A novel lentiviral vector-based approach to generate chimeric antigen receptor T cells targeting Aspergillus fumigatus.

Invasive aspergillosis (IA) is a common and deadly mold infection in immunocompromised patients. As morbidity and mortality of IA are primarily driven by poor immune defense, adjunct immunotherapies, such as chimeric antigen receptor (CAR) T cells, are direly needed. Here, we propose a novel approach to generate Aspergillus fumigatus (AF)-CAR T cells using the single-chain variable fragment domain of monoclonal antibody AF-269-5 and a lentiviral vector system. These cells successfully targeted mature hyphal filaments of representative clinical and reference AF isolates and elicited a potent release of cytotoxic effectors and type 1 T cell cytokines. Furthermore, AF-CAR T cells generated from peripheral blood mononuclear cells of four healthy human donors and expanded with either of three cytokine stimulation regimens (IL-2, IL-2 + IL-21, or IL-7 + IL-15) significantly suppressed mycelial growth of AF-293 after 18 hours of co-culture and synergized with the immunomodulatory antifungal agent caspofungin to control hyphal growth for 36 hours. Moreover, cyclophosphamide-immunosuppressed NSG mice with invasive pulmonary aspergillosis that received two doses of 5 million AF-CAR T cells (6 and 48 hours after AF infection) showed significantly reduced morbidity on day 4 post-infection (P < 0.001) and significantly improved 7-day survival (P = 0.049) compared with mice receiving non-targeting control T cells, even without concomitant antifungal chemotherapy. In conclusion, we developed a novel lentiviral strategy to obtain AF-CAR T cells with high targeting efficacy, yielding significant anti-AF activity in vitro and short-term protection in vivo. Our approach could serve as an important steppingstone for future clinical translation of antifungal CAR T-cell therapy after further refinement and thorough preclinical evaluation.IMPORTANCEInvasive aspergillosis (IA) remains a formidable cause of morbidity and mortality in patients with hematologic malignancies and those undergoing hematopoietic stem cell transplantation. Despite the introduction of several new Aspergillus-active antifungals over the last 30 years, the persisting high mortality of IA in the setting of continuous and profound immunosuppression is a painful reminder of the major unmet need of effective antifungal immune enhancement therapies. The success of chimeric antigen receptor (CAR) T-cell therapy in cancer medicine has inspired researchers to translate this approach to opportunistic infections, including IA. Aiming to refine anti-Aspergillus CAR T-cell therapy and improve its feasibility for future clinical translation, we herein developed and validated a novel antibody-based CAR construct and lentiviral transduction method to accelerate the production of CAR T cells with high targeting efficacy against Aspergillus fumigatus. Our unique approach could provide a promising platform for future clinical translation of CAR T-cell-based antifungal immunotherapy.

GXMR-CAR containing distinct GXM-specific single-chain variable fragment (scFv) mediated the cell activation against Cryptococcus spp. And had difference in the strength of tonic signaling.

Cryptococcus spp. has a polysaccharide capsule composed of glucuronoxylomannan-GXM, a major virulence factor that can prevent the recognition of fungi by immune cells. Chimeric Antigen Receptor (CAR) redirects T cells to target Cryptococcus spp. as previously demonstrated by a CAR specific to GXM, GXMR-CAR. The current study evaluated the strength of the signal transduction triggered by GXMR-CAR, composed of a distinct antigen-binding domain sourced from a single-chain variable fragment (scFv). GXM-specific scFv derived from mAbs 2H1 and 18B7, 2H1-GXMR-CAR and 18B7-GXMR-CAR, respectively, were designed to express CD8 molecule as hinge/transmembrane, and the costimulatory molecule CD137 (4-1BB) coupled to CD3ζ. The 2H1-GXMR-CAR or 18B7-GXMR-CAR Jurkat cells recognized soluble GXM from C. gattii and C. neoformans, and the levels of IL-2 released by the modified cells did not differ between the GXMR-CAR constructs after exposure to Cryptococcus spp. 18B7-GXMR-CAR triggered tonic signaling was more pronounced in modified Jurkat cells, and a protein kinase inhibitor of the Src family (dasatinib) significantly reduced GXMR-CAR tonic signaling and inhibited cell activation against ligands. 18B7 scFv showed a structural modification of the variable heavy (VH) chain that clarified the difference in the strength of tonic signaling and the level of cell activation between 2H1-GXMR-CAR and 18B7-GXMR-CAR. GXMR-CAR constructs induced T-cell activation against clinical isolates of Cryptococcus spp. and serum from patients with cryptococcosis induced high levels of IL-2, mainly in cells modified with 18B7-GXMR-CAR. Thus, 18B7-GXMR-CAR and 2H1-GXMR-CAR mediated T cell activation against Cryptococcus spp. and 18B7 and 2H1 scFv influenced the strength of tonic signaling.

