Lynn Macdonald

High-throughput engineering of the mouse genome coupled withhigh-resolution expression analysis

One of the most effective approaches for determining gene function involves engineering mice with mutations or deletions in endogenous genes of interest. Historically, this approach has been limited by the difficulty and time required to generate such mice. We describe the development of a high-throughput and largely automated process, termed VelociGene, that uses targeting vectors based on bacterial artificial chromosomes (BACs). VelociGene permits genetic alteration with nucleotide precision, is not limited by the size of desired deletions, does not depend on isogenicity or on positive–negative selection, and can precisely replace the gene of interest with a reporter that allows for high-resolution localization of target-gene expression. We describe custom genetic alterations for hundreds of genes, corresponding to about 0.5–1.0% of the entire genome. We also provide dozens of informative expression patterns involving cells in the nervous system, immune system, vasculature, skeleton, fat and other tissues.*Note: In the author list of the AOP version of this article, the name of author Rostislav Chernomorsky was misspelled Rostislav Chernomorski. This has been corrected in the online and print versions of the article.

Hyperalgesia, synovitis and multiple biomarkers of inflammation are suppressed by interleukin 1 inhibition in a novel animal model of gouty arthritis

Background: Monosodium urate (MSU) and calcium pyrophosphate dihydrate (CPPD) crystal-induced interleukin 1 β (IL1β) release contributes to inflammation in subcutaneous air pouch and peritoneal models of acute gout and pseudogout. However, consequences of IL1 inhibition have not been explored in more clinically relevant models of crystal-induced arthritis. Objective: To develop a novel mouse model of acute gouty ankle arthritis and use it to assess the effects of genetic deletion of IL1 receptor type (IL1R1) and of exogenous mIL1 Trap (a high-affinity blocker of mouse IL1α and IL1β) on pain, synovitis and systemic inflammatory biomarkers. Methods: MSU crystals were injected into the mouse ankle joint and pain and ankle swelling were measured over 4 days. The effects of IL1 inhibition were determined in this model, and in the comparator models of crystal-induced peritonitis and subcutaneous air pouch inflammation. Results: Both IL1R1-null mice and mice pretreated with mIL1 Trap showed reduced neutrophil influx in MSU and CPPD crystal-induced peritonitis and air pouch models (p<0.05). In the ankle joint model, both IL1R1 knockout mice and pretreatment with mIL1 Trap were associated with significant reductions in MSU crystal-induced elevations in hyperalgesia, inflammation, serum amyloid A and the levels of multiple inflammatory cytokines and chemokines (p<0.05). Additionally, it was found that administration of mIL1 Trap after MSU crystal injection reduced established hyperalgesia and ankle swelling. Conclusions: IL1 inhibition both prevented and relieved pain and ankle joint inflammation in response to intra-articular MSU crystals in mice. Results suggested that IL1 Trap has the potential to both prevent and treat gouty arthritis.

Angiogenic sprouting into neural tissue requires Gpr124, an orphan G protein-coupled receptor

The vasculature of the CNS is structurally and functionally distinct from that of other organ systems and is particularly prone to developmental abnormalities and hemorrhage. Although other embryonic tissues undergo primary vascularization, the developing nervous system is unique in that it is secondarily vascularized by sprouting angiogenesis from a surrounding perineural plexus. This sprouting angiogenesis requires the TGF-β and Wnt pathways because ablation of these pathways results in aberrant sprouting and hemorrhage. We have genetically deleted Gpr124, a member of the large family of long N-terminal group B G protein-coupled receptors, few members of which have identified ligands or well-defined biologic functions in mammals. We show that, in the developing CNS, Gpr124 is specifically expressed in the vasculature and is absolutely required for proper angiogenic sprouting into the developing neural tube. Embryos lacking Gpr124 exhibit vascular defects characterized by delayed vascular penetration, formation of pathological glomeruloid tufts within the CNS, and hemorrhage. In addition, they display defects in palate and lung development, two processes in which TGF-β and/or Wnt pathways also play important roles. We also show that TGF-β stimulates Gpr124 expression, and ablation of Gpr124 results in perturbed TGF-β pathway activation, suggesting roles for Gpr124 in modulating TGF-β signaling. These results represent a unique function attributed to a long N-terminal group B–type G protein-coupled receptor in a mammalian system.

