Drug-regulated CD33-targeted CAR T cells control AML using clinically optimized rapamycin dosing

Chimeric antigen receptor (CAR) designs that incorporate pharmacologic control are desirable; however, designs suitable for clinical translation are needed. We designed a fully human, rapamycin-regulated drug product for targeting CD33+ tumors called dimerizaing agent-regulated immunoreceptor complex (DARIC33). T cell products demonstrated target-specific and rapamycin-dependent cytokine release, transcriptional responses, cytotoxicity, and in vivo antileukemic activity in the presence of as little as 1 nM rapamycin. Rapamycin withdrawal paused DARIC33-stimulated T cell effector functions, which were restored following reexposure to rapamycin, demonstrating reversible effector function control. While rapamycin-regulated DARIC33 T cells were highly sensitive to target antigen, CD34+ stem cell colony-forming capacity was not impacted. We benchmarked DARIC33 potency relative to CD19 CAR T cells to estimate a T cell dose for clinical testing. In addition, we integrated in vitro and preclinical in vivo drug concentration thresholds for off-on state transitions, as well as murine and human rapamycin pharmacokinetics, to estimate a clinically applicable rapamycin dosing schedule. A phase I DARIC33 trial has been initiated (PLAT-08, NCT05105152), with initial evidence of rapamycin-regulated T cell activation and antitumor impact. Our findings provide evidence that the DARIC platform exhibits sensitive regulation and potency needed for clinical application to other important immunotherapy targets.

Abstract 581: bbT369, a dual-targeted and CBLB gene-edited autologous CART product, demonstrates anti-lymphoma activity in preclinical mouse models

Anti-CD19 CAR T cell therapies have improved outcomes for non-Hodgkin lymphoma (NHL) patients. However, only 30-40% of patients treated with commercially available CART cell therapies obtain long term remission, highlighting the need for more efficacious and durable therapies. Emerging clinical data suggest several failure modes for CD19 CAR T cell therapies: including loss or downregulation of CD19 antigen, loss of co-stimulation pathways on tumor cells, exhaustion of CAR-T cells, and immunosuppressive microenvironments. To overcome these hurdles, we devised the next-generation autologous CAR-T cell therapy bbT369. bbT369 is dual targeted (CD79a/CD20) CAR T cell therapy that uses an OR gate design to limit antigen escape, has split 41BB and CD28 co-stimulatory domain architecture to augment T cell activation, and contains a knock-out of the CBLB gene to enhance potency and reduce T cell exhaustion. Here we report the first results with bbT369, demonstrating anti-lymphoma activity in in vitro assays and in vivo using xenograft mouse models.

We demonstrate that CD79a and CD20 expression is B cell lineage restricted in normal human tissue and confirm that these proteins are co-expressed in diffuse large B cell samples. To target these antigens, we show a split dual-targeting CAR configuration is optimal for bbT369-directed tumor cell killing. Using an engineered megaTAL, we demonstrate high on-target activity of greater than 75% insertions and deletions (Indels) at the CBLB target site using clinical-scale manufacturing processes and low off-target activity (all off-targets less than 0.2%). In in vitro tumor co-culture assays, we show that inclusion of the CBLB gene edit in bbT369 increases Interleukin (IL)-2 production relative to an unedited anti-CD79a/CD20 CAR T cell control. Using various xenograft mouse models, we showed that bbT369 has similar or improved efficacy compared to anti-CD19 CAR drug product, including in low tumor-antigen models. In the Toledo subcutaneous xenograft model, bbT369 showed a 3-fold increase in T cell expansion compared with an unedited anti-CD79a/CD20 dual-targeting CAR T cell control. Furthermore, while a fraction of mice (3/5) receiving the unedited anti-CD79a/CD20 dual-targeting CAR T cells experienced late relapses (between 60-80 days following initial tumor clearance), all mice (n=5) receiving bbT369 were fully protected from late relapses (up to day 104 of follow-up). Collectively, the data support a first-in-human trial for bbT369 to evaluate initial safety and efficacy in NHL patients.