2H1-GXMR-CAR and 18B7-GXMR-CAR are efficiently expressed on the cell surface;2H1-GXMR-CAR and 18B7-GXMR-CAR redirected T cells toward the ligands;18B7-GXMR-CAR provided highest levels of tonic signaling;Binding pocket of 18B7 scFv favored the tonic signaling triggered by GXMR-CAR;Binding pocket of 18B7 scFv favored the tonic signaling triggered by GXMR-CAR.

Modification of Hinge/Transmembrane and Signal Transduction Domains Improves the Expression and Signaling Threshold of GXMR-CAR Specific to Cryptococcus spp.

Chimeric antigen receptors (CARs) redirect T cells to recognize a specific target. CAR components play a pivotal role in antigen specificity, structure stability, expression on cell surface, and induction of cellular activation, which together determine the success of CAR T-cell therapy. CAR products targeting B-cell lymphoma encouraged the development of new CAR applications beyond cancer. For example, our group developed a CAR to specifically target glucuronoxylomannan (GXM) in the capsule of Cryptococcus species, called GXMR-CAR or GXMR-IgG4-28ζ. Cryptococcus are fungi that cause the life-threatening disease cryptococcosis, and GXMR-IgG4-28ζ redirected T cells to target yeast and titan cell forms of Cryptococcus spp. Here, we replaced the IgG4-hinge and CD28-transmembrane domains from GXMR-CAR with a CD8α molecule as the hinge/transmembrane and used CD28 or 4-1BB molecules as co-stimulatory domains, creating GXMR-8-28ζ and GXMR-8-BBζ, respectively. Jurkat cells expressing GXMR-CAR containing CD8α as the hinge/transmembrane improved the CAR expression and induced a tonic signaling. GXMR-8-28ζ and GXMR-8-BBζ induced high levels of IL-2 and up-regulation of CD69 expression in the presence of reference strains of C. neoformans and C. gattii. Moreover, GXMR-8-28ζ and GXMR-8-BBζ showed increased strength in response to incubation with clinical isolates of Cryptococcuss spp., and 4-1BB co-stimulatory domain triggered a more pronounced cellular activation. Dasatinib, a tyrosine kinase inhibitor, attenuated the GXMR-CAR signaling cascade's engagement in the presence or absence of its ligand. This study optimized novel second-generation GXMR-CARs containing the CD8-hinge/transmembrane domain that improved CAR expression, antigen recognition, and signal strength in T-cell activation.

Titan Cells and Yeast Forms of Cryptococcus neoformans and Cryptococcus gattii Are Recognized by GXMR-CAR.

Cryptococcosis, a systemic mycosis that affects both the immunocompromised and immunocompetent, is caused by the inhalation of dehydrated yeasts or fungal spores of Cryptococcus gattii or Cryptococcus neoformans. The Cryptococcus spp. polysaccharide capsule is composed mainly of glucuronoxylomannan-GXM, its major virulence factor. The capsule thickness increases to more than 15 µm during titanization, favoring the pathogenesis of cryptococcosis. Previous studies demonstrated that cytotoxic T cells that had been bioengineered with GXM-targeting chimeric antigen receptor (GXMR-CAR) were able to recognize C. neoformans by promoting the control of titanization. GXMR-CAR, a second-generation CAR, contains a single-chain variable fragment that originates from a 18B7 clone: a human IgG4 hinge, followed by a human CD28 (transmembrane/cytoplasmic domains) and a CD3ς chain. In the current study, we redirected T cells to target distinct C. neoformans and C. gattii cell types by GXMR-CAR. Lentiviral particles carrying the GXMR-CAR sequence were used to transduce Jurkat cells, and these modified cells interacted with the GXM of the C. gattii R265 strain. Moreover, GXMR-CAR mediated the recognition of C. gattii and C. neoformans yeasts with both thin and thick polysaccharide capsules, and GXMR-CAR Jurkat cells interacted with titan cells sourced from both Cryptococcus spp. Thus, bioengineered cells using CAR can improve the treatment of cryptococcosis.

