YscU recognizes translocators as export substrates of the Yersinia injectisome

YscU is an essential component of the export apparatus of the Yersinia injectisome. It consists of an N-terminal transmembrane domain and a long cytoplasmic C-terminal domain, which undergoes auto-cleavage at a NPTH site. Substitutions N263A and P264A prevented cleavage of YscU and abolished export of LcrV, YopB and YopD but not of Yop effectors. As a consequence, yscU(N263A) mutant bacteria made needles without the LcrV tip complex and they could not form translocation pores. The graft of the export signal of the effector YopE, at the N-terminus of LcrV, restored LcrV export and assembly of the tip complex. Thus, YscU cleavage is required to acquire the conformation allowing recognition of translocators, which represent an individual category of substrates in the hierarchy of export. In addition, yscU(N263A) mutant bacteria exported reduced amounts of the YscP ruler and made longer needles. Increasing YscP export resulted in needles with normal size, depending on the length of the ruler. Hence, the effect of the yscU(N263A) mutation on needle length was the consequence of a reduced YscP export.     

LcrV is a channel size-determining component of the Yop effector translocon of Yersinia

Delivery of Yop effector proteins by pathogenic Yersinia across the eukaryotic cell membrane requires LcrV, YopB and YopD. These proteins were also required for channel formation in infected erythrocytes and, using different osmolytes, the contact-dependent haemolysis assay was used to study channel size. Channels associated with LcrV were around 3 nm, whereas the homologous PcrV protein of Pseudomonas aeruginosa induced channels of around 2 nm in diameter. In lipid bilayer membranes, purified LcrV and PcrV induced a stepwise conductance increase of 3 nS and 1 nS, respectively, in 1 M KCl. The regions important for channel size were localized to amino acids 127-195 of LcrV and to amino acids 106-173 of PcrV. The size of the channel correlated with the ability to translocate Yop effectors into host cells. We suggest that LcrV is a size-determining structural component of the Yop translocon.     

YspD: A Potential Therapeutic Target for Drug Design to Combat Yersinia enterocolitica Infection

YspD is an annotated hydrophilic translocator of Ysa–Ysp type III secretion system of Yersinia enterocolitica. YspD has sequence, secondary structure and three-dimensional structure similar to other hydrophilic translocators. All hydrophilic translocators lack transmembrane region and possess intramolecular coiled-coil region. Disordered regions are mostly clustered at the N-terminal. Large loops provide flexibility, allowing conformational changes during oligomerization and protein–protein interaction. LcrV and PcrV have globular N-terminal and C-terminal domains, connected by intramolecular coiled-coil region. YspD, IpaD, SipD and BipD lack globular N-terminal and C-terminal domains. Their N-terminal and C-terminal domain have a bundle like structure connected by the intramolecular coiled-coil. The intramolecular coiled-coil regions (helix-5&9) of YspD showed maximum conservation, followed by helices at N-terminal. Polar interactions are mainly involved during dimerization of YspD, involving polar residues from helix-9 of both the YspD molecules. A methionine forms the boundary of interaction between the two YspD molecules. The two YspD molecules are arranged in antiparallel fashion to form the dimer. N-terminal of YspB interacted with C-terminal of YspD molecule to form a pentameric complex, consisting four YspD molecules and one YspB molecule. Sequence, structural similarity and presence of specific motifs in YspD (like chaperone protein) indicate the ability of N-terminal domain to show self-chaperoning activity and regulate folding and conformational state of YspD during its journey from the bacterial cytoplasm to the needle tip. Structural analysis of YspD and its mechanism of interaction with other proteins would enable us to design drugs against this hydrophilic protein to combat Yersinia infection.

     

Generation and Characterization of Murine Monoclonal Antibodies to Recombinant YopM, YopB and LcrV Proteins of Yersinia pestis

