Cytolethal distending toxin induces the formation of transient messenger-rich ribonucleoprotein nuclear invaginations in surviving cells

Authors: Lamia Azzi-Martin ^aff001; Wencan He ^aff001; Christelle Péré-Védrenne ^aff001; Victoria Korolik ^aff002; Chloé Alix ^aff001; Martina Prochazkova-Carlotti ^aff001; Jean-Luc Morel ^aff003; Emilie Le Roux-Goglin ^aff001; Philippe Lehours ^aff001; Mojgan Djavaheri-Mergny ^aff005; Christophe F. Grosset ^aff006; Christine Varon ^aff001; Pierre Dubus ^aff001; Armelle Ménard ^aff001
Authors place of work: Univ. Bordeaux, INSERM, Bordeaux Research in Translational Oncology, BaRITOn, U1053, Bordeaux, France ^aff001; Institute for Glycomics, Griffith University, Gold Coast Campus, Gold Coast, Australia ^aff002; Univ. Bordeaux, CNRS; UMR5293, Institut des maladies neurodégénératives, Bordeaux, France ^aff003; CHU de Bordeaux, Laboratoire de Bactériologie, Centre National de Référence des Campylobacters et des Hélicobacters, Bordeaux, France ^aff004; Univ. Bordeaux, INSERM U1218 ACTION, Institut Bergonié, Bordeaux France, INSERM U1138, Centre de Recherche des Cordeliers, Paris, France. Metabolomics and Cell Biology Platforms, Institut Gustave Roussy, Villejuif, France ^aff005; Univ. Bordeaux, INSERM, Biothérapies des Maladies Génétiques, Inflammatoires et Cancer, BMGIC, U1035, Bordeaux, France ^aff006; CHU de Bordeaux, Pôle biologie et pathologie, Service de biologie des tumeurs, Bordeaux, France ^aff007
Published in the journal: Cytolethal distending toxin induces the formation of transient messenger-rich ribonucleoprotein nuclear invaginations in surviving cells. PLoS Pathog 15(9): e32767. doi:10.1371/journal.ppat.1007921
Category: Research Article
doi: https://doi.org/10.1371/journal.ppat.1007921

Summary

Humans are frequently exposed to bacterial genotoxins involved in digestive cancers, colibactin and Cytolethal Distending Toxin (CDT), the latter being secreted by many pathogenic bacteria. Our aim was to evaluate the effects induced by these genotoxins on nuclear remodeling in the context of cell survival. Helicobacter infected mice, coculture experiments with CDT- and colibactin-secreting bacteria and hepatic, intestinal and gastric cells, and xenograft mouse-derived models were used to assess the nuclear remodeling in vitro and in vivo. Our results showed that CDT and colibactin induced-nuclear remodeling can be associated with the formation of deep cytoplasmic invaginations in the nucleus of giant cells. These structures, observed both in vivo and in vitro, correspond to nucleoplasmic reticulum (NR). The core of the NR was found to concentrate ribosomes, proteins involved in mRNA translation, polyadenylated RNA and the main components of the complex mCRD involved in mRNA turnover. These structures are active sites of mRNA translation, correlated with a high degree of ploidy, and involve MAPK and calcium signaling. Additional data show that insulation and concentration of these adaptive ribonucleoprotein particles within the nucleus are dynamic, transient and protect the cell until the genotoxic stress is relieved. Bacterial genotoxins-induced NR would be a privileged gateway for selected mRNA to be preferably transported therein for local translation. These findings offer new insights into the context of NR formation, a common feature of many cancers, which not only appears in response to therapies-induced DNA damage but also earlier in response to genotoxic bacteria.

Keywords:

Messenger RNA – Cytoplasm – Cell staining – Fluorescence imaging – DNA damage – Nuclear staining – DAPI staining – Cytoplasmic staining

Introduction

Humans are frequently exposed to bacterial genotoxins associated with digestive diseases such as the cytolethal distending toxin (CDT) and colibactin, a polyketide-non-ribosomal peptide genotoxin. CDT had been identified in many pathogenic mucosal bacteria of the microbiota, i.e. Campylobacter species, Helicobacter species, Escherichia species, Shigella species, Salmonella species, Haemophilus species, Aggregatibacter actinomycetemcomitans and Providencia alcalifaciens. CDT is composed of 3 subunits, i.e. CdtA, CdtB and CdtC, of which CdtB subunit is the most conserved of the subunits among CDT-secreting bacteria (reviewed in [1] and [2]). The study of toxins produced by these bacteria revealed a conserved mechanism of action related to the active CDT subunit CdtB, a dual-function enzyme that can act as a phosphatidylinositol-3,4,5-triphosphate phosphatase and a DNase. CdtB targets the nucleus where it induces single and double-strand DNA breaks, which is associated with a cell cycle arrest and a cellular and nuclear distention (reviewed in [3]). Similar effects are caused upon colibactin intoxication [4].

A direct correlation between the induction of DNA damage and invagination of the nuclear envelope was demonstrated using etoposide, a topoisomerase II inhibitor [5]. These structures, also called reticular membrane network, (intra)nucleoplasmic reticulum (NR) or nuclear tubules/invaginations, involve the relocation of the RNA binding protein, UNR/CSDE1 (Upstream of N-Ras/Cold shock domain-containing protein E1), that appear to be concentrated in cytoplasmic cores deeply invaginated into the distended nuclei, forming a novel type of NR, called “UNR-NR”, involved in mRNA translation [6]. Indeed, various NR are known to be induced in different physiological or pathological states [7]. Their appearance increases in tumor cells. Microorganisms also trigger the formation of NR and even hijack them to sustain efficient colonization, multiplication and survival [7]. However, NR formation had not been reported during bacterial infection. Only intranuclear pseudoinclusions were shown in mouse liver cells treated with Helicobacter pullorum sonicates [8]. Together, these observations suggested a possible link between CDT and NR formation that requires elucidation.

In this study, we used in vivo and in vitro models to investigate the role of bacterial genotoxins in nuclear remodeling. Liver tissues of mice infected with Helicobacter hepaticus were used first. Then, in vitro cocultures of human cell lines were performed using wild type strains of H. hepaticus and H. pullorum, their corresponding CDT-knockout mutant strains [9], as well as other toxin-secreting bacteria. To attribute the effects observed specifically to CDT, we used transgenic cell lines allowing the tetracycline-inducible expression of the active subunit CdtB of H. hepaticus and its corresponding H265L mutated CdtB (CdtB-H265L), lacking catalytic activity [10]. These transgenic cell lines were engrafted into immunodeficient mice and the xenograft-derived tumors were used to characterize the nuclear remodeling in vivo. Time course experiments of NR formation, DNA and RNA FISH, transmission electron microscopy, ribopuromycilation assay, UNR silencing and pharmacological inhibitors assays were conducted to characterize the genotoxin-induced UNR-NR. As UNR is a RNA-binding protein involved in cytoplasmic mRNA metabolism that was found in different RNA-associated complexes, its known partners have been evaluated using immunostaining/imaging.

Ethics statement

Animal material provided from previous studies approved by the Ethics Committee for Animal Care and Experimentation CEEA 50 in Bordeaux (Comité d'Ethique en matière d'Expérimentation Animale agréé par le ministre chargé de la Recherche, “dossier no. Dir 13126B- V2”, “saisines” no. 4808-CA-I [11] and 13126B [10], Bordeaux, France), according to the treaty no.123 of the European Convention for the Protection of Vertebrate Animals. Animal experiments were performed in A2 animal facility (security level 2) by trained authorized personnel only.

