scholarly journals Mice with human immune system components as in vivo models for infections with human pathogens

2011 ◽  
Vol 89 (3) ◽  
pp. 408-416 ◽  
Author(s):  
Patrick C Rämer ◽  
Obinna Chijioke ◽  
Sonja Meixlsperger ◽  
Carol S Leung ◽  
Christian Münz
Blood ◽  
2010 ◽  
Vol 116 (20) ◽  
pp. 4158-4167 ◽  
Author(s):  
Till Strowig ◽  
Obinna Chijioke ◽  
Paolo Carrega ◽  
Frida Arrey ◽  
Sonja Meixlsperger ◽  
...  

Abstract To investigate human natural killer (NK)–cell reactivity in vivo we have reconstituted human immune system components by transplantation of human hematopoietic progenitor cells into NOD-scid IL2Rγnull mice. We demonstrate here that this model allows the development of all NK-cell subsets that are also found in human adult peripheral and cord blood, including NKp46+CD56− NK cells. Similar to human cord blood, NK cells from these reconstituted mice require preactivation by interleukin-15 to reach the functional competence of human adult NK cells. Mainly the terminally differentiated CD16+ NK cells demonstrate lower reactivity without this stimulation. After preactivation, both CD16+ and CD16− NK cells efficiently produce interferon-γ and degranulate in response to stimulation with NK cell–susceptible targets, including K562 erythroleukemia cells. NK-cell lines, established from reconstituted mice, demonstrate cytotoxicity against this tumor cell line. Importantly, preactivation can as well be achieved by bystander cell maturation via poly I:C stimulation in vitro and injection of this maturation stimulus in vivo. Preactivation in vivo enhances killing of human leukocyte antigen class I negative tumor cells after their adoptive transfer. These data suggest that a functional, but resting, NK-cell compartment can be established in immune-compromised mice after human hematopoietic progenitor cell transfer.


Vaccines ◽  
2020 ◽  
Vol 8 (1) ◽  
pp. 89 ◽  
Author(s):  
Johannes Koenig ◽  
Sebastian J. Theobald ◽  
Renata Stripecke

Human cytomegalovirus (HCMV or HHV-5) is a globally spread pathogen with strictly human tropism that establishes a life-long persistence. After primary infection, high levels of long-term T and B cell responses are elicited, but the virus is not cleared. HCMV persists mainly in hematopoietic reservoirs, whereby occasional viral reactivation and spread are well controlled in immunocompetent hosts. However, when the immune system cannot control viral infections or reactivations, such as with newborns, patients with immune deficiencies, or immune-compromised patients after transplantations, the lytic outbursts can be severely debilitating or lethal. The development of vaccines for immunization of immune-compromised hosts has been challenging. Several vaccine candidates did not reach the potency expected in clinical trials and were not approved. Before anti-HCMV vaccines can be tested pre-clinically in immune-compromised hosts, reliable in vivo models recapitulating HCMV infection might accelerate their clinical translation. Therefore, immune-deficient mouse strains implanted with human cells and tissues and developing a human immune system (HIS) are being explored to test anti-HCMV vaccines. HIS-mice resemble immune-compromised hosts as they are equipped with antiviral human T and B cells, but the immune reactivity is overall low. Several groups have independently shown that HCMV infections and reactivations can be mirrored in HIS mice. However, these models and the analyses employed varied widely. The path forward is to improve human immune reconstitution and standardize the analyses of adaptive responses so that HIS models can be forthrightly used for testing novel generations of anti-HCMV vaccines in the preclinical pipeline.


