Research Article
Abstract
The microRNA (miRNA) processing enzyme Dicer1 is required for zygotic and embryonic development, but the early embryonic lethality of Dicer1 null alleles in mice has limited our ability to address the role of Dicer1 in normal mouse growth and development. To address this question, we used a mouse mutant with a hypomorphic Dicer1 allele (Dicerd/d) and found that Dicer1 deficiency resulted in female infertility. This defect in female Dicerd/d mice was caused by corpus luteum (CL) insufficiency and resulted, at least in part, from the impaired growth of new capillary vessels in the ovary. We found that the impaired CL angiogenesis in Dicerd/d mice was associated with a lack of miR17-5p and let7b, 2 miRNAs that participate in angiogenesis by regulating the expression of the antiangiogenic factor tissue inhibitor of metalloproteinase 1. Furthermore, injection of miR17-5p and let7b into the ovaries of Dicerd/d mice partially normalized tissue inhibitor of metalloproteinase 1 expression and CL angiogenesis. Our data indicate that the development and function of the ovarian CL is a physiological process that appears to be regulated by miRNAs and requires Dicer1 function.
Authors
Motoyuki Otsuka, Min Zheng, Masaaki Hayashi, Jing-Dwan Lee, Osamu Yoshino, Shengcai Lin, Jiahuai Han
Abstract
Congenital myasthenias (CMs) arise from defects in neuromuscular junction–associated proteins. Deciphering the molecular bases of the CMs is required for therapy and illuminates structure-function relationships in these proteins. Here, we analyze the effects of a mutation in 1 of 4 homologous subunits in the AChR from a CM patient, a Leu to Pro mutation at position 42 of the δ subunit. The mutation is located in a region of contact between subunits required for rapid opening of the AChR channel and impedes the rate of channel opening. Substitutions of Gly, Lys, or Asp for δL42, or substitutions of Pro along the local protein chain, also slowed channel opening. Substitution of Pro for Leu in the ε subunit slowed opening, whereas this substitution had no effect in the β subunit and actually sped opening in the α subunit. Analyses of energetic coupling between residues at the subunit interface showed that δL42 is functionally linked to αT127, a key residue in the adjacent α subunit required for rapid channel opening. Thus, δL42 is part of an intersubunit network that enables ACh binding to rapidly open the AChR channel, which may be compromised in patients with CM.
Authors
Xin-Ming Shen, Taku Fukuda, Kinji Ohno, Steven M. Sine, Andrew G. Engel
Abstract
The molecular pathogenesis of pediatric astrocytomas is still poorly understood. To further understand the genetic abnormalities associated with these tumors, we performed a genome-wide analysis of DNA copy number aberrations in pediatric low-grade astrocytomas by using array-based comparative genomic hybridization. Duplication of the BRAF protooncogene was the most frequent genomic aberration, and tumors with BRAF duplication showed significantly increased mRNA levels of BRAF and a downstream target, CCND1, as compared with tumors without duplication. Furthermore, denaturing HPLC showed that activating BRAF mutations were detected in some of the tumors without BRAF duplication. Similarly, a marked proportion of low-grade astrocytomas from adult patients also had BRAF duplication. Both the stable silencing of BRAF through shRNA lentiviral transduction and pharmacological inhibition of MEK1/2, the immediate downstream phosphorylation target of BRAF, blocked the proliferation and arrested the growth of cultured tumor cells derived from low-grade gliomas. Our findings implicate aberrant activation of the MAPK pathway due to gene duplication or mutation of BRAF as a molecular mechanism of pathogenesis in low-grade astrocytomas and suggest inhibition of the MAPK pathway as a potential treatment.
Authors
Stefan Pfister, Wibke G. Janzarik, Marc Remke, Aurélie Ernst, Wiebke Werft, Natalia Becker, Grischa Toedt, Andrea Wittmann, Christian Kratz, Heike Olbrich, Rezvan Ahmadi, Barbara Thieme, Stefan Joos, Bernhard Radlwimmer, Andreas Kulozik, Torsten Pietsch, Christel Herold-Mende, Astrid Gnekow, Guido Reifenberger, Andrey Korshunov, Wolfram Scheurlen, Heymut Omran, Peter Lichter
Abstract
Current anticancer therapy is a delicate balance between elimination of malignant cells and harmful side effects for the host. In this study, we used a tumor-homing peptide to engineer anti-CD40 agonist antibodies and recombinant IL-2 such that they were selectively delivered into spontaneously arising tumors in a transgenic mouse model of islet cell carcinogenesis. Intravenous injection of these agents, either separately or together, led to accumulation in the vicinity of tumor neovessels without toxic side effects. Although both molecules are critical for adaptive immunity, the most profound effects were seen in endothelial cells. Combined, local anti-CD40 and IL-2 therapy reduced tumor vascularity and significantly delayed tumor growth in mice. Remarkably, tumor-bearing mice remained disease-free long-term when targeted anti-CD40 and IL-2 were combined with transfers of preactivated antitumor immune cells. In this therapeutic setting, triggering of CD40 on endothelial cells induced an inflammatory response of the vessel wall and facilitated effector cell accumulation in the tumor parenchyma while IL-2 promoted antigen-specific immune cell persistence. We believe this is a novel and highly effective anticancer approach, whereby tumor stroma is “conditioned” for enhanced immune cell entry and survival, facilitating immune-mediated tumor destruction and leading to a sustained antitumor response.