Summary YopM, an effector, YopB, a translator, and LcrV, a regulator, are proteins forming important componants of type III secretion system of Yersinia pestis. Recombinant truncated YopM of 32 kDa, YopB of 28 kDa and LcrV of 31 kDa sizes were utilized for priming BALB/c mice for the generation of monoclonal antibodies following standard poly-ethylene glycol (PEG) fusion protocol. Nine, 10 and 6 stabilized hybridoma cell lines could be generated against YopM, YopB and LcrV proteins, respectively. All these monoclonal antibodies were found reactive to Y. pestis strain A1122 and did not show any cross-reactivity to Y. enterocolitica, Y. pseudotuberculosis, Y. kristensenii, Y. frederiksenii, Y. intermedia, Klebsiella pneumoniae, Escherichia coli, Salmonella typhi, Salmonella abortus-equi and Staphylococcus aureus tested by ELISA and Western blotting. Monoclonal antibodies also exhibited reactivity to their corressponding native protein antigens in Y. pestis i.e. 42 kDa for YopM, 41 kDa for YopB and 37 kDa for LcrV in immunoblotting. Reactivity of monoclonal antibodies was further assessed on 26 Y. pestis isolates including 18 from 1994 plague outbreak regions (11 from pneumonic patients, 7 from rodents) and 8 from rodents of Deccan plateau of Southern India by Western blotting as well as by sandwich ELISA. The monoclonal antibodies could specifically locate the expression of yopM, yopB and lcrV genes among these Indian Y. pestis strains as well. Results obtained with sandwich ELISA and Western blot were identical to those observed by PCR. Monoclonal antibodies to Yops, therefore, can be employed for an early and reliable identification of virulent Y. pestis strains.     

Role of SycD, the chaperone of the Yersinia Yop translocators YopB and YopD

Extracellular Yersinia adhering at the surface of a eukaryotic cell translocate effector Yops across the plasma membrane of the cell by a mechanism requiring YopD and YopB, the latter probably mediating pore formation. We studied the role of SycD, the intrabacterial chaperone of YopD. By producing GST–YopB hybrid proteins and SycD in Escherichia coli , we observed that SycD also binds specifically to YopB and that this binding reduces the toxicity of GST–YopB in E. coli . By analysis of a series of truncated GST–YopB proteins, we observed that SycD does not bind to a discrete segment of YopB. Using the same approach, we observed that YopD can also bind to YopB. Binding between YopB and YopD occurred even in the presence of SycD, and a complex composed of these three proteins could be immunoprecipitated from the cytoplasm of Yersinia . In a sycD mutant, the intracellular pool of YopB and YopD was greatly reduced unless the lcrV gene was also deleted. As LcrV is known to interact with YopB and YopD and to promote their secretion, we speculate that SycD prevents a premature association between YopB–YopD and LcrV.     

Translocators YopB and YopD from Yersinia enterocolitica form a multimeric integral membrane complex in eukaryotic cell membranes

The type III secretion systems are contact-activated secretion systems that allow bacteria to inject effector proteins across eukaryotic cell membranes. The secretion apparatus, called injectisome or needle complex, includes a needle that terminates with a tip structure. The injectisome exports its own distal components, like the needle subunit and the needle tip. Upon contact, it exports two hydrophobic proteins called translocators (YopB and YopD in Yersinia enterocolitica) and the effectors. The translocators, assisted by the needle tip, form a pore in the target cell membrane, but the structure of this pore remains elusive. Here, we purified the membranes from infected sheep erythrocytes, and we show that they contain integrated and not simply adherent YopB and YopD. In blue native PAGE, these proteins appeared as a multimeric 500- to 700-kDa complex. This heteropolymeric YopBD complex could be copurified after solubilization in 0.5% dodecyl maltoside but not visualized in the electron microscope. We speculate that this complex may not be stable and rigid but only transient.     

Status of YopM and YopN in the Yersinia Yop virulon: YopM of Y.enterocolitica is internalized inside the cytosol of PU5-1.8 macrophages by the YopB, D, N delivery apparatus.

The Yersinia Yop virulon is an anti-host system made up of four elements: (i) a type III secretion system called Ysc; (ii) a system designed to deliver bacterial proteins into eukaryotic target cells (YopB, YopD); (iii) a control element (YopN); and (iv) a set of intracellularly delivered proteins designed to disarm these cells or disrupt their communications (YopE, YopH and possibly others). YopM, another Yop protein, binds thrombin and is thus presumed to act as an extracellular effector. Here, we analyzed YopM from Y.enterocolitica and we wondered whether it could also be delivered inside eukaryotic cells. To answer this question we applied the Yop-Cya reporter strategy. Hybrids made of 141 or 100 N-terminal residues of YopM fused to Cya were delivered inside PU5-1.8 macrophages by recombinant Y.enterocolitica strains. YopB and YopD were required as translocators. Leakage of the reporters into the macrophage culture supernatant during the bacterial infection increased strongly when YopN was missing, showing that YopN is involved in the control of delivery of YopM inside eukaryotic cells. YopN itself was not delivered into the macrophages. In conclusion, YopM is translocated inside the eukaryotic cells and its physiopathological role should be revised or completed.     

