Cambridge Healthtech Institute’s 5th Annual

Emerging Indications for Therapeutic Antibodies

New Targets, Pathways, and Strategies for Non-Cancer Therapeutics

May 13 - 14, 2024 ALL TIMES EST

Significant advances in the fields of immunology and protein science are driving the development of biotherapeutics in a growing range of therapeutic areas beyond oncology. These advances support the identification of new and unique targets and pathways, new approaches to developing biotherapeutics for unserved medical needs, methods of binding to elusive targets, and translational science for patient stratification. The PEGS Emerging Indications for Therapeutic Antibodies conference provides a forum for research organizations with diverse portfolios to explore new science and technology in the development of the next generation of safe and effective therapeutics in therapeutic areas including autoimmunity, pain, infectious diseases, metabolic/cardiovascular diseases, and neuroscience.

Sunday, May 12

Main Conference Registration1:00 pm

Recommended Pre-Conference Short Course2:00 pm

SC3: In silico and Machine Learning Tools for Antibody Design and Developability Predictions

*Separate registration required. See short course page for details.

Monday, May 13

Registration and Morning Coffee7:00 am

AUTOIMMUNITY AND INFLAMMATION

8:20 am

Chairperson's Remarks

Ahuva Nissim, PhD, Professor, Antibody and Therapeutic Engineering, William Harvey Research Institute, Queen Mary University of London

8:30 am

Development of Izokibep: An IL-17A Selective Affibody Molecule for Autoimmune Diseases

Fredrik Frejd, PhD, CSO, Affibody AB

Izokibep is a novel Affibody molecule engineered to develop a potentially best-in-class IL-17A blocking ligand trap with femtomolar binding affinity and small molecular size that translates to high therapeutic efficacy in patients with psoriasis, psoriatic arthritis, and hidradenitis suppurativa. Excellent three-year safety and efficacy data support both the IL-17 program as well as the Affibody drug class in general. Izokibep is now in late-stage clinical development.

9:00 am

Engineering Long-Circulating IL-35 to Suppress Inflammation and Autoimmune Diseases

Jun Ishihara, PhD, Lecturer, Bioengineering, Imperial College London

IL-35 is a strong multi-pathway anti-inflammatory cytokine, but it is difficult to produce. Our computational structural analyses identified the intracellular binding site of IL-35, succeeding large-scale production by mammalian cells. For autoimmune diseases, current therapies are treating the symptoms. We engineered lymph-node targeted IL-35, which achieves therapeutic effects in rheumatoid arthritis and directly suppresses activated immune cells. IL-35 would offer long-term treatment-free periods for patients with many inflammatory diseases.

  • IL-35 induces Tregs, Bregs, tolerogenic DCs, M2 macrophages
  • IL-35 is reportedly effective in many inflammatory diseases (RA, T1D, MS, scleroderma, AD, ILD, IBD, infections, stroke)
  • New cytokine-based therapies for autoimmune diseases
9:30 am

Biomarker-Driven Therapeutic Antibody Discovery and Development for Fibro-Inflammatory Diseases

Laurent Audoly, PhD, Co-Founder & CEO, PriveBio Inc.; Executive Partner, Apollo Health Ventures; Senior Advisor & Professor of the Practice, AI Drug Discovery & Development, Northeastern University

Biomarker-driven therapeutic intervention increases the probability that a novel medicine will benefit the right patient population at the right time. PriveBio is advancing a pipeline of first-in-class therapeutics built in tandem with a precision medicine framework for testing in patients to achieve efficient proof-of-biology and early proof-of-concept in fibro-inflammatory diseases to ultimately achieve disease modification.

10:00 am

TRB-061: A Selective, Potent TNFR2 Agonist for the Treatment of Autoimmune and Inflammatory Diseases

Robin Aglietti, PhD, Principal Scientist, BioTherapeutics, TRexBio

TNFR2 is highly expressed on immunosuppressive regulatory T cells (Tregs) that modulate immune homeostasis. We developed a TNFR2-selective agonist, TRB-061, that demonstrates potent in vivo Treg augmentation, providing protection in preclinical inflammatory models. Our deep biology platform reveals the molecular details of TNFR2 agonism on Treg activation and expansion. Interrogation of TRB-061 signaling suggests differentiated clinical opportunities that position TRB-061 as a promising Treg modulator for inflammatory and autoimmune indications.