Citation Format: Michael Certo, Christopher Baldeviano, Sharlene Adams, Martin Asimis, Alexander Astrakhan, Andy Chavkin, Maria L. Cabral, Jimmy Chu, Marie Debrue, Devina Desai, John Evans, Pinky Htun, Amanda Iniguez, Jordan Jarjour, Carl Johnson, Harini Kantamneni, Sema Kurtulus, Michael Magee, Unja Martin, Seamus McKenney, Sara Miller, Prashant Nambiar, Vinh Khang Nguyen, Mauris Nnamani, Jen Obrigewitch, Lisa Pechilis, Molly Perkins, Christopher Petersen, Jason Pinger, Cindy Rogers, Nick Rouillard, Kendal Sanson, Emily Thompson, Collin Walter, Roslyn Yi, Sarah Voytek, Philip Gregory. bbT369, a dual-targeted and CBLB gene-edited autologous CART product, demonstrates anti-lymphoma activity in preclinical mouse models [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 581.

Sensitive and adaptable pharmacological control of CAR T cells through extracellular receptor dimerization

Chimeric antigen receptor (CAR) T cell therapies have achieved promising outcomes in several cancers, however more challenging oncology indications may necessitate advanced antigen receptor designs and functions. Here we describe a bipartite receptor system comprised of separate antigen targeting and signal transduction polypeptides, each containing an extracellular dimerization domain. We demonstrate that T cell activation remains antigen dependent but can only be achieved in the presence of a dimerizing drug, rapamycin. Studies performed in vitro and in xenograft mouse models illustrate equivalent to superior anti-tumor potency compared to currently used CAR designs, and at rapamycin concentrations well below immunosuppressive levels. We further show that the extracellular positioning of the dimerization domains enables the administration of recombinant re-targeting modules, potentially extending antigen targeting. Overall, this novel regulatable CAR design has exquisite drug sensitivity, provides robust anti-tumor responses, and is uniquely flexible for multiplex antigen targeting or retargeting, which may further assist the development of safe, potent and durable T cell therapeutics.

Abstract 1536: Enhancing CAR T cell activity by linking IL-12 expression to the endogenous PDCD1 promoter

Chimeric antigen receptor (CAR) T cells have shown great promise in treating certain late stage hematological malignancies. While very encouraging, current CAR T cell therapies have not shown the same level of success in targeting solid tumors and alternative approaches are required to achieve clinical efficacy in solid tumor patients. We describe a combinatorial approach whereby targeted gene deletion and transgene insertion occur simultaneously resulting in more potent CAR T cells for solid tumor applications.

Immunomodulatory cytokines can stimulate vigorous antitumor responses and are candidates for increasing CAR T cell efficacy in solid tumors. However, the clinical application of cytokine therapy has been limited by systemic toxicity, particularly for strong effector cytokines such as IL-12. Limiting IL-12 expression to within the tumor microenvironment may reduce unwanted toxicity while enhancing CAR T cell functionality.

Immune checkpoint gene programed cell death 1 (PDCD1) is a regulator of T cell functionality that is highly upregulated following T cell activation, with antibody and nuclease-mediated inactivation of the PD-1 signaling pathway having been shown to enhance CAR T cell functionality. Here, we used megaTAL genome editing/homology directed repair (HDR) to place an IL-12 transgene under the control of the PDCD1 promoter, linking IL-12 production with CAR T cell activation as well as eliminating PD-1 expression. CAR expression was combined with site specific transgene expression as follows: lentiviral vector-engineered T cells were treated with a PDCD1-specific megaTAL and transduced with adeno associated virus-6 (AAV6) containing a promoter-less IL-12 transgene flanked by PDCD1 homology regions. We observed highly efficient HDR, with inducible IL-12 expression from the endogenous PDCD1 promoter being dependent on T cell activation. Minimal IL-12 production was detected under resting conditions, whereas PMA/Ionomycin or co-culture with CAR+ target cell lines resulted in higher IL-12 secretion. Expression of IL-12 under the PDCD1 promoter enhanced CAR T cell cytokine production and cytotoxicity, especially under conditions of repeated antigen exposure.