Mice with megabase humanization of their immunoglobulin genes generate antibodies as efficiently as normal mice

Significance The accompanying paper describes the precise, in situ replacement of six megabases of mouse immune genes with the corresponding human immune genes. This manuscript shows that this genomic engineering feat resulted in a unique kind of “HumAb” mouse. Dubbed VelocImmune, these mice efficiently generate antibodies that can be rapidly reformatted into therapeutics. VelocImmune mice have proven to be extraordinarily efficient and productive, generating over a dozen therapeutic candidates that have already progressed into human clinical trials for a variety of important diseases. Mice genetically engineered to be humanized for their Ig genes allow for human antibody responses within a mouse background (HumAb mice), providing a valuable platform for the generation of fully human therapeutic antibodies. Unfortunately, existing HumAb mice do not have fully functional immune systems, perhaps because of the manner in which their genetic humanization was carried out. Heretofore, HumAb mice have been generated by disrupting the endogenous mouse Ig genes and simultaneously introducing human Ig transgenes at a different and random location; KO-plus-transgenic humanization. As we describe in the companion paper, we attempted to make mice that more efficiently use human variable region segments in their humoral responses by precisely replacing 6 Mb of mouse Ig heavy and kappa light variable region germ-line gene segments with their human counterparts while leaving the mouse constant regions intact, using a unique in situ humanization approach. We reasoned the introduced human variable region gene segments would function indistinguishably in their new genetic location, whereas the retained mouse constant regions would allow for optimal interactions and selection of the resulting antibodies within the mouse environment. We show that these mice, termed VelocImmune mice because they were generated using VelociGene technology, efficiently produce human:mouse hybrid antibodies (that are rapidly convertible to fully human antibodies) and have fully functional humoral immune systems indistinguishable from those of WT mice. The efficiency of the VelocImmune approach is confirmed by the rapid progression of 10 different fully human antibodies into human clinical trials.

Precise and in situ genetic humanization of 6 Mb of mouse immunoglobulin genes

Significance This paper describes a major advance in genomic engineering, describing by far the largest genetic humanization of the mouse ever attempted. Six megabases of mouse immune genes were replaced in a precise manner and “in situ” (in the orthologous position) with the corresponding human immune genes using largechimeric bacterial artificial chromosome targeting vectors. The accompanying manuscript demonstrates that the engineered mice function with high efficiency and have already generated therapeutic candidates that have progressed into human trials. Genetic humanization, which involves replacing mouse genes with their human counterparts, can create powerful animal models for the study of human genes and diseases. One important example of genetic humanization involves mice humanized for their Ig genes, allowing for human antibody responses within a mouse background (HumAb mice) and also providing a valuable platform for the generation of fully human antibodies as therapeutics. However, existing HumAb mice do not have fully functional immune systems, perhaps because of the manner in which they were genetically humanized. Heretofore, most genetic humanizations have involved disruption of the endogenous mouse gene with simultaneous introduction of a human transgene at a new and random location (so-called KO-plus-transgenic humanization). More recent efforts have attempted to replace mouse genes with their human counterparts at the same genetic location (in situ humanization), but such efforts involved laborious procedures and were limited in size and precision. We describe a general and efficient method for very large, in situ, and precise genetic humanization using large compound bacterial artificial chromosome–based targeting vectors introduced into mouse ES cells. We applied this method to genetically humanize 3-Mb segments of both the mouse heavy and κ light chain Ig loci, by far the largest genetic humanizations ever described. This paper provides a detailed description of our genetic humanization approach, and the companion paper reports that the humoral immune systems of mice bearing these genetically humanized loci function as efficiently as those of WT mice.

Elements between the IgH variable (V) and diversity (D) clusters influence antisense transcription and lineage-specific V(D)J recombination

Ig and T-cell receptor (TCR) variable-region gene exons are assembled from component variable (V), diversity (D) and joining (J) gene segments during early B and T cell development. The RAG1/2 endonuclease initiates V(D)J recombination by introducing DNA double-strand breaks at borders of the germ-line segments. In mice, the Ig heavy-chain (IgH) locus contains, from 5′ to 3′, several hundred VH gene segments, 13 D segments, and 4 JH segments within a several megabase region. In developing B cells, IgH variable-region exon assembly is ordered with D to JH rearrangement occurring on both alleles before appendage of a VH segment. Also, IgH VH to DJH rearrangement does not occur in T cells, even though DJH rearrangements occur at low levels. In these contexts, V(D)J recombination is controlled by modulating substrate gene segment accessibility to RAG1/2 activity. To elucidate control elements, we deleted the 100-kb intergenic region that separates the VH and D clusters (generating ΔVH-D alleles). In both B and T cells, ΔVH-D alleles initiated high-level antisense and, at lower levels, sense transcription from within the downstream D cluster, with antisense transcripts extending into proximal VH segments. In developing T lymphocytes, activated germ-line antisense transcription was accompanied by markedly increased IgH D-to-JH rearrangement and substantial VH to DJH rearrangement of proximal IgH VH segments. Thus, the VH-D intergenic region, and likely elements within it, can influence silencing of sense and antisense germ-line transcription from the IgH D cluster and thereby influence targeting of V(D)J recombination.