The N-terminal domain of Tob55 has a receptor-like function in the biogenesis of mitochondrial beta-barrel proteins

beta-Barrel proteins constitute a distinct class of mitochondrial outer membrane proteins. For import into mitochondria, their precursor forms engage the TOM complex. They are then relayed to the TOB complex, which mediates their insertion into the outer membrane. We studied the structure-function relationships of the core component of the TOB complex, Tob55. Tob55 precursors with deletions in the N-terminal domain were not affected in their targeting to and insertion into the mitochondrial outer membrane. Replacement of wild-type Tob55 by these deletion variants resulted in reduced growth of cells, and mitochondria isolated from such cells were impaired in their capacity to import beta-barrel precursors. The purified N-terminal domain was able to bind beta-barrel precursors in a specific manner. Collectively, these results demonstrate that the N-terminal domain of Tob55 recognizes precursors of beta-barrel proteins. This recognition may contribute to the coupling of the translocation of beta-barrel precursors across the TOM complex to their interaction with the TOB complex.     

Conformational stability and differential structural analysis of LcrV, PcrV, BipD, and SipD from type III secretion systems

Diverse Gram-negative bacteria use type III secretion systems (T3SS) to translocate effector proteins into the cytoplasm of eukaryotic cells. The type III secretion apparatus (T3SA) consists of a basal body spanning both bacterial membranes and an external needle. A sensor protein lies at the needle tip to detect environmental signals that trigger type III secretion. The Shigella flexneri T3SA needle tip protein, invasion plasmid antigen D (IpaD), possesses two independently folding domains in vitro. In this study, the solution behavior and thermal unfolding properties of IpaD's functional homologs SipD (Salmonella spp.), BipD (Burkholderia pseudomallei), LcrV (Yersinia spp.), and PcrV (Pseudomonas aeruginosa) were examined to identify common features within this protein family. CD and FTIR data indicate that all members within this group are alpha-helical with properties consistent with an intramolecular coiled-coil. SipD showed the most complex unfolding profile consisting of two thermal transitions, suggesting the presence of two independently folding domains. No evidence of multiple folding domains was seen, however, for BipD, LcrV, or PcrV. Thermal studies, including DSC, revealed significant destabilization of LcrV, PcrV, and BipD after N-terminal deletions. This contrasted with SipD and IpaD, which behaved like two-domain proteins. The results suggest that needle tip proteins share significant core structural similarity and thermal stability that may be the basis for their common function. Moreover, IpaD and SipD possess properties that distinguish them from the other tip proteins.     

Insertion of a Yop translocation pore into the macrophage plasma membrane by Yersinia enterocolitica: requirement for translocators YopB and YopD, but not LcrG

The Yersinia survival strategy is based on its ability to inject effector Yops into the cytosol of host cells. Translocation of these effectors across the eukaryotic cell membrane requires YopB, YopD and LcrG, but the mechanism is unclear. An effector polymutant of Y. pseudotuberculosis has a YopB-dependent contact haemolytic activity, indicating that YopB participates in the formation of a pore in the cell membrane. Here, we have investigated the formation of such a pore in the plasma membrane of macrophages. Infection of PU5-1.8 macrophages with an effector polymutant Y. enterocolitica led to complete flattening of the cells, similar to treatment with the pore-forming streptolysin O from Streptococcus pyogenes. Upon infection, cells released the low-molecular-weight marker BCECF (623 Da) but not the high-molecular-weight lactate dehydrogenase, indicating that there was no membrane lysis but, rather, insertion of a pore of small size into the macrophage plasma membrane. Permeation to lucifer yellow CH (443 Da) but not to Texas red-X phalloidin (1490 Da) supported this hypothesis. All these events were found to be dependent not only on translocator YopB as expected but also on YopD, which was required equally. In contrast, LcrG was not necessary. Consistently, lysis of sheep erythrocytes was also dependent on YopB and YopD, but not on LcrG.     

