Fibroblastic reticular cells regulate intestinal inflammation via IL-15-mediated control of group 1 ILCs.

Fibroblastic reticular cells (FRCs) of secondary lymphoid organs form distinct niches for interaction with hematopoietic cells. We found here that production of the cytokine IL-15 by FRCs was essential for the maintenance of group 1 innate lymphoid cells (ILCs) in Peyer's patches and mesenteric lymph nodes. Moreover, FRC-specific ablation of the innate immunological sensing adaptor MyD88 unleashed IL-15 production by FRCs during infection with an enteropathogenic virus, which led to hyperactivation of group 1 ILCs and substantially altered the differentiation of helper T cells. Accelerated clearance of virus by group 1 ILCs precipitated severe intestinal inflammatory disease with commensal dysbiosis, loss of intestinal barrier function and diminished resistance to colonization. In sum, FRCs act as an 'on-demand' immunological 'rheostat' by restraining activation of group 1 ILCs and thereby preventing immunopathological damage in the intestine.

Solvent-induced proteome profiling for proteomic quantitation and target discovery of small molecular drugs.

Target identification by modification-free proteomic approaches can potentially reveal the pharmacological mechanism of small molecular compounds. By combining the recent solvent-induced protein precipitation (SIP) method with TMT-labeling quantitative proteomics, we propose solvent-induced proteome profiling (SIPP) approach to identify small molecule-protein interactions. The SIPP approach enables to depict denaturation curves of the target protein by varying concentrations of organic solvents to induce unfolding and precipitation of the cellular proteome. By using this approach, we have successfully identified the known targets of market drugs and natural products and extended the proteome information of SIP for target identification.

[Discussion on the Authenticity Verification Method in the Verification of Medical Device Registration Quality Management System].

Authenticity verification is a very important aspect of medical device registration quality management system verification of medical device. How to verify the authenticity of samples is a problem worth discussing. This study analyzes the methods of authenticity verification from the aspects of product retention sample, registration inspection report, traceability of records, hardware facilities and equipment. In order to provide reference for relevant supervisors and inspectors in the verification of registration quality management system.

Maturation of lymph node fibroblastic reticular cells from myofibroblastic precursors is critical for antiviral immunity.

The stromal scaffold of the lymph node (LN) paracortex is built by fibroblastic reticular cells (FRCs). Conditional ablation of lymphotoxin-ß receptor (LTßR) expression in LN FRCs and their mesenchymal progenitors in developing LNs revealed that LTßR-signaling in these cells was not essential for the formation of LNs. Although T cell zone reticular cells had lost podoplanin expression, they still formed a functional conduit system and showed enhanced expression of myofibroblastic markers. However, essential immune functions of FRCs, including homeostatic chemokine and interleukin-7 expression, were impaired. These changes in T cell zone reticular cell function were associated with increased susceptibility to viral infection. Thus, myofibroblasic FRC precursors are able to generate the basic T cell zone infrastructure, whereas LTßR-dependent maturation of FRCs guarantees full immunocompetence and hence optimal LN function during infection.

Type 3 Innate Lymphoid Cells Direct Goblet Cell Differentiation via the LT-LTßR Pathway during Listeria Infection.

As a specialized subset of intestinal epithelial cells (IECs), goblet cells (GCs) play an important role during the antibacterial response via mucin production. However, the regulatory mechanisms involved in GC differentiation and function during infection, particularly the role of immune cell-IEC cross-talk, remain largely unknown. In this study, using Villin∆Ltbr conditional knockout mice, we demonstrate that LTßR, expressed on IECs, is required for GC hyperplasia and mucin 2 (MUC2) expression during Listeria infection for host defense but not homeostatic maintenance in the naive state. Analysis of single gene-deficient mice revealed that the ligand lymphotoxin (LT), but not LIGHT, and type 3 innate lymphoid cells (ILC3s), but not conventional T cells, are required for MUC2-dependent Listeria control. Conditional deficiency of LT in ILC3s further confirmed the importance of LT signals derived from ILC3s. Lack of ILC3-derived LT or IEC-derived LTßR resulted in the defective expression of genes related to GC differentiation but was not correlated with IEC proliferation and cell death, which were found to be normal by Ki-67 and Annexin V staining. In addition, the alternative NF-κB signaling pathway (involving RelB) in IECs was found to be required for the expression of GC differentiation-related genes and Muc2 and required for the anti-Listeria response. Therefore, our data together suggest a previously unrecognized ILC3-IEC interaction and LT-LTßR-RelB signaling axis governing GC differentiation and function during Listeria infection for host defense.