Glucuronoxylomannan in the Cryptococcus species capsule as a target for Chimeric Antigen Receptor T-cell therapy.

BACKGROUND AIMS: The genus Cryptococcus comprises two major fungal species that cause clinical infections in humans: Cryptococcus gattii and Cryptococcus neoformans. To establish invasive human disease, inhaled cryptococci must penetrate the lung tissue and reproduce. Each year, about 1 million cases of Cryptococcus infection are reported worldwide, and the infection's mortality rate ranges from 20% to 70%. Many HIV+/AIDS patients are affected by Cryptococcus infections, with 220,000 cases of cryptococcal meningitis reported worldwide in this population every year (C. neoformans infection statistics, via the Centers for Disease Control and Prevention, https://www.cdc.gov/fungal/diseases/cryptococcosis-neoformans/statistics.html). To escape from host immune cell attack, Cryptococcus covers itself in a sugar-based capsule composed primarily of glucuronoxylomannan (GXM). To evade phagocytosis, yeast cells increase to a >45-µm perimeter and become titan, or giant, cells. Cryptococci virulence is directly proportional to the percentage of titan/giant cells present during Cryptococcus infection. To combat cryptococcosis, the authors propose the redirection of CD8+ T cells to target the GXM in the capsule via expression of a GXM-specific chimeric antigen receptor (GXMR-CAR). RESULTS: GXMR-CAR has an anti-GXM single-chain variable fragment followed by an IgG4 stalk in the extracellular domain, a CD28 transmembrane domain and CD28 and CD3-ς signaling domains. After lentiviral transduction of human T cells with the GXMR-CAR construct, flow cytometry demonstrated that 82.4% of the cells expressed GXMR-CAR on their surface. To determine whether the GXMR-CAR+ T cells exhibited GXM-specific recognition, these cells were incubated with GXM for 24 h and examined with the use of brightfield microscopy. Large clusters of proliferating GXMR-CAR+ T cells were observed in GXM-treated cells, whereas no clusters were observed in control cells. Moreover, the interaction of GXM with GXMR-CAR+ T cells was detected via flow cytometry by using a GXM-specific antibody, and the recognition of GXM by GXMR-CAR T cells triggered the secretion of granzyme and interferon gamma (IFN-γ). The ability of GXMR-CAR T cells to bind to the yeast form of C. neoformans was detected by fluorescent microscopy, but no binding was detected in mock-transduced control T cells (NoDNA T cells). Moreover, lung tissue sections were stained with Gomori Methenamine Silver and evaluated by NanoZoomer (Hamamatsu), revealing a significantly lower number of titan cells, with perimeters ranging from 50 to 130 µm and giant cells >130 µm in the CAR T-cell treated group when compared with other groups. Therefore, the authors validated the study's hypothesis by the redirection of GXMR-CAR+ T cells to target GXM, which induces the secretion of cytotoxic granules and IFN-γ that will aid in the control of cryptococcosis CONCLUSIONS: Thus, these findings reveal that GXMR-CAR+ T cells can target C. neoformans. Future studies will be focused on determining the therapeutic efficacy of GXMR-CAR+ T cells in an animal model of cryptococcosis.

Live Monitoring and Analysis of Fungal Growth, Viability, and Mycelial Morphology Using the IncuCyte NeuroTrack Processing Module.

