Your search keyword '"Ye Zhan"' showing total 12 results

1. B Cell Production of Tumor Necrosis Factor in Response to Pneumocystis murina Infection in Mice

Author

Opata, Michael M., primary, Ye, Zhan, additional, Hollifield, Melissa, additional, and Garvy, Beth A., additional

Published

2013

2. Distinct CCR2 + Gr1 + Cells Control Growth of the Yersinia pestis Δ yopM Mutant in Liver and Spleen during Systemic Plague

Author

Ye, Zhan, primary, Uittenbogaard, Annette M., additional, Cohen, Donald A., additional, Kaplan, Alan M., additional, Ambati, Jayakrishna, additional, and Straley, Susan C., additional

Published

2011

3. Gr1+Cells Control Growth of YopM-NegativeYersinia pestisduring Systemic Plague

Author

Ye, Zhan, primary, Kerschen, Edward J., additional, Cohen, Donald A., additional, Kaplan, Alan M., additional, van Rooijen, Nico, additional, and Straley, Susan C., additional

Published

2009

4. Anti-LcrV Antibody Inhibits Delivery of Yops by Yersinia pestis KIM5 by Directly Promoting Phagocytosis

Author

Cowan, Clarissa, primary, Philipovskiy, Alexander V., additional, Wulff-Strobel, Christine R., additional, Ye, Zhan, additional, and Straley, Susan C., additional

Published

2005

5. B Cell Production of Tumor Necrosis Factor in Response to Pneumocystis murinaInfection in Mice

Author

Opata, Michael M., Ye, Zhan, Hollifield, Melissa, and Garvy, Beth A.

Abstract

ABSTRACTPneumocystisspecies are opportunistic fungal pathogens that induce tumor necrosis factor (TNF) production by alveolar macrophages. Here we report that B cells from the draining lymph nodes as well as lung CD4+T cells are important producers of TNF upon Pneumocystis murinainfection. To determine the importance of B cell-derived TNF in the primary response to P. murina, we generated bone marrow chimeras whose B cells were unable to produce TNF. The lung P. murinaburden at 10 days postinfection in TNF knockout (TNFKO) chimeras was significantly higher than that in wild-type (WT) chimeras, which corresponded to reduced numbers of activated CD4+T cells in the lungs at this early time point. Furthermore, CD4+T cells isolated from P. murina-infected TNFKO chimeras were unable to stimulate clearance of P. murinaupon adoptive transfer to recombinase-deficient (RAG1KO) hosts. Together, these data indicate that B cell-derived TNF plays an important function in promoting CD4+T cell expansion and production of TNF and facilitating protection against P. murinainfection.

Published

2013

6. Distinct CCR2+ Gr1+ Cells Control Growth of the Yersinia pestis ΔyopM Mutant in Liver and Spleen during Systemic Plague

Author

Ye, Zhan, Uittenbogaard, Annette M., Cohen, Donald A., Kaplan, Alan M., Ambati, Jayakrishna, and Straley, Susan C.

Abstract

We are using a systemic plague model to identify the cells and pathways that are undermined by the virulence protein YopM of the plague bacterium Yersinia pestis. In this study, we pursued previous findings that Gr1+cells are required to selectively limit growth of yopM Y. pestis and that CD11b+cells other than polymorphonuclear leukocytes (PMNs) are selectively lost in spleens infected with parent Y. pestis. When PMNs were ablated from mice, yopM Y. pestis grew as well as the parent strain in liver but not in spleen, showing that these cells are critical for controlling growth of the mutant in liver but not spleen. In mice lacking expression of the chemokine receptor CCR2, wild-type growth was restored to yopM Y. pestis in both organs. In spleen, the Gr1+cells differentially recruited by parent and yopM Y. pestis infections were CCR2+Gr1+CD11b+CD11cLo-IntMAC3+iNOS+(inducible nitric oxide synthase-positive) inflammatory dendritic cells (iDCs), and their recruitment to spleen from blood was blocked when YopM was present in the infecting strain. Consistent with influx of iDCs being affected by YopM in spleen, the growth defect of the yopM mutant was relieved by the parent Y. pestis strain in a coinfection assay in which the parent strain could affect the fate of the mutant in trans. In a mouse model of bubonic plague, CCR2 also was shown to be required for yopM Y. pestis to show wild-type growth in skin. The data imply that YopM's pathogenic effect indirectly undermines signaling through CCR2. We propose a model for how YopM exerts its different effects in liver and spleen.