Materials and methods

Cell lines, bacterial strains and culture conditions are shown in Table 1. The content of NR is morphologically defined using immunostaining and electronic microscopy. UNR-NR was monitored using UNR protein as a marker [6]. Antibodies and the working dilutions used for immunohistochemistry and immunocytochemistry are detailed in S1 Table. Reagents and secondary antibodies, infection of mice with H. hepaticus, ribopuromycilation assay, RT-qPCR, and statistical analyses are detailed in Supplementary Materials and Methods.

**Tab. 1. Bacterial strains and cell lines.**

Coculture experiments

Non-transgenic cells were seeded on culture plates or glass coverslips 24 h before addition of bacteria to the culture media at a density appropriate for each experiment (20,000 to 40,000 cells per well for glass coverslips). H. hepaticus and H. pullorum suspensions were prepared in Brucella broth to optical density of 0.6 (600 nm) corresponding to a concentration of 2.8 x10⁸ colony forming units/ml; H. pylori suspensions were prepared in Brucella broth to optical density of 1.0 (600 nm) corresponding to a concentration of 2.1x10⁸ colony forming units/ml; E. coli suspensions were prepared in Luria Bertani medium to optical density of 1.0 (600 nm) corresponding to a concentration of 5x10⁸ colony forming units/ml. For coculture experiments, the culture medium was removed and a volume corresponding to a multiplicity of infection (MOI) of 100 bacteria/cell in renewed medium supplemented with fetal calf serum was added and incubation continued for 72 h. For some coculture experiments, bacteria were seeded on semipermeable tissue culture inserts (0.2 μm pore size, Anopore, Nunc, Naperville, IL, USA) fitted into wells containing cultured epithelial cells. Cells (Table 1) were either not infected to serve as controls or infected for 72 h with H. hepaticus, H. pullorum and E. coli at a multiplicity of infection (MOI) of 100 bacteria/cell as previously reported [4]. For H. pylori, infections were carried out for 24, 48 and 72 h at a MOI of 25 bacteria/cell [12].

UNR immunodetection on tissue sections combined with interphase fluorescence in situ hybridization (FISH)

To correlate UNR association with the chromosomal content (DNA FISH) or with the poly(A) tail of mRNA (RNA FISH), sequential fluorescent labeling was performed using 6-μm tissue sections, prepared from formalin-fixed paraffin-embedded human Hep-3B xenografts [10]. Firstly, UNR immunodetection was performed, images were captured and coordinates of each image were recorded to ensure repositioning of the slide to the same area after FISH assay. Secondly, interphase DNA or RNA FISH detection was performed using the same slide; the images were captured using the repositioning function of the microscope (Zeiss Axioplan 2 fluorescence microscope, Zeiss, Jena, Germany).

DNA FISH targeted the short arm of chromosome 6 (chromosome region 6p25) (SpectrumRed probe, Abbott France, Rungis, France) and the long arm of chromosome 11 (chromosome region 11q13.3) (SpectrumGreen probe, Abbott France) and was performed as previously described [13]. RNA FISH targeting polyadenylated mRNA was also performed as described [10]. At each step, slides were mounted with Vectashield antifade medium containing 4’,6-diamidino 2-phenylindole (DAPI) (Vector Laboratories, Laboratoires Eurobio/Abcys, Les Ulis, France).

Small interference RNA silencing

siRNA silencing was performed using a pool of 3 target-specific 19–25 nucleotide siRNAs designed to knock down UNR gene expression (sc-76809, Santa Cruz Biotechnology, Heidelberg, Germany). Transgenic Hep3B cells (Table 1) were grown in 12-wells cell culture plates to 70% confluency and the transgene expression was induced with doxycycline (200 ng/ml) 18 hours prior to siRNA transfection according to optimized conditions. As a result, 20 pMoles siRNAs anti-UNR or a scrambled control sequence siRNA (5’-GGGCAAGACGAGCGGGAAG-3’) was added and mixed with lipofectamine (Lipofectamine RNAiMAX Transfection Reagent, Invitrogen, Carlsbad, CA, US) in Opti-MEM medium according to manufacturer’s instructions.

Immunofluorescence, image analysis and protein quantification

Cell cultures grown on glass coverslips and fluorescently labeled were mounted on microscope slides with Fluoromount-G (Clinisciences SA, Montrouge, France) and treated as previously reported [12] with minor modifications. Tissue sections prepared from formalin-fixed paraffin-embedded tissues were also submitted to immunofluorescence protocol. Proteins were analyzed by immunostaining with primary antibodies (reference and dilutions are shown in S1 Table). Dual-, triple- and quadruple-color imaging with Alexa Fluor 647-labeled (far-red), Alexa Fluor594-labeled or Fluor 594-labeled phalloidin (red), Alexa Fluor 488-labeled (green) secondary antibodies, and 4',6'-diamidino-2-phenylindole (DAPI, blue) was obtained using selective laser excitation at 647, 594, 488 and 358 nm, respectively. Traditional widefield fluorescence imaging was performed using Eclipse 50i epi-fluorescence microscope (Nikon, Champigny sur Marne, France) equipped with the Nis Element acquisition software and a 640 (numerical aperture, 1.3) oil immersion objective (40X). Confocal microscopy was performed as previously reported [9] using a SP5 confocal microscope (Leica, Leica microsystems GmbH, Wetzlar, German) with a ×63/numerical aperture 1.4 Plan Neofluor objective lens. To prevent cross-contamination between fluorochromes, each channel was imaged sequentially by using the multitrack recording module before merging. z-stack pictures were obtained using LAS AF, Leica software. Subsequent quantification of proteins in nucleoplasm, cytoplasm and NR were performed with ImageJ (v. 1.52n) [9].

Protein quantification in nucleoplasm, cytoplasm and foci was performed by measuring the pixel intensity with the “Plot Profile” function of ImageJ (v. 1.52n) [14] using capture of fluorescent staining (confocal imaging). For cytoplasmic protein, the quantification data from the nucleoplasm corresponding to background noise have been subtracted from those of the cytoplasm and foci.

The number of cells with UNR-positive nuclei in vivo (formalin-fixed paraffin-embedded tissue) might be underestimated compared to that of cells with a smaller nucleus, as 3 μm- and 6 μm-tissue sections were cut and the size of the nuclei is significantly increased in response to the CDT.

Results

Helicobacter hepaticus infection triggers nuclear remodeling of hepatocytes in mice in association with the formation of UNR nucleoplasmic reticulum in vivo

Immunohistochemical analyses of the liver of mice infected with H. hepaticus for 14 months [11] revealed the localization of UNR in nuclear foci of some giant hepatocytes (Fig 1A). Immunofluorescent staining confirmed the remodeling of hepatocytes following H. hepaticus infection with enlarged nuclei (Fig 1B and 1C). Quantification analysis revealed that nuclear foci formation was a rare event in non-infected mice while a 3-fold increase of NR+ cells was detected in livers of infected mice (Fig 1D), with an average surface area of 50.6 μm² for these NR+ nuclei vs 25.5 μm² for NR- nuclei in infected mice (Fig 1C, blue boxes), corresponding to 270 μm³ vs 96.9 μm³. The nuclear foci were found to lack DAPI staining, concentrated UNR protein (3.06 ± 0.47-fold increase in nuclear foci vs the cytoplasm, p = 0.002, Fig 1E) and were surrounded by the nuclear lamina and DAPI foci (yellow arrowheads, Fig 1B).