A novel dual-flux immunochromatographic test strip based on luminescence resonance energy transfer for simultaneous detection of ochratoxin A and deoxynivalenol.

Mycotoxins are secondary metabolites of fungi, which seriously threaten human health. Among them, ochratoxin A (OTA) and deoxynivalenol (DON) have become the main factors that pollute cereals and by-products. In order to achieve simultaneous detection of OTA and DON quantitatively, a novel dual-flux immunochromatographic assay (dICA) was established. The dual-flux assay is based on upconversion nanoparticles (UCNPs) as fluorescence tags to label antigens and gold nanoparticles (AuNPs) as fluorescence quencher to label monoclonal antibodies (mAbs). The intensity of the green fluorescence (540 nm) of UCNPs can be used as an analytical signal, indicating the formation of antigen-antibody immune complexes, thereby indicating the presence or absence of the target analyte. The intensity of the red fluorescence (660 nm) of UCNPs is not affected and can be used as a quality control signal, and the dual-flux bidirectional single-line labeling mode allows for the simultaneous detection of two different mycotoxins on two test lines. This work indicated that the developed dICA provided a sensitive, rapid, and reliable on-site simultaneous detection of multiple mycotoxins.

Knockdown of SGLT1 prevents the apoptosis of cardiomyocytes induced by glucose fluctuation via relieving oxidative stress and mitochondrial dysfunction.

Fluctuations in the concentration of glucose in the blood is more detrimental than a constantly high level of glucose with respect to the development of cardiovascular complications associated with diabetes mellitus (DM). Sodium glucose cotransporter 2 (SGLT2) inhibitors have been developed as antidiabetic drugs with cardiovascular benefits; however, whether inhibition of SGLT1 protects the diabetic heart remains to be determined. This study investigated the role of SGLT1 in rat H9c2 cardiomyocytes subjected to fluctuating levels of glucose and the underlying mechanisms. The results indicated that knockdown of SGLT1 restored cell proliferation and suppressed the cytotoxicity associated with fluctuating glucose levels. Oxidative stress was induced in H9c2 cells subjected to fluctuating glucose levels, but these changes were effectively reversed by knockdown of SGLT1, as manifested by reductions in the level of intracellular reactive oxygen species and increased antioxidant activity. Further study demonstrated that knockdown of SGLT1 attenuated the mitochondrial dysfunction in H9c2 cells exposed to fluctuating glucose levels, by restoring mitochondrial membrane potential and promoting mitochondrial fusion. In addition, knockdown of SGLT1 downregulated the expression of Bax, upregulated the expression of Bcl-2, and reduced the activation of caspase-3 in H9c2 cells subjected to fluctuating levels of glucose. Collectively, our results show that knockdown of SGLT1 ameliorates the apoptosis of cardiomyocyte caused by fluctuating glucose levels via regulating oxidative stress and combatting mitochondrial dysfunction.

Glucose fluctuation accelerates cardiac injury of diabetic mice via sodium-dependent glucose cotransporter 1 (SGLT1).

Recent studies have shown that blood glucose fluctuation is associated with complications of diabetes mellitus (DM). SGLT1 (sodium-dependent glucose cotransporter 1), is highly expressed in pathological conditions of heart, and is expressed in cardiomyocytes induced by high glucose. Herein, we constructed a diabetic mouse model with glucose fluctuation to investigate whether SGLT1 is involved in glucose fluctuation-induced cardiac injury. Echocardiography, histology examination, and TUNEL staining were performed to evaluate cardiac dysfunction and damage. To assess glucose fluctuation-induced oxidative stress, reactive oxygen species (ROS), malondialdehyde (MDA), superoxide dismutase (SOD), catalase (CAT), and glutathione (GSH) levels were measured. To assess mitochondrial dysfunction, mitochondrial membrane potential (MMP), ATP content, mitochondrial respiratory chain complex activity, and expression of mitochondrial fusion and fission proteins were determined. The results indicated that diabetic mice with glucose fluctuation showed elevation of cardiac SGLT1 expression, left ventricular dysfunction, oxidative stress and mitochondrial dysfunction. Knockdown of SGLT1 could abrogate the effects of glucose fluctuation on cardiac injury. Thus, our study highlighted that SGLT1 plays an important role in glucose fluctuation induced cardiac injury through oxidative stress and mitochondrial dysfunction.