2021 ◽  
Vol 9 (Suppl 1) ◽  
pp. A22.1-A22
Author(s):  
C Reitinger ◽  
F Nimmerjahn

BackgroundRecent findings in cancer immunotherapy have reinforced the hypothesis that the immune system is able to control most cancers. Immunomodulatory antibodies can enhance immune responses, having the potential to generate anti-cancer immunity.1–4Materials and MethodsMost current studies addressing this question are performed in murine mouse model systems or use in vitro culture systems, which do not reflect the human in vivo situation, potentially leading to results that cannot be fully translated into human cancer therapy. Therefore, it is necessary to establish a new mouse model, which allows the study of cancer immunotherapy in the context of a human immune system. We focused on the establishment of a humanized mouse model, in which different immunomodulatory antibodies can be tested in the presence of a human immune system.ResultsFirst experiments concerning the suitability to test immunomodulatory antibodies in the humanized mouse model, revealed that effects of checkpoint-control antibody a-CTLA-4 were similar to the effects seen in patients of clinical studies. To analyse the anti-tumor activities of immunomodulatory antibodies in vivo we are establishing a human melanoma-like tumor model in humanized mice.ConclusionsThis enables us to test the efficacy of immunomodulatory agonistic antibodies (such as CP-870,893) and checkpoint control antibodies (such as anti-CTLA-4) in eliminating a melanoma-like tumor. Furthermore, parameters like tumor infiltrating human cells und cytokine/chemokine production can be analysed.ReferencesSchuster M, Nechansky A, Loibner H. Cancer immunotherapy. Biotechnol J 2006;1:138–147.Mellman I, Coukos G, Dranoff G. Cancer immunotherapy comes of age. Nature rev 2011;480:480–489.Finn OJ. Immuno-oncology: understanding the function and dysfunction of the immune system in cancer. Annals of Oncology 2012;23:vii6–vii9.Langer LF, Clay TM, Morse MA. Update on anti-CTLA-4 in clinical trials. Expert Opin Biol Ther 2007;8:1245–1256.Disclosure InformationC. Reitinger: None. F. Nimmerjahn: None.


Vaccine ◽  
2017 ◽  
Vol 35 (45) ◽  
pp. 6143-6153 ◽  
Author(s):  
Liang Cheng ◽  
Zheng Zhang ◽  
Guangming Li ◽  
Feng Li ◽  
Li Wang ◽  
...  

2019 ◽  
Author(s):  
Lance Daharsh ◽  
Amanda E. Ramer-Tait ◽  
Qingsheng Li

AbstractBackgroundHumanized mice featuring a functional human immune system are an important pre-clinical model for examining immune responses to human-specific pathogens. This model has been widely utilized to study human diseases that are otherwise impossible or difficult to investigate in humans or with other animal models. However, one limitation of using humanized mice is their native murine gut microbiome, which significantly differs from the one found in humans. These differences may be even greater for mice housed and bred in specific pathogen free conditions. Given the importance of the gut microbiome to human health and disease, these differences may profoundly impact the ability to translate the results from humanized mice studies to human disease. Further, there is a critical need for improved pre-clinical models to study the complex in vivo relationships of the gut microbiome, immune system, and human disease. We therefore created double humanized mice with both a functional human immune system and stable human-like gut microbiome.ResultsSurgery was performed on NOD.Cg-PrkdcscidII2rgtm1Wjl/SzJ (NSG) mice to create bone-marrow, liver, thymus (BLT) humanized mice. After immune reconstitution, mice were treated with broad spectrum antibiotics to deplete murine gut bacteria and then transplanted with fecal material from healthy human donors. Characterization of 173 fecal samples obtained from 45 humanized mice revealed that double humanized mice had unique 16S rRNA gene profiles consistent with those of the individual human donor samples. Importantly, transplanted human-like gut microbiomes were stable in mice for the duration of the study, up to 14.5 weeks post-transplant. Microbiomes of double humanized mice also harbored predicted functional capacities that more closely resembled those of the human donors compared to humanized mice.ConclusionsHere, we describe successful engraftment of a stable human microbiome in BLT humanized mice to further improve this preclinical humanized mouse model. These double humanized mice represent a unique and tractable new model to study the complex relationships between the human gut microbiome, human immune system, and human disease in vivo.


2021 ◽  
Vol 12 ◽  
Author(s):  
Tijana Martinov ◽  
Kelly M. McKenna ◽  
Wei Hong Tan ◽  
Emily J. Collins ◽  
Allie R. Kehret ◽  
...  