Efficient live-imaging methods are pivotal to understand fungal morphogenesis, especially as it relates to interactions with host immune cells and mechanisms of antifungal drugs. Due to the notable similarities in growth patterns of neuronal cells and mycelial networks, we sought to repurpose the NeuroTrack (NT) processing module of the IncuCyte time-lapse microscopy system as a tool to quantify mycelial growth and branching of pathogenic fungi. We showed the robustness of NT analysis to study Candida albicans and five different molds and confirmed established characteristics of mycelial growth kinetics. We also documented high intra- and interassay reproducibility of the NT module for a spectrum of spore inocula and culture periods. Using GFP-expressing Aspergillus fumigatus and Rhizopus arrhizus, the feasibility of fluorescence-based NT analysis was validated. In addition, we performed proof-of-concept experiments of NT analysis for several translational applications such as studying the morphogenesis of a filamentation-defective C. albicans mutant, the effects of different classes of antifungals (polyenes, azoles, and echinocandins), and coculture with host immune cells. High accuracy was found, even at high immune cell-to-fungus ratios or in the presence of fungal debris. For antifungal efficacy studies, addition of a cytotoxicity dye further refined IncuCyte-based analysis, facilitating real-time determination of fungistatic and fungicidal activity in a single assay. Complementing conventional MIC-based assays, NT analysis is an appealing method to study fungal morphogenesis and viability in the context of antifungal compound screening and evaluation of novel immune therapeutics.IMPORTANCE Pathogenic fungi remain a major cause of infectious complications in immunocompromised patients. Microscopic techniques are crucial for our understanding of fungal biology, host-pathogen interaction, and the pleiotropic effects of antifungal drugs on fungal cell growth and morphogenesis. Taking advantage of the morphological similarities of neuronal cell networks and mycelial growth patterns, we employed the IncuCyte time-lapse microscopy system and its NeuroTrack image analysis software package to study growth and branching of a variety of pathogenic yeasts and molds. Using optimized image processing definitions, we validated IncuCyte NeuroTrack analysis as a reliable and efficient tool for translational applications such as antifungal efficacy evaluation and coculture with host immune effector cells. Hence, the IncuCyte system and its NeuroTrack module provide an appealing platform for efficient in vitro studies of antifungal compounds and immunotherapeutic strategies in medical mycology.

Methods of Controlling Invasive Fungal Infections Using CD8+ T Cells.

Invasive fungal infections (IFIs) cause high rates of morbidity and mortality in immunocompromised patients. Pattern-recognition receptors present on the surfaces of innate immune cells recognize fungal pathogens and activate the first line of defense against fungal infection. The second line of defense is the adaptive immune system which involves mainly CD4+ T cells, while CD8+ T cells also play a role. CD8+ T cell-based vaccines designed to prevent IFIs are currently being investigated in clinical trials, their use could play an especially important role in acquired immune deficiency syndrome patients. So far, none of the vaccines used to treat IFI have been approved by the FDA. Here, we review current and future antifungal immunotherapy strategies involving CD8+ T cells. We highlight recent advances in the use of T cells engineered using a Sleeping Beauty vector to treat IFIs. Recent clinical trials using chimeric antigen receptor (CAR) T-cell therapy to treat patients with leukemia have shown very promising results. We hypothesized that CAR T cells could also be used to control IFI. Therefore, we designed a CAR that targets ß-glucan, a sugar molecule found in most of the fungal cell walls, using the extracellular domain of Dectin-1, which binds to ß-glucan. Mice treated with D-CAR+ T cells displayed reductions in hyphal growth of Aspergillus compared to the untreated group. Patients suffering from IFIs due to primary immunodeficiency, secondary immunodeficiency (e.g., HIV), or hematopoietic transplant patients may benefit from bioengineered CAR T cell therapy.

Phase I trials using Sleeping Beauty to generate CD19-specific CAR T cells.

BACKGROUND: T cells expressing antigen-specific chimeric antigen receptors (CARs) improve outcomes for CD19-expressing B cell malignancies. We evaluated a human application of T cells that were genetically modified using the Sleeping Beauty (SB) transposon/transposase system to express a CD19-specific CAR. METHODS: T cells were genetically modified using DNA plasmids from the SB platform to stably express a second-generation CD19-specific CAR and selectively propagated ex vivo with activating and propagating cells (AaPCs) and cytokines. Twenty-six patients with advanced non-Hodgkin lymphoma and acute lymphoblastic leukemia safely underwent hematopoietic stem cell transplantation (HSCT) and infusion of CAR T cells as adjuvant therapy in the autologous (n = 7) or allogeneic settings (n = 19). RESULTS: SB-mediated genetic transposition and stimulation resulted in 2,200- to 2,500-fold ex vivo expansion of genetically modified T cells, with 84% CAR expression, and without integration hotspots. Following autologous HSCT, the 30-month progression-free and overall survivals were 83% and 100%, respectively. After allogeneic HSCT, the respective 12-month rates were 53% and 63%. No acute or late toxicities and no exacerbation of graft-versus-host disease were observed. Despite a low antigen burden and unsupportive recipient cytokine environment, CAR T cells persisted for an average of 201 days for autologous recipients and 51 days for allogeneic recipients. CONCLUSIONS: CD19-specific CAR T cells generated with SB and AaPC platforms were safe, and may provide additional cancer control as planned infusions after HSCT. These results support further clinical development of this nonviral gene therapy approach. TRIAL REGISTRATION: Autologous, NCT00968760; allogeneic, NCT01497184; long-term follow-up, NCT01492036. FUNDING: National Cancer Institute, private foundations, and institutional funds. Please see Acknowledgments for details.