In summary, we describe a novel genome editing strategy to enhance CAR T cell functionality. Using HDR, we were able to engineer CAR T cells to simultaneously disrupt the PDCD1 gene and place a potentially therapeutic transgene under inducible transcriptional control. The IL-12/CAR T cells exhibited activation-dependent IL-12 production and enhanced cytokine and cytotoxicity responses against tumor cells in vitro. HDR may represent a promising approach to enhance CAR T cell functionality in solid tumor applications.

Citation Format: Baeckseung Lee, Wai-Hang Leung, Jasdeep Mann, Kyle Havens, Joel Gay, Richard A. Morgan, Alexander Astrakhan. Enhancing CAR T cell activity by linking IL-12 expression to the endogenous PDCD1 promoter [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 1536.

Efficient Enrichment of Gene-Modified Primary T Cells via CCR5-Targeted Integration of Mutant Dihydrofolate Reductase

Targeted gene therapy strategies utilizing homology-driven repair (HDR) allow for greater control over transgene integration site, copy number, and expression-significant advantages over traditional vector-mediated gene therapy with random genome integration. However, the relatively low efficiency of HDR-based strategies limits their clinical application. Here, we used HDR to knock in a mutant dihydrofolate reductase (mDHFR) selection gene at the gene-edited CCR5 locus in primary human CD4⁺ T cells and selected for mDHFR-modified cells in the presence of methotrexate (MTX). Cells were transfected with CCR5-megaTAL nuclease mRNA and transduced with adeno-associated virus containing an mDHFR donor template flanked by CCR5 homology arms, leading to up to 40% targeted gene insertion. Clinically relevant concentrations of MTX led to a greater than 5-fold enrichment for mDHFR-modified cells, which maintained a diverse TCR repertoire over the course of expansion and drug selection. Our results demonstrate that mDHFR/MTX-based selection can be used to enrich for gene-modified T cells ex vivo, paving the way for analogous approaches to increase the percentage of HIV-resistant, autologous CD4⁺ T cells infused into HIV⁺ patients, and/or for in vivo selection of gene-edited T cells for the treatment of cancer.

Abstract 1708: Effective and reversible control of anti-tumor activity in vivo with a drug-regulated CAR T cell platform (DARIC)

Redirecting T cells against tumors by introducing antigen-specific chimeric antigen receptors (CAR) has shown promising clinical results as a potential treatment strategy for certain cancers. However, traditional CARs are constitutively active, resulting in the persistent loss of all target cells (including off -tumor, on-target activity against normal tissues that express the target antigen) and enhanced potential of excessive T cell activation to drive cytokine release syndrome. While “off switches” based on suicide cassettes or other depleting cell approaches are in development, such systems by definition result in the elimination of the therapeutic cells. Here we have developed a novel drug-regulated CAR-based antigen targeting approach termed Dimerizing Agent Regulated Immune-receptor Complex (DARIC) that aims to: i) minimize the long-term toxicity of CAR T treatment; ii) allow the targeting of previously inaccessible antigens; and iii) be amenable to multiplex antigen targeting. The DARIC platform separates the antigen recognition and signaling functions of a CAR into two distinct polypeptides that are further engineered to contain the FKPB12 and FRB small-molecule regulated dimerization domains. In the absence of the dimerizing drug (e.g. rapamycin or the non-immunosuppressive rapalog AP21967) the DARIC system lacks signaling activity. However, the addition of dimerizing agent drives the interaction of the two DARIC subunits, fully restoring CAR function. Using CD19 as a model system, we show that treatment of CD19-DARIC+ T cells with rapamycin or AP21967 results in equivalent cytotoxicity, cytokine production and proliferation compared to a standard CD19-targeting CAR. Importantly, CD19-DARIC T cells were activated by picomolar levels of rapamycin and exhibited a higher antigen sensitivity than standard CD19-CAR T cells in vitro. In an aggressive CD19+Nalm-6 xenograft tumor mouse model, CD19-DARIC T cells did not exhibit anti-tumor activity in the absence of dimerizing agent. However, CD19-DARIC treated mice that received either low-dose rapamycin or AP21967 showed an equivalent level of tumor control compared to standard CD19-CAR treated animals. This activity was dependent on the presence of the dimerizing drug, as cessation of drug treatment resulted in the loss of CD19-DARIC T cell activity and the expansion of Nalm-6 tumors cells in the DARIC T cell treated mice, consistent with the ability to switch off CD19-DARIC T cells in vivo by withdrawing drug. Taken together, these results highlight the potential of the DARIC platform to facilitate the regulation of CAR T cell function both in vitro and in vivo.