<i>In vivo</i> detection of UNR protein in liver of mice infected with <i>Helicobacter hepaticus</i>. — **Fig. 1. *In vivo* detection of UNR protein in liver of mice infected with *Helicobacter hepaticus*.**

NR were not detected in tumoral tissue of the liver in H. hepaticus-infected mice presenting hepatocarcinoma, but rather in the neighboring non-tumoral areas or in mice without adenocarcinoma (S1 Fig). This suggested that H. hepaticus is directly responsible for NR formation in mice. Moreover, obvious formation of UNR-NR in the giant cells indicates that CDT of H. hepaticus may play a role in the formation of these structures.

Stomachs of mice infected with the non-CDT secreting H. felis strain CS1 for 55 weeks [15] were also analyzed. Immunohistochemical analyses did not reveal any UNR-NR formation in non-infected nor infected mice (S2 Fig). Similar results were obtained when using stomachs of mice infected with H. pylori strains SS1, HPAG1 and TN2GF4 for 55 weeks [15], regardless of the virulence factors secreted by these H. pylori. These results further correlate with the absence of CDT secretion by these gastric Helicobacters.

Together these data suggest that the invaginated structures observed in the hepatocytes of mice infected with H. hepaticus exhibit characteristics of the previously reported “UNR-NR” [6]

Infection with genotoxin-secreting bacteria promotes formation of nucleoplasmic reticulum in vitro

Coculture experiments with H. hepaticus and H. pullorum were performed with Hep3B hepatic cells and SW480 intestinal cells (Table 1), as these bacilli colonize the intestine and the liver. Both Helicobacters induced a significant increase of UNR-NR within the larger nuclei of both cell types (Figs 2 and S3A and S3B). The formation of UNR-NR was almost absent in non-infected cells and in cells infected with the CDT-knockout mutant strains, suggesting that these two CDT-secreting Helicobacters are associated with the formation of nuclear UNR-NR and that the CDT is likely to be the main virulence factor associated with UNR-NR formation. NR formation was also observed in Huh7 hepatic and HT29 intestinal cells where tiny UNR-rich foci were more rarely observed.

<i>In vitro</i> detection of UNR protein during bacterial infection. — **Fig. 2. *In vitro* detection of UNR protein during bacterial infection.**

Non-CDT secreting bacterial pathogens H. pylori and Shiga toxin-2 secreting E. coli did not induce major nuclear remodeling nor increased the number of UNR-NR in Hep3B, SW480 and in the H. pylori-susceptible AGS gastric cell line (Table 1 and S3A–S3D Fig and Supplementary Results). In contrast, those cell lines showed a significant nuclear remodeling associated with the increase in UNR-NR upon infection with CDT-secreting Helicobacters or colibactin-secreting extra-intestinal pathogenic E. coli (Figs 2 and S3A–S3C). Taken together, these results suggest that CDT and colibactin, two bacterial cyclomodulins and genotoxins, induced the formation of UNR-NR.

Coculture experiments were also performed using a Transwell system which prevents contact between bacteria and cultured cells, but allows the diffusion of soluble factors. NR formation was still observed after coculture with H. hepaticus in the Transwell system, but to a lesser extent, while colibactin-induced NR formation was not observed (Fig 2C). These results present additional support for attributing NR formation to these toxins. Indeed, CDT is internalized in the host cell by endocytosis independently of the contact with the host cell, while colibactin is directly injected into the host cell during E. coli infection, which requires direct contact with the host cell [4]

The CdtB subunit promotes the nuclear remodeling and UNR nucleoplasmic reticulum formation in hepatocytes

To elucidate if the observed effects could be specifically attributed to the CdtB subunit, stable transgenic cell lines conditionally expressing the active CdtB [10] were used (Table 1). CdtB of H. hepaticus was expressed in situ in the cells in a time-dependent manner, controlled by doxycycline induction. In vitro analysis (Fig 3A) demonstrated the formation of UNR-NR in distended CdtB-expressing Hep3B cells as compared to the Red Fluorescent Protein (RFP)-expressing control cells and cells expressing the H. hepaticus H265L CdtB mutant, suggesting that this catalytic residue is critical for the induction of UNR-NR. The apparent increase in UNR in the cytoplasm observed using wide field microscopy in CdtB expressing cells (Fig 3A) is likely to be the consequence of an increase in the size of the cell leading to this optical effect, since UNR expression was similar in the 3 cell populations (S3E Fig).

<i>In vitro</i> effects of the CdtB subunit on the localization of UNR protein in liver transgenic cell lines. — **Fig. 3. *In vitro* effects of the CdtB subunit on the localization of UNR protein in liver transgenic cell lines.**

Time course experiment showed that UNR-NR formation in Hep3B cells began as early as 24 h after CdtB induction with a maximum effect observed in 3 to 5 days (Fig 3B1), despite termination of the induction of CdtB on day 3. After 5 days, the percentage of UNR-NR-positive cells started to gradually decrease (Fig 3B1, pink curve) and a concomitant resumption of cellular proliferation and mitosis was observed (Fig 3B2, black and purple curve, respectively). It is therefore likely that the cells, having efficiently repaired their genome after CdtB-mediated DNA damage, proliferated de novo and biased the real percentage of UNR-NR-positive cells present on the coverslip. To further strengthen these data, the number of UNR-NR-positive cells per mm² was quantified (Fig 3B1, green curve): a decrease of UNR-NR-positive cells was observed over time (from day 5 to 10) without any cell death, suggesting that CdtB-induced NR is a transient and reversible process.

UNR-NR formation was also associated with an increase of Ki-67 nuclear antigen (Fig 3B3, red curve). As Ki-67 is expressed during all active phases of the cell cycle, G1, S, G2, and mitosis, this increase most likely reflects the expression of Ki-67 accumulated in the G2 phase following the CdtB-induced G2/M cell cycle arrest, as previously reported [10]. Non-cycling cells arrested in G2/M were also previously reported to be Ki-67-positive in other studies [16][17]. Thus, Ki-67 is unlikely to be a pertinent marker for evaluation of cell proliferation in response to CDT intoxication.

UNR-NR was associated with γH2AX foci formation (Fig 3B3, blue curve), a surrogate marker for double-stranded DNA breaks, this effect being very important in response to the CdtB (Fig 3C). In addition, the stronger γH2AX signal correlated with the bigger nuclei (S3F Fig), confirming that CdtB-induced DNA damage is associated with megalocytosis.

