Soluble Antigen Arrays Displaying Mimotopes Direct the Response of Diabetogenic T Cells

This document is the Accepted Manuscript version of a Published Work that appeared in final form in ACS Chemical Biology, copyright © American Chemical Society after peer review and technical editing by the publisher. To access the final edited and published work see https://doi.org/10.1021/acschembio.9b00090.Type 1 diabetes (T1D) is an autoimmune disorder which develops when insulin-producing, pancreatic beta cells are destroyed by an aberrant immune response. Current therapies for T1D either treat symptoms or cause global immunosuppression, which leave patients at risk of developing long-term complications or vulnerable to foreign pathogens. Antigen-specific immunotherapies have emerged as a selective approach for autoimmune diseases by inducing tolerance while mitigating global immunosuppression. We previously reported SAgAs with multiple copies of a multiple sclerosis (MS) autoantigen grafted onto hyaluronic acid (HA) as an efficacious therapy in experimental autoimmune encephalomyelitis. While the immune response of MS is distinct from T1D, the mechanism of SAgAs was hypothesized to be similar and via induction of immune tolerance to diabetes antigens. We synthesized SAgAs composed of HA polymer backbone conjugated with multiple copies of the T1D autoantigen mimotope p79 using aminooxy chemistry (SAgAp79) or using copper-catalyzed alkyne-azide cycloaddition (cSAgAp79) chemistry. SAgAs constructed using the hydrolyzable aminooxy linkage, thus capable of releasing p79, exhibited physicochemical properties similar to the triazole linkage. Both SAgAp79 versions showed high specificity and efficacy in stimulating epitope-specific T cells. SAgAs can be taken up by most immune cell populations but do not induce their maturation, and conventional dendritic cells are responsible for the brunt of antigen presentation within splenocytes. cSAgAp79 was more stimulatory than SAgAp79 both in vitro and in vivo, an effect that was ascribed to the peptide modification rather than the type of linkage. In summary, we provide here the first proof-of-principle that SAgA therapy could also be applicable to T1D.NIH T32 GM008545Juvenile Diabetes Research Foundation (2-SRA-2017-312-S-B)NIH Shared Instrumentation Grant # S10RR024664NSF Major Research Instrumentation Award # 1625923NIH S10OD020056Diabetes Research Center grant P30DK063608NIH HHSN272201300006

Use of Polyhexanide and Nanomedicine Approach for Effective Treatments of Cutaneous Leishmaniasis

Despite huge suffering caused by cutaneous leishmaniasis (CL), there is no effective and affordable treatment strategy against CL and no licensed vaccines. The current treatments show limited efficacy and high toxicity. Improved therapies through discovery of novel drugs and/or an alternative treatment approaches are/is urgently needed. We aimed at identifying a novel antileishmanial agent and developing an innovative nanoparticle (NP) based platform for safe and effective treatments against CL. We discovered that polyhexanide (PHMB), a widely used antimicrobial polymer and wound antisepsis, shows an inherent antileishmanial activity at submicromolar concentrations. PHMB appears to kill L. major parasites via a dual mechanism involving disruption of membrane integrity and selective chromosome condensation. However, host chromosomes binding appear to be limited by exclusion from mammalian cell nuclei. Moreover, we attempted to establish effective drug delivery systems that overcome the various shortcomings in the present treatment of CL. In this scenario, we initially studied the cellular interactions of NPs and their uptake mechanisms into mammalian cells before applying them in drug delivery system. We obtained clear evidence for the involvement of multiple endocytic routes to internalize NPs. Physicochemical properties of NPs, cell type, temperature and pathogenesis of the target diseases were shown to be determinant factors. Thereafter, a mechanism based host- and pathogen-directed combination therapy comprising PHMB and CpG ODN immunomodulator was established for overall synergistic effect against CL. It simultaneously targets the pathogen and the host immunity with effective delivery system. The results show that PHMB binds to CpG ODN and form stable nanopolyplexes for efficient cell entry and therapy. The nanopolyplexes displayed enhanced cellular uptake and antileishmanial potency while drastically reducing the toxicity against mammalian cells. In conclusion, our findings clearly indicate that PHMB can be used as effective candidate drug against CL and as non-viral delivery of immunomodulatorynucleic acids. Moreover, our proof-of concept study showed nanomedicine approaches are effective strategy to challenge CL and other human diseases