Citation Format: Wai-Hang Leung, Michael Certo, Holly Horton, Joel Gay, Tracy VandenBerg, Jordan Jarjour, Alexander Astrakhan. Effective and reversible control of anti-tumor activity in vivo with a drug-regulated CAR T cell platform (DARIC) [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 1708. doi:10.1158/1538-7445.AM2017-1708

Abstract 3756: Efficient generation of CAR T cells by site-specific gene addition into the TRAC locus

Genetically engineered T cells represent a promising new approach to the treatment of cancer. Positive results in recent clinical trials exploiting T cells engineered to express chimeric antigen receptors (CARs) have highlighted the potential for these cell-based therapies in patients with B cell malignancies. To extend these successes to a broader range of tumor types may require additional T cell engineering beyond simple CAR addition, such as gene knockout and/or coupling deletion of a target gene with site-specific addition of a CAR transgene. To this end, we have developed a genome editing strategy for the simultaneous elimination of an endogenous target gene with site-specific addition of a CAR via homology-directed repair (HDR). To demonstrate the utility of this approach, we used a previously characterized megaTAL (an engineered nuclease created by the fusion of an engineered meganuclease and a transcription activator-like (TAL) -DNA binding domain) specific for the T cell receptor alpha constant region gene (TRAC). Delivery of this megaTAL to primary human T cells via mRNA electroporation results in efficient and specific disruption of the TRAC locus (Boissel et al, 2013). To achieve simultaneous target gene disruption with site-specific CAR transgene insertion, we designed an adeno-associated virus (AAV) vector for DNA template delivery encoding the CAR and flanked by regions of DNA homologous to the genome immediately surrounding the megaTAL cleavage site. Co-delivery of the megaTAL and AAV encoding a CD19-CAR with TRAC homology arms resulted in >50% CAR+TRAC- cells. In vitro assays of cytotoxicity and cytokine responses against CD19+ Nalm-6 cells confirmed that TRAC-targeted CD19-CAR T cells were comparable to CD19-CAR T cells generated by lentiviral transduction. Interestingly, a similar level of CAR T cell function was observed even though TRAC-targeted CD19-CAR T cells expressed lower amounts of the CAR, as determined by flow cytometry. Similar CAR integration efficiency and functional efficacy was observed using a TRAC-targeting AAV vector containing a distinct B cell maturation antigen (BCMA)-specific CAR. These findings demonstrate megaTAL-mediated targeted gene addition as a feasible, efficient, and potentially safer approach for generation of gene-edited CAR T cell product. Moreover, the ability to combine the disruption of a target gene with the site-specific integration of the CAR eliminates the need for randomly integrating viral vectors while satisfying the potential need for more complex genome-edited T cell products.

Citation Format: Baeckseung Lee, Wai-Hang Leung, Mark Pogson, Jordan Jarjour, Alexander Astrakhan. Efficient generation of CAR T cells by site-specific gene addition into the TRAC locus [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 3756. doi:10.1158/1538-7445.AM2017-3756

Homology-Directed Recombination for Enhanced Engineering of Chimeric Antigen Receptor T Cells