Since the late 1980s, mice have been repopulated with human hematopoietic cells to study the fundamental biology of human hematopoiesis and immunity, as well as a broad range of human diseases in vivo. Multiple mouse recipient strains have been developed and protocols optimized to efficiently generate these “humanized” mice. Here, we review three guiding principles that have been applied to the development of the currently available models: (1) establishing tolerance of the mouse host for the human graft; (2) opening hematopoietic niches so that they can be occupied by human cells; and (3) providing necessary support for human hematopoiesis. We then discuss four remaining challenges: (1) human hematopoietic lineages that poorly develop in mice; (2) limited antigen-specific adaptive immunity; (3) absent tolerance of the human immune system for its mouse host; and (4) sub-functional interactions between human immune effectors and target mouse tissues. While major advances are still needed, the current models can already be used to answer specific, clinically-relevant questions and hopefully inform the development of new, life-saving therapies.


Blood ◽  
2006 ◽  
Vol 108 (2) ◽  
pp. 487-492 ◽  
Author(s):  
Ping Lan ◽  
Noriko Tonomura ◽  
Akira Shimizu ◽  
Shumei Wang ◽  
Yong-Guang Yang

Studies of the human immune system have been limited by the lack of an appropriate in vivo model. For this reason, efforts have been made to develop murine models with a functional human immune system. We report here that cotransplantation of human fetal thymus/liver tissues and CD34+ hematopoietic stem/progenitor cells led to the development of sustained human hematopoiesis and a functional human immune system in immunodeficient NOD/SCID mice. The humanized mice showed systemic repopulation with a comprehensive array of human lymphohematopoietic cells, including T cells, B cells, and dendritic cells, and the formation of secondary lymphoid organs. Furthermore, these mice produce high levels of human IgM and IgG antibodies and mediate strong immune responses in vivo as demonstrated by skin xenograft rejection. Thus, the humanized NOD/SCID mice described in this paper provide a powerful model system to study human immune function.


Blood ◽  
2008 ◽  
Vol 111 (8) ◽  
pp. 4293-4296 ◽  
Author(s):  
Noriko Tonomura ◽  
Katsuyoshi Habiro ◽  
Akira Shimizu ◽  
Megan Sykes ◽  
Yong-Guang Yang

Abstract Humanized mice with a functional human immune system would be very useful for in vivo studies of human immunobiology. We have previously shown that cotransplantation of human fetal thymus/liver tissues and CD34+ fetal liver cells into immunodeficient nonobese diabetic severe combined immunodeficiency (NOD/SCID) mice leads to the development of multiple lineages of human lymphohematopoietic cells and formation of secondary lymphoid organs with normal architecture. Here, we evaluated the ability of these humanized mice to develop antigen-specific, T cell–dependent antibody responses after in vivo immunization with T-dependent antigen, 2,4-dinitrophenyl hapten-keyhole limpet hemocyanin (DNP23-KLH). Human T cells from DNP23-KLH–immunized mice showed strong proliferation in response to KLH in vitro. Furthermore, T cell–dependent production of DNP-specific human antibodies (mainly IgG1 and IgG2) was detected in all immunized mice. These results confirm that a functional human immune system can be established in immunodeficient mice through cotransplantation of human fetal thymus/liver tissues and CD34+ hematopoietic stem/progenitor cells.


Blood ◽  
2021 ◽  
Vol 138 (Supplement 1) ◽  
pp. 2406-2406
Author(s):  
Giorgia Zanetti ◽  
Giuseppina Astone ◽  
Luca Cappelli ◽  
William Chiu ◽  
Maria Teresa Cacciapuoti ◽  
...  