Intermittent high glucose induces pyroptosis of rat H9C2 cardiomyocytes via sodium-glucose cotransporter 1.

Cardiomyocyte death is an important pathogenic process in cardiac complications of diabetes. Diabetic patients often suffer glycemic variability. Pyroptosis is a form of programmed cell death triggered by inflammasomes and related with caspase-1 and gasdermin D activation. The present study was designed to examine the effects of intermittent high glucose simulating glycemic variability on the pyroptosis of cardiomyocytes in vitro. Rat H9C2 cardiomyocytes were incubated with normal glucose (NG), constant high glucose (CHG) and intermittent high glucose (IHG). Results showed that compared to CHG treatment, IHG further inhibited cell proliferation and promoted cell death of H9C2 cardiomyocytes. In addition, IHG upregulated higher levels of the expressions of inflammasome NLR family pyrin domain containing 3 (NLRP3) and adaptor protein apoptosis-associated speck-like protein containing CARD domain (ASC) and increased higher levels of activated caspase-1 and gasdermin D than CHG treatment. Moreover, the production of reactive oxygen species (ROS) and activation of NF-κB that is induced by IHG were significantly higher than that induced by CHG. Knockdown of sodium-glucose cotransporters 1 (SGLT1) in H9C2 cardiomyocytes was performed and the effects of SGLT1 on IHG-induced pyroptosis was evaluated. The results demonstrated that knockdown of SGLT1 partially reduced IHG-induced pyroptosis, ROS generation and NF-κB activation. Our results indicated that IHG is harmful to cardiomyocytes and it might be partially because of the SGLT1-depedent pyroptosis in cardiomyocytes.

Langerhans Cells Control Lymphatic Vessel Function during Inflammation via LIGHT-LTßR Signaling.

The lymphatic vasculature is an important route for dendritic cell (DC) or tumor cell migration from peripheral tissues to draining lymph nodes (DLNs). However, the underlying molecular and cellular mechanisms remain poorly understood. In this study, using conventional bone marrow chimeric mice and additional UVB radiation, we found that deficiency of LIGHT but not lymphotoxin (LT) α1ß2, likely on radioresistant Langerhans cells (LCs), resulted in impaired skin DC migration to DLNs during LPS-induced inflammation. In addition, LT ß receptor (LTßR), but not herpes virus entry mediator, was found to be the receptor of LIGHT controlling DC migration. Furthermore, conditional deficiency of LTßR in Tie2 cre or Lyve1 cre mice, but not in LTßR-deficient bone marrow chimeric mice, impaired DC migration, suggesting an important role of LTßR in radioresistant lymphatic endothelial cells (LECs), although the role of LTßR in blood endothelial cells remains intriguing. Mechanistically, the gene expression of both CCL21 and CCL19 was found to be reduced in skin LECs isolated from LC-LIGHT-conditionally deficient or Lyve1 cre Ltbr fl/fl mice compared with their controls upon LPS stimulation. Soluble recombinant LIGHT was able to upregulate CCL21 and CCL19 gene expression on SVEC4-10 endothelial cells. Doxycycline, an inhibitor of soluble LIGHT release in the inflamed skin, impaired skin CCL21 and CCL19 expression and DC migration. In addition, melanoma cell metastasis to DLNs was also inhibited in LC-LIGHT-conditionally deficient or Lyve1 cre Ltbr fl/fl mice. Together, our data suggest, to our knowledge, a previously unrecognized scenario in which LCs activate LECs via the LIGHT-LTßR signaling axis to promote DC migration or tumor cell metastasis.

Differential Roles of LTßR in Endothelial Cell Subsets for Lymph Node Organogenesis and Maturation.