Hep3B transgenic cells were also engrafted into immunodeficient mice subsequently treated with doxycycline to induce the transgene expression [10]. Immunostaining analysis of engrafted cells from the sacrificed animals showed highly distended nuclei (reaching sometimes 50 μm of diameter) with large and multiple UNR-NR in response to the CdtB expression as compared to RFP- and CdtB-H265L-derived cells which presented very few and tiny UNR-NR (Fig 3D). The fluorescence imaging confirmed that CdtB induced UNR-NR foci, reaching up to 10 μm, contained UNR proteins and were surrounded by proteins of the nuclear pore complex (NPC, Fig 3E). A zone without UNR immunostaining was observable in the center of some UNR-NR suggesting the existence of unidentified elements in the invaginated structures. A global decrease in DAPI staining, likely to reflect chromatin decondensation, was also observed in UNR-NR containing nuclei of CdtB-expressing engrafted cells (S3G Fig).

As CdtB induced-NR occurred in the largest nuclei (Figs 1C and 3D), a possible link between NR formation and polyploidy was evaluated by DNA FISH. Subsequently, NR foci were identified in nuclei with a high number of chromosome (>8 copies) in more than 70% of the distended Hep3B-intoxicated cells. It is noteworthy that among enlarged cells, cells with higher chromosome content corresponded to those with the largest UNR-NR (Fig 3F).

Effects of UNR silencing on CdtB-induced nucleoplasmic reticulum formation in hepatic cells

siRNA-mediated silencing experiments were performed to examine the involvement of UNR in the formation of NR using Hep3B transgenic cell lines in vitro. Transfection with siRNAs (control and UNR/CSDE1 siRNA), carried out 24 hours after transgene induction, did not affect the cellular viability nor the formation of NR. Silencing UNR by adding the siRNA 12 h prior to transgene induction resulted in a massive cell death of RFP-, CdtB- and CdtB-H265L-expressing Hep3B cells, demonstrating that UNR is essential for cell survival. Transfection with siRNAs concomitantly with the transgene induction led to cell death of RFP- and CdtB-H265L-expressing cells, whereas CdtB-expressing giant cells displaying UNR-NR survived. RT-qPCR confirmed UNR/CSDE1 siRNA-mediated silencing (Fig 4A) in surviving cells, which displayed cytoplasmic UNR extinction, but still contained concentrated UNR in NR (Fig 4A). These data suggest that NRs enable the cells to resist interference-RNA mediated protein depletion, implicating NR formation in cell survival.

**Fig. 4. Effects of UNR silencing and pharmacological inhibitors on nucleoplasmic reticulum formation.**

Regulation of CdtB-induced nucleoplasmic reticulum formation

The effect of a range of pharmacological inhibitors on UNR-NR formation had been tested (Fig 4B). A reduction of UNR-NR formation was observed in presence of calcium channel blockers and mitogen-activated protein kinase (MAPK) inhibitors such as extracellular signal–regulated kinases (ERK1/2), c-Jun N-terminal kinase (JNK), and p38 MAPK. Furthermore, protein synthesis appears to play an important role in UNR-NR formation since cycloheximide reduced their formation. Actinomycin D, a transcription inhibitor, did not have a significant effect on NR formation.

Characterization of CdtB-induced nucleoplasmic reticulum content in hepatic cells

Classification of NR structures has been proposed according to the involvement of the outer nuclear membrane [7]. Most CdtB-induced invaginations corresponded to Type II double-membrane-walled invagination of the inner and outer nuclear membranes with an inter-membrane space (green arrowheads, Fig 5A2 and 5A3). This double-membraned NR was continuous with the cytoplasm (Fig 5A0), pierced by nuclear pores (blue arrowhead, Fig 5A2) and enclosed a cytoplasmic core that extended into the nucleoplasm (Fig 5A0). Some cores were interconnected within the same nucleus (Figs 5A3 and 6D1). Nuclear lamina and NPC were detected around the cytoplasmic core (Figs 1B and 3E and S4). Some invaginations terminated as blind-ending tubes within the nucleoplasm, the nucleoplasmic ends showing an association with nucleoli (Fig 5A, red arrowhead). NR contained ribosomes (Fig 6B), cytoskeletal elements (Fig 5A2, white long arrow) and mitochondria (Fig 5A3 and 5B). The zone without UNR staining in the core, observed in Figs 3E and 6A, 6B and 6C, probably corresponds to a mitochondrion. As previously observed [18], NR contain calnexin, a molecular chaperone of the endoplasmic reticulum (ER), and multi-pass ER membrane receptors for inositol 1,4,5-trisphosphate (S4 Fig). Other cytoplasmic proteins were also found in NR, most of these, however, were present at the same level as in the cytoplasm (S4 Fig). No association between NR formation and senescence could be found (S3H Fig). CdtB-induced NR appeared to occur in cells with low chromatin density (S3G Fig), which excludes apoptotic cells.

<i>In vitro</i> ultrastructure analysis of Hep3B-intoxicated cells. — **Fig. 5. *In vitro* ultrastructure analysis of Hep3B-intoxicated cells.**

**Fig. 6. CdtB-induced Type-II nucleoplasmic reticulum concentrates mCRD-associated proteins, mRNA and are active site of translation.**

CdtB-induced nucleoplasmic reticulum concentrates ribonucleoparticles with translational and mRNA decay activities

High levels of UNR and the cytoplasmic isoform of polyadenylate-binding protein-1 (PABPC1/PABP1) were previously reported in NR [6]. In vivo, these translation regulators are direct partners [19] and were found colocalized in high quantity in CdtB-induced NR core (Fig 6A). As expected, the nuclear isoform PABPN1/PABP2 (nuclear polyadenylate-binding protein-1/nuclear polyadenylate-binding protein 2) was found exclusively in the nucleus (S4 Fig).

Translation initiation in eukaryotes requires the involvement of multiple initiation factors. PABPC1 binds to PABP-interacting protein 1 (PAIP1) to enhance translation. PABPC1 also binds to eIF4G (eukaryotic translation Initiation Factor 4), a component of the eIF4F complex containing eIF4E (eukaryotic translation Initiation Factor 4E), enhancing both the affinity of eIF4E for the cap structure and PABPC1 for poly (A), thus effectively locking proteins onto both ends of the mRNA. Immunostaining of engrafted cells (Fig 6A and 6C) showed that CdtB-induced-NRs concentrate the translational initiation factors PABPC1, PAIP1, eIF4G, eIF4E, as well as eIF4E nucleocytoplasmic shuttle protein 4E-Transporter (EIF4ENIF1 or 4E-T). Translation elongation (EEF2 for Eukaryotic Elongation Factor 2) and termination (eRF1 and eRF3, eukaryotic peptide chain Release Factor subunit 1/3) associated factors were also found in NR but these proteins did not concentrate in these structures in contrast to the translational initiation-associated proteins (S4 Fig).

Polyadenylation is crucial for mRNA stability and translation initiation. The oligo (dT) labeling revealed that mRNA were distributed throughout the cytoplasm and concentrated within UNR-NR in engrafted cells (Fig 6C and 6E), suggesting that mRNA nucleocytoplasmic transport would be favored to these structures.

A two-fold increase in ribosomes was found in the CdtB-induced NR compared to cytoplasm (RPL10, Fig 6B and 6E). Consequently, Hep3B transgenic living cells were subjected to ribopuromycilation assay to detect translation. Translating ribosomes were found to be distributed throughout the cytoplasm for all the experimental conditions and colocated with UNR in most of the CdtB-induced NR (Fig 6D and 6E). Comparative quantification of the translating ribosome proteins revealed a slight, but significant increase of translating ribosomes in UNR-NR vs cytoplasm. It should be noted, that during this in vitro assay, a soft digitonin membrane permeabilization was performed. Because NR concentrates many proteins and mRNA, it is possible that it forms an additional barrier restricting the access of puromycin to the core of the invaginations.