Gene editing by homology-directed recombination (HDR) can be used to couple delivery of a therapeutic gene cassette with targeted genomic modifications to generate engineered human T cells with clinically useful profiles. Here, we explore the functionality of therapeutic cassettes delivered by these means and test the flexibility of this approach to clinically relevant alleles. Because CCR5-negative T cells are resistant to HIV-1 infection, CCR5-negative anti-CD19 chimeric antigen receptor (CAR) T cells could be used to treat patients with HIV-associated B cell malignancies. We show that targeted delivery of an anti-CD19 CAR cassette to the CCR5 locus using a recombinant AAV homology template and an engineered megaTAL nuclease results in T cells that are functionally equivalent, in both in vitro and in vivo tumor models, to CAR T cells generated by random integration using lentiviral delivery. With the goal of developing off-the-shelf CAR T cell therapies, we next targeted CARs to the T cell receptor alpha constant (TRAC) locus by HDR, producing TCR-negative anti-CD19 CAR and anti-B cell maturation antigen (BCMA) CAR T cells. These novel cell products exhibited in vitro cytolytic activity against both tumor cell lines and primary cell targets. Our combined results indicate that high-efficiency HDR delivery of therapeutic genes may provide a flexible and robust method that can extend the clinical utility of cell therapeutics.

Efficient Modification of the CCR5 Locus in Primary Human T Cells With megaTAL Nuclease Establishes HIV-1 Resistance

A naturally occurring 32-base pair deletion of the HIV-1 co-receptor CCR5 has demonstrated protection against HIV infection of human CD4⁺ T cells. Recent genetic engineering approaches using engineered nucleases to disrupt the gene and mimic this mutation show promise for HIV therapy. We developed a megaTAL nuclease targeting the third extracellular loop of CCR5 that we delivered to primary human T cells by mRNA transfection. The CCR5 megaTAL nuclease established resistance to HIV in cell lines and disrupted the expression of CCR5 on primary human CD4⁺ T cells with a high efficiency, achieving up to 80% modification of the locus in primary cells as measured by molecular analysis. Gene-modified cells engrafted at levels equivalent to unmodified cells when transplanted into immunodeficient mice. Furthermore, genetically modified CD4⁺ cells were preferentially expanded during HIV-1 infection in vivo in an immunodeficient mouse model. Our results demonstrate the feasibility of targeting CCR5 in primary T cells using an engineered megaTAL nuclease, and the potential to use gene-modified cells to reconstitute a patient's immune system and provide protection from HIV infection.

Efficient modification of CCR5 in primary human hematopoietic cells using a megaTAL nuclease and AAV donor template

Genetic mutations or engineered nucleases that disrupt the HIV co-receptor CCR5 block HIV infection of CD4(+) T cells. These findings have motivated the engineering of CCR5-specific nucleases for application as HIV therapies. The efficacy of this approach relies on efficient biallelic disruption of CCR5, and the ability to efficiently target sequences that confer HIV resistance to the CCR5 locus has the potential to further improve clinical outcomes. We used RNA-based nuclease expression paired with adeno-associated virus (AAV)-mediated delivery of a CCR5-targeting donor template to achieve highly efficient targeted recombination in primary human T cells. This method consistently achieved 8 to 60% rates of homology-directed recombination into the CCR5 locus in T cells, with over 80% of cells modified with an MND-GFP expression cassette exhibiting biallelic modification. MND-GFP-modified T cells maintained a diverse repertoire and engrafted in immune-deficient mice as efficiently as unmodified cells. Using this method, we integrated sequences coding chimeric antigen receptors (CARs) into the CCR5 locus, and the resulting targeted CAR T cells exhibited antitumor or anti-HIV activity. Alternatively, we introduced the C46 HIV fusion inhibitor, generating T cell populations with high rates of biallelic CCR5 disruption paired with potential protection from HIV with CXCR4 co-receptor tropism. Finally, this protocol was applied to adult human mobilized CD34(+) cells, resulting in 15 to 20% homologous gene targeting. Our results demonstrate that high-efficiency targeted integration is feasible in primary human hematopoietic cells and highlight the potential of gene editing to engineer T cell products with myriad functional properties.

megaTALs: a rare-cleaving nuclease architecture for therapeutic genome engineering

