Characterization of the canine CD20 as a therapeutic target for comparative passive immunotherapy.

Anti-CD20 therapies have revolutionized the treatment of B-cell malignancies. Despite these advances, relapsed and refractory disease remains a major treatment challenge. The optimization of CD20-targeted immunotherapies is considered a promising strategy to improve current therapies. However, research has been limited by the scarcity of preclinical models that recapitulate the complex interaction between the immune system and cancers. The addition of the canine lymphoma (cNHL) model in the development of anti-CD20 therapies may provide a clinically relevant approach for the translation of improved immunotherapies. Still, an anti-CD20 therapy for cNHL has not been established stressing the need of a comprehensive target characterization. Herein, we performed an in-depth characterization on canine CD20 mRNA transcript and protein expression in a cNHL biobank and demonstrated a canine CD20 overexpression in B-cell lymphoma samples. Moreover, CD20 gene sequencing analysis identified six amino acid differences in patient samples (C77Y, L147F, I159M, L198V, A201T and G273E). Finally, we reported the use of a novel strategy for the generation of anti-CD20 mAbs, with human and canine cross-reactivity, by exploring our rabbit derived single-domain antibody platform. Overall, these results support the rationale of using CD20 as a target for veterinary settings and the development of novel therapeutics and immunodiagnostics.

Synthetic antibody discovery against native antigens by CRISPR/Cas9-library generation and endoplasmic reticulum screening.

Despite the significant advances of antibodies as therapeutic agents, there is still much room for improvement concerning the discovery of these macromolecules. Here, we present a new synthetic cell-based strategy that takes advantage of eukaryotic cell biology to produce highly diverse antibody libraries and, simultaneously, link them to a high-throughput selection mechanism, replicating B cell diversification mechanisms. The interference of site-specific recognition by CRISPR/Cas9 with error-prone DNA repair mechanisms was explored for the generation of diversity, in a cell population containing a gene for a light chain antibody fragment. We achieved up to 93% of cells containing a mutated antibody gene after diversification mechanisms, specifically inside one of the antigen-binding sites. This targeted variability strategy was then integrated into an intracellular selection mechanism. By fusing the antibody with a KDEL retention signal, the interaction of antibodies and native membrane antigens occurs inside the endoplasmic reticulum during the process of protein secretion, enabling the detection of high-quality leads for expression and affinity by flow cytometry. We successfully obtained antibody lead candidates against CD3 as proof of concept. In summary, we developed a novel antibody discovery platform against native antigens by endoplasmic synthetic library generation using CRISPR/Cas9, which will contribute to a faster discovery of new biotherapeutic molecules, reducing the time-to-market.

Establishment of a bioluminescent canine B-cell lymphoma xenograft model for monitoring tumor progression and treatment response in preclinical studies.

Canine diffuse large B-cell lymphoma (DLBCL) is one of the most common cancers in dogs which shares remarkable similarities with its human counterpart, making the dog an excellent model for the investigation of novel therapeutic agents. However, the integration of canine lymphoma in comparative studies has been limited due in part to the lack of suitable xenograft mouse models for preclinical studies. To overcome these limitations, we established and characterized a localized subcutaneous bioluminescent canine DLBCL xenograft mouse model. The canine CLBL-1 cell line stably expressing the luciferase and green fluorescent protein reporters was generated and used to establish the xenograft tumor model. A pilot study was first conducted with three different cell densities (0.1×10(6), 0.5×10(6) and 1×10(6) cells) in SCID mice. All mice presented homogeneous tumor induction within eight days after subcutaneous injection, with a 100% engraftment efficiency and no significant differences were observed among groups. The tumors were highly aggressive and localized at the site of inoculation and reproduced histological features and immunophenotype consistent with canine DLBCL. Importantly, xenograft tumors were detected and quantified by bioluminescent imaging. To assess response to therapy, a therapeutic study with a histone deacetylase inhibitor, panobinostat, was performed. The results demonstrated that panobinostat (20 mg/kg) efficiently inhibited tumor growth and that bioluminescent imaging allowed the monitorization and quantification of tumor response to therapy. In summary, this study provides a bioluminescence canine DLBCL model that offers high engraftment efficiency, preservation of tumor features, and noninvasive monitoring of tumor progression, validating the model as a promising preclinical tool for both veterinary and human medicine.

Development of synthetic light-chain antibodies as novel and potent HIV fusion inhibitors.

OBJECTIVE: To develop a novel and potent fusion inhibitor of HIV infection based on a rational strategy for synthetic antibody library construction. DESIGN: The reduced molecular weight of single-domain antibodies (sdAbs) allows targeting of cryptic epitopes, the most conserved and critical ones in the context of HIV entry. Heavy-chain sdAbs from camelids are particularly suited for this type of epitope recognition because of the presence of long and flexible antigen-binding regions [complementary-determining regions (CDRs)]. METHODS: We translated camelid CDR features to a rabbit light-chain variable domain (VL) and constructed a library of minimal antibody fragments with elongated CDRs. Additionally to elongation, CDRs' variability was restricted to binding favorable amino acids to potentiate the selection of high-affinity sdAbs. The synthetic library was screened against a conserved, hidden, and crucial-to-fusion sequence on the heptad-repeat 1 (HR1) region of the HIV-1 envelope glycoprotein. RESULTS: Two anti-HR1 VLs, named F63 and D104, strongly inhibited laboratory-adapted HIV-1 infectivity. F63 also inhibited infectivity of HIV-1 and HIV-2 primary isolates similarly to the Food and Drug Administration-approved fusion inhibitor T-20 and HIV-1 strains resistant to T-20. Moreover, epitope mapping of F63 revealed a novel target sequence within the highly conserved hydrophobic pocket of HR1. F63 was also capable of interacting with viral and cell lipid membrane models, a property previously associated with T-20's inhibitory mechanism. CONCLUSION: In summary, to our best knowledge, we developed the first potent and broad VL sdAb fusion inhibitor of HIV infection. Our study also gives insights into engineering strategies that could be explored to enhance the development of antiviral drugs.

Assessing combinatorial strategies to multimerize libraries of single-domain antibodies.

Single-domain antibodies (SDAs) are among the most studied and interesting antibody fragments. These molecules combine advantages of antibodies and small molecules. However, SDAs present a low efficiency of in vivo targeting because of their low binding avidity and fast clearance from blood circulation. Multimerization of SDA can overcome these drawbacks and increase their therapeutic potency. In this work, we developed and compared three strategies that allow construction of SDA dimers derived from rabbit light chains--PCR overlap, sticky PCR, and restriction/ligation. The restriction/ligation strategy proved to be the most efficient and feasible method to construct a successful library of SDA dimers. To further explore this technique, we constructed different libraries that differed in linker length between the two SDAs, and assessed its efficiency to deliver antigen-specific SDA dimers. We efficiently increased both the molecular size and avidity of antibody fragments, increasing the possibility of these molecules to bind to their antigen. Therefore, this work describes efficient tools for therapeutic development of SDA dimers.