UNR and PABPC1 are subunits of the major coding-region determinant (mCRD)-mediated mRNA instability complex in association with 3 other RNA binding proteins, i.e. PAIP1, NSAP1 and AUF1 [20] As for UNR, both PAIP1 and NSAP1 were found concentrated in the core of NR and colocated with PABPC1 (Fig 6A and 6E). The analysis of the last partner of mCRD-mediated complex, p37 AUF1, is complicated by the existence of four isoforms generated by alternative splicing of AUF1 transcript [21] and no antibody targeting specifically AUF1 cytosolic isoforms can be produced. p42/45 AUF1 nuclear isoforms are mainly located in the nucleus, while the p37/40 isoforms are more weakly expressed in the cytoplasm. AUF1 detection revealed a strong nuclear signal and a weak signal in cytoplasm and NR (Fig 6A and 6E). Nevertheless, the concentration of a majority of mCRD complex components and of the RNA binding protein DEAD-box helicase, DDX6 [22] (Fig 6B and 6E) in the CdtB-induced NR, suggests these structures contain many trans-acting regulators involved in mRNA stability [23]

Together, these data suggest CdtB-induced-NR are active sites of mRNA translation and decay.

Discussion

Herein, we report the formation of nuclear membrane invagination/NR during bacterial infection: H. hepaticus infection triggers NR formation in the hepatocytes of infected mice. Coculture experiments with H. hepaticus and H. pullorum showed that these two Helicobacters are associated with the formation of NR. In contrast, NR formation was almost absent in cells infected with the corresponding CDT-knockout mutant strains showing that CDT is the main factor responsible for NR formation. The transgenic cell line expressing the CdtB, and especially that expressing the H265L mutated CdtB lacking catalytic activity, allowed to attribute NR formation to the CdtB subunit. NR formation was associated with a profound nuclear remodeling following H. hepaticus infection and a significant increase in nucleus size. Moreover, the bigger the nuclei, the stronger the DNA damage. Colibactin, another bacterial genotoxin, also triggered NR formation, suggesting that NR formation is a consequence of genotoxic-induced DNA damage. This hypothesis is supported by the fact that etoposide, a potent DNA damaging agent, also induces NR formation [5]. The tight association of NR with γH2AX-positive DNA lesions following γ-radiation and the regulator of cellular response to DNA damage 53BP1 [24] constitute an additional argument to support a role for a dynamic NR formation in DNA damage repair.

NR have not been previously reported during bacterial infection in NR-susceptible cell lines (Vero, Hela and CHO), even for bacteria whose toxin is targeted to the ER [7]. Unlike other ER-translocating toxins acting in the cytosol, CdtB is subjected to an atypical translocation mechanism from the ER to the nucleus, a nuclear access via NR would facilitate CdtB transport to the nucleus where the toxin damages host-cell DNA. GST-tagged CdtB and ER were reported once previously to be colocated at NR-like structure in HeLa cells but this NR was pre-existing in uninfected cells, suggesting it was a normal cellular structure rather than a byproduct of CdtB intoxication [25] Immunostaining of transgenic intestinal SW480 cells expressing the CdtB of H. hepaticus showed that NR did not concentrate CdtB (S5B Fig). It is thus unlikely that NR sustain the nucleo-cytoplasmic shuttling of the CdtB to the nucleus where the toxin exerts its toxicity. In addition, quantification of CdtB in NR- versus NR+ cells did not reveal significant differences between the levels of CdtB expression and NR formation (S5A Fig).

Virus and protozoa infections also induce jagged appearance of the nuclear lamina with evidence of invaginations of the nuclear envelope [7], but presenting a different composition compared to CdtB-induced NR. Indeed, the cytomegalovirus and alphaherpesvirus-induced NR are devoid of ribosomes and mitochondria [26] and Toxoplasma gondii-induced NR (parasitophorous vacuole) show little specific colocalization with markers for host ER or mitochondria [27] Thus, CdtB-induced UNR-NR are structures different to those observed in response to virus and protozoa infections. This, again, emphasizes the unique aspects of CDT intoxication.

Many cytoplasmic proteins are present in CdtB-induced NR but at a level similar to that in the cytoplasm, probably randomly included during NR formation. The composition of CdtB-induced NR is reminiscent of that of ribonucleoprotein granules, such as stress granules (SG), processing bodies (GW/P-bodies), three structurally and dynamically linked compartments important in the post-transcriptional regulation of gene expression [28] CdtB-induced NR shares some proteins and mRNA components (eIF4E, DDX6) either with SG and GW/P-bodies but ultrastructure and protein composition of these NR revealed divergences to that of SG and GW/P-bodies [29] It is unlikely that CdtB-induced NR correspond to SG or GW-/P-bodies invaginated in the nucleus, since these bodies were never detected in the cytoplasm of the CdtB intoxicated cells. The accumulation of the PABPC1 and eIF4G in CdtB-induced NR, two markers selectively recruited to SG but missing in GW/P-bodies, as well as the absence of accumulation of the GW/P-bodies proteins (GW182 and AGO2), allow to definitively exclude that CdtB-induced NR correspond to GW/P-bodies invaginated in the nucleus. Besides, the size of these NR (in the range of μm) would be similar to that observed in SG [30] However, the non-spheroid/ellipsoid structures of CdtB-induced NR, the concentration of the large 60S ribosomal subunits RPL10 excluded in SG [31], and the lack of accumulation of TIA1 (T cell intracellular antigen), a common SG marker, do not allow to conclude that CdtB-induced NR are SG invaginated into the nucleus. Additionally, SG are distant from the nuclear envelope, mitochondria and ER [29] while CdtB-induced NR are deeply invaginated into nuclei and tightly linked to these organelles.

CdtB and colibactin triggered the formation of messenger ribonucleoprotein (mRNP) particles clustered and invaginated into deep nuclear channels. Compared to the cytoplasm, a slight increase of translation was observed in these dynamic particles, whose formation is dependent on an active translation. These transient particles, induced in response to DNA damage, also concentrate and insulate mRNAs, preinitiation factors and specific RNA-binding proteins, such as the subunits of the mCRD complex involved in mRNA destabilization [20] Accordingly, CdtB-induced NR may be transient signaling hubs controlling mRNA turnover and translation of selected mRNAs. Indeed, already formed NR invaginations were shown to be resorbed back into the envelope, supporting the idea that NR events are reversible and dynamic. [32]

Silencing experiments revealed that 1) UNR is essential for the survival of CdtB-expressing cells in vitro and 2) NR resist to RNA interference-mediated protein depletion and is implicated in cell survival, which is in line with an active mRNA translation and decay in these structure. During UNR silencing, the absence of extinction of UNR signal only in NR in CdtB-Hep3B giant surviving cells may be explained by various compatible hypotheses. CdtB-NR are dense particles formed by long narrow tubular channels ending with a core concentrating mRNA and RNA binding proteins, likely resulting in a restricted access of the UNR siRNA to the nuclear invaginations. As proteins are concentrated in NR, their stability would also be favored. Moreover, NRs are site of mRNA accumulation, suggesting that nucleo-cytoplasmic transport of mRNA via the nuclear pores might be preferentially directed from the nucleus to these structures deeply invaginated in the nucleoplasm rather than to the cytoplasm. CdtB-induced NR would thus be a privileged gateway for selected mRNA, as UNR mRNA, preferentially transported therein for local translation in this protected structure, and thus able to avoid the cytoplasmic siRNA. The presence of a cytoplasmic core and NPC around NR supports a possible role for these structures in nucleo-cytoplasmic transport. Clear association of a subset of NR with nucleoli would also be consistent with a role in transport [33] Additionally, numerous CdtB-induced NR contained cytoskeletal elements that are thought to facilitate trafficking of mRNAs and organites such as mitochondria [34] Thus, UNR-NR would be essential dynamic cellular structures involved in the survival of DNA-damaged cells. UNR-NR would be the hubs that intercept a subset of signaling molecules, thereby communicating a “state of emergency” to other signaling pathways, modulating metabolism, growth and survival.