Authors
Juliana Hamzah, Delia Nelson, Gerd Moldenhauer, Bernd Arnold, Günter J. Hämmerling, Ruth Ganss
Abstract
The pathogenic nature of cancer is attributed, at least in part, to the ability of tumors cells to induce systemic and local mechanisms of immune tolerance. However, we previously reported that tumor-free survival in up to 100% of tolerized HER-2/neu transgenic mice can be achieved by administration of neu-specific mAb concurrently with a HER-2/neu–expressing, GM-CSF–secreting whole cell vaccine. In this report, we show that one mechanism of improved antitumor activity induced by the combination of these 2 neu-targeted interventions was enhanced Fc-mediated activation of APCs. Specifically, in vivo studies demonstrated localization of radiolabeled neu-specific mAb at the vaccine site. Subsequently, increased accumulation of neu-specific mAb at the vaccine-draining lymph node correlated with increased vaccine cell uptake by DCs in vivo. This led to enhancement of CD8+ neu-specific T cell function in terms of proliferation, cytokine production, and central memory development. Thus, the administration of a neu-specific mAb with a neu-targeted GM-CSF–secreting tumor vaccine enhanced induction of neu-specific CD8+ T cells through Fc-mediated activation of DCs. This multimodality attack on the same tumor antigen may have the potential to overcome tolerance to self antigens and weaken the immunosuppressive networks within the tumor microenvironment.
Authors
Peter S. Kim, Todd D. Armstrong, Hong Song, Matthew E. Wolpoe, Vivian Weiss, Elizabeth A. Manning, Lan Qing Huang, Satoshi Murata, George Sgouros, Leisha A. Emens, R. Todd Reilly, Elizabeth M. Jaffee
Abstract
Poxviruses such as the causative agent of smallpox have developed multiple strategies to suppress immune responses, including the suppression of DC activation. Since poxviruses are large DNA viruses, we hypothesized that their detection by DCs may involve the endosomal DNA recognition receptor TLR9. Indeed, we have shown here that DC recognition of ectromelia virus (ECTV), the causative agent of mousepox, completely depended on TLR9. The importance of TLR9 was highlighted by the fact that mice lacking TLR9 showed drastically increased susceptibility to infection with ECTV. In contrast, we found that the strongly attenuated poxvirus modified vaccinia virus Ankara (MVA) activated DCs by both TLR9-dependent and -independent pathways. We therefore tested whether we could use the broader induction of immune responses by MVA to protect mice from a lethal infection with ECTV. Indeed, MVA given at the same time as a lethal dose of ECTV protected mice from death. Importantly, MVA also rescued TLR9-deficient mice if administered 2 full days after an otherwise lethal infection with ECTV. Therefore, these data suggest an essential role for TLR9 in the defense against poxviruses. In addition, postexposure application of MVA may protect against lethal poxvirus infection.
Authors
Christofer Samuelsson, Jürgen Hausmann, Henning Lauterbach, Michaela Schmidt, Shizuo Akira, Hermann Wagner, Paul Chaplin, Mark Suter, Meredith O’Keeffe, Hubertus Hochrein
Abstract
Sensory neurons in the airways are finely tuned to respond to reactive chemicals threatening airway function and integrity. Nasal trigeminal nerve endings are particularly sensitive to oxidants formed in polluted air and during oxidative stress as well as to chlorine, which is frequently released in industrial and domestic accidents. Oxidant activation of airway neurons induces respiratory depression, nasal obstruction, sneezing, cough, and pain. While normally protective, chemosensory airway reflexes can provoke severe complications in patients affected by inflammatory airway conditions like rhinitis and asthma. Here, we showed that both hypochlorite, the oxidizing mediator of chlorine, and hydrogen peroxide, a reactive oxygen species, activated Ca2+ influx and membrane currents in an oxidant-sensitive subpopulation of chemosensory neurons. These responses were absent in neurons from mice lacking TRPA1, an ion channel of the transient receptor potential (TRP) gene family. TRPA1 channels were strongly activated by hypochlorite and hydrogen peroxide in primary sensory neurons and heterologous cells. In tests of respiratory function, Trpa1–/– mice displayed profound deficiencies in hypochlorite- and hydrogen peroxide–induced respiratory depression as well as decreased oxidant-induced pain behavior. Our results indicate that TRPA1 is an oxidant sensor in sensory neurons, initiating neuronal excitation and subsequent physiological responses in vitro and in vivo.