Cellular cross-talk mediated by lymphotoxin αß-lymphotoxin ß receptor (LTßR) signaling plays a critical role in lymph node (LN) development. Although the major role of LTßR signaling has long been considered to occur in mesenchymal lymphoid tissue organizer cells, a recent study using a VE-cadherincreLtbrfl/fl mouse model suggested that endothelial LTßR signaling contributes to the formation of LNs. However, the detailed roles of LTßR in different endothelial cells (ECs) in LN development remain unknown. Using various cre transgenic mouse models (Tekcre , a strain targeting ECs, and Lyve1cre , mainly targeting lymphatic ECs), we observed that specific LTßR ablation in Tekcre+ or Lyve1cre+ cells is not required for LN formation. Moreover, double-cre-mediated LTßR depletion does not interrupt LN formation. Nevertheless, TekcreLtbrfl/fl mice exhibit reduced lymphoid tissue inducer cell accumulation at the LN anlagen and impaired LN maturation. Interestingly, a subset of ECs (VE-cadherin+Tekcre-low/neg ECs) was found to be enriched in transcripts related to hematopoietic cell recruitment and transendothelial migration, resembling LN high ECs in adult animals. Furthermore, endothelial Tek was observed to negatively regulate hematopoietic cell transmigration. Taken together, our data suggest that although Tekcre+ endothelial LTßR is required for the accumulation of hematopoietic cells and full LN maturation, LTßR in VE-cadherin+Tekcre-low/neg ECs in embryos might represent a critical portal-determining factor for LN formation.

Accessibility from the Cytoplasm Is Critical for ssrA Tag-Mediated Degradation of Integral Membrane Proteins by ClpXP Protease.

The AAA+ protease ClpXP has long been established as the cellular rescue system that degrades ssrA-tagged proteins resulting from stalled ribosomes. Until recently, in all of these studies soluble proteins were used as model substrates, since the ClpXP complex and the related adapter SspB are all cytosolic proteins. In a previous study, we found that the introduction of an ssrA tag can facilitate complete degradation of a large and stable trimeric integral membrane protein AcrB, which is the first reported example of a membrane protein substrate. To investigate the mechanism of degradation of a membrane protein by a soluble protein complex, we experimented with the truncation of the C-terminal tail of AcrB. We found that the C-terminal tail is important for degradation, as systematic truncation of the tail diminished degradation. Thus, we hypothesize that membrane proteins need a cytosolic tail/domain for ClpXP-SspB to latch on to initiate degradation. To test this hypothesis, we introduced the ssrA tag at the C-terminal of several membrane proteins, including AqpZ, YiiP, YajR, as well as their truncation fragments, and examined their degradation. We found that the ssrA-facilitated degradation of membrane proteins by ClpXP-SspB depends on the presence of a CT tail or domain, which is critical for accessibility of the tag by ClpXP-SspB. When the ssrA tag is not well-exposed to the cytosol, FtsH can access and degrade the tagged protein, given that the substrate protein is metastable.

The ssrA-Tag Facilitated Degradation of an Integral Membrane Protein.

ATP-dependent degradation plays a critical role in the quality control and recycling of proteins in cells. However, complete degradation of membrane proteins by ATP-dependent proteases in bacteria is not well-studied. We discovered that the degradation of a multidomain and multispan integral membrane protein AcrB could be facilitated by the introduction of a ssrA-tag at the C-terminus of the protein sequence and demonstrated that the cytoplasmic unfoldase-protease complex ClpXP was involved in the degradation. This is the first report to our knowledge to reveal that the ClpXP complex is capable of degrading integral membrane proteins. The chaperone SspB also played a role in the degradation. Using purified proteins, we demonstrated that the addition of the ssrA-tag did not drastically affect the structure of AcrB, and the degradation of detergent solubilized AcrB by purified ClpXP could be observed in vitro.

Alternative NF-κB signaling regulates mTEC differentiation from podoplanin-expressing precursors in the cortico-medullary junction.