Cutting Edge: FcγRIII (CD16) and FcγRI (CD64) Are Responsible for Anti-Glycoprotein 75 Monoclonal Antibody TA99 Therapy for Experimental Metastatic B16 Melanoma

mAb therapy for experimental metastatic melanoma relies on activating receptors for the Fc portion of IgG (FcγR). Opposing results on the respective contribution of mouse FcγRI, FcγRIII, and FcγRIV have been reported using the gp75-expressing B16 melanoma and the protective anti-gp75 mAb TA99. We analyzed the contribution of FcγRs to this therapy model using bioluminescent measurement of lung metastases loads, novel mouse strains, and anti-FcγR blocking mAbs. We found that the TA99 mAb-mediated effects in a combination therapy using cyclophosphamide relied on activating FcγRs. The combination therapy, however, was not more efficient than mAb therapy alone. We demonstrate that FcγRI and, unexpectedly, FcγRIII contributed to TA99 mAb therapeutic effects, whereas FcγRIV did not. Therefore, FcγRIII and FcγRI are, together, responsible for anti-gp75 mAb therapy of B16 lung metastases. Our finding that mouse FcγRIII contributes to Ab-induced tumor reduction correlates with clinical data on its human functional equivalent human FcγRIIIA (CD16A).

Mechanisms of anaphylaxis in human low-affinity IgG receptor locus knock-in mice.

Background: Anaphylaxis can proceed through distinct IgE‐ or IgG‐dependent pathways, which have been investigated in various mouse models. We developed a novel mouse strain in which the human low‐affinity IgG receptor locus, comprising both activating (hFc&ggr;RIIA, hFc&ggr;RIIIA, and hFc&ggr;RIIIB) and inhibitory (hFc&ggr;RIIB) hFc&ggr;R genes, has been inserted into the equivalent murine locus, corresponding to a locus swap. Objective: We sought to determine the capabilities of hFc&ggr;Rs to induce systemic anaphylaxis and identify the cell types and mediators involved. Methods: hFc&ggr;R expression on mouse and human cells was compared to validate the model. Passive systemic anaphylaxis was induced by injection of heat‐aggregated human intravenous immunoglobulin and active systemic anaphylaxis after immunization and challenge. Anaphylaxis severity was evaluated based on hypothermia and mortality. The contribution of receptors, mediators, or cell types was assessed based on receptor blockade or depletion. Results: The human‐to‐mouse low‐affinity Fc&ggr;R locus swap engendered hFc&ggr;RIIA/IIB/IIIA/IIIB expression in mice comparable with that seen in human subjects. Knock‐in mice were susceptible to passive and active anaphylaxis, accompanied by downregulation of both activating and inhibitory hFc&ggr;R expression on specific myeloid cells. The contribution of hFc&ggr;RIIA was predominant. Depletion of neutrophils protected against hypothermia and mortality. Basophils contributed to a lesser extent. Anaphylaxis was inhibited by platelet‐activating factor receptor or histamine receptor 1 blockade. Conclusion: Low‐affinity Fc&ggr;R locus‐switched mice represent an unprecedented model of cognate hFc&ggr;R expression. Importantly, IgG‐related anaphylaxis proceeds within a native context of activating and inhibitory hFc&ggr;Rs, indicating that, despite robust hFc&ggr;RIIB expression, activating signals can dominate to initiate a severe anaphylactic reaction.

