Abstract
The Helicobacter pylori Cag type IV secretion system (Cag T4SS) has an important role in the pathogenesis of gastric cancer. The Cag T4SS outer membrane core complex (OMCC) is organized into three regions: a 14-fold symmetric outer membrane cap (OMC) composed of CagY, CagX, CagT, CagM, and Cag3; a 17-fold symmetric periplasmic ring (PR) composed of CagY and CagX; and a stalk with unknown composition. We investigated how CagT, CagM, and a conserved antenna projection (AP) region of CagY contribute to the structural organization of the OMCC. Single-particle cryo-EM analyses showed that complexes purified from ΔcagT or ΔcagM mutants no longer had organized OMCs, but the PRs remained structured. OMCCs purified from a CagY antenna projection mutant (CagY∆AP) were structurally similar to WT OMCCs, except for the absence of the α-helical antenna projection. These results indicate that CagY and CagX are sufficient for maintaining a stable PR, but the organization of the OMC requires CagY, CagX, CagM, and CagT. Our results highlight an unexpected structural independence of two major subdomains of the Cag T4SS OMCC.
Introduction
Helicobacter pylori is a Gram-negative bacterium infecting over half of the world’s population (Hooi et al, 2017). H. pylori colonization of the stomach results in gastric inflammation (gastritis) and an increased risk for the development of gastric cancer, peptic ulcer disease, and mucosa-associated lymphoid tissue lymphoma (Atherton, 2006; Kusters et al, 2006; Malfertheiner et al, 2023). H. pylori strains harboring the cag pathogenicity island (cag PAI), a 40-kb chromosomal region that encodes a type IV secretion system (T4SS) and the secreted effector protein CagA, are more frequently associated with gastric cancer and peptic ulcer disease, compared with cag PAI–negative strains (Blaser et al, 1995; Parsonnet et al, 1997; Nomura et al, 2002; Plummer et al, 2007; Cover, 2016; Tran et al, 2024).
T4SSs are used by many different species of bacteria to transport DNA, proteins, and other substrates across the bacterial envelope (Costa et al, 2024). The components of T4SSs in Gram-negative bacteria are organized, at a minimum, into an outer membrane core complex (OMCC) and an inner membrane complex (Macé et al, 2022; Sheedlo et al, 2022; Costa et al, 2024). The OMCC is positioned in the periplasm between the bacterial outer and inner membranes (OM and IM, respectively). The Agrobacterium tumefaciens VirB/VirD4 T4SS, several conjugation systems (e.g., pKM101 and R388), and the Xanthomonas citri T4SS are considered prototypical or “minimized” T4SSs (Costa et al, 2021, 2024; Sheedlo et al, 2022). The OMCCs of prototype T4SSs consist of VirB7, VirB9, and VirB10 (Costa et al, 2021, 2024; Sheedlo et al, 2022). Expanded T4SSs are more complex than prototype (minimized) T4SSs, and typically have OMCCs composed of homologs of VirB7, VirB9, and VirB10, as well as additional species-specific components. Examples of bacteria that contain expanded T4SSs include H. pylori, Legionella pneumophila, and Coxiella burnetii (Costa et al, 2021, 2024; Sheedlo et al, 2022).
The H. pylori Cag T4SS OMCC consists of CagX, CagY, CagT, CagM, and Cag3 (Frick-Cheng et al, 2016; Chung et al, 2019; Sheedlo et al, 2020, 2022). Although CagT, CagX, and CagY share regions of structural homology with VirB7, VirB9, and VirB10, respectively, CagM and Cag3 are species-specific proteins found only in H. pylori (Cendron & Zanotti, 2011; Fischer, 2011; Frick-Cheng et al, 2016; Chung et al, 2019; Sheedlo et al, 2020). The H. pylori Cag T4SS OMCC is organized into three subassemblies: the outer membrane cap (OMC), the periplasmic ring (PR), and the stalk. Within the H. pylori Cag T4SS OMCC, there is a mismatch in symmetry elements between the 14-fold symmetric OMC and the 17-fold symmetric PR (Fig 1) (Chung et al, 2019; Sheedlo et al, 2020). Symmetry mismatches, although with different ratios, have also been detected in OMCCs from other T4SSs, including the L. pneumophila Dot/Icm T4SS (Durie et al, 2020; Sheedlo et al, 2021), the F-type T4SS (Amin et al, 2021; Liu et al, 2022), and the R388 conjugation system (Macé et al, 2022).
The OMC of the H. pylori Cag T4SS OMCC is a ∼42-nm-diameter “cap”-shaped subassembly that abuts the bacterial OM (Chang et al, 2018; Hu et al, 2019) (Fig 1). Structural analysis of the Cag T4SS OMCC by single-particle cryo-electron microscopy (cryo-EM) revealed the structural organization of CagX, CagY, CagT, CagM, and Cag3 and showed that within each asymmetric unit (ASU) of the OMC, these components are present in a stoichiometric ratio of 1:1:2:2:5 (CagX:CagY:CagT:CagM:Cag3) (Fig 1A and B) (Sheedlo et al, 2020, 2022). Structural analysis highlighted the numerous and intricate protein–protein interactions among components of the OMC.