CdtB-induced NR is surrounded by the nuclear lamina tightly linked with chromatin, suggesting a role for chromatin in NR formation. The fact that condensins exert force on chromatin-nuclear envelope tethers to mediate NR formation [32], supports this hypothesis in CdtB-induced NR.

UNR-NR was also present at a basal level in the hepatocytes of non-infected mice and in cancer derived-cell lines (Hep3B and SW480). In vivo Unr expression study in mice using tissue microarray showed that the formation of UNR-NR was restricted to trophoblast giant cells in the developing placenta and hepatocytes [6], the two human polyploid cell types resulting from endoreplication. Endoreplication is also known to confer genome instability [35] As UNR-NR formation is associated with DNA damage/repair, the formation of UNR-NR at a basal level may be a cellular response to genome instability triggered by endoreplication. Genomic instability that accumulates in cancer derived-cell lines (Hep3B and SW480) may also lead to UNR-NR formation in those cells.

CdtB promotes endoreplication leading to giant polyploid cells,[10] these latter cells presented the highest and largest UNR-NR. Since endoreplication and polyploidy are required for the maintenance of cell identity, CdtB-induced NR may occur in giant endoreplicating polyploid cells that would rewire DNA damage response networks to overcome replication stress-induced barriers, giving advantages for cell survival and growth. This is supported by the fact that NR can be formed de novo without mitosis [36] and tumor cells can evade DNA-damage through DNA endoreduplication and reversible polyploidy. [37]

While senescence and apoptosis were observed in our models (coculture experiments and xenograft mice), we found no association between CdtB-induced NR formation and apoptosis or senescence phenotypes, constituting an additional argument to support a role for NR in cell survival. Indeed, cellular senescence is often considered as a terminal cell state, but it was shown to be reversible in some polyploid cancer cells following DNA damage. [38] Overcoming the genotoxic damage in those cancer cells is associated with reversible polyploidy which coincides with reversible senescence [37] Here, the CdtB-intoxicated giant polyploid cells accumulate NR, survive and keep proliferating with an apparent NR resorption and return back to normal size, suggesting de-polyploidisation. Thus, we can assume that those CdtB-intoxicated polyploid cells might have entered cellular senescence and rewired the DNA damage response and repair networks to escape the genotoxic stress-associated senescence,[39] leading to cell survival and de-polyploidisation. Additionally, the presence of calnexin in NR may maintain a Ca²⁺ store in close proximity to the nuclear matrix, allowing the transport of Ca²⁺ to the nucleus, which is necessary to regulate gene transcription as well as cell proliferation.

The CdtB-induced invaginations were less notable in the presence of inhibitors targeting the MAPK/ERK, JNK and p38 MAPK pathways, as well as with SERCA Ca²⁺ channel blockers. Ca²⁺ regulates ERK signaling [40] Knowing that elevated Ca²⁺ concentration [41] and CDT activates the MAPK/ERK cascade,[42] SERCA and ERK/MAPK inhibitors would counteract the CDT effects and therefore reduced the number of CdtB-induced NR. NR is known to facilitate Ca²⁺ exchanges between the cytoplasm and the nucleoplasm, and to preserve the ability to generate nucleoplasmic Ca²⁺ transients in cells via IP3R and ryanodine receptors [18] CdtB-induced NR probably sustains increased expression of genes regulated by localized Ca²⁺ release and increases export of mRNA for translation (NR and Ca²⁺ signaling reviewed in [7]).

CDT intoxication was associated with various phenotypes, i.e. apoptosis and cell death, DNA proper or improper repair and cell survival, senescence and endoreduplication. Here, we showed that the genotoxic stress induced by bacterial genotoxin can also promote the formation of NR deeply invaginated in the nucleoplasm of giant nuclei together with profound nuclear reorganization (chromatin remodeling, hyperploidization). The core of the genotoxin-induced NR concentrates proteins involved in mRNA translation, polyadenylated RNA, ribosomes, as well as the main subunits of the mCRD complex involved in mRNA turnover. These dynamic cellular structures are active sites of mRNA translation and decay. Their formation has not been previously reported to occur during bacterial infections. They may correspond to a privileged gateway for the synthesis of selected mRNA preferentially transported from the nucleus through pores and translated therein. Our conclusion is that these transient reversible structures allow the cell to pause and repair the DNA damage caused by bacterial genotoxins to maintain cell survival (S6 Fig). In this latter case, this may contribute to the resistance of cancer cells to radiotherapies and some chemotherapies inducing DNA damage.

Supporting information

S1 Fig [green]
detection of UNR protein in liver of mice infected with .

S2 Fig [a]
Detection of UNR protein in mice stomachs during infection.

S3 Fig [a]
detection of UNR-NR during bacterial infection.

S4 Fig [green]
Subcellular localization of proteins in response to the CdtB of .

S5 Fig [ha]
Subcellular localization of proteins in response to the CdtB of in intestinal cells.

S6 Fig [pdf]
Cytolethal distending toxin induces the formation of transient messenger-rich ribonucleoprotein nuclear invaginations in surviving cells 1- Bacterial genotoxin infection and cytoplasmic CdtB active subunit internalization 2- Giant nuclei together with profound nuclear reorganization in response to DNA damage—3- Cell cycle pause and DNA damage repair 4- Cell survival and cell cycle re-entry.

S1 Table [docx]
Antibodies used for immunohistochemistry and immunocytochemistry experiments.