The thymic epithelium forms specialized niches to enable thymocyte differentiation. While the common epithelial progenitor of medullary and cortical thymic epithelial cells (mTECs and cTECs) is well defined, early stages of mTEC lineage specification have remained elusive. Here, we utilized in vivo targeting of mTECs to resolve their differentiation pathways and to determine whether mTEC progenitors participate in thymocyte education. We found that mTECs descend from a lineage committed, podoplanin (PDPN)-expressing progenitor located at the cortico-medullary junction. PDPN(+) junctional TECs (jTECs) represent a distinct TEC population that builds the thymic medulla, but only partially supports negative selection and thymocyte differentiation. Moreover, conditional gene targeting revealed that abrogation of alternative NF-κB pathway signaling in the jTEC stage completely blocked mTEC development. Taken together, this study identifies jTECs as lineage-committed mTEC progenitors and shows that NF-κB-dependent progression of jTECs to mTECs is critical to secure central tolerance.

IFN-γ-producing CD4+ T cells promote generation of protective germinal center-derived IgM+ B cell memory against Salmonella Typhi.

Abs play a significant role in protection against the intracellular bacterium Salmonella Typhi. In this article, we investigated how long-term protective IgM responses can be elicited by a S. Typhi outer-membrane protein C- and F-based subunit vaccine (porins). We found that repeated Ag exposure promoted a CD4(+) T cell-dependent germinal center reaction that generated mutated IgM-producing B cells and was accompanied by a strong expansion of IFN-γ-secreting T follicular helper cells. Genetic ablation of individual cytokine receptors revealed that both IFN-γ and IL-17 are required for optimal germinal center reactions and production of porin-specific memory IgM(+) B cells. However, more profound reduction of porin-specific IgM B cell responses in the absence of IFN-γR signaling indicated that this cytokine plays a dominant role. Importantly, mutated IgM mAbs against porins exhibited bactericidal capacity and efficiently augmented S. Typhi clearance. In conclusion, repeated vaccination with S. Typhi porins programs type I T follicular helper cell responses that contribute to the diversification of B cell memory and promote the generation of protective IgM Abs.

Study of the degradation of a multidrug transporter using a non-radioactive pulse chase method.

Proteins are constantly synthesized and degraded in living cells during their growth and division, often in response to metabolic and environmental conditions. The synthesis and breakdown of proteins under different conditions reveal information about their mechanism of function. The metabolic incorporation of non-natural amino acid azidohomoalanine (AHA) and subsequent labeling via click chemistry emerged as a non-radioactive strategy useful in the determination of protein kinetics and turnover. We used the method to monitor the degradation of two proteins involved in the multidrug efflux in Escherichia coli, the inner membrane transporter AcrB and its functional partner membrane fusion protein AcrA. Together they form a functional complex with an outer membrane channel TolC to actively transport various small molecule compounds out of E. coli cells. We found that both AcrA and AcrB lasted for approximately 6 days in live E. coli cells, and the stability of AcrB depended on the presence of AcrA but not on active efflux. These results lead to new insight into the multidrug resistance in Gram-negative bacteria conferred by efflux.

Organization of ribosomes and nucleoids in Escherichia coli cells during growth and in quiescence.

We have examined the distribution of ribosomes and nucleoids in live Escherichia coli cells under conditions of growth, division, and in quiescence. In exponentially growing cells translating ribosomes are interspersed among and around the nucleoid lobes, appearing as alternative bands under a fluorescence microscope. In contrast, inactive ribosomes either in stationary phase or after treatment with translation inhibitors such as chloramphenicol, tetracycline, and streptomycin gather predominantly at the cell poles and boundaries with concomitant compaction of the nucleoid. However, under all conditions, spatial segregation of the ribosomes and the nucleoids is well maintained. In dividing cells, ribosomes accumulate on both sides of the FtsZ ring at the mid cell. However, the distribution of the ribosomes among the new daughter cells is often unequal. Both the shape of the nucleoid and the pattern of ribosome distribution are also modified when the cells are exposed to rifampicin (transcription inhibitor), nalidixic acid (gyrase inhibitor), or A22 (MreB-cytoskeleton disruptor). Thus we conclude that the intracellular organization of the ribosomes and the nucleoids in bacteria are dynamic and critically dependent on cellular growth processes (replication, transcription, and translation) as well as on the integrity of the MreB cytoskeleton.

Correlation between AcrB trimer association affinity and efflux activity.