Genetic Engineering of T Cells to Target HERV-K, an Ancient Retrovirus on Melanoma.

PURPOSE: The human endogenous retrovirus (HERV-K) envelope (env) protein is a tumor-associated antigen (TAA) expressed on melanoma but not normal cells. This study was designed to engineer a chimeric antigen receptor (CAR) on T-cell surface, such that they target tumors in advanced stages of melanoma. EXPERIMENTAL DESIGN: Expression of HERV-K protein was analyzed in 220 melanoma samples (with various stages of disease) and 139 normal organ donor tissues using immunohistochemical (IHC) analysis. HERV-K env-specific CAR derived from mouse monoclonal antibody was introduced into T cells using the transposon-based Sleeping Beauty (SB) system. HERV-K env-specific CAR(+) T cells were expanded ex vivo on activating and propagating cells (AaPC) and characterized for CAR expression and specificity. This includes evaluating the HERV-K-specific CAR(+) T cells for their ability to kill A375-SM metastasized tumors in a mouse xenograft model. RESULTS: We detected HERV-K env protein on melanoma but not in normal tissues. After electroporation of T cells and selection on HERV-K(+) AaPC, more than 95% of genetically modified T cells expressed the CAR with an effector memory phenotype and lysed HERV-K env(+) tumor targets in an antigen-specific manner. Even though there is apparent shedding of this TAA from tumor cells that can be recognized by HERV-K env-specific CAR(+) T cells, we observed a significant antitumor effect. CONCLUSIONS: Adoptive cellular immunotherapy with HERV-K env-specific CAR(+) T cells represents a clinically appealing treatment strategy for advanced-stage melanoma and provides an approach for targeting this TAA on other solid tumors.

Bioengineering T cells to target carbohydrate to treat opportunistic fungal infection.

Clinical-grade T cells are genetically modified ex vivo to express chimeric antigen receptors (CARs) to redirect their specificity to target tumor-associated antigens in vivo. We now have developed this molecular strategy to render cytotoxic T cells specific for fungi. We adapted the pattern-recognition receptor Dectin-1 to activate T cells via chimeric CD28 and CD3-ζ (designated "D-CAR") upon binding with carbohydrate in the cell wall of Aspergillus germlings. T cells genetically modified with the Sleeping Beauty system to express D-CAR stably were propagated selectively on artificial activating and propagating cells using an approach similar to that approved by the Food and Drug Administration for manufacturing CD19-specific CAR(+) T cells for clinical trials. The D-CAR(+) T cells exhibited specificity for ß-glucan which led to damage and inhibition of hyphal growth of Aspergillus in vitro and in vivo. Treatment of D-CAR(+) T cells with steroids did not compromise antifungal activity significantly. These data support the targeting of carbohydrate antigens by CAR(+) T cells and provide a clinically appealing strategy to enhance immunity for opportunistic fungal infections using T-cell gene therapy.

Synthesis and characterization of a novel inhibitor of C-reactive protein-mediated proinflammatory effects.