Published

2010

7. Distinct CCR2+Gr1+Cells Control Growth of the Yersinia pestisΔyopMMutant in Liver and Spleen during Systemic Plague

Author

Ye, Zhan, Uittenbogaard, Annette M., Cohen, Donald A., Kaplan, Alan M., Ambati, Jayakrishna, and Straley, Susan C.

Abstract

ABSTRACTWe are using a systemic plague model to identify the cells and pathways that are undermined by the virulence protein YopM of the plague bacterium Yersinia pestis. In this study, we pursued previous findings that Gr1+cells are required to selectively limit growth of ΔyopM Y. pestisand that CD11b+cells other than polymorphonuclear leukocytes (PMNs) are selectively lost in spleens infected with parent Y. pestis. When PMNs were ablated from mice, ΔyopM Y. pestisgrew as well as the parent strain in liver but not in spleen, showing that these cells are critical for controlling growth of the mutant in liver but not spleen. In mice lacking expression of the chemokine receptor CCR2, wild-type growth was restored to ΔyopM Y. pestisin both organs. In spleen, the Gr1+cells differentially recruited by parent and ΔyopM Y. pestisinfections were CCR2+Gr1+CD11b+CD11cLo-IntMAC3+iNOS+(inducible nitric oxide synthase-positive) inflammatory dendritic cells (iDCs), and their recruitment to spleen from blood was blocked when YopM was present in the infecting strain. Consistent with influx of iDCs being affected by YopM in spleen, the growth defect of the ΔyopMmutant was relieved by the parent Y. pestisstrain in a coinfection assay in which the parent strain could affect the fate of the mutant in trans. In a mouse model of bubonic plague, CCR2 also was shown to be required for ΔyopM Y. pestisto show wild-type growth in skin. The data imply that YopM's pathogenic effect indirectly undermines signaling through CCR2. We propose a model for how YopM exerts its different effects in liver and spleen.

Published

2010

8. Gr1+Cells Control Growth of YopM-Negative Yersinia pestisduring Systemic Plague

Author

Ye, Zhan, Kerschen, Edward J., Cohen, Donald A., Kaplan, Alan M., van Rooijen, Nico, and Straley, Susan C.

Abstract

ABSTRACTYopM, a protein toxin of Yersinia pestis, is necessary for virulence in a mouse model of systemic plague. We previously reported YopM-dependent natural killer (NK) cell depletion from blood and spleen samples of infected mice. However, in this study we found that infection with Y. pestisKIM5 (YopM+) caused depletion of NK cells in the spleen, but not in the liver, and antibody-mediated ablation of NK cells had no effect on bacterial growth. There was no YopM-associated effect on the percentage of dendritic cells (DCs) or polymorphonuclear leukocytes (PMNs) in the early stage of infection; however, there was a YopM-associated effect on PMN integrity and on the influx of monocytes into the spleen. Ablation of Gr1+cells caused loss of the growth defect of YopM−Y. pestisin both the liver and spleen. In contrast, ablation of macrophages/DCs inhibited growth of both parent and mutant bacteria, accompanied by significantly fewer lesion sites in the liver. These results point toward PMNs and inflammatory monocytes as major cell types that control growth of YopM−Y. pestis. Infection with fully virulent Y. pestisCO92 and a YopM−derivative by intradermal and intranasal routes showed that the absence of YopM significantly increased the 50% lethal dose only in the intradermal model, suggesting a role for YopM in bubonic plague, in which acute inflammation occurs soon after infection.