Die Verwendung von Polyhexaniden und Konzepten der Nanomedizin zur effektiven Behandlung kutaner Leishmaniose

Despite huge suffering caused by cutaneous leishmaniasis (CL), there is no effective and affordable treatment strategy against CL and no licensed vaccines. The current treatments show limited efficacy and high toxicity. Improved therapies through discovery of novel drugs and/or an alternative treatment approaches are/is urgently needed. We aimed at identifying a novel antileishmanial agent and developing an innovative nanoparticle (NP) based platform for safe and effective treatments against CL. We discovered that polyhexanide (PHMB), a widely used antimicrobial polymer and wound antisepsis, shows an inherent antileishmanial activity at submicromolar concentrations. PHMB appears to kill L. major parasites via a dual mechanism involving disruption of membrane integrity and selective chromosome condensation. However, host chromosomes binding appear to be limited by exclusion from mammalian cell nuclei. Moreover, we attempted to establish effective drug delivery systems that overcome the various shortcomings in the present treatment of CL. In this scenario, we initially studied the cellular interactions of NPs and their uptake mechanisms into mammalian cells before applying them in drug delivery system. We obtained clear evidence for the involvement of multiple endocytic routes to internalize NPs. Physicochemical properties of NPs, cell type, temperature and pathogenesis of the target diseases were shown to be determinant factors. Thereafter, a mechanism based host- and pathogen-directed combination therapy comprising PHMB and CpG ODN immunomodulator was established for overall synergistic effect against CL. It simultaneously targets the pathogen and the host immunity with effective delivery system. The results show that PHMB binds to CpG ODN and form stable nanopolyplexes for efficient cell entry and therapy. The nanopolyplexes displayed enhanced cellular uptake and antileishmanial potency while drastically reducing the toxicity against mammalian cells. In conclusion, our findings clearly indicate that PHMB can be used as effective candidate drug against CL and as non-viral delivery of immunomodulatorynucleic acids. Moreover, our proof-of concept study showed nanomedicine approaches are effective strategy to challenge CL and other human diseases.Obgleich enorme Leiden mit der kutanen Leishmaniose einhergehen stehen bis dato keine wirkungsvollen und erschwinglichen Therapien oder zugelassene Impfstoffe zur Verfügung. Die derzeitigen Behandlungsmethoden sind kaum effektiv und zeichnen sich vor allem durch ihre enormen Nebenwirkungen aus. Aus diesem Grund ist die Erforschung neuartiger Wirkstoffe und Therapieansätze gegen kutane Leishmaniose zwingend notwendig. Die vorliegende Arbeit beschreibt die Entdeckung eines neuen antileishmanialen Wirkstoffes und die Etablierung eines innovativen und auf Nanopartikeln basierenden Verfahrens zur sicheren und effizienten Behandlung der kutanen Leishmaniose. Das Polyhexanid, welches bereits Verwendung als antimikrobielles Polymer und als Wundantiseptikum findet, weist bereits in submikromolaren Konzentrationen eine immanente antileishmaniale Wirkung auf. Den Beobachtungen zu Folge beeinflusst das Polyhexanid die Integrität der parasitären Zellmembran und führt zur selektiven Chromosomenkondensation des Parasiten Leishmania major. Eine potentielle Chromosomenmodifikation in der Säugetierzelle wird durch den Ausschluss des Polyhexanides aus dem Zellkern verhindert. Um die zahlreichen Mängel der aktuellen Behandlungsmethoden gegen kutane Leishmaniose zu überwinden, wurde zudem ein effizientes System der Wirkstoffabgabe etabliert. Diesbezüglich wurden zunächst die zellulären Wechselwirkungen der Nanopartikel und deren Aufnahme in die Säugtierzelle untersucht ehe diese als Vehikel für den Wirkstoff verwendet wurden. Es konnte gezeigt werden, dass die Nanopartikel über mehrere endozytische Wege internalisiert werden. Physikochemische Eigenschaften der Nanopartikel, der Zelltyp, die Temperatur und erregerspezifische Pathogenese gehören zu den beeinflussenden Faktoren. Daraufhin wurde eine Kombinationstherapie bestehend aus Polyhexaniden und dem unmethylierten Immunmodulator Zystein-Phosphat-Guanin Oligodeoxynukleotid mit synergistischen antileishmanialen Auswirkungen, etabliert. Dies gestattet eine gegen den Erreger zielgerichtete Behandlung und die zeitgleiche Stimulierung der Wirtsimmunität. Die Bildung eines stabilen Nanopolyplexes bestehend aus dem Polyhexanid und dem oben genannten Immunmodulator befähigen die effiziente Aufnahme in die Zelle und somit die Behandlung. Der Nanopolyplex ermöglicht eine verbesserte Aufnahme in die Zelle und antileishmaniale Wirksamkeit wohingegen die Toxizität gegenüber Säugetierzellen drastisch reduziert ist. Zusammenfassend lässt sich feststellen, dass Polyhexanide als effizienter Wirkstoffkandidat gegen kutane Leishmaniose und als nicht-viraler Träger von immunmodulatorischen Nukleinsäuren zu betrachten sind. Zugleich wurde gezeigt, dass die Nanomedizin einen wertvollen Beitrag zur Bekämpfung der kutanen Leishmaniose und sicherlich auch anderer Krankheitserregern leisten kann