Modified needle-tip PcrV proteins reveal distinct phenotypes relevant to the control of type III secretion and intoxication by Pseudomonas aeruginosa

The type III secretion system (T3SS) is employed to deliver effector proteins to the cytosol of eukaryotic hosts by multiple species of Gram-negative bacteria, including Pseudomonas aeruginosa. Translocation of effectors is dependent on the proteins encoded by the pcrGVHpopBD operon. These proteins form a T3S translocator complex, composed of a needle-tip complex (PcrV), translocons (PopB and PopD), and chaperones (PcrG and PcrH). PcrV mediates the folding and insertion of PopB/PopD in host plasmic membranes, where assembled translocons form a translocation channel. Assembly of this complex and delivery of effectors through this machinery is tightly controlled by PcrV, yet the multifunctional aspects of this molecule have not been defined. In addition, PcrV is a protective antigen for P. aeruginosa infection as is the ortholog, LcrV, for Yersinia. We constructed PcrV derivatives containing in-frame linker insertions and site-specific mutations. The expression of these derivatives was regulated by a T3S-specific promoter in a pcrV-null mutant of PA103. Nine derivatives disrupted the regulation of effector secretion and constitutively released an effector protein into growth medium. Three of these regulatory mutants, in which the linker was inserted in the N-terminal globular domain, were competent for the translocation of a cytotoxin, ExoU, into eukaryotic host cells. We also isolated strains expressing a delayed-toxicity phenotype, which secrete translocators slowly despite the normal level of effector secretion. Most of the cytotoxic translocation-competent strains retained the protective epitope of PcrV derivatives, and Mab166 was able to protect erythrocytes during infection with these strains. The use of defined PcrV derivatives possessing distinct phenotypes may lead to a better understanding of the functional aspects of T3 needle-tip proteins and the development of therapeutic agents or vaccines targeting T3SS-mediated intoxication.     

Attachment of LcrV from Yersinia pestis at dual binding sites to human TLR-2 and human IFN-gamma receptor

The virulence antigen (V-antigen, LcrV) of Yersinia pestis, the causative agent of bubonic plague, is an established protective antigen known to regulate, target, and mediate type III translocation of cytotoxic yersiniae outer proteins termed Yops; LcrV also prompts TLR2-dependent upregulation of anti-inflammatory IL-10. In this study, we determined the parameters of specific interaction of LcrV with TLR2 expressed on human transfected HEK293 cells (TLR2+/CD14-), VTEC2.HS cells (TLR2+/CD14-), primary monocytes (TLR2+/CD14+), and THP-1 cells (TLR2+/CD14+). The IRRL314-317 motif of the extracellular domain of human and mouse TLR2 accounted for high-affinity binding of LcrV. The CD14 co-receptor did not influence this interaction. LcrV did not bind to human U937 (TLR2-/CD14-) and alveolar macrophages (TLR2-/CD14+) in the absence of receptor-bound human IFN-gamma or a synthetic C-terminal fragment (hIFN-gamma132-143). The latter, but not mouse IFN-gamma (or synthetic control peptides), shared a GRRA138-141 site necessary for high-affinity specific binding. LcrV of Y. pestis shares the N-terminal LEEL32-35 binding site of Yersinia enterocolitica and also has an exposed internal DEEI203-206 binding site. Comparison of binding constants and consideration of steric restrictions indicate that binding is not cooperative and only the internal site binds LcrV to target cells. Both the LEEL32-35 and DEEI203-206 binding sites are removed by five amino acids from DKN residues associated with biological activity of bound LcrV. LcrV of Y. pestis promoted both TLR2/CD14-dependent and TLR2/CD14-independent amplification of IL-10 and concomitant downregulation of TNF-alpha in human target cells. The ability of LcrV to utilize human IFN-gamma (a major inflammatory effector of innate immunity) to minimize inflammation is insidious and may account in part for the severe symptoms of plague in man.     