Networking Coffee Break10:30 am

NEURODEGENERATIVE DISEASE STRATEGIES

11:00 am

Targeting TDP-43 with Next-Generation Vectorized Antibodies

Damien Nevoltris, PhD, Senior Team Leader Antibody Engineering, AC Immune SA

TAR DNA binding protein-43 (TDP-43) is a hallmark of devastating neurodegenerative diseases, such as amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). Recently, we reported that a monoclonal antibody (mAb) targeting TDP-43, ACI-5891, conferred neuroprotection in ALS/FTD models. To improve brain penetration of mAbs which necessitates high dosing regimens, we created and evaluated the potency of a single-dose vectorized full-length antibody delivered by adeno-associated virus in mouse model.

11:30 am

Antibodies to Re-Target AAV Delivery to the Brain

Abhishek Chatterjee, PhD, Professor, Chemistry, Boston College

The genetic code expansion technique enables precise incorporation of noncanonical ncAAs carrying diverse chemical functionalities into proteins expressed within living cells. This technology offers new opportunities to precisely engineer next-generation biotherapeutics with new capabilities. This presentation explores recent strides made in enhancing the scalability of this approach, and its application in generating homogeneous site-specific antibody conjugates, and precisely modified adeno-associated virus capsids for GT applications with heightened precision and efficacy.

Session Break12:00 pm

12:05 pm Luncheon Presentation INona's Fully Human Heavy Chain Only Antibodies to Develop Next-Gen Biotherapeutics

Jason Noon, Associate Director of Biology, Nona Biosciences

Nona Biosciences a biotechnology company specializes in proprietary transgenic mice for fully human antibody production. Our fully human heavy chain only antibody (HCAb) platform offers compact size, efficient discovery, and minimal immunogenicity.Join us to explore HCAb's application in Next-Gen biotherapeutics like ADCs, mRNA, and immune cell engagers. Learn about NonaCAR for Next-Gen cell therapies, featuring successful NonaCAR-T projects and our robust HCAb discovery via NonaCarFx screening

Session Break1:05 pm

CHALLENGES AND SOLUTIONS FOR EMERGING INDICATIONS

1:10 pm

Chairperson's Remarks

Laurent Audoly, PhD, Co-Founder & CEO, PriveBio Inc.; Executive Partner, Apollo Health Ventures; Senior Advisor & Professor of the Practice, AI Drug Discovery & Development, Northeastern University

1:15 pm

Universal Vaccines and Universal Antivenom: How to Elicit Broadly Neutralizing Antibodies in Vivo

Jacob Glanville, Founder, CEO & President, Centivax

From infectious disease to snake venom, mutational diversity of target proteins frequently limits the utility of vaccines and therapeutics. Here we present two examples of in vivo elicitation of broadly neutralizing antibodies. In the case of vaccines, we review how this enables pan-influenza and pan-coronavirus vaccines. In the case of snake envenoming, we review how a cocktail of two bnAbs and an inhibitor enables protection against hundreds of snake species.

1:45 pm

Developing pHLA-Targeting T Cell Engagers against Novel Targets in Solid Tumors

Leah Sibener, PhD, Co-Founder & Vice President, Therapeutic Discovery, 3T Biosciences, Inc.

Numerous immunotherapy modalities leverage T cells’ unmatched ability to recognize and kill tumor cells; however, clinical responses in cold tumors have been limited. Recently, T cell engagers targeting peptide-HLA molecules (pHLA) have demonstrated transformative responses in these indications. We’ve developed 3T-TRACE to rapidly identify pHLA antigens recognized orphan T cells from patient tumors, and 3T-PRIME, a TCR mimetic platform to expand the development of this promising modality.

2:15 pm

KEYNOTE PRESENTATION: Challenges and Opportunities in Therapeutic Antibodies for Non-Cancer Indications

Antonios Aliprantis, MD, PhD, Vice President, Program Leadership, Pioneering Medicines, Flagship Pioneering

Therapeutic antibodies have been available for almost 3 decades for non-oncology indications, particularly in inflammation and immunology. However, progress has relied on empiric discovery processes resulting in long cycle times from conception to approval. We will review technologic advances in systems modeling, antibody identification, and the modulation of antibody function, which have led to optimized candidates and opened the door to new indication opportunities for patients.

