gated by a conformationally constrained beta-hairpin. These structures capture the secretion of a virulence factor across the outer membrane of gram-negative bacteria.

Crystal structure of the FimD usher bound to its cognate FimC―FimH substrate

Type 1 pili are the archetypal representative of a widespread class of adhesive multisubunit fibres in Gram-negative bacteria. During pilus assembly, subunits dock as chaperone-bound complexes to an usher, which catalyses their polymerization and mediates pilus translocation across the outer membrane. Here we report the crystal structure of the full-length FimD usher bound to the FimC–FimH chaperone–adhesin complex and that of the unbound form of the FimD translocation domain. The FimD–FimC–FimH structure shows FimH inserted inside the FimD 24-stranded β-barrel translocation channel. FimC–FimH is held in place through interactions with the two carboxy-terminal periplasmic domains of FimD, a binding mode confirmed in solution by electron paramagnetic resonance spectroscopy. To accommodate FimH, the usher plug domain is displaced from the barrel lumen to the periplasm, concomitant with a marked conformational change in the β-barrel. The amino-terminal domain of FimD is observed in an ideal position to catalyse incorporation of a newly recruited chaperone–subunit complex. The FimD–FimC–FimH structure provides unique insights into the pilus subunit incorporation cycle, and captures the first view of a protein transporter in the act of secreting its cognate substrate.

Mapping and identification of essential gene functions on the X chromosome of Drosophila

The Drosophila melanogaster genome consists of four chromosomes that contain 165 Mb of DNA, 120 Mb of which are euchromatic. The two Drosophila Genome Projects, in collaboration with Celera Genomics Systems, have sequenced the genome, complementing the previously established physical and genetic maps. In addition, the Berkeley Drosophila Genome Project has undertaken large‐scale functional analysis based on mutagenesis by transposable P element insertions into autosomes. Here, we present a large‐scale P element insertion screen for vital gene functions and a BAC tiling map for the X chromosome. A collection of 501 X‐chromosomal P element insertion lines was used to map essential genes cytogenetically and to establish short sequence tags (STSs) linking the insertion sites to the genome. The distribution of the P element integration sites, the identified genes and transcription units as well as the expression patterns of the P‐element‐tagged enhancers is described and discussed.

Modulating Effects of the Plug, Helix, and N- and C-terminal Domains on Channel Properties of the PapC Usher

The chaperone/usher system is one of the best characterized pathways for protein secretion and assembly of cell surface appendages in Gram-negative bacteria. In particular, this pathway is used for biogenesis of the P pilus, a key virulence factor used by uropathogenic Escherichia coli to adhere to the host urinary tract. The P pilus individual subunits bound to the periplasmic chaperone PapD are delivered to the outer membrane PapC usher, which serves as an assembly platform for subunit incorporation into the pilus and secretion of the pilus fiber to the cell surface. PapC forms a dimeric, twin pore complex, with each monomer composed of a 24-stranded transmembrane β-barrel channel, an internal plug domain that occludes the channel, and globular N- and C-terminal domains that are located in the periplasm. Here we have used planar lipid bilayer electrophysiology to characterize the pore properties of wild type PapC and domain deletion mutants for the first time. The wild type pore is closed most of the time but displays frequent short-lived transitions to various open states. In comparison, PapC mutants containing deletions of the plug domain, an α-helix that caps the plug domain, or the N- and C-terminal domains form channels with higher open probability but still exhibiting dynamic behavior. Removal of the plug domain results in a channel with extremely large conductance. These observations suggest that the plug gates the usher channel closed and that the periplasmic domains and α-helix function to modulate the gating activity of the PapC twin pore.