BACKGROUND: Numerous studies have shown that high C-reactive protein (CRP) levels predict cardiovascular disease and augur a poor prognosis in patients with acute coronary syndromes. Much in vitro and in vivo data support of a role for CRP in atherogenesis. There is an urgent need to develop inhibitors that specifically block the biological effects of CRP in vivo. The one-bead-one-compound (OBOC) combinatorial library method has been used to discover ligands against several biological targets. In this study, we use a novel fluorescence-based screening method to screen an OBOC combinatorial library for the discovery of peptides against human CRP. METHODS: Human CRP was labeled with fluorescein isothiocyanate (FITC) and human serum albumin (HuSA) was labeled with phycoerythrin (PE) and used for screening. The OBOC library LWH-01 was synthesized on TentaGel resin beads using a standard solid-phase "split/mix" approach. RESULTS: By subtraction screening, eight peptides that bind specifically to CRP and not to HuSA were identified. In human aortic endothelial cells (HAECs) incubated with CRP, inhibitors CRPi-2, CRPi-3, and CRPi-6 significantly inhibited CRP-induced superoxide, cytokine release, and nuclear factor-κB (NFκB) activity. Molecular docking studies demonstrate that CRPi-2 interacts with the two Ca(2+) ions in the single subunit of CRP. The binding of CRPi-2 is reminiscent of choline binding. CONCLUSIONS: Future studies will examine the utility of this inhibitor in animal models and clinical trials.

C-reactive protein induces release of both endothelial microparticles and circulating endothelial cells in vitro and in vivo: further evidence of endothelial dysfunction.

BACKGROUND: Inflammation is pivotal in atherosclerosis. A key early event in atherosclerosis is endothelial dysfunction. C-reactive protein (CRP), the prototypic marker of inflammation in humans, is a risk marker for cardiovascular disease, and there is mounting evidence to support its role in atherothrombosis. CRP has been shown to promote endothelial dysfunction both in vitro and in vivo. Emerging biomarkers of endothelial dysfunction include circulating endothelial cells (CECs) and endothelial microparticles (EMPs). However, there is a paucity of data examining the effect of CRP on CEC and EMP production in vitro and in vivo. METHODS: In this report, we treated human aortic endothelial cells (HAECs) with increasing concentrations of CRP (0-50 µg/mL) or boiled CRP. We counted CECs and EMPs by flow cytometry. RESULTS: Although CRP treatment resulted in a significant increase in release of both CECs and EMPs, boiled CRP failed to have an effect. Pretreatment of HAECs with sepiapterin or diethylenetriamine NONOate, both of which preserve nitric oxide (NO), resulted in attenuation of CRP's effects on CECs and EMPs. CD32 and CD64 blocking antibodies but not CD16 antibody or lectin-like oxidized LDL receptor 1 small interfering RNA (LOX-1 siRNA) prevented CRP-induced production of CECs and EMPs. Furthermore, delivery of human CRP to Wistar rats compared with human serum albumin resulted in significantly increased CECs and EMPs, corroborating the in vitro findings. CONCLUSIONS: We provide novel data that CRP, via NO deficiency, promotes endothelial dysfunction by inducing release of CECs and EMPs, which are biomarkers of endothelial dysfunction.

Rapid discovery of death ligands with one-bead-two-compound combinatorial library methods.

The one-bead-one-compound (OBOC) technology enables one to generate thousands to millions of chemical molecules on resin beads (90 µm diameter) such that each bead displays 10(13) copies of the same chemical entity. Whole-cell binding assays have been developed to screen OBOC combinatorial libraries for ligands that bind to specific cell surface receptors. While very powerful, this screening method does not address the downstream cell signaling properties of the binding ligand. We have modified the OBOC technology by introducing a fixed known cell adhesion ligand to the outer layer of each bead. This one-bead-two-compound (OB2C) library configuration allows the bound cells to interact with the random immobilized chemical molecules on each bead. The bound cells can then be probed for specific cellular responses such as apoptosis and activation or inhibition of a specific cell signaling pathway. To validate this concept, an OB2C combinatorial library was created such that a random hexapeptide plus a high affinity lymphoma targeting ligand LLP2A were displayed on each bead. This LLP2A-X(6) OB2C library was then screened with human T-cell leukemia cells (Molt-4) for cell death responses. After 5 days of incubation, propidium iodide was added to the bead library to stain dead cells. Beads coated by red fluorescent cells were isolated for sequence analysis. Two ligands identified by this method, when added to the lymphoid cancer cells, were able to induce cell death.

On-demand cleavable linkers for radioimmunotherapy.