Epitope-based precision immunotherapy of Type 1 diabetes

Antigen-specific immunotherapies (ASITs) address important clinical needs in treating autoimmune diseases. However, Type 1 diabetes is a heterogeneous disease wherein patient characteristics influence responsiveness to ASITs. Targeting not only disease-relevant T cell populations, but also specific groups of patients using precision medicine is a new goal toward achieving effective treatment. HLA-restricted peptides provide advantages over protein as antigens, however, methods for profiling antigen-specific T cells need to improve in sensitivity, depth, and throughput to facilitate epitope selection. Delivery approaches are highly diverse, illustrating the many ways relevant antigen-presenting cell populations and anatomical locations can be targeted for tolerance induction. The role of persistence of antigen presentation in promoting durable antigen-specific tolerance requires further investigation. Based on the outcome of ASIT trials, the field is moving toward using patient-specific variations to improve efficacy, but challenges still lie on the path to delivering more effective and safer treatment to the T1D patient population

Efficient Presentation of Multiple Endogenous Epitopes to Both CD4+ and CD8+ Diabetogenic T Cells for Tolerance

Antigen-specific immunotherapy of type 1 diabetes, typically via delivery of a single native β cell antigen, has had little clinical benefit to date. With increasing evidence that diabetogenic T cells react against multiple β cell antigens, including previously unappreciated neo-antigens that can be emulated by mimotopes, a shift from protein- to epitope-based therapy is warranted. To this end, we aimed to achieve efficient co-presentation of multiple major epitopes targeting both CD4+ and CD8+ diabetogenic T cells. We have compared native epitopes versus mimotopes as well as various targeting signals in an effort to optimize recognition by both types of T cells in vitro. Optimal engagement of all T cells was achieved with segregation of CD8 and CD4 epitopes, the latter containing mimotopes and driven by endosome-targeting signals, after delivery into either dendritic or stromal cells. The CD4+ T cell responses elicited by the endogenously delivered epitopes were comparable with high concentrations of soluble peptide and included functional regulatory T cells. This work has important implications for the improvement of antigen-specific therapies using an epitope-based approach to restore tolerance in type 1 diabetes and in a variety of other diseases requiring concomitant targeting of CD4+ and CD8+ T cells