2:45 pm

Therapeutic Silencing Spp1 in Cardiac Macrophages Suppresses Atrial Fibrillation

Noor Momin, PhD, Assistant Professor, University of Pennsylvania

Atrial fibrillation and the risk of its lethal complications are worsened by atrial fibrosis. Our recent study implicates osteopontin, which is encoded by Spp1, and secreted by atrial macrophages in this fibrosis. We now find that silencing Spp1 in this subset of cardiac macrophages using an engineered antibody-siRNA conjugate reduces atrial fibrosis and suppresses AFib, thus offering an immunotherapy for this common arrhythmia.

Networking Refreshment Break3:15 pm

Transition to Plenary Keynote Session4:15 pm

PLENARY KEYNOTE SESSION

4:25 pm

Plenary Keynote Introduction

Laszlo G. Radvanyi, PhD, President & Scientific Director, Ontario Institute for Cancer Research

4:35 pm

Driving New CAR T Cells

Marcela V. Maus, MD, PhD, Associate Professor, Medicine; Director, Cellular Immunotherapy, Massachusetts General Hospital

We will talk about various roads and challenges in driving new CAR T cells toward the clinic, and learnings from clinical experience.

YOUNG SCIENTIST KEYNOTE

5:20 pm

High-Throughput Discovery of Protein Folding Stability and Dynamics

Gabriel J. Rocklin, PhD, Assistant Professor, Pharmacology, Northwestern University

Every protein has its own conformational energy landscape that governs its folding stability and dynamics. These varied landscapes are rarely predictable in protein engineering but strongly influence function, aggregation, immunogenicity, and more. Our lab develops new large-scale methods to measure stability and dynamics. I will share lessons from stability measurements of >750,000 protein domains and dynamics measurements of >5,000 domains, highlighting the potential to rationally engineer stability and dynamics.

Welcome Reception in the Exhibit Hall with Poster Viewing6:05 pm

YOUNG SCIENTIST MEET-UP

7:00 pm

Facilitators of Young Scientist Meet Up: IN-PERSON ONLY

Orhi Esarte Palomero, PhD, Postdoctoral Fellow, Pharmacology, Northwestern University

Alexandros Karyolaimos, PhD, Researcher, Department of Biochemistry & Biophysics, Stockholm University

Shakiba Nikfarjam, PhD, Postdoc, Lawrence Livermore National Lab

Network, Inspire Others and Connect

The young scientist meet-up is an opportunity for scientists entering the field to develop connections across institutions, and for established leaders to come build relationships with the next generation of scientists. The meet-up will pave the way for mentorships, professional opportunities, and scientific discovery.

  • Get to know fellow peers and colleagues
  • Make connections and network with other institutions
  • Inspire others and be inspired!​​​

Close of Day7:30 pm

Tuesday, May 14

Registration and Morning Coffee7:30 am

OTHER EMERGING INDICATIONS

7:55 am

Chairperson’s Remarks

Leah Sibener, PhD, Co-Founder & Vice President, Therapeutic Discovery, 3T Biosciences, Inc.

8:00 am

Targeting GIP and GLP-1 for Treatment of Obesity

Michael Wolfe, MD, Professor, Physiology and Biophysics, Case Western Reserve University

GLP-1 and GIP are incretin hormones, whose primary physiologic property are to stimulate postprandial insulin secretion. GLP-1, and more recently GIP, analogues have been used as appetite suppressants to effectively treat obesity. Ironically, genetic disruption of GLP-1 and GIP—which like insulin is overexpressed in obesity—prevents obesity, and antibodies to GIP or its receptor (GIPR) have been shown to effectively treat obesity independent of appetite by decreasing intestinal nutrient absorption and adipocyte lipid storage. Because GIP overexpression is regarded as one of the etiologic factors of obesity, abrogation of GIP signaling may represent a more logical approach for obesity therapy.