The V Antigen of Yersinia pestis Regulates Yop Vectorial Targeting as Well as Yop Secretion through Effects on YopB and LcrG

Yersinia pestis expresses a set of secreted proteins called Yops and the bifunctional LcrV, which has both regulatory and antihost functions. Yops and LcrV expression and the activity of the type III mechanism for their secretion are coordinately regulated by environmental signals such as Ca²⁺ concentration and eukaryotic cell contact. In vitro, Yops and LcrV are secreted into the culture medium in the absence of Ca²⁺ as part of the low-Ca²⁺ response (LCR). The LCR is induced in a tissue culture model by contact with eukaryotic cells that results in Yop translocation into cells and subsequent cytotoxicity. The secretion mechanism is believed to indirectly regulate expression of lcrV and yop operons by controlling the intracellular concentration of a secreted negative regulator. LcrG, a secretion-regulatory protein, is thought to block secretion of Yops and LcrV, possibly at the inner face of the inner membrane. A recent model proposes that when the LCR is induced, the increased expression of LcrV yields an excess of LcrV relative to LcrG, and this is sufficient for LcrV to bind LcrG and unblock secretion. To test this LcrG titration model, LcrG and LcrV were expressed alone or together in a newly constructed lcrG deletion strain, a ΔlcrG2 mutant, of Y. pestis that produces low levels of LcrV and constitutively expresses and secretes Yops. Overexpression of LcrG in this mutant background was able to block secretion and depress expression of Yops in the presence of Ca²⁺ and to dramatically decrease Yop expression and secretion in growth medium lacking Ca²⁺. Overexpression of both LcrG and LcrV in the ΔlcrG2 strain restored wild-type levels of Yop expression and Ca²⁺ control of Yop secretion. Surprisingly, when HeLa cells were infected with the ΔlcrG2 strain, no cytotoxicity was apparent and translocation of Yops was abolished. This correlated with an altered distribution of YopB as measured by accessibility to trypsin. These effects were not due to the absence of LcrG, because they were alleviated by restoration of LcrV expression and secretion alone. LcrV itself was found to enter HeLa cells in a nonpolarized manner. These studies supported the LcrG titration model of LcrV’s regulatory effect at the level of Yop secretion and revealed a further role of LcrV in the deployment of YopB, which in turn is essential for the vectorial translocation of Yops into eukaryotic cells.     

Yersinia enterocolitica type III secretion chaperone SycD: recombinant expression, purification and characterization of a homodimer

Yersinia species pathogenic to human benefit from a protein transport machinery, a type three secretion system (T3SS), which enables the bacteria to inject effector proteins into host cells. Several of the transport substrates of the Yersinia T3SS, called Yops (Yersinia outer proteins), are assisted by specific chaperones (Syc for specific Yop chaperone) prior to transport. Yersinia enterocolitica SycD (LcrH in Yersinia pestis and Yersinia pseudotuberculosis) is a chaperone dedicated to the assistance of the translocator proteins YopB and YopD, which are assumed to form a pore in the host cell membrane. In an attempt to make SycD amenable to structural investigations we recombinantly expressed SycD with a hexahistidine tag in Escherichia coli. Combining immobilized nickel affinity chromatography and gel filtration we obtained purified SycD with an exceptional yield of 120mg per liter of culture and homogeneity above 95%. Analytical gel filtration and cross-linking experiments revealed the formation of homodimers in solution. Secondary structure analysis based on circular dichroism suggests that SycD is mainly composed of alpha-helical elements. To prove functionality of purified SycD previously suggested interactions of SycD with Yop secretion protein M2 (YscM2), and low calcium response protein V (LcrV), respectively, were reinvestigated.     

The weak interaction of LcrV and TLR2 does not contribute to the virulence of Yersinia pestis

Yersinia pestis and the enteropathogenic Yersinia pseudotuberculosis and Yersinia enterocolitica share the virulence-antigen LcrV. Previously, using reverse genetics we have proven that LcrV contributes to the virulence of Y. enterocolitica serotype O:8 by inducing IL-10 via Toll-like receptor 2 (TLR2). However, both the ability of Y. pestis LcrV to activate TLR2 and a possible role of TLR2-dependent IL-10 induction by LcrV in Y. pestis are not yet known. To eliminate interference from additional protein sequences, we produced LcrVs without affinity tags from Y. pestis and from Y. enterocolitica O:8 (LcrVO:8). LcrVO:8 was much more potent in TLR2-activity than Y. pestis LcrV. To analyse the role of TLR2 in plague, we infected both wild-type and TLR2-/- mice subcutaneously with Y. pestis GB. While TLR2-/- mice exhibited lower blood levels of IL-10 (day 2 post-infection) and of the pro-inflammatory cytokines TNF-alpha, IFN-gamma and MCP-1 (day 4) than wild-type mice, there was no significant difference in survival. The low TLR2-activity of Y. pestis LcrV and associated cytokine expression might explain why - in contrast to Y. enterocolitica O:8 infection - TLR2-deficient mice are not more resistant than wild-type mice in a bubonic plague model.     