The PR of the Cag T4SS sits directly below the OMC in the periplasm (Fig 1). This part of the OMCC contains CagY and CagX in a stoichiometric ratio of 1:1 (Fig 1A). Although the PR has a different symmetry than the OMC, it is physically connected to the OMC by both CagY and CagX, which bridge the symmetry mismatch in a way that has not been fully defined (Chung et al, 2019; Sheedlo et al, 2020). The stalk, spanning the distance between the PR and the IM, is the least characterized region of the OMCC because of the very low-resolution map available for this part of the structure (Chung et al, 2019) (Fig 1C and D). The composition and potential symmetry of the stalk have not been determined.
The portion of CagY localized to the OMC contains helix–loop–helix elements (residues 1,793–1,863) that are designated as the antenna projection (AP) (Sheedlo et al, 2020; Tran et al, 2023). The AP region of CagY is structurally similar to corresponding α-helical domains of VirB10 in conjugation systems and other prototype T4SSs (Chandran et al, 2009; Fronzes et al, 2009; Jakubowski et al, 2009; Banta et al, 2011; Sgro et al, 2018; Chung et al, 2019; Darbari et al, 2020; Sheedlo et al, 2020; Costa et al, 2021; Tran et al, 2023). Based on cryo-electron tomography (cryo-ET) analysis of intact bacteria, the part of the OMCC containing the CagY AP is localized in close proximity to the OM, and single-particle cryo-EM analysis of purified complexes showed that the 14 CagY AP elements organize into an α-helical bundle (Chang et al, 2018; Chung et al, 2019; Hu et al, 2019). The CagY antenna region is predicted to form an outer membrane pore, similar to corresponding VirB10 domains in other T4SSs (Chandran et al, 2009; Banta et al, 2011; Sgro et al, 2018; Chung et al, 2019; Darbari et al, 2020; Tran et al, 2023).
All five protein components of the Cag T4SS OMCC are required for Cag T4SS activity (Fischer et al, 2001; Johnson et al, 2014; Frick-Cheng et al, 2016). Single-particle cryo-EM analysis showed the structures and locations of CagX, CagY, CagT, CagM, and Cag3 in the OMCC and mapped the numerous protein–protein interactions among the components (Chung et al, 2019; Sheedlo et al, 2020). Previous analyses suggested that OMCCs do not form in ∆cagX or ∆cagY mutant strains (Frick-Cheng et al, 2016; Hu et al, 2019). Analysis of a ∆cag3 mutant strain showed that a stable OMCC could form in the absence of Cag3 (Sheedlo et al, 2020), but the roles of the other OMCC components (CagT and CagM) in the structural stability of the complex have not been carefully analyzed.
In this study, we expand our understanding of the roles of CagT, CagM, and the AP region of CagY in the organization of the H. pylori Cag T4SS OMCC. We use single-particle cryo-EM analysis and mass spectrometry to investigate the structure and composition of OMCCs purified from ∆cagT and ∆cagM mutant strains, and we analyze the structure of OMCCs purified from an H. pylori strain lacking the CagY AP (CagY∆AP). We show that OMCCs purified from the CagY∆AP mutant have structures similar to those of WT OMCCs, except for the absence of the CagY AP region. Complexes purified from the ΔcagT mutant lack CagT and Cag3, leading to destabilization of the OMC, but maintain a structured PR. Similarly, complexes purified from the ΔcagM mutant lack CagM, CagT, and Cag3 and no longer have a structured OMC, but retain a structured PR. These data indicate that CagX and CagY are sufficient for maintaining a stable PR, but the structural organization of the OMC requires four proteins (CagX, CagY, CagT, and CagM). These results highlight the numerous protein–protein interactions required for OMC organization, the unexpected structural independence of the OMC and PR subdomains, and the finding that the organization of the OMCC does not require the CagY AP.
Results
CagT is essential for OMC structural stability and non-essential for PR stability
First, we sought to determine the structural organization of the OMCC in the absence of the CagT. CagT is a lipoprotein that has limited sequence similarity to VirB7 homologs, but it shares structural relatedness to X. citri VirB7 within the N-terminal region (Fischer, 2011; Backert et al, 2017; Sgro et al, 2018; Chung et al, 2019; McClain et al, 2020). Two copies of CagT are present in each ASU of the OMC (Sheedlo et al, 2020) (Fig 1A and B). Both copies are localized in the outer layer of this subassembly, and the cysteine residue predicted to be lipidated is positioned to interact with the bacterial outer membrane (Chung et al, 2019; Sheedlo et al, 2020). Studies of a mutant strain engineered to produce CagT with an altered lipobox indicated that CagT lipidation is essential for CagT stability and Cag T4SS activity (McClain et al, 2020). A ∆cagT deletion mutant is defective in both the translocation of CagA into gastric epithelial cells and the induction of IL-8 in AGS gastric epithelial cells (Fischer et al, 2001; Johnson et al, 2014; Frick-Cheng et al, 2016), indicating that CagT is required for Cag T4SS function. Immunoblot analysis of Cag T4SS complexes isolated from the ∆cagT mutant showed that the preparations did not contain CagT or Cag3, but CagY, CagX, and CagM were still detected (Frick-Cheng et al, 2016). Cryo-ET analysis of OMCCs in the ∆cagT bacteria lacked peripheral density, and fewer T4SS complexes were detected in the ∆cagT mutant than in WT bacteria (Hu et al, 2019). Negative stain EM analysis of Cag T4SS complexes purified from the ∆cagT mutant showed no structured OMCCs but did show some thin rings with a ∼19-nm diameter (Frick-Cheng et al, 2016). However, the lack of a high-resolution OMCC structure available at the time of the previous work limited any detailed conclusions that could be made about the role of CagT in the overall organization of OMCC, other than concluding that it was important for complex stability. Now, with the availability of a 3.4 Å resolution structure and the molecular model of the WT Cag T4SS OMCC (Fig 1) (Chung et al, 2019; Sheedlo et al, 2020), we decided to more closely examine how CagT, a conserved T4SS component, contributes to the overall structural organization of the OMCC.