Humanized mouse model supports development, function, and tissue residency of human natural killer cells

Significance Humanized mice represent a promising approach to study the human immune system in health and disease. However, insufficient development and function of human lymphocytes limit the applicability of humanized mice for cancer biology and therapy. We demonstrate that human SIRPA and IL15 knock-in (SRG-15) mice support efficient development of circulating and tissue-resident natural killer (NK) cells, intraepithelial lymphocytes, and innate lymphoid cell subsets. In contrast to previous humanized mouse models, human NK cells in SRG-15 mice mediate efficient antibody-dependent cellular cytotoxicity and thereby enable NK cell-targeted cancer immunotherapy of tumor xenografts. As such, SRG-15 humanized mice may facilitate translational research by enabling the development of novel NK and CD8+ T cell-based therapeutic approaches that target human infections and malignancies. Immunodeficient mice reconstituted with a human immune system represent a promising tool for translational research as they may allow modeling and therapy of human diseases in vivo. However, insufficient development and function of human natural killer (NK) cells and T cell subsets limit the applicability of humanized mice for studying cancer biology and therapy. Here, we describe a human interleukin 15 (IL15) and human signal regulatory protein alpha (SIRPA) knock-in mouse on a Rag2−/− Il2rg−/− background (SRG-15). Transplantation of human hematopoietic stem and progenitor cells into SRG-15 mice dramatically improved the development and functional maturation of circulating and tissue-resident human NK and CD8+ T cells and promoted the development of tissue-resident innate lymphoid cell (ILC) subsets. Profiling of human NK cell subsets by mass cytometry revealed a highly similar expression pattern of killer inhibitory receptors and other candidate molecules in NK cell subpopulations between SRG-15 mice and humans. In contrast to nonobese diabetic severe combined immunodeficient Il2rg−/− (NSG) mice, human NK cells in SRG-15 mice did not require preactivation but infiltrated a Burkitt’s lymphoma xenograft and efficiently inhibited tumor growth following treatment with the therapeutic antibody rituximab. Our humanized mouse model may thus be useful for preclinical testing of novel human NK cell-targeted and combinatory cancer immunotherapies and for studying how they elicit human antitumor immune responses in vivo.

Platelets expressing IgG receptor FcγRIIA/CD32A determine the severity of experimental anaphylaxis

Platelet-derived serotonin contributes to FcγRIIA/CD32A-induced IgG-dependent anaphylaxis. Potent platelets Anaphylaxis results from inappropriate immune responses to allergens. Human platelets express the IgG receptor FcγRIIA/CD32A and release inflammatory mediators in response to their engagement, but their contribution to anaphylaxis is not well understood. Beutier et al. developed mouse models that express either human FcγRIIA/CD32A alone or the full human IgG receptor complexity to understand the role of platelets in anaphylaxis. Anaphylaxis induced a marked decrease in platelet levels, but preventive platelet depletion reduced anaphylaxis severity. A clinical study of patients with drug-induced anaphylaxis revealed that a severe reaction was likewise associated with fewer circulating platelets. Activated platelets released serotonin, which contributed to anaphylaxis severity. These results reveal a critical role for platelets in IgG-mediated anaphylaxis. Platelets are key regulators of vascular integrity; however, their role in anaphylaxis, a life-threatening systemic allergic reaction characterized by the loss of vascular integrity and vascular leakage, remains unknown. Anaphylaxis is a consequence of inappropriate cellular responses triggered by antibodies to generally harmless antigens, resulting in a massive mediator release and rapidly occurring organ dysfunction. Human platelets express receptors for immunoglobulin G (IgG) antibodies and can release potent mediators, yet their contribution to anaphylaxis has not been previously addressed in mouse models, probably because mice do not express IgG receptors on platelets. We investigated the contribution of platelets to IgG-dependent anaphylaxis in human IgG receptor–expressing mouse models and a cohort of patients suffering from drug-induced anaphylaxis. Platelet counts dropped immediately and markedly upon anaphylaxis induction only when they expressed the human IgG receptor FcγRIIA/CD32A. Platelet depletion attenuated anaphylaxis, whereas thrombocythemia substantially worsened its severity. FcγRIIA-expressing platelets were directly activated by IgG immune complexes in vivo and were sufficient to restore susceptibility to anaphylaxis in resistant mice. Serotonin released by activated platelets contributed to anaphylaxis severity. Data from a cohort of patients suffering from drug-induced anaphylaxis indicated that platelet activation was associated with anaphylaxis severity and was accompanied by a reduction in circulating platelet numbers. Our findings identify platelets as critical players in IgG-dependent anaphylaxis and provide a rationale for the design of platelet-targeting strategies to attenuate the severity of anaphylactic reactions.