Radioimmunotherapy (RIT) using radiolabeled antibodies or its fragments holds great promise for cancer therapy. However, its clinical potential is often limited by the undesirable radiation exposure to normal organs such as liver, kidney, and bone marrow. It is important to develop new strategies in RIT that enable protection of vital organs from radiation exposure while maintaining therapeutic radiation dose to the cancer. One way to achieve this is to clear radiometal rapidly from the circulation after accumulation of radioimmunoconjugates (RIC) in the tumor. Our strategy is to place a highly efficient and specific cleavable linker between radiometal chelate and the tumor targeting agent. Such linker must be resistant to cleavage by enzymes present in the plasma and tumor. After radiotargeting agents have accumulated in the tumor, a cleaving agent (protease) can be administered to the patient "on demand" to cleave the specific linker, resulting in the release of radiometal from the circulating RIC, in a form that can be cleared rapidly by the kidneys. TNKase, a serine protease tissue plasminogen activator and thrombolytic agent, which has been approved for clinical use in patient with acute myocardial infarction, was selected as an on-demand cleaving agent in our model. TNKase specific on-demand cleavable (ODC) linkers were identified through screening random internally quenched fluorescent resonance energy transfer (FRET) "one-bead-one-compound" (OBOC) combinatorial peptide libraries. FRET-OBOC peptide libraries containing L-amino acid(s) in the center of the random linear peptide and D-amino acids flanking both sides of the L-amino acid(s) were used for screening. Peptide beads susceptible to TNKase but resistant to plasma and tumor-associated protease cleavage were isolated for sequence analysis. The focus of this chapter is on the methods that have been used to identify and characterize ODC linkers and protease-specific substrates.

Development of TNKase-specific cleavable peptide-linked radioimmunoconjugates for radioimmunotherapy.

Radioimmunotherapy (RIT) is a method for selectively delivering radionuclides to cancer cells while reducing the radiation dose to normal tissues. However, because of slow clearance of MAbs, normal tissues also received radiotoxicity. One of the promising strategies is linking on-demand cleavable (ODC) peptides between radiometal chelates and the tumor targeting agents. We have tested this proof-of-concept by using ODC peptides that are designed to be cleaved only by TNKase and are resistant to cleavage by enzymes present in the plasma and the tumor. TNKase-specific peptide linkers using l- and d-amino acids were screened by OBOC combinatorial peptide libraries. One of the best peptides was linked to radiometal chelate and ChL6-MAb to prepare radioimmunoconjugate (RIC). Optimization and characterization of the linker conjugation to MAb show (a) 1-2 peptides linked to each MAb; (b) immunoreactivity >80%; (c) specific activity of the RIC 0.7-1 microCi/microg; (d) RIC stable over 7 days in human plasma; and (e) radiometal-chelated ODC peptide cleaved from the RIC in plasma by TNKase at clinical dose levels of 10 microg/ml. The percent release of radiochelate from RIC was 50% at 24h and 85% over 7 2h in vitro. This novel ODC-linked RIC could be a potential molecule for RIT.

Rainbow beads: a color coding method to facilitate high-throughput screening and optimization of one-bead one-compound combinatorial libraries.

We have developed a new color-encoding method that facilitates high-throughput screening of one-bead one-compound (OBOC) combinatorial libraries. Polymer beads displaying chemical compounds or families of compounds are stained with oil-based organic dyes that are used as coding tags. The color dyes do not affect cell binding to the compounds displayed on the surface of the beads. We have applied such rainbow beads in a multiplex manner to discover and profile ligands against cell surface receptors. In the first application, a series of OBOC libraries with different scaffolds or motifs are each color-coded; small samples of each library are then combined and screened concurrently against live cells for cell attachment. Preferred libraries can be rapidly identified and selected for subsequent large-scale screenings for cell surface binding ligands. In a second application, beads with a series of peptide analogues (e.g., alanine scan) are color-coded, combined, and tested for binding against a specific cell line in a single-tissue culture well; the critical residues required for binding can be easily determined. In a third application, ligands reacting against a series of integrins are color-coded and used as a readily applied research tool to determine the integrin profile of any cell type. One major advantage of this straightforward and yet powerful method is that only an ordinary inverted microscope is needed for the analysis, instead of sophisticated (and expensive) fluorescent microscopes or flow cytometers.

Evaluation of ketone-oxime method for developing therapeutic on-demand cleavable immunoconjugates.