Using mass spectrometry, negative stain EM, and single-particle cryo-EM analyses, we analyzed the composition and structure of Cag T4SS complexes purified from the ∆cagT mutant. Liquid chromatography–tandem mass spectrometry (LC-MS/MS) analysis of T4SS complexes purified from the ∆cagT mutant showed that the samples contained CagX, CagY, and CagM, but lacked Cag3 and CagT (Table 1). These results concur with previous immunoblot results (Frick-Cheng et al, 2016). As before, negative stain EM showed that complexes isolated from the ∆cagT mutant differed markedly from WT OMCCs (Fig 2A), with only ∼19-nm-wide thin rings visible in the images of T4SS complexes purified from the ∆cagT mutant (Fig 2B). However, now with a better understanding of the overall Cag T4SS OMCC structure, we recognized that these rings have a size and appearance similar to the PR of the OMCC.
To examine this more closely, we collected a cryo-EM dataset of complexes purified from the ∆cagT mutant and used 2D and 3D single-particle analysis to characterize the complexes (Fig S1A and B, Table S1). The “en face” views of 2D classes of mutant particles contain none of the secondary structural features of the OMC that usually dominate this view of WT OMCCs (Fig 2C and D), indicating that this part of the complex is no longer stably organized in the absence of CagT. However, the averages did show the presence of a structured ring, ∼19 nm in diameter with 17-fold symmetry (Fig 2E). This is the same width and symmetry as the PR in WT OMCCs (Fig 1A). Thus, 2D analysis of the cryo-EM images indicates that T4SS complexes lacking CagT no longer have a structured OMC but appear to retain an organized PR.
3D reconstructions of complexes purified from the ∆cagT mutant confirmed the 2D analysis. Although there is amorphous density in the 3D reconstruction that can be attributed to the OMC, the density is extremely noisy with no apparent secondary structural features or symmetry (Fig S1). Although the mass spectrometry analysis detected CagM, CagY, and CagX in the samples, including CagY and CagX peptides from regions localized in the OMC, neither the 2D averages nor the 3D reconstruction showed any defined structural features that can be attributed to these proteins in the OMC. However, the ∆cagT complexes still have a structurally defined PR. A 3D structure of the PR with 17-fold symmetry applied reached 8.0 Å resolution (Fig S2A–C) and had secondary structural features that made it possible to place molecular models for CagY (residues 1,469–1,603) and CagX (residues 32–130, 261–323) built from the WT PR EM density map into the ∆cagT PR density map (Fig 2F–H). Although there are some minor differences between the high-resolution WT PR model and the ∆cagT PR map (Fig S3A), likely because of the heterogeneity in the ∆cagT particles, the overall structural integrity of the PR is preserved.
Overall, these analyses show that CagT is required for the stable association of Cag3 with the OMCC and is essential for the structural organization of CagM, CagX, and CagY within the OMC. However, even in the absence of an organized OMC, the overall structural organization of the PR is maintained.
Loss of the CagY AP region does not alter the structural organization of the OMCC
The importance of CagT in the OMC structure might be explained solely by the central position of the 28 copies of CagT found in each OMC (Fig 1) (Sheedlo et al, 2020). However, CagT is also a lipoprotein, with the position of post-translational lipid moieties likely providing a mechanism to anchor the OMC to the outer membrane (McClain et al, 2020; Sheedlo et al, 2020). Thus, CagT might contribute to the OMC structure through its interactions with the outer membrane. Another Cag T4SS protein that contacts the outer membrane is CagY (Chung et al, 2019; Sheedlo et al, 2020). The CagY AP motif is highly conserved among VirB10 family members, is predicted to form a channel in the outer membrane, and is required for H. pylori Cag T4SS activity (Tran et al, 2023). Specifically, an H. pylori mutant lacking the CagY AP (residues 1,793–1,863) is defective in IL-8 induction and CagA translocation (Tran et al, 2023). VirB10 AP regions are predicted to form a channel through the outer membrane, and cryo-ET analysis of the H. pylori T4SS showed that the OMCC region containing the CagY AP is localized adjacent to the outer membrane (Chang et al, 2018; Hu et al, 2019). If OMC interactions with the outer membrane contribute to OMC assembly or overall stability, the CagY AP motif would be predicted to be important for OMC organization. To test this hypothesis, we investigated whether the presence or absence of the CagY AP region influences the overall structure of the OMCC.