Rare-cleaving endonucleases have emerged as important tools for making targeted genome modifications. While multiple platforms are now available to generate reagents for research applications, each existing platform has significant limitations in one or more of three key properties necessary for therapeutic application: efficiency of cleavage at the desired target site, specificity of cleavage (i.e. rate of cleavage at 'off-target' sites), and efficient/facile means for delivery to desired target cells. Here, we describe the development of a single-chain rare-cleaving nuclease architecture, which we designate 'megaTAL', in which the DNA binding region of a transcription activator-like (TAL) effector is used to 'address' a site-specific meganuclease adjacent to a single desired genomic target site. This architecture allows the generation of extremely active and hyper-specific compact nucleases that are compatible with all current viral and nonviral cell delivery methods.

Development of B-lineage predominant lentiviral vectors for use in genetic therapies for B cell disorders

Sustained, targeted, high-level transgene expression in primary B lymphocytes may be useful for gene therapy in B cell disorders. We developed several candidate B-lineage predominant self-inactivating lentiviral vectors (LV) containing alternative enhancer/promoter elements including: the immunoglobulin β (Igβ) (B29) promoter combined with the immunoglobulin µ enhancer (EµB29); and the endogenous BTK promoter with or without Eµ (EµBtkp or Btkp). LV-driven enhanced green fluorescent protein (eGFP) reporter expression was evaluated in cell lines and primary cells derived from human or murine hematopoietic stem cells (HSC). In murine primary cells, EµB29 and EµBtkp LV-mediated high-level expression in immature and mature B cells compared with all other lineages. Expression increased with B cell maturation and was maintained in peripheral subsets. Expression in T and myeloid cells was much lower in percentage and intensity. Similarly, both EµB29 and EµBtkp LV exhibited high-level activity in human primary B cells. In contrast to EµB29, Btkp and EµBtkp LV also exhibited modest activity in myeloid cells, consistent with the expression profile of endogenous Bruton's tyrosine kinase (Btk). Notably, EµB29 and EµBtkp activity was superior in all expression models to an alternative, B-lineage targeted vector containing the EµS.CD19 enhancer/promoter. In summary, EµB29 and EµBtkp LV comprise efficient delivery platforms for gene expression in B-lineage cells.

Antiplatelet antibodies in WASP(-) mice correlate with evidence of increased in vivo platelet consumption

OBJECTIVE

To study the role of antiplatelet antibodies in the thrombocytopenia of murine Wiskott-Aldrich syndrome (WAS).

MATERIALS AND METHODS

A flow cytometric method was developed for detection of serum antiplatelet antibodies via their binding to intact target platelets lacking surface antibodies. Platelets were labeled with 5-chloromethylfluorescein diacetate (CMFDA) in order to track their clearance from the circulation. WASP(-)muMT(-/-) mice were generated by standard breeding methods.

RESULTS

Serum antiplatelet antibodies were detected in approximately 40% of WASP(-) males. The mean level of reticulated platelets is significantly increased in these antibody(+) males. While WASP(-) males show an approximately 50% reduction in platelet counts, 5% to 10% show a more severe thrombocytopenia associated with increased reticulated platelets, suggesting the presence of clearance-inducing antiplatelet antibodies. In support of that inference, 90% of the latter mice show detectable serum antiplatelet antibodies. The antibodies are primarily immunoglobulin G, and are also detected in >30% of CD47(-/-) males. WASP(-)muMT(-/-) males, which demonstrate no serum- or platelet-associated antibodies, show a degree of thrombocytopenia similar to that of WASP(-) males. Their platelet clearance rates remain accelerated--more so in WASP(-)muMT(-/-) than WASP(+)muMT(-/-) recipients.

CONCLUSIONS

These findings suggest that platelet WASP deficiency results in an increase in platelet clearance rates by two mechanisms: an antibody-independent mechanism that largely requires WASP deficiency in trans, and an antibody-dependent mechanism that does not. Both an increased incidence of antiplatelet antibodies and an increased susceptibility to their effects contribute to antibody-dependent clearance of WASP(-) platelets.