Zdroje

1. O Cróinín T, Backert S. Host epithelial cell invasion by Campylobacter jejuni: trigger or zipper mechanism? Front Cell Infect Microbiol. 2012;2: 25. doi: 10.3389/fcimb.2012.00025 22919617

2. Jinadasa RN, Bloom SE, Weiss RS, Duhamel GE. Cytolethal distending toxin: a conserved bacterial genotoxin that blocks cell cycle progression, leading to apoptosis of a broad range of mammalian cell lineages. Microbiol Read Engl. 2011;157: 1851–1875. doi: 10.1099/mic.0.049536–0

3. Bezine E, Vignard J, Mirey G. The cytolethal distending toxin effects on Mammalian cells: a DNA damage perspective. Cells. 2014;3: 592–615. doi: 10.3390/cells3020592 24921185

4. Nougayrède J-P, Homburg S, Taieb F, Boury M, Brzuszkiewicz E, Gottschalk G, et al. Escherichia coli induces DNA double-strand breaks in eukaryotic cells. Science. 2006;313: 848–851. doi: 10.1126/science.1127059 16902142

5. Dellaire G, Kepkay R, Bazett-Jones DP. High resolution imaging of changes in the structure and spatial organization of chromatin, gamma-H2A.X and the MRN complex within etoposide-induced DNA repair foci. Cell Cycle Georget Tex. 2009;8: 3750–3769. doi: 10.4161/cc.8.22.10065 19855159

6. Saltel F, Giese A, Azzi L, Elatmani H, Costet P, Ezzoukhry Z, et al. Unr defines a novel class of nucleoplasmic reticulum involved in mRNA translation. J Cell Sci. 2017;130: 1796–1808. doi: 10.1242/jcs.198697 28386023

7. Malhas A, Goulbourne C, Vaux DJ. The nucleoplasmic reticulum: form and function. Trends Cell Biol. 2011;21: 362–373. doi: 10.1016/j.tcb.2011.03.008 21514163

8. Ceelen LM, Haesebrouck F, D’Herde K, Krysko DV, Favoreel H, Vandenabeele P, et al. Mitotic catastrophe as a prestage to necrosis in mouse liver cells treated with Helicobacter pullorum sonicates. J Morphol. 2009;270: 921–928. doi: 10.1002/jmor.10730 19217023

9. Péré-Védrenne C, Cardinaud B, Varon C, Mocan I, Buissonnière A, Izotte J, et al. The Cytolethal Distending Toxin Subunit CdtB of Helicobacter Induces a Th17-related and Antimicrobial Signature in Intestinal and Hepatic Cells In Vitro. J Infect Dis. 2016;213: 1979–1989. doi: 10.1093/infdis/jiw042 26908757

10. Péré-Védrenne C, Prochazkova-Carlotti M, Rousseau B, He W, Chambonnier L, Sifré E, et al. The Cytolethal Distending Toxin Subunit CdtB of Helicobacter hepaticus Promotes Senescence and Endoreplication in Xenograft Mouse Models of Hepatic and Intestinal Cell Lines. Front Cell Infect Microbiol. 2017;7: 268. doi: 10.3389/fcimb.2017.00268 28713773

11. Le Roux-Goglin E, Dubus P, Asencio C, Jutand M-A, Rosenbaum J, Mégraud F. Hepatic lesions observed in hepatitis C virus transgenic mice infected by Helicobacter hepaticus. Helicobacter. 2013;18: 33–40. doi: 10.1111/j.1523-5378.2012.00995.x 23067369

12. Varon C, Duriez A, Lehours P, Ménard A, Layé S, Zerbib F, et al. Study of Helicobacter pullorum proinflammatory properties on human epithelial cells in vitro. Gut. 2009;58: 629–635. doi: 10.1136/gut.2007.144501 18579667

13. de Planell-Saguer M, Rodicio MC, Mourelatos Z. Rapid in situ codetection of noncoding RNAs and proteins in cells and formalin-fixed paraffin-embedded tissue sections without protease treatment. Nat Protoc. 2010;5: 1061–1073. doi: 10.1038/nprot.2010.62 20539282

14. Schneider CA, Rasband WS, Eliceiri KW. NIH Image to ImageJ: 25 years of image analysis. Nat Methods. 2012;9: 671–675. doi: 10.1038/nmeth.2089 22930834

15. Varon C, Dubus P, Mazurier F, Asencio C, Chambonnier L, Ferrand J, et al. Helicobacter pylori infection recruits bone marrow-derived cells that participate in gastric preneoplasia in mice. Gastroenterology. 2012;142: 281–291. doi: 10.1053/j.gastro.2011.10.036 22062361

16. Lundblad D, Landberg G, Roos G, Lundgren E. Ki-67 as a marker for cell cycle regulation by interferon. Anticancer Res. 1991;11: 2131–2136. 1723263

17. van Oijen MG, Medema RH, Slootweg PJ, Rijksen G. Positivity of the proliferation marker Ki-67 in noncycling cells. Am J Clin Pathol. 1998;110: 24–31. doi: 10.1093/ajcp/110.1.24 9661919

18. Collado-Hilly M, Shirvani H, Jaillard D, Mauger J-P. Differential redistribution of Ca2+-handling proteins during polarisation of MDCK cells: Effects on Ca2+ signalling. Cell Calcium. 2010;48: 215–224. doi: 10.1016/j.ceca.2010.09.003 20932574

19. Ray S, Anderson EC. Stimulation of translation by human Unr requires cold shock domains 2 and 4, and correlates with poly(A) binding protein interaction. Sci Rep. 2016;6: 22461. doi: 10.1038/srep22461 26936655

20. Grosset C, Chen CY, Xu N, Sonenberg N, Jacquemin-Sablon H, Shyu AB. A mechanism for translationally coupled mRNA turnover: interaction between the poly(A) tail and a c-fos RNA coding determinant via a protein complex. Cell. 2000;103: 29–40. doi: 10.1016/s0092-8674(00)00102-1 11051545

21. Wagner BJ, DeMaria CT, Sun Y, Wilson GM, Brewer G. Structure and genomic organization of the human AUF1 gene: alternative pre-mRNA splicing generates four protein isoforms. Genomics. 1998;48: 195–202. doi: 10.1006/geno.1997.5142 9521873

22. Weston A, Sommerville J. Xp54 and related (DDX6-like) RNA helicases: roles in messenger RNP assembly, translation regulation and RNA degradation. Nucleic Acids Res. 2006;34: 3082–3094. doi: 10.1093/nar/gkl409 16769775

23. Damgaard CK, Lykke-Andersen J. Translational coregulation of 5’TOP mRNAs by TIA-1 and TIAR. Genes Dev. 2011;25: 2057–2068. doi: 10.1101/gad.17355911 21979918

24. Legartová S, Stixová L, Laur O, Kozubek S, Sehnalová P, Bártová E. Nuclear structures surrounding internal lamin invaginations. J Cell Biochem. 2014;115: 476–487. doi: 10.1002/jcb.24681 24123263

25. Guerra L, Nemec KN, Massey S, Tatulian SA, Thelestam M, Frisan T, et al. A novel mode of translocation for cytolethal distending toxin. Biochim Biophys Acta. 2009;1793: 489–495. doi: 10.1016/j.bbamcr.2008.11.017 19118582

26. Klupp BG, Granzow H, Fuchs W, Keil GM, Finke S, Mettenleiter TC. Vesicle formation from the nuclear membrane is induced by coexpression of two conserved herpesvirus proteins. Proc Natl Acad Sci U S A. 2007;104: 7241–7246. doi: 10.1073/pnas.0701757104 17426144

27. Reese ML, Boothroyd JC. A helical membrane-binding domain targets the Toxoplasma ROP2 family to the parasitophorous vacuole. Traffic Cph Den. 2009;10: 1458–1470. doi: 10.1111/j.1600-0854.2009.00958.x 19682324

28. Kedersha N, Stoecklin G, Ayodele M, Yacono P, Lykke-Andersen J, Fritzler MJ, et al. Stress granules and processing bodies are dynamically linked sites of mRNP remodeling. J Cell Biol. 2005;169: 871–884. doi: 10.1083/jcb.200502088 15967811