To examine the structural contribution of the conserved AP region of CagY to OMCC organization, we used both negative stain EM and single-particle cryo-EM analyses to investigate the structural organization of Cag T4SS OMCCs purified from a CagY∆AP mutant strain. Negative stain analysis showed that OMCCs from the CagY∆AP mutant globally resembled WT OMCCs (Figs 2A and 3A). To determine whether there were more nuanced changes in the architecture of the Cag T4SS not evident by low-resolution negative stain imaging, we then examined these OMCCs using cryo-EM analysis (Fig S4A and B, Table S1). 2D analysis of particles in vitrified ice showed that the “en face” views of the CagY∆AP OMCCs contained clear secondary structural elements and were similar in diameter to WT OMCCs (Figs 2C and 3B); however, the innermost central density, corresponding to where 14 copies of the CagY AP region form an α-helical channel, is missing in the mutant complexes (Fig 3B). 2D classes representing side views of the mutant complexes showed pairs of CagY∆AP OMCCs interacting where the channel is usually located (Fig 3B). This interaction between OMCCs has not been observed in analyses of WT or ∆cag3 OMCCs (Chung et al, 2019; Sheedlo et al, 2020). 3D single-particle cryo-EM analysis of OMCCs purified from the CagY∆AP mutant showed that although the complexes clearly lack the AP extension, the maps of the OMC and the PR (at the resolutions of 3.8 and 6.6 Å, respectively) (Fig S5A–F) are very similar to the corresponding maps of the WT OMC and PR (Figs 3C–H and S3B and C). CagY in the CagY∆AP OMC, other than missing the helix–loop–helix regions (corresponding to the deleted amino acids 1,793–1,863), adopts the same conformation as CagY in the WT OMC (Fig 3C–H). The CagY∆AP PR also has the same overall organization as the WT PR, although there are some minor differences that cannot be directly modeled at the current resolution of the map (Fig S3C). Thus, although the CagY AP region is required for the biological function of the H. pylori Cag T4SS (Tran et al, 2023) and likely interacts with the OM (Chang et al, 2018; Hu et al, 2019), it is not required for the overall structural stability and organization of the OMCC.
CagM, an H. pylori-specific T4SS component, is required for a structured OMC but not PR stability
We next characterized the role of the H. pylori-specific T4SS protein CagM in the structural organization of the OMCC. CagM does not have obvious homologs in any non-H. pylori species (Sheedlo et al, 2020). As with CagT, there are two copies of CagM found in each ASU of the OMC (Fig 1A); however, unlike CagT, both copies of CagM are found in the inner layer, rather than the outer layer, of this subassembly (Fig 1) (Chung et al, 2019; Sheedlo et al, 2020). CagM is essential for Cag T4SS function, because a ∆cagM mutant is defective in the translocation of CagA and induction of IL-8 in AGS gastric cells (Fischer et al, 2001; Johnson et al, 2014; Frick-Cheng et al, 2016). Based on immunoblot analysis, OMCCs purified from the ∆cagM mutant only contain CagX and CagY, with CagM, CagT, and Cag3 not detected (Frick-Cheng et al, 2016). To carefully examine the role of this species-specific T4SS protein in the structural organization of the Cag T4SS OMCC, we purified T4SS complexes from the ∆cagM mutant and examined their composition and structure using mass spectrometry, negative stain EM, and single-particle cryo-EM analyses.
LC-MS/MS analysis of complexes purified from the ∆cagM mutant showed that the preparations contained CagX and CagY, but lacked CagT, CagM, and Cag3 (Table 1), matching the previous immunoblot analysis (Frick-Cheng et al, 2016). Examination of the mutant particles by negative stain revealed thin rings similar to complexes purified from the ∆cagT mutant (Figs 2B and 4A). We speculate that the ability to visualize these structures in the current study but not in a previous study (Frick-Cheng et al, 2016) is attributable to the use of larger volume bacterial cultures and improved purification strategies.
We collected a cryo-EM dataset and analyzed the resulting particles using 2D and 3D single-particle cryo-EM approaches (Fig S6A and B, Table S1). In the 2D averages, the ∆cagM complexes have no structured OMC (Fig 4B), in contrast to the well-defined OMC visible in WT OMCCs (Fig 2C); however, there is density for the PR with clear secondary structural features and 17-fold symmetry (Fig 4B and C). 3D reconstruction of these particles confirmed the observations based on analysis of the 2D averages and showed there was no structured density for the OMC (Fig S6A). However, the ∆cagM complexes still have a structurally defined PR. The 3D reconstruction of the PR from the ∆cagM mutant reached 8.5 Å with 17-fold symmetry imposed (Fig S7A–C), and secondary structural features expected at this resolution were visible in the map (Fig 4D–F). We can place molecular models of the regions of CagY (residues 1,469–1,603) and CagX (residues 32–130, 261–323) found in the PR directly into this density (Fig 4F), showing that these parts of CagX and CagY remain structured in the ∆cagM background. Although there are some subtle differences between the 3D structure of the ∆cagM PR and WT PR (Fig S3D), this analysis shows that the ∆cagM PR, even without a structured OMC, retains its overall structural organization. Therefore, these results indicate that CagM is required for CagT and Cag3 association with the OMCC, is required for the structural organization of the OMC, and is not required for maintaining the structural organization of the PR.