Published

2009

9. Gr1+Cells Control Growth of YopM-Negative Yersinia pestis during Systemic Plague

Author

Ye, Zhan, Kerschen, Edward J., Cohen, Donald A., Kaplan, Alan M., van Rooijen, Nico, and Straley, Susan C.

Abstract

YopM, a protein toxin of Yersinia pestis, is necessary for virulence in a mouse model of systemic plague. We previously reported YopM-dependent natural killer (NK) cell depletion from blood and spleen samples of infected mice. However, in this study we found that infection with Y. pestis KIM5 (YopM+) caused depletion of NK cells in the spleen, but not in the liver, and antibody-mediated ablation of NK cells had no effect on bacterial growth. There was no YopM-associated effect on the percentage of dendritic cells (DCs) or polymorphonuclear leukocytes (PMNs) in the early stage of infection; however, there was a YopM-associated effect on PMN integrity and on the influx of monocytes into the spleen. Ablation of Gr1+cells caused loss of the growth defect of YopM–Y. pestis in both the liver and spleen. In contrast, ablation of macrophages/DCs inhibited growth of both parent and mutant bacteria, accompanied by significantly fewer lesion sites in the liver. These results point toward PMNs and inflammatory monocytes as major cell types that control growth of YopM–Y. pestis. Infection with fully virulent Y. pestis CO92 and a YopM–derivative by intradermal and intranasal routes showed that the absence of YopM significantly increased the 50% lethal dose only in the intradermal model, suggesting a role for YopM in bubonic plague, in which acute inflammation occurs soon after infection.

Published

2009

10. Anti-LcrV Antibody Inhibits Delivery of Yops by Yersinia pestisKIM5 by Directly Promoting Phagocytosis

Author

Cowan, Clarissa, Philipovskiy, Alexander V., Wulff-Strobel, Christine R., Ye, Zhan, and Straley, Susan C.

Abstract

ABSTRACTLcrV of Yersinia pestisis a major protective antigen proposed for inclusion in subunit plague vaccines. One way that anti-LcrV antibody is thought to protect is by inhibiting the delivery of toxins called Yops to host cells. The present study characterizes the relation between this inhibition and the phagocytosis of the bacteria. J774A.1 cells were infected with Y. pestisKIM5 in the presence of a protective polyclonal anti-LcrV antibody or a nonprotective polyclonal anti-YopM antibody, and delivery of YopH and YopE into the cytoplasm was assayed by immunoblotting. The ability to inhibit the delivery of these Yops depended upon having antibody bound to the cell surface; blocking conditions that prevented the binding of antibody to Fc receptors prevented the inhibition of Yop delivery. Anti-LcrV antibody also promoted phagocytosis of the yersiniae, whereas F(ab′)2fragments did not. Further, anti-LcrV antibody could not inhibit the delivery of Yops into cells that were unable to phagocytose due to the presence of cytochalasin D. However, Yops were produced only by extracellular yersiniae. We hypothesize that anti-LcrV antibody does not directly inhibit Yop delivery but instead causes phagocytosis, with consequent inhibition of Yop protein production in the intracellular yersiniae. The prophagocytic effect of anti-LcrV antibody extended to mouse polymorphonuclear neutrophils (PMNs) in vitro, and PMNs were shown to be critical for protection: when PMNs in mice were ablated, the mice lost all ability to be protected by anti-LcrV antibody.

Published

2005

11. Distinct CCR2(+) Gr1(+) cells control growth of the Yersinia pestis ΔyopM mutant in liver and spleen during systemic plague.