29. Souquere S, Mollet S, Kress M, Dautry F, Pierron G, Weil D. Unravelling the ultrastructure of stress granules and associated P-bodies in human cells. J Cell Sci. 2009;122: 3619–3626. doi: 10.1242/jcs.054437 19812307

30. Kedersha N, Anderson P. Mammalian stress granules and processing bodies. Methods Enzymol. 2007;431: 61–81. doi: 10.1016/S0076-6879(07)31005-7 17923231

31. Kedersha N, Chen S, Gilks N, Li W, Miller IJ, Stahl J, et al. Evidence that ternary complex (eIF2-GTP-tRNA(i)(Met))-deficient preinitiation complexes are core constituents of mammalian stress granules. Mol Biol Cell. 2002;13: 195–210. doi: 10.1091/mbc.01-05-0221 11809833

32. Bozler J, Nguyen HQ, Rogers GC, Bosco G. Condensins exert force on chromatin-nuclear envelope tethers to mediate nucleoplasmic reticulum formation in Drosophila melanogaster. G3 Bethesda Md. 2014;5: 341–352. doi: 10.1534/g3.114.015685 25552604

33. Drozdz MM, Vaux DJ. Shared mechanisms in physiological and pathological nucleoplasmic reticulum formation. Nucl Austin Tex. 2017;8: 34–45. doi: 10.1080/19491034.2016.1252893 27797635

34. Jorgens DM, Inman JL, Wojcik M, Robertson C, Palsdottir H, Tsai W-T, et al. Deep nuclear invaginations are linked to cytoskeletal filaments—integrated bioimaging of epithelial cells in 3D culture. J Cell Sci. 2017;130: 177–189. doi: 10.1242/jcs.190967 27505896

35. Fox DT, Duronio RJ. Endoreplication and polyploidy: insights into development and disease. Dev Camb Engl. 2013;140: 3–12. doi: 10.1242/dev.080531 23222436

36. Goulbourne CN, Malhas AN, Vaux DJ. The induction of a nucleoplasmic reticulum by prelamin A accumulation requires CTP:phosphocholine cytidylyltransferase-α. J Cell Sci. 2011;124: 4253–4266. doi: 10.1242/jcs.091009 22223883

37. Puig P-E, Guilly M-N, Bouchot A, Droin N, Cathelin D, Bouyer F, et al. Tumor cells can escape DNA-damaging cisplatin through DNA endoreduplication and reversible polyploidy. Cell Biol Int. 2008;32: 1031–1043. doi: 10.1016/j.cellbi.2008.04.021 18550395

38. Erenpreisa J, Cragg MS. Three steps to the immortality of cancer cells: senescence, polyploidy and self-renewal. Cancer Cell Int. 2013;13: 92. doi: 10.1186/1475-2867-13-92 24025698

39. Zheng L, Dai H, Zhou M, Li X, Liu C, Guo Z, et al. Polyploid cells rewire DNA damage response networks to overcome replication stress-induced barriers for tumour progression. Nat Commun. 2012;3: 815. doi: 10.1038/ncomms1825 22569363

40. Chuderland D, Seger R. Calcium regulates ERK signaling by modulating its protein-protein interactions. Commun Integr Biol. 2008;1: 4–5. doi: 10.4161/cib.1.1.6107 19704446

41. Schwan C, Kruppke AS, Nölke T, Schumacher L, Koch-Nolte F, Kudryashev M, et al. Clostridium difficile toxin CDT hijacks microtubule organization and reroutes vesicle traffic to increase pathogen adherence. Proc Natl Acad Sci U S A. 2014;111: 2313–2318. doi: 10.1073/pnas.1311589111 24469807

42. Guerra L, Carr HS, Richter-Dahlfors A, Masucci MG, Thelestam M, Frost JA, et al. A bacterial cytotoxin identifies the RhoA exchange factor Net1 as a key effector in the response to DNA damage. PloS One. 2008;3: e2254. doi: 10.1371/journal.pone.0002254 18509476

43. Burnens AP, Stanley J, Nicolet J. Possible association of Helicobacter pullorum with lesions of vibrionic hepatitis in poultry. Campylobacter, Helicobacter and related organisms. Plenum Press, New York. Newell D.J., Ketley J.M., Feldman R.A.:; pp. 291–293.

44. Varon C, Mocan I, Mihi B, Péré-Védrenne C, Aboubacar A, Moraté C, et al. Helicobacter pullorum cytolethal distending toxin targets vinculin and cortactin and triggers formation of lamellipodia in intestinal epithelial cells. J Infect Dis. 2014;209: 588–599. doi: 10.1093/infdis/jit539 24470577

45. Fox JG, Dewhirst FE, Tully JG, Paster BJ, Yan L, Taylor NS, et al. Helicobacter hepaticus sp. nov., a microaerophilic bacterium isolated from livers and intestinal mucosal scrapings from mice. J Clin Microbiol. 1994;32: 1238–1245. 8051250

46. Arnold IC, Zigova Z, Holden M, Lawley TD, Rad R, Dougan G, et al. Comparative whole genome sequence analysis of the carcinogenic bacterial model pathogen Helicobacter felis. Genome Biol Evol. 2011;3: 302–308. doi: 10.1093/gbe/evr022 21402865

47. Lee A, Hazell SL, O’Rourke J, Kouprach S. Isolation of a spiral-shaped bacterium from the cat stomach. Infect Immun. 1988;56: 2843–2850. 3169989

48. Franco AT, Israel DA, Washington MK, Krishna U, Fox JG, Rogers AB, et al. Activation of beta-catenin by carcinogenic Helicobacter pylori. Proc Natl Acad Sci U S A. 2005;102: 10646–10651. doi: 10.1073/pnas.0504927102 16027366

49. Blanchard TG, Nedrud JG. Laboratory maintenance of helicobacter species. Curr Protoc Microbiol. 2006;Chapter 8: Unit8B.1. doi: 10.1002/9780471729259.mc08b01s00 18770594

50. Oh JD, Kling-Bäckhed H, Giannakis M, Xu J, Fulton RS, Fulton LA, et al. The complete genome sequence of a chronic atrophic gastritis Helicobacter pylori strain: evolution during disease progression. Proc Natl Acad Sci U S A. 2006;103: 9999–10004. doi: 10.1073/pnas.0603784103 16788065

51. van Doorn NE, Namavar F, Sparrius M, Stoof J, van Rees EP, van Doorn LJ, et al. Helicobacter pylori-associated gastritis in mice is host and strain specific. Infect Immun. 1999;67: 3040–3046. 10338517

52. Keto Y, Ebata M, Okabe S. Gastric mucosal changes induced by long term infection with Helicobacter pylori in Mongolian gerbils: effects of bacteria eradication. J Physiol Paris. 2001;95: 429–436. 11595471

53. Gouali M, Ruckly C, Carle I, Lejay-Collin M, Weill F-X. Evaluation of CHROMagar STEC and STEC O104 chromogenic agar media for detection of Shiga Toxin-producing Escherichia coli in stool specimens. J Clin Microbiol. 2013;51: 894–900. doi: 10.1128/JCM.03121-12 23284030

54. Schindelin J, Rueden CT, Hiner MC, Eliceiri KW. The ImageJ ecosystem: An open platform for biomedical image analysis. Mol Reprod Dev. 2015;82: 518–529. doi: 10.1002/mrd.22489 26153368