Discussion
In this study, we investigated the roles of individual H. pylori Cag T4SS OMCC proteins in the stability of the OMCC. Previous studies of H. pylori deletion mutants lacking OMCC components, using low-resolution negative stain EM and cryo-ET approaches, provided preliminary evidence that there were differences in how the individual proteins contribute to the overall OMCC structural organization and stability. OMCCs could not be purified at all from ∆cagY and ∆cagX mutants, and the Cag T4SS was not visible by cryo-ET analysis in bacteria lacking either CagY or CagX (Frick-Cheng et al, 2016; Hu et al, 2019). In contrast, structured OMCCs, composed of CagY, CagX, CagM, and CagT, were isolated from a ∆cag3 mutant (Frick-Cheng et al, 2016; Sheedlo et al, 2020). These results suggested a model in which evolutionarily conserved T4SS components (such as CagX and CagY) might play a more important role in the overall stability and structural organization of the Cag T4SS OMCC than species-specific components (such as Cag3). Our careful examination in the current study of T4SS complexes purified from strains lacking either CagT, a Cag T4SS component whose N-terminus is structurally related to the corresponding region of X. citri VirB7 (Sgro et al, 2018; Sheedlo et al, 2020), or CagM, an H. pylori-specific protein, shows that this model is too simplistic. Although OMCCs isolated from ∆cagT and ∆cagM mutants had structured PRs, neither had structured OMCs. Thus, whether a T4SS protein is conserved or species-specific does not, de facto, provide information about its role in the T4SS structural organization or stability. Instead, each protein’s contribution to OMCC organization depends more on its location within the structure than whether it is conserved across species (Fig 5).
The characteristics of T4SS complexes purified from H. pylori mutant strains lacking individual T4SS components are consistent with what might be predicted by examining the structure of the WT Cag T4SS OMCC. The cryo-EM maps of the WT H. pylori Cag T4SS OMCC showed that protein–protein interactions among the five protein components, especially in the OMC, create an intricate network of interdependence. These include interactions between duplicate copies of CagT, interactions between duplicate copies of CagM, interactions among the multiple copies of Cag3, and CagT-Cag3, CagT-CagM, CagT-CagY, Cag3-CagM, CagM-CagX, CagT-CagY, and CagX-CagY interactions (Sheedlo et al, 2020). The requirement of CagY and CagX for the formation of a stable OMCC (Frick-Cheng et al, 2016) is consistent with the presence of both proteins in the PR, a role of both proteins in physically traversing the symmetry mismatch between the PR and OMC, and the presence of both proteins in a central location within the OMC (Fig 5A). The localization of CagT and CagM within the Cag T4SS OMCC structure is also consistent with the roles of these proteins in the formation of a stable OMC. CagT and CagM make up either the outer or inner “spokes” of the OMC that help connect CagX and CagY in the center of the complex with Cag3 located at the periphery (Fig 5A) (Chung et al, 2019; Sheedlo et al, 2020). In the absence of either CagT or CagM, the structural stability of these spokes breaks down, disrupting the organization of the OMC (Fig 5D and E). In contrast, the multiple copies of Cag3 are localized at the periphery of the OMC (Chung et al, 2019; Sheedlo et al, 2020) and are not required for stable interactions between CagM, CagT, CagX, and CagY. Thus, in the absence of Cag3, the OMC has a smaller diameter but otherwise remains structured (Fig 5C) (Sheedlo et al, 2020).
Although the structure of the Cag T4SS explains the roles of CagX, CagY, CagM, CagT, and Cag3 in OMC organization, it was not obvious how the loss of a structured OMC would affect the integrity of the PR. Parts of CagX and CagY make important structural contributions to the PR and the OMC, and CagX and CagY bridge the symmetry mismatch between these subassemblies (Sheedlo et al, 2020). Because folded domains of CagX and CagY are found in both the OMC and the PR, one model predicts that the loss of an organized OMC would also have a deleterious effect on the PR. However, our analysis of OMCCs purified from ∆cagM and ∆cagT mutants unexpectedly showed that the PR remains structurally intact with 17-fold symmetry even when the OMC is not structured (Fig 5D and E). These results provide experimental evidence for the existence of oligomerization domains within two different regions of CagX and CagY (i.e., domains of these proteins localized to either the OMC or the PR).