Topology of the outer membrane usher PapC determined by site-directed fluorescence labeling

In contrast to typical membrane proteins that span the lipid bilayer via transmembrane α-helices, bacterial outer membrane proteins adopt a β-barrel architecture composed of antiparallel transmembrane β-strands. The topology of outer membrane proteins is difficult to predict accurately using computer algorithms, and topology mapping protocols commonly used for α-helical membrane proteins do not work for β-barrel proteins. We present here the topology of the PapC usher, an outer membrane protein required for assembly and secretion of P pili by the chaperone/usher pathway in uropathogenic Escherichia coli. An initial attempt to map PapC topology by insertion of protease cleavage sites was largely unsuccessful due to lack of cleavage at most sites and the requirement to disrupt the outer membrane to identify periplasmic sites. We therefore adapted a site-directed fluorescence labeling technique to permit topology mapping of outer membrane proteins using small molecule probes in intact bacteria. Using this method, we demonstrated that PapC has the potential to encode up to 32 transmembrane β-strands. Based on experimental evidence, we propose that the usher consists of an N-terminal β-barrel domain comprised of 26 β-strands and that a distinct C-terminal domain is not inserted into the membrane but is located instead within the lumen of the N-terminal β-barrel similar to the plug domains encoded by the outer membrane iron-siderophore uptake proteins.

Separation of intact pyruvate dehydrogenase complex using blue native agarose gel electrophoresis.

We show that the blue native gel polyacrylamide electrophoresis system (BN‐PAGE) can be applied to pyruvate dehydrogenase complex (PDC). BN‐PAGE has been used extensively to study the multisubunit enzymes of oxidative phosphorylation, as nondenaturing separation in the first dimension maintains holoenzyme integrity. However, the standard protocol was inappropriate for PDC as, at 10 MDa, it is approximately ten times larger than the largest respiratory chain enzyme complex. Therefore, agarose was substituted for polyacrylamide. Moreover, a substantial decrease in salt concentration was necessary to prevent dissociation of PDC. As with standard BN‐PAGE, immunoblots of second‐dimensional sodium dodecyl sulfate‐PAGE (SDS‐PAGE) provided more detailed information on specific subunits and subcomplexes. The method was applied to human heart mitochondrial fragments, control cultured human cells, ρ0 cells that lack mitochondrial DNA, and two cell lines derived from patients with PDC deficiency. The PDC deficient cell lines showed a clear correlation between amount of PDC holoenzyme and disease severity. In cells lacking mitochondrial DNA, synthesis and assembly of all PDC subunits (all nuclearly encoded) appeared normal, suggesting that respiratory function has no regulatory role in PDC biogenesis. Blue native agarose gel electrophoresis coupled with standard second‐dimensional SDS‐PAGE provides a new tool to be used in conjunction with biochemical assays and immunoblots of one‐dimensional SDS‐PAGE to further elucidate the nature of PDC in normal and disease states. Furthermore, other cellular protein complexes of 1 MDa or more can be analysed by this method.

Domain activities of PapC usher reveal the mechanism of action of an Escherichia coli molecular machine

P pili are prototypical chaperone–usher pathway-assembled pili used by Gram-negative bacteria to adhere to host tissues. The PapC usher contains five functional domains: a transmembrane β-barrel, a β-sandwich Plug, an N-terminal (periplasmic) domain (NTD), and two C-terminal (periplasmic) domains, CTD1 and CTD2. Here, we delineated usher domain interactions between themselves and with chaperone–subunit complexes and showed that overexpression of individual usher domains inhibits pilus assembly. Prior work revealed that the Plug domain occludes the pore of the transmembrane domain of a solitary usher, but the chaperone–adhesin-bound usher has its Plug displaced from the pore, adjacent to the NTD. We demonstrate an interaction between the NTD and Plug domains that suggests a biophysical basis for usher gating. Furthermore, we found that the NTD exhibits high-affinity binding to the chaperone–adhesin (PapDG) complex and low-affinity binding to the major tip subunit PapE (PapDE). We also demonstrate that CTD2 binds with lower affinity to all tested chaperone–subunit complexes except for the chaperone–terminator subunit (PapDH) and has a catalytic role in dissociating the NTD–PapDG complex, suggesting an interplay between recruitment to the NTD and transfer to CTD2 during pilus initiation. The Plug domain and the NTD–Plug complex bound all of the chaperone–subunit complexes tested including PapDH, suggesting that the Plug actively recruits chaperone–subunit complexes to the usher and is the sole recruiter of PapDH. Overall, our studies reveal the cooperative, active roles played by periplasmic domains of the usher to initiate, grow, and terminate a prototypical chaperone–usher pathway pilus.