Author

Ye Z, Uittenbogaard AM, Cohen DA, Kaplan AM, Ambati J, and Straley SC

Subjects

Animals, Antigens, Ly genetics, Antigens, Ly metabolism, Bacterial Outer Membrane Proteins metabolism, CD11b Antigen metabolism, Disease Models, Animal, Female, Gene Expression Regulation, Liver microbiology, Mice, Mice, Inbred C57BL, Mutation, Neutrophils physiology, Receptors, CCR2 genetics, Receptors, Chemokine genetics, Skin microbiology, Spleen microbiology, Virulence, Yersinia pestis genetics, Yersinia pestis pathogenicity, Bacterial Outer Membrane Proteins genetics, Plague microbiology, Receptors, CCR2 metabolism, Receptors, Chemokine metabolism, Yersinia pestis growth & development

Abstract

We are using a systemic plague model to identify the cells and pathways that are undermined by the virulence protein YopM of the plague bacterium Yersinia pestis. In this study, we pursued previous findings that Gr1(+) cells are required to selectively limit growth of ΔyopM Y. pestis and that CD11b(+) cells other than polymorphonuclear leukocytes (PMNs) are selectively lost in spleens infected with parent Y. pestis. When PMNs were ablated from mice, ΔyopM Y. pestis grew as well as the parent strain in liver but not in spleen, showing that these cells are critical for controlling growth of the mutant in liver but not spleen. In mice lacking expression of the chemokine receptor CCR2, wild-type growth was restored to ΔyopM Y. pestis in both organs. In spleen, the Gr1(+) cells differentially recruited by parent and ΔyopM Y. pestis infections were CCR2(+) Gr1(+) CD11b(+) CD11c(Lo-Int) MAC3(+) iNOS(+) (inducible nitric oxide synthase-positive) inflammatory dendritic cells (iDCs), and their recruitment to spleen from blood was blocked when YopM was present in the infecting strain. Consistent with influx of iDCs being affected by YopM in spleen, the growth defect of the ΔyopM mutant was relieved by the parent Y. pestis strain in a coinfection assay in which the parent strain could affect the fate of the mutant in trans. In a mouse model of bubonic plague, CCR2 also was shown to be required for ΔyopM Y. pestis to show wild-type growth in skin. The data imply that YopM's pathogenic effect indirectly undermines signaling through CCR2. We propose a model for how YopM exerts its different effects in liver and spleen.

Published

2011

12. Gr1+ cells control growth of YopM-negative yersinia pestis during systemic plague.

Author

Ye Z, Kerschen EJ, Cohen DA, Kaplan AM, van Rooijen N, and Straley SC

Subjects

Animals, Antigens, Ly physiology, Bacterial Outer Membrane Proteins analysis, Dendritic Cells immunology, Female, Immunity, Innate, Killer Cells, Natural immunology, Liver immunology, Macrophages immunology, Mice, Mice, Inbred C57BL, Neutrophils immunology, Plague microbiology, Spleen immunology, Bacterial Outer Membrane Proteins physiology, Monocytes immunology, Plague immunology, Yersinia pestis growth & development

Abstract

YopM, a protein toxin of Yersinia pestis, is necessary for virulence in a mouse model of systemic plague. We previously reported YopM-dependent natural killer (NK) cell depletion from blood and spleen samples of infected mice. However, in this study we found that infection with Y. pestis KIM5 (YopM(+)) caused depletion of NK cells in the spleen, but not in the liver, and antibody-mediated ablation of NK cells had no effect on bacterial growth. There was no YopM-associated effect on the percentage of dendritic cells (DCs) or polymorphonuclear leukocytes (PMNs) in the early stage of infection; however, there was a YopM-associated effect on PMN integrity and on the influx of monocytes into the spleen. Ablation of Gr1(+) cells caused loss of the growth defect of YopM(-) Y. pestis in both the liver and spleen. In contrast, ablation of macrophages/DCs inhibited growth of both parent and mutant bacteria, accompanied by significantly fewer lesion sites in the liver. These results point toward PMNs and inflammatory monocytes as major cell types that control growth of YopM(-) Y. pestis. Infection with fully virulent Y. pestis CO92 and a YopM(-) derivative by intradermal and intranasal routes showed that the absence of YopM significantly increased the 50% lethal dose only in the intradermal model, suggesting a role for YopM in bubonic plague, in which acute inflammation occurs soon after infection.

Published

2009