The PR is composed of only CagX and CagY (Sheedlo et al, 2020). In the PR, 17 copies of the N-terminus of CagX (residues 32–323) and a segment of CagY (residues 1,469–1,603) interact to form a ∼19-nm ring structure. In the OMC, there are 14 copies of the C-terminal region of CagX (residues 349–515) and CagY (residues 1,677–1,910) (Sheedlo et al, 2020). Although the precise molecular details for how CagX and CagY bridge the symmetry mismatch between the PR and OMC are not known, a low-resolution non-symmetrized density map determined using a focused refinement strategy provided insight about the region of CagX that connects the subassemblies (Sheedlo et al, 2020). Although the resolution in this region was not adequate to build a molecular model, it clearly showed α-helical tubes extending from 14 of the 17 CagX densities in the PR to where CagX is localized in the OMC (Sheedlo et al, 2020). Thus, a long α-helix of CagX bridges the PR and OMC. There was no density for CagY observed in the region of the non-symmetrized structure connecting the OMC with the PR, leading to a proposed model where a stretch of CagY missing in the symmetrized maps of the PR and OMC (residues 1,604–1,676) connects these subassemblies via a flexible loop (Sheedlo et al, 2020). Our finding that the PR remains structured even in the absence of an organized OMC is consistent with a model in which the CagX and CagY regions bridging the PR and OMC are structurally flexible.
The results of the current study indicate that a ∆cagT mutant can assemble a stable PR, but the OMC portion of the OMCC is disorganized (Fig 5D). The simplest explanation is that the 28 copies of CagT in the OMCC are essential for the structural stability of the OMC (Fig 5A). In addition, CagT is a lipoprotein, and the amino acids predicted to be post-translationally lipidated are located at sites in the CagT structure where they could interact with the OM (Sheedlo et al, 2020). Therefore, another possible explanation for the loss of OMC stability in the ∆cagT background could be the disruption of important OMC interactions with the OM. An additional region of the OMCC that interacts with the outer membrane is the CagY AP, which is predicted to form an outer membrane channel (Tran et al, 2023). For this reason, we hypothesized that the CagY AP might also be required for OMC formation. To our surprise, analysis of OMCCs from a CagY∆AP mutant revealed that these complexes had structures similar to WT OMCCs (Fig 5B), except for the absence of densities corresponding to the 14 CagY AP domains in the CagY∆AP complexes. The CagY∆AP PR has some subtle differences when compared to the WT PR, suggesting that changes in the CagY AP might influence the structure of CagY in the PR. However, our current studies do not provide any mechanistic insight into how these changes would be propagated. Most importantly, these studies indicate that the CagY AP is required for Cag T4SS function (Tran et al, 2023) but is not required for OMCC assembly.
In future experiments, it will be important to determine whether the results observed in the current study extend to T4SSs in other bacterial species. For example, the Legionella Dot/Icm T4SS OMCC contains two well-defined OMC and PR subassemblies exhibiting symmetry mismatch (Durie et al, 2020; Sheedlo et al, 2021), so it will be interesting to determine the roles of VirB7 and Legionella-specific OMC components in the formation of the OMC and PR in this T4SS. Similarly, it will be interesting to determine whether the I-layer in the R388 T4SS OMCC or the X. citri T4SS is stable in the absence of VirB7 (Sgro et al, 2018; Macé et al, 2022). Within the F-type T4SS, the OMCC is organized into a central cone (analogous to the I-layer) and an outer ring (analogous to the O-layer); therefore, VirB7 might be non-essential for the stability of the central cone in this OMCC (Amin et al, 2021; Liu et al, 2022; Kishida et al, 2024).
Finally, although these results do not provide any direct evidence for how Cag T4SSs assemble in vivo, they do support a key role of CagX and CagY in the overall T4SS structural stability. At least in the context of purified complexes, the regions of CagX and CagY found in the OMC require both CagT and CagM to maintain their structural organization. In general, our results support a model for the T4SS assembly pathway that was proposed based on cryo-ET analyses of Cag T4SSs visualized in WT, ∆cag3, and ∆cagT bacterial cells (Hu et al, 2019). In this model, CagX, CagY, and CagM first assemble into a central “cylinder” located between the inner and outer membranes that serves as the structural scaffold for the subsequent addition of CagT and Cag3 to form the OMC. Further studies will be required to elucidate the sequence of steps required for T4SS assembly in intact bacteria.
Materials and Methods
Bacterial strains, plasmids, and cell culture
H. pylori strains were cultured on trypticase soy agar plates containing 5% sheep blood in ambient air supplemented with 5% CO2. Liquid cultures of H. pylori were grown in Brucella broth supplemented with 10% vol/vol heat-inactivated FBS. CagY∆AP (deletion of CagY amino acids 1,793–1,863), unmarked ∆cagT, and unmarked ∆cagM mutant strains, each containing sequences encoding HA-CagF, have been described previously (Frick-Cheng et al, 2016; Tran et al, 2023).
T4SS OMCC purification
OMCCs were purified from mutant H. pylori strains using a purification method targeting HA-CagF, as described previously (Frick-Cheng et al, 2016; Chung et al, 2019). In brief, strains were grown in liquid culture for about 20 h, the bacteria were pelleted at 3,300g for 15 min at 4°C, and the pellet was resuspended in RIPA buffer (50 mM Hepes, 100 mM NaCl, 1% NP-40, and 0.025% deoxycholate supplemented with 1 mM phenylmethylsulfonyl fluoride and protease inhibitors [Roche]) and sonicated on ice (at 25% amp, 10 s on and 10 s off, five times). The suspension was then incubated for 1 h at 4°C. The insoluble material was pelleted, the bacterial lysate was incubated with anti-HA antibodies non-covalently linked to protein G Dynabeads (Invitrogen) for 30 min, and then the complexes were eluted with HA peptide for 1 h at RT.