Abstract Introduction: Immunotherapy is a promising therapeutic intervention for cancer treatment. Activation of the immune system via checkpoint blockade has been shown to produce antitumor responses in patients with both solid and hematological tumors. However, many patients do not respond to checkpoint inhibitors, and additional therapies are needed to treat these patients. Testing immunotherapies requires a functional human immune system; thus, it is difficult to evaluate their effectiveness using conventional experimental models. For this reason, establishing in vivo models that closely reproduce not only human tumors, but also their interactions with the human immune system, has become mandatory. Methods: We developed a humanized mouse model and combined it with a patient-derived tumor xenograft (PDTX). Humanized mice (HuMice) were generated by transplantation of cord blood or mobilized peripheral blood CD34+ hematopoietic stem and progenitor cells into preconditioned immunodeficient mice. We compared human engraftment in 3 different mouse strains: NSG (NOD.Cg-Prkdc scidIl2rg tm1Wjl/SzJ), NSGS (NOD.Cg-Prkdc scidIl2rg tm1Wjl Tg(CMV-IL3,CSF2,KITLG)1Eav/MloySzJ) and NBSGW (NOD.Cg-Kit W-41J Tyr + Prkdc scid Il2rg tm1Wjl/ThomJ). Immune cell profiling and distribution was performed using flow cytometry and immunohistochemistry. The B cell receptor (BCR) repertoire was evaluated using an RNA-based NGS assay. To evaluate the maturation and functionality of T cells developing in HuMice we performed proliferation, degranulation and intracellular cytokine staining. Results: Two months after CD34+ cell transplantation, we observed high levels of human hematopoietic chimerism in all the 3 strains. NSGS mice supported high-level chimerism as early as 1 month after transplantation, with more than 25% of human CD45+ cells in the blood. In all mice the majority of human circulating leukocytes were CD19+ B cells. An early appearance of CD3+ human T cells was detected in NSGS mice as compared to the other strains. Notably, the T cell expansion correlated with a decrease in relative B cell abundance while the myeloid cell contribution to the graft remained steady. We documented the differentiation of CD4+ and CD8+ human T cells at a 2:1 ratio. The characterization of the T cell subsets revealed that the majority was represented by CD45RA-CCR7- effector memory cells in both the spleen and the blood of HuMice. Nevertheless, recipient mice did not exhibit overt signs of graft-versus-host disease. We also evaluated the cytotoxic potential of T cells isolated from the spleen of HuMice: ex vivo peptide antigen (i.e. EBV) presentation let to generation of effective and specific cytotoxic T-cells. After assessing a functional human immune system reconstitution in HuMice, we challenged them in vivo with low-passage tumor fragments from a diffuse large B cell lymphoma (DLBCL) PDTX. All tumor implants were successfully engrafted in both HuMice and non-humanized controls. Remarkably, all the 3 HuMice strains showed a significant reduction in the tumor volume and/or eradication compared to matched non-humanized controls. Flow cytometry analysis of the peripheral blood of humanized PDTX revealed that the tumor engraftment elicited a significant expansion of CD3+ T cells and cytotoxic CD8+ lymphocytes. Moreover, tumors developing in HuMice exhibited intermediate to high levels of tumor infiltrating T lymphocytes commingling with the neoplastic B cells, as determined by immunohistochemistry. Large areas of necrosis were often observed in PDTX of HuMice. Infiltrating CD3+ cells were TIGIT, PD-1 and Lag-3 positive, and did not efficiently proliferate ex vivo: all features consistent with an exhaustion phenotype. PDTX of HuMice often displayed larger areas of necrosis. Conclusions: Collectively, our data demonstrate that a robust reconstitution can be achieved in different strains of immunocompromised mice and that HuMice elicit effective anti-lymphoma responses. PDTX HuMice represent a powerful platform to study host-tumor interactions, and to test novel immune-based strategies (CAR-T, bifunctional Abs) and new pharmacological approaches to counteract T-cell exhaustion. Figure 1 Figure 1. Disclosures Scandura: Abbvie: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding; Constellation: Research Funding; MPN-RF (Foundation): Research Funding; CR&T (Foudation): Research Funding; European Leukemia net: Honoraria, Other: travel fees . Roth: Janssen: Consultancy; Merck: Consultancy.


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