8:30 am

Biotherapeutics for Mast Cell-Associated Inflammatory Diseases

Joel Goldstein, PhD, Executive Director R&D, Celldex Therapeutics

Mast cells (MCs) are immune cells that drive or contribute to the pathophysiology of allergic, inflammatory, autoimmune, and fibrotic disorders. Activation of the KIT receptor by its sole ligand, SCF, is required for MC survival. Reduction of MCs through the KIT-directed inhibitory antibody barzolvolimab has shown promising clinical activity in chronic urticarias and prurigo nodularis. SCF neutralization is expected to similarly decrease MC numbers. TSLP neutralization has demonstrated clinical activity in asthma. CDX-622 is a bispecific antibody that simultaneously neutralizes SCF and TSLP and may offer enhanced therapeutic benefit by targeting complementary pathways that drive chronic inflammation.

Coffee Break in the Exhibit Hall with Poster Viewing9:00 am

PLENARY KEYNOTE SESSION

10:00 amTransition to Plenary Keynote Session
10:10 am

Plenary Keynote Introduction 

Jennifer R. Cochran, PhD, Senior Associate Vice Provost for Research, Macovski Professor of Bioengineering, Stanford University

10:15 am

Laboratory Evolution of Genome Editing Proteins for Precise Gene Correction and Targeted Gene Integration in Mammalian Cells 

David R. Liu, PhD, Richard Merkin Professor and Director, Merkin Institute of Transformative Technologies in Healthcare; Core Institute Member and Vice-Chair of the Faculty, Broad Institute; Director, Chemical Biology and Therapeutic Sciences Program; Investigator, Howard Hughes Medical Institute; Thomas Dudley Cabot Professor of the Natural Sciences and Professor of Chemistry and Chemical Biology, Harvard University

In this lecture I will describe the use of protein evolution and protein engineering to develop precision genome editing technologies. These technologies include base editors, prime editors, recombinases, and CRISPR-associated transposases (CASTs). Base editors and prime editors have been used by many laboratories around the world to correct pathogenic mutations, resulting in ex vivo and in vivo one-time treatments that rescue disease phenotypes in many animal models of devastating genetic disorders. At least nine base editing clinical trials have begun, with positive clinical readouts from at least three of these trials, and the first prime editing clinical trial was recently cleared by FDA to begin in the U.S. I will also describe the use of phage-assisted continuous evolution (PACE) to evolve prime editors, recombinases, and CASTs to enable efficient targeted gene-sized integration in human cells, addressing a longstanding challenge in the genome editing field. These engineered and evolved proteins enable precise target gene correction, disruption, or insertion in a wide range of organisms with broad implications for the life sciences and therapeutics.

Celebrating 20 Years in the Exhibit Hall with Poster Viewing11:00 am

12:00 pm

New Biotherapeutic Strategies to Treat Heart Disease

Nicholas Marston, MD, MPH, Preventive Cardiologist and Assistant Professor, Brigham and Women's Hospital and Harvard Medical School

How we treat heart disease has evolved significantly in recent years. Monoclonal antibodies and RNA-based therapies have dominated new drug development, and CRISPR-based gene editing has entered clinical trials. Large-scale genomics has identified numerous novel proteins for these platforms to target, and nowhere has this been more evident than in hyperlipidemia, where over a dozen new therapies have been developed for four genetically validated therapeutic targets: PCSK9, Lp(a), ANGPTL3, Apo-CIII.

12:30 pm

FEATURED POSTER PRESENTATION: Anti-Idiotypic Antibody as Booster Vaccine against Respiratory Syncytial Virus

Shreya Mukhopadhyay, PhD, Postdoctoral Research Fellow, Antibody Discovery, Merck

RSV causes respiratory infections in both children and adults globally. This study investigated using anti-idiotypic antibodies as a booster vaccine for RSV by targeting a broad RSV-neutralizing antibody RB1. Cryo-EM analysis confirmed the Anti-ID mimics the binding of RSV prefusion F protein to RB1. Mice primed with RSV-F and boosted with Anti-ID showed specific B-cell responses. This suggests Anti-IDs have potential as booster vaccines for RSV and other infectious diseases.

Close of Emerging Indications for Therapeutic Antibodies Conference1:00 pm

Recommended Dinner Short Course6:30 pm

SC6: Best Practices for Targeting GPCRs, Ion Channels, and Transporters with Monoclonal Antibodies

*Separate registration required. See short course page for details.






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