LC-MS/MS analysis of Cag T4SS OMCCs
To analyze the protein content of the immunopurified samples, samples were digested and prepared for analysis using S-traps (Protifi), following the manufacturer’s recommended protocol. The resulting tryptic peptides were analyzed by data-dependent LC-MS/MS (McClain et al, 2023). Briefly, peptides were autosampled onto a 200 mm by 0.1 mm (Jupiter 3 micron, 300A) self-packed analytical column coupled directly to an LTQ linear ion trap mass spectrometer (Thermo Fisher Scientific) using a nanoelectrospray source, and resolved using an aqueous-to-organic gradient. Both the intact masses (MS) and fragmentation patterns (MS/MS) of the peptides were collected in a data-dependent manner using dynamic exclusion to maximize the depth of coverage. Resulting peptide MS/MS spectral data were searched against an H. pylori database to which sequences of common contaminants and reversed versions of each protein had been added, using SEQUEST. Peptide spectral matches were collated, filtered, and compared using Scaffold (Proteome Software). Protein identifications required a minimum of two unique peptides per protein and were filtered to a 1% false discovery rate for peptides and a 5% false discovery rate for proteins.
Negative stain EM sample preparation and data collection
Negative stain EM was carried out using established methods (Ohi et al, 2004). 400-mesh copper grids covered with carbon-coated collodion film (Electron Microscopy Sciences) were glow-discharged for 30 s at 5 mA in a PELCO easiGlow glow discharge unit (Ted Pella). 3.5 μl of the Cag T4SS sample (as purified) was adsorbed to the grids and incubated for 1 min at RT. The grids were then washed twice with water, negatively stained with 0.75% (wt/vol) uranyl formate solution, and blotted until dry. Negative stain images were taken using a Tecnai Spirit T12 transmission electron microscope (Thermo Fisher Scientific) operated at 120 kV and at a nominal magnification of 26,000x (2.3 Å/pixel). Images were acquired with Leginon (Suloway et al, 2005) on a 4K × 4K Rio complementary metal-oxide semiconductor camera (Gatan) at −1.5-μm defocus value.
Cryo-EM sample preparation
Cryo-EM samples were prepared as described previously (Chung et al, 2019; Sheedlo et al, 2020). In brief, 3.5 μl of the Cag T4SS OMCC sample (as purified) was applied to a glow-discharged Quantifoil R 2/2 UT 200-mesh copper grid (Quantifoil). The sample was applied to a grid three to four times, incubated for 60 s each before blotting, and vitrified by plunge freezing in a slurry of liquid ethane using Vitrobot (Thermo Fisher Scientific) at 20°C and 100% humidity.
Cryo-EM data collection
Images were collected on a Titan Krios electron microscope (Thermo Fisher Scientific) equipped with K3 Summit Direct Electron Detector (Gatan) operated at 300 kV with a nominal pixel size of 1.08 Å per pixel. The Bioquantum energy filter (Gatan) was inserted with a slit width of 20 eV. Micrographs were acquired using SerialEM software (Mastronarde, 2005). The electron dose totaled 60 e/Å2, and the defocus range was −1 to −2.5 μm.
Cryo-EM data analysis
cryoSPARC v.4.2.1 was used for image processing of all cryo-EM datasets (Punjani et al, 2017). Fig S1 shows data processing steps for cryo-EM analysis of T4SS complexes purified from the ∆cagT mutant. For analysis of the ∆cagT OMCC, 310,039 particles were selected by template picking in cryoSPARC. After iterative 2D classification, classes with clear secondary structural features were retained, corresponding to 8,415 particles. These particles were used in a reference-free initial 3D reconstruction (ab initio model in cryoSPARC) designating two 3D classes, no applied symmetry (C1), and a resolution range of 35–12 Å (the default cryoSPARC setting). The 3D classes resembled previous PR structures and did not have density resembling the OMC. In an effort to visualize any structured OMC density, one of the ab initio 3D volumes was used as the initial model in a non-uniform refinement that used 8,415 particles and imposed C14 or C17 symmetry. Both reconstructions contained artifacts and lacked any secondary structural features associated with either the OMC or the PR. Because there were 2D averages with 17-fold symmetry, we did another ab initio reconstruction applying C17 symmetry, designating two 3D classes, and choosing a resolution range of 20–4 Å. The best class contained 5,706 particles. These particles were used in a subsequent local refinement, using the ab initio model as the initial volume, and a solvent mask that was created from the ab initio model that was padded and dilated 10 pixels each. The rotation search extent was 10°. After local refinement, the final resolution was 8 Å (Fig S2).