Function of the usher N-terminus in catalysing pilus assembly

The chaperone/usher (CU) pathway is a conserved bacterial secretion system that assembles adhesive fibres termed pili or fimbriae. Pilus biogenesis by the CU pathway requires a periplasmic chaperone and an outer membrane (OM) assembly platform termed the usher. The usher catalyses formation of subunit–subunit interactions to promote polymerization of the pilus fibre and provides the channel for fibre secretion. The mechanism by which the usher catalyses pilus assembly is not known. Using the P and type 1 pilus systems of uropathogenic Escherichia coli, we show that a conserved N‐terminal disulphide region of the PapC and FimD ushers, as well as residue F4 of FimD, are required for the catalytic activity of the ushers. PapC disulphide loop mutants were able to bind PapDG chaperone–subunit complexes, but did not assemble PapG into pilus fibres. FimD disulphide loop and F4 mutants were able to bind chaperone–subunit complexes and initiate assembly of pilus fibres, but were defective for extending the pilus fibres, as measured using in vivo co‐purification and in vitro pilus polymerization assays. These results suggest that the catalytic activity of PapC is required to initiate pilus biogenesis, whereas the catalytic activity of FimD is required for extension of the pilus fibre.

Molecular basis of usher pore gating in Escherichia coli pilus biogenesis

Significance Gram-negative bacteria use chaperone-usher pathway (CUP) pili to colonize host tissues and mediate biofilm formation. CUP ushers are outer membrane (OM) pore proteins that catalyze pilus assembly and mediate pilus extrusion in a gated fashion to maintain OM homeostasis. Using antibiotic sensitivity and electrophysiology experiments, specific residues of two ushers, FimD of type 1 pili and PapC of P pili, were identified as crucial for proper usher gating. Further, deletion of the P pilus anchoring/terminator subunit resulted in an open usher conformation, indicating this subunit may be a target for antivirulence compounds to potentiate antibiotic treatment. Identification of mechanisms that can be used to increase bacterial sensitivity to antibiotics is crucial for development of novel compounds to fight infections. Extracellular fibers called chaperone-usher pathway pili are critical virulence factors in a wide range of Gram-negative pathogenic bacteria that facilitate binding and invasion into host tissues and mediate biofilm formation. Chaperone-usher pathway ushers, which catalyze pilus assembly, contain five functional domains: a 24-stranded transmembrane β-barrel translocation domain (TD), a β-sandwich plug domain (PLUG), an N-terminal periplasmic domain, and two C-terminal periplasmic domains (CTD1 and 2). Pore gating occurs by a mechanism whereby the PLUG resides stably within the TD pore when the usher is inactive and then upon activation is translocated into the periplasmic space, where it functions in pilus assembly. Using antibiotic sensitivity and electrophysiology experiments, a single salt bridge was shown to function in maintaining the PLUG in the TD channel of the P pilus usher PapC, and a loop between the 12th and 13th beta strands of the TD (β12–13 loop) was found to facilitate pore opening. Mutation of the β12–13 loop resulted in a closed PapC pore, which was unable to efficiently mediate pilus assembly. Deletion of the PapH terminator/anchor resulted in increased OM permeability, suggesting a role for the proper anchoring of pili in retaining OM integrity. Further, we introduced cysteine residues in the PLUG and N-terminal periplasmic domains that resulted in a FimD usher with a greater propensity to exist in an open conformation, resulting in increased OM permeability but no loss in type 1 pilus assembly. These studies provide insights into the molecular basis of usher pore gating and its roles in pilus biogenesis and OM permeability.