The majority of membrane proteins function as oligomers. However, it remains largely unclear how the oligomer stability of protein complexes correlates with their function. Understanding the relationship between oligomer stability and activity is essential to protein research and to virtually all cellular processes that depend on the function of protein complexes. Proteins make lasting or transient interactions as they perform their functions. Obligate oligomeric proteins exist and function exclusively at a specific oligomeric state. Although oligomerization is clearly critical for such proteins to function, a direct correlation between oligomer affinity and biological activity has not yet been reported. Here, we used an obligate trimeric membrane transporter protein, AcrB, as a model to investigate the correlation between its relative trimer affinity and efflux activity. AcrB is a component of the major multidrug efflux system in Escherichia coli. We created six AcrB constructs with mutations at the transmembrane intersubunit interface, and we determined their activities using both a drug susceptibility assay and an ethidium bromide accumulation assay. The relative trimer affinities of these mutants in detergent micelles were obtained using blue native polyacrylamide gel electrophoresis. A correlation between the relative trimer affinity and substrate efflux activity was observed, in which a threshold trimer stability was required to maintain efflux activity. The trimer affinity of the wild-type protein was approximately 3 kcal/mol more stable than the threshold value. Once the threshold was reached, an additional increase of stability in the range observed had no observable effect on protein activity.

IL-7-producing stromal cells are critical for lymph node remodeling.

Nonhematopoietic stromal cells of secondary lymphoid organs form important scaffold and fluid transport structures, such as lymph node (LN) trabeculae, lymph vessels, and conduits. Furthermore, through the production of chemokines and cytokines, these cells generate a particular microenvironment that determines lymphocyte positioning and supports lymphocyte homeostasis. IL-7 is an important stromal cell-derived cytokine that has been considered to be derived mainly from T-cell zone fibroblastic reticular cells. We show here that lymphatic endothelial cells (LECs) are a prominent source of IL-7 both in human and murine LNs. Using bacterial artificial chromosome transgenic IL-7-Cre mice, we found that fibroblastic reticular cells and LECs strongly up-regulated IL-7 expression during LN remodeling after viral infection and LN reconstruction after avascular transplantation. Furthermore, IL-7-producing stromal cells contributed to de novo formation of LyveI-positive lymphatic structures connecting reconstructed LNs with the surrounding tissue. Importantly, diphtheria toxin-mediated depletion of IL-7-producing stromal cells completely abolished LN reconstruction. Taken together, this study identifies LN LECs as a major source of IL-7 and shows that IL-7-producing stromal cells are critical for reconstruction and remodeling of the distinct LN microenvironment.

Magneto-Mechanical Coupling Study of Magnetorheological Elastomer Thin Films for Sensitivity Enhancement.

Magnetorheological elastomer thin films (MREFs) exhibit remarkable deformability and an adjustable modulus under magnetic fields, rendering them promising in fields such as robotics, flexible sensors, and biomedical engineering. Here, we fabricated MREF by introducing magnetostrictive particles (MSPs) and evaluated the magneto-mechanical coupling effect on the enhancement of sensitivity. The saturation magnetization (Ms) in a parallel anisotropic TbDyFe-PDMS MREF was 5.8 emu/g, and the initial tensile modulus was 55% greater than that of an Iso MREF. We propose a nonlinear magnetorheological formula on the magnetostriction effect, incorporating magnetic dipole interactions and the nonlinear prestress of magnetic particles. This formula highlights the complex nonlinear relationship between the external magnetic field (H) and the key parameters that affect the enhanced MR effect of MSPs-MREF, such as saturation magnetization, remanence (Mr), magnetostriction constant (λs) and stress deviator in ferromagnetic particles (Sed) in the magnetic chain structure. Furthermore, we validate the influence of the key parameters of the rectified magnetorheological formula on a nonlinear magneto-mechanical behavior of MSPs-MREF in PDMS-based MSPs-MREF models by using finite-element simulations. Finally, we developed a biosensor based on MSPs-MREF to detect human serum albumin at low concentrations in human urine samples. There is a 4-fold increase in sensitivity, a lower detection of limit (0.442 µg/mL), and a faster response time (15 min) than traditional biosensors, which in the future might provide an effective way of detecting biomolecules of low concentrations.