Fig S4 shows data processing steps for cryo-EM analysis of OMCCs purified from the CagY∆AP mutant. For analysis of the CagY∆AP OMCC, 633,415 particles were selected by template picking in cryoSPARC. After iterative 2D classification, classes with clear secondary structural features were retained, containing a combined 22,643 particles. These particles were subjected to an ab initio 3D reconstruction designating one 3D class not applying symmetry, and using a resolution range of 35–12 Å. This model was used as a reference for a non-uniform 3D refinement with C1 symmetry, resulting in a density map with a global resolution of 6.8 Å. For the focused refinement of the CagY∆AP OMC, the C1 ab initio 3D structure was used as the initial model for a non-uniform refinement imposing C14 symmetry. This resulting 3D volume was used to create soft masks for both particle subtraction and local refinement. After particle subtraction and refinement, a final local refinement was performed, which yielded a map with a final resolution of 3.8 Å. For the focused refinement of the CagY∆AP PR, the C1 ab initio model was used as the initial model for a non-uniform refinement imposing C17 symmetry. This resulting volume was used to create soft masks for both particle subtraction and local refinement. After particle subtraction and refinement, a final local refinement was performed, which yielded a final resolution of 6.6 Å (Fig S5).
Fig S6 shows data processing steps for cryo-EM analysis of T4SS complexes purified from the ∆cagM mutant. For analysis of the ∆cagM OMCC, 78,268 particles were selected by template picking in cryoSPARC. After iterative 2D classification, 2D classes with clear secondary structural features were retained, containing a combined 4,251 particles. These particles were subjected to a reference-free initial 3D reconstruction (ab initio model in cryoSPARC) designating two 3D classes, no applied symmetry, and a resolution range of 35–12 Å. The best 3D class contained 3,009 particles and had features with 17-fold symmetry. To attempt to visualize any OMC density in this 3D map, the volume was used in a non-uniform refinement imposing C14 symmetry. However, the C14 reconstruction contained artifacts and lacked any secondary structural features. To determine a higher resolution structure of the ∆cagM PR, the best volume was used as an initial 3D model for non-uniform refinement with C17 symmetry. This map was used to create a soft mask for local refinement. Local refinement with C17 imposed symmetry resulted in a map with 4.1 Å resolution calculated for the “tight mask” at FSC = 0.143; however, this resolution does not match the secondary features present in the map or the resolutions shown in the local resolution map (Fig S7). Taking these observations into consideration, the more accurate resolution estimation appears to be 8.5 Å as calculated by cryoSPARC when using the criterion of a “loose mask” at FSC = 0.5. This resolution matches the features seen in this map and agrees with the local resolution calculations.
Map-to-model cross-correlation values for the ASU were calculated using Phenix (Liebschner et al, 2019). Map–map correlations between mutant and WT maps were done in chimera using the “measure correlation” command. ChimeraX was used to make figures of maps and models (Pettersen et al, 2021).
Data Availability
The cryo-EM maps have been deposited in the Electron Microscopy Data Bank under accession codes EMD-44587 (∆cagT PR), EMD-42290 (CagY∆AP OMC), EMD-42392 (CagY∆AP PR), and EMD-42393 (∆cagM PR).
Acknowledgements
We thank the TL Cover and MD Ohi laboratories for helpful discussions, and we thank Ashleigh Raczkowski, Vinson Lam, and Alexandra Rizo for cryo-EM advice. The UM Cryo-EM Facility has received generous support from the U-M Life Sciences Institute, the U-M Biosciences Initiative, and the Beckman Foundation. The Vanderbilt Institute for Infection, Immunology, and Inflammation provided support to SC Tran and KN Bryant. This work was supported by the NIH AI118932 (to TL Cover and MD Ohi), AI039657 (to TL Cover), CA116087 (to TL Cover), T32AI112541, T32GM008320, DGE 1841052 (to JR Roberts), NIH S10OD030275 (to MD Ohi), and the Department of Veterans Affairs BX004447 (to TL Cover). Mass spectrometry analysis was supported by the Vanderbilt Digestive Diseases Research Center (P30DK058404) and the Vanderbilt-Ingram Cancer Center (P30 CA068485).
Author Contributions
JR Roberts: data curation, formal analysis, validation, investigation, visualization, and writing—original draft, review, and editing.
SC Tran: data curation, formal analysis, validation, investigation, visualization, and writing—original draft, review, and editing.
AE Frick-Cheng: validation, investigation, visualization, and writing—original draft, review, and editing.
KN Bryant: formal analysis, investigation, visualization, methodology, and writing—original draft, review, and editing.
CD Okoye: investigation, methodology, and writing—original draft, review, and editing.
WH McDonald: data curation, formal analysis, and methodology.
TL Cover: conceptualization, resources, data curation, formal analysis, supervision, funding acquisition, validation, investigation, methodology, project administration, and writing—original draft, review, and editing.
MD Ohi: conceptualization, resources, formal analysis, supervision, funding acquisition, validation, investigation, visualization, methodology, project administration, and writing—original draft, review, and editing.
Conflict of Interest Statement
The authors declare that they have no conflict of interest.
- Received December 26, 2023.
- Revision received March 28, 2024.
- Accepted March 28, 2024.
- © 2024 Roberts et al.
This article is available under a Creative Commons License (Attribution 4.0 International, as described at https://creativecommons.org/licenses/by/4.0/).