Proinflammatory signalling stimulated by the type III translocation factor YopB is counteracted by multiple effectors in epithelial cells infected with Yersinia pseudotuberculosis

Type III secretion systems are used by several pathogens to translocate effector proteins into host cells. Yersinia pseudotuberculosis delivers several Yop effectors (e.g. YopH, YopE and YopJ) to counteract signalling responses during infection. YopB, YopD and LcrV are components of the translocation machinery. Here, we demonstrate that a type III translocation protein stimulates proinflammatory signalling in host cells, and that multiple effector Yops counteract this response. To examine proinflammatory signalling by the type III translocation machinery, HeLa cells infected with wild-type or Yop-Y. pseudotuberculosis strains were assayed for interleukin (IL)-8 production. HeLa cells infected with a YopEHJ- triple mutant released significantly more IL-8 than HeLa cells infected with isogenic wild-type, YopE-, YopH- or YopJ- bacteria. Complementation analysis demonstrated that YopE, YopH or YopJ are sufficient to counteract IL-8 production. IL-8 production required YopB, but did not require YopD, pore formation or invasin-mediated adhesion. In addition, YopB was required for activation of nuclear factor kappa B, the mitogen-activated protein kinases ERK and JNK and the small GTPase Ras in HeLa cells infected with the YopEHJ- mutant. We conclude that interaction of the Yersinia type III translocator factor YopB with the host cell triggers a proinflammatory signalling response that is counteracted by multiple effectors in host cells.     

The structure of the human adenovirus 2 penton

The adenovirus penton, a noncovalent complex of the pentameric penton base and trimeric fiber proteins, comprises the vertices of the adenovirus capsid and contains all necessary components for viral attachment and internalization. The 3.3 A resolution crystal structure of human adenovirus 2 (hAd2) penton base shows that the monomer has a basal jellyroll domain and a distal irregular domain formed by two long insertions, a similar topology to the adenovirus hexon. The Arg-Gly-Asp (RGD) motif, required for interactions with cellular integrins, occurs on a flexible surface loop. The complex of penton base with bound N-terminal fiber peptide, determined at 3.5 A resolution, shows that the universal fiber motif FNPVYPY binds at the interface of adjacent penton base monomers and results in a localized structural rearrangement in the insertion domain of the penton base. These results give insight into the structure and assembly of the adenovirus capsid and will be of use for gene-therapy applications.     

The C-terminal globular domain of the prion protein is necessary and sufficient for import into the endoplasmic reticulum

The mammalian prion protein (PrP) is composed of an unstructured flexible N-terminal region and a C-terminal globular domain. We examined the import of PrP into the endoplasmic reticulum (ER) of neuronal cells and show that information present in the C-terminal globular domain is required for ER import of the N terminus. N-terminal fragments of PrP, devoid of structural domains located in the C terminus, remained in the cytosol with an uncleaved signal peptide and were rapidly degraded by the proteasome. Conversely, the separate C-terminal domain of PrP, comprising the highly ordered helix 2-loop-helix 3 motif, was entirely imported into the ER. As a consequence, two PrP mutants linked to inherited prion disease in humans, PrP-W145Stop and PrP-Q160Stop, were partially retained in the cytosol. The cytosolic fraction was characterized by an uncleaved N-terminal signal peptide and was degraded by the proteasome. Our study identified a new regulatory element in the C-terminal globular domain of PrP necessary and sufficient to promote import of PrP into the ER.     

Quantifying Interactions of a Membrane Protein Embedded in a Lipid Nanodisc using Fluorescence Correlation Spectroscopy

Using fluorescence correlation spectroscopy, we measured a dissociation constant of 20 nM between EGFP-labeled LcrV from Yersinia pestis and its cognate membrane-bound protein YopB inserted into a lipid nanodisc. The combination of fluorescence correlation spectroscopy and nanodisc technologies provides a powerful approach to accurately measure binding constants of interactions between membrane bound and soluble proteins in solution. Straightforward sample preparation, acquisition, and analysis procedures make this combined technology attractive for accurately measuring binding kinetics for this important class of protein-protein interactions.