Authors
Bret F. Bessac, Michael Sivula, Christian A. von Hehn, Jasmine Escalera, Lauren Cohn, Sven-Eric Jordt
Abstract
Intravenous infusion of recombinant human activated Factor VII (FVIIa) has been used for over a decade in the successful management of bleeding episodes in patients with inhibitory antibodies to Factor VIII or Factor IX. Previously, we showed that expression of murine FVIIa (mFVIIa) from an adeno-associated viral (AAV) vector corrected abnormal hemostatic parameters in hemophilia B mice. To pursue this as a therapeutic approach, we sought to define safe and effective levels of FVIIa for continuous expression. In mice transgenic for mFVIIa or injected with AAV-mFVIIa, we analyzed survival, expression levels, in vitro and in vivo coagulation tests, and histopathology for up to 16 months after birth/mFVIIa expression. We found that continuous expression of mFVIIa at levels at or below 1.5 μg/ml was safe, effective, and compatible with a normal lifespan. However, expression levels of 2 μg/ml or higher were associated with thrombosis and early mortality, with pathologic findings in the heart and lungs that were rescued in a low–factor X (low-FX) mouse background, suggesting a FX-mediated effect. The findings from these mouse models of continuous FVIIa expression have implications for the development of a safe gene transfer approach for hemophilia and are consistent with the possibility of thromboembolic risk of continuously elevated FVIIa levels.
Authors
Majed N. Aljamali, Paris Margaritis, Alexander Schlachterman, Shing Jen Tai, Elise Roy, Ralph Bunte, Rodney M. Camire, Katherine A. High
Abstract
HBV-specific CD8+ T cells are critical for a successful immune response to HBV infection. They are markedly diminished in number in patients who fail to control the virus, but the mechanisms resulting in their depletion remain ill defined. Here, we dissected the defective HBV-specific CD8+ T cell response associated with chronic HBV infection by gene expression profiling. We found that HBV-specific CD8+ T cells from patients with different clinical outcomes could be distinguished by their patterns of gene expression. Microarray analysis revealed that overlapping clusters of functionally related apoptotic genes were upregulated in HBV-specific CD8+ T cells from patients with chronic compared with resolved infection. Further analysis confirmed that levels of the proapoptotic protein Bcl2-interacting mediator (Bim) were upregulated in HBV-specific CD8+ T cells from patients with chronic HBV infection. Blocking Bim-mediated apoptosis enhanced recovery of HBV-specific CD8+ T cells both in culture and directly ex vivo. Consistent with evidence that Bim mediates apoptosis of CD8+ T cells expressing low levels of CD127 (IL-7R), the few surviving HBV-specific CD8+ T cells were CD127hi and had elevated levels of the antiapoptotic protein Mcl1, suggesting they were amenable to IL-7–mediated rescue from apoptosis. We therefore postulate that Bim-mediated attrition of HBV-specific CD8+ T cells contributes to the inability of these cell populations to persist and control viral replication.
Authors
A. Ross Lopes, Paul Kellam, Abhishek Das, Claire Dunn, Antonia Kwan, Joanna Turner, Dimitra Peppa, Richard J. Gilson, Adam Gehring, Antonio Bertoletti, Mala K. Maini
Abstract
Platelet adhesion to vascular subendothelium, mediated in part by interactions between collagen and glycoprotein VI (GPVI) complexed with Fc receptor γ-chain, is crucial for thrombus formation. Antiplatelet therapy benefits patients with various thrombotic and ischemic diseases, but the safety and efficacy of existing treatments are limited. Recent data suggest GPVI as a promising target for a novel antiplatelet therapy, for example, GPVI-specific Abs that deplete GPVI from the surface of platelets. Here, we characterized GPVI-specific auto-Abs (YA-Abs) from the first reported patient with ongoing platelet GPVI deficiency caused by the YA-Abs. To obtain experimentally useful human GPVI–specific mAbs with characteristics similar to YA-Abs, we generated human GPVI–specific mouse mAbs and selected 2 representative mAbs, mF1201 and mF1232, whose binding to GPVI was inhibited by YA-Abs. In vitro, mF1201, but not mF1232, induced human platelet activation and GPVI shedding, and mF1232 inhibited collagen-induced human platelet aggregation. Administration of mF1201 and mF1232 to monkeys caused GPVI immunodepletion with and without both significant thrombocytopenia and GPVI shedding, respectively. When a human/mouse chimeric form of mF1232 (cF1232) was labeled with a fluorescent endocytosis probe and administered to monkeys, fluorescence increased in circulating platelets and surface GPVI was lost. Loss of platelet surface GPVI mediated by cF1232 was successfully reproduced in vitro in the presence of a cAMP-elevating agent. Thus, we have characterized cAMP-dependent endocytosis of GPVI mediated by a human GPVI–specific mAb as what we believe to be a novel antiplatelet therapy.
Authors
Hiroshi Takayama, Yoshitaka Hosaka, Kazuyuki Nakayama, Kamon Shirakawa, Katsuki Naitoh, Tomokazu Matsusue, Mikihiko Shinozaki, Motoyasu Honda, Yukiko Yatagai, Tetsushi Kawahara, Jiro Hirose, Tooru Yokoyama, Michiru Kurihara, Shoji Furusako
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ISSN: 0021-9738 (print), 1558-8238 (online)