Wiskott-Aldrich syndrome protein is required for homeostasis and function of invariant NKT cells

NKT cells comprise a separate T lineage expressing semi-invariant T cell receptors. Canonical invariant NKT (iNKT) cells specifically recognize lipid Ags presented by CD1d, a MHC class I-like molecule. iNKT cells function, in part, as initial responders to bacterial infection and play a role in immune surveillance and tumor rejection. The Wiskott-Aldrich Syndrome protein (WASp) serves as a crucial link between cellular stimuli and cytoskeletal rearrangements. Although we and others have identified a key role for WASp in homeostasis of T-regulatory and marginal zone B cells, little data exist regarding the role for WASp within the iNKT lineage. Analysis of WASp-expressing cell populations in heterozygous female WASp mice revealed a substantial selective advantage for WASp(+) vs WASp(-) iNKT cells. Although adult WASp-deficient (WASp(-/-)) mice had normal thymic and bone marrow iNKT numbers, we observed 2- to 3-fold reduction in the numbers of iNKT cells in the spleen and liver. This peripheral iNKT deficit is manifested, in part, due to defective iNKT homeostasis. WASp(-/-) iNKT cells exhibited reduced levels of integrin surface expression and decreased homing and/or retention within peripheral tissues in a competitive repopulation model. In addition, analysis of young mice showed that WASp is important for both maturation and egress of thymic iNKT cells. WASp(-/-) iNKT cells also exhibited a marked reduction in Ag-induced proliferation and cytokine production. Our findings highlight the crucial role for WASp in iNKT development, homeostasis, and activation, and identify iNKT dysfunction as an additional factor likely to contribute to the clinical features observed in WAS patients.

Local increase in thymic stromal lymphopoietin induces systemic alterations in B cell development

The cytokine thymic stromal lymphopoietin (TSLP) drives immature B cell development in vitro and may regulate T helper type 2 responses. Here we analyzed the involvement of TSLP in B cell development in vivo with a doxycycline-inducible, keratin 5-driven transgene encoding TSLP (K5-TSLP). K5-TSLP-transgenic mice given doxycycline showed an influx of immature B cells into the periphery, with population expansion of follicular mature B cells, near-complete loss of marginal zone and marginal zone precursor B cells, and 'preferential' population expansion of peritoneal B-1b B cells. These changes promoted cryoglobulin production and immune complex-mediated renal disease. Identical events occurred in mice without T cells, in alternative TSLP-transgenic models and in K5-TSLP-transgenic mice with undetectable systemic TSLP. These observations suggest that signals mediating localized TSLP expression may modulate systemic B cell development and promote humoral autoimmunity.

Sustained correction of B-cell development and function in a murine model of X-linked agammaglobulinemia (XLA) using retroviral-mediated gene transfer

X-linked agammaglobulinemia (XLA) is a human immunodeficiency caused by mutations in Bruton tyrosine kinase (Btk) and characterized by an arrest in early B-cell development, near absence of serum immunoglobulin, and recurrent bacterial infections. Using Btk- and Tec-deficient mice (BtkTec–/–) as a model for XLA, we determined if Btk gene therapy could correct this disorder. Bone marrow (BM) from 5-fluorouracil (5FU)–treated BtkTec–/– mice was transduced with a retroviral vector expressing human Btk and transplanted into BtkTec–/– recipients. Mice engrafted with transduced hematopoietic cells exhibited rescue of both primary and peripheral B-lineage development, recovery of peritoneal B1 B cells, and correction of serum immunoglobulin M (IgM) and IgG3 levels. Gene transfer also restored T-independent type II immune responses, and B-cell antigen receptor (BCR) proliferative responses. B-cell progenitors derived from Btk-transduced stem cells exhibited higher levels of Btk expression than non-B cells; and marking studies demonstrated a selective advantage for Btk-transduced B-lineage cells. BM derived from primary recipients also rescued Btk-dependent function in secondary hosts that had received a transplant. Together, these data demonstrate that gene transfer into hematopoietic stem cells can reconstitute Btk-dependent B-cell development and function in vivo, and strongly support the feasibility of pursuing Btk gene transfer for XLA.