The use of antibody molecules in immunoassay, molecular targeting, or detection techniques encompasses a broad variety of applications affecting nearly every field of medical science. In cancer therapy, monoclonal antibodies (mAb) have been used as vehicles to deliver radionuclides, toxins, or drugs to the target cancer cells. New conjugation methods are most needed to conjugate a wide variety of targeting small molecules and peptidomimatic compounds. Here, we exploited a keto-oxime method for conjugation of protease susceptible linkers to an antibody. This modified method involves two steps: (i) introduction of methyl ketone linkers (referred to as linker moiety) to the primary amines present in the antibody and (ii) conjugation of ketone linkers to aminoxy functional group present in the conjugated moiety (referred to as functional moiety). We have optimized this conjugation method and shown that approximately 10 functional moieties can be conjugated to antibody. Conjugation was verified by MALDI-TOF MS and Western blot analysis. The acidic pH conditions used in this method did not change the immune reactivity of the Ab. In addition, in vitro protease susceptibility assay was performed to validate this method for prodrug release assay as well as to remove excess radioimmune conjugates from circulation. This orthogonal method is compatible with peptides containing a thiol, amino, or carboxyl groups in the conjugation moiety.

CS1 (CRACC, CD319) induces proliferation and autocrine cytokine expression on human B lymphocytes.

CS1 (CRACC, CD319), a member of the CD2 family of cell surface receptors, is implicated in the activation of NK cell-mediated cytotoxicity. Previous studies showed that CS1 is also expressed on activated B cells. However, the functional role of CS1 in human B-lymphocytes is not known. Two isoforms of CS1, CS1-L and CS1-S, are expressed in human NK cells that differentially regulate NK cell function. CS1-L contains immunoreceptor tyrosine-based switch motifs in its cytoplasmic domain whereas CS1-S lacks immunoreceptor tyrosine-based switch motifs. In this study, we show that human B lymphocytes express only the CS1-L isoform, and its expression is up-regulated upon B cell activation with various stimulators. Moreover, anti-CS1 mAb strongly enhanced proliferation of both freshly isolated as well as activated B cells. The enhanced proliferation effects of CS1 were most prominent on B cells activated by anti-CD40 mAbs and/or hrIL-4. The effects of CS1 on B cell proliferation were shown on both naive and memory B cells. Human cytokine microarray and quantitative real-time PCR results indicated that CS1 activation enhanced mRNA transcripts of flt3 ligand, lymphotoxin A, TNF, and IL-14. Neutralizing Abs against lymphotoxin A, TNF-alpha, and/or flt3 ligand abolished the ability of CS1 on the B cell proliferation. These results suggest that activation of B lymphocytes, through surface CS1, may be mediated through secretion of autocrine cytokines and CS1 may play a role in the regulation of B lymphocyte proliferation during immune responses.

Development of tissue plasminogen activator specific "on demand cleavable" (odc) linkers for radioimmunotherapy by screening one-bead-one-compound combinatorial peptide libraries.

New strategies are needed to protect normal organs from radiation in cancer radioimmunotherapy (RIT). This can be achieved by rapid clearance of radiometal in the circulation after accumulation of radioimmunoconjugates (RIC) in the tumor. Our strategy is to place highly efficient and specific cleavable linkers between radiometal chelates and the tumor targeting agents. Such linkers must be resistant to cleavage by enzymes present in the plasma and the tumor. After radiotargeting agents have accumulated in the tumor, a cleaving agent can be administered "on demand" to cleave a specific linker, resulting in the release of radiometal from the circulating RIC in a form that will have rapid renal clearance. We have selected TNKase, a thrombolytic agent approved for patient use, as our model on-demand cleaving agent. To identify TNKase-specific linkers, we screened fluorescent-quenched random "one-bead-one-compound" (OBOC) combinatorial peptide libraries. d-Amino acid containing peptides that were specific for TNKase but were resistant to cleavage by plasma and tumor-associated proteases were identified. One of these peptide substrates (rqYKYkf) was used to link the DOTA chelate to ChL6, a monoclonal antibody known to target breast cancer. This antibody conjugate was stable in plasma for 7 days while preserving the immunoreactivity to intact tumor cells. The addition of TNKase at clinical achievable plasma level (10 mug/mL) resulted in the release of 28% of the radiometal from the radioimmunoconjugate within 72 h. This lead linker, after further optimization to increase its response to TNKase, may be useful in the development of more effective radioimmunotherapeutic and radioimaging agents.