Enhance the homogeneity, potency, and safety of your antibody-drug conjugates (ADCs) thanks to ProteoGenix’s flexible and diversified antibody-drug conjugate service platform. Drawing from 20+ years of experience in ADC development, our platform allies the high productivity of the XtenCHOᵀᴹ cell line with the high efficiency of click chemistry for antibody conjugation and robust bioanalytical methods. Obtain high-quality ADC products with up to 90% of antibodies conjugated with the desired drug-to-antibody (DAR) ratio.

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Why choose ProteoGenix for your antibody-drug
conjugate development project?

Flexible conjugation strategies

Choose between chemical (cysteine and lysine) and click chemistry conjugation methods according to your unique needs

Drug diversity and dual drug ADC development

Choose the best drug for an optimal therapeutic efficacy or opt for dual drug systems thanks to our click chemistry platform for a synergist treatment

IP free

Keep full ownership of the antibodies developed for your ADC applications

Accelerated antibody production

Seep up ADC development and antibody engineering (affinity, click chemistry…) thanks to our highly productive cell line – XtenCHOᵀᴹ

Extensive bioanalytical capabilities

Characterize DAR values, drug load distribution, % of free drug and antibody with high accuracy and precision to ensure high success rates during clinical development

Solid track record

Benefit from 20+ years of experience in antibody-drug conjugate (ADC) development a 5 therapeutic ADCs in clinical trials

Vast range of complimentary services

Streamline ADC development thanks to our flexible solutions in antibody discovery (phage display, hybridoma), engineering (affinity, stability), and stable cell line generation

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ProteoGenix’s Antibody Drug Conjugate Development Process

I. Preliminary phase (optional)

  • • Antibody is provided by the customer
    Or
  • Antibody discovery (hybridoma or antibody phage display) and antibody production (XtenCHO™)
  • Antibody affinity maturation
  • Optimal parameter determination: antibody, linker, payload, DAR, payload location and distribution, among others.

Payload Selection and ADC Development

  • Antibody engineering for click chemistry conjugation and rapid production in XtenCHO™ cells
  • Appropriate selection of the payload (payload is chosen based on its mechanisms of action, potency and therapeutic relevance for the specific target).

Antibody Conjugation

  • Conjugation approaches :
  • Chemical conjugation
  • Ezymatic conjugation

ADC Optimization and Bioanalysis

  • The ADC is optimized to achieve the desired drug-to-antibody ratio (DAR)
  • Perform quality control tests to determine:

– The desired DAR

– Overall antibody quality

ADC Is Delivered

High Productivity (scale-up) Stable Cell Line Development (Optional)

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How Much Does Antibody Drug Conjugation (ADC) Development Cost?

Antibody-drug conjugates (ADCs) are a category of biopharmaceutical drugs engineered as precise, targeted therapies for cancer treatment. Distinguished from traditional chemotherapy, ADCs are designed to selectively seek out and eliminate tumor cells, while preserving the well-being of healthy cells.

Our antibody-drug conjugate service can vary significantly in cost depending on several factors. Our prices start at a few thousand euros and scale upward depending on project complexity. The final cost is influenced by factors such as the source of the antibody and or antigen – whether provided by you or produced by our expert team at ProteoGenix. Additionally, the chosen approach for conjugation, be it chemical or enzymatic linkage, plays a role in determining the overall cost.

We are committed to providing transparent and fair pricing, enabling you to access high-quality ADC development services without breaking the bank. Unlock the therapeutic potential of your antibody with our cost-effective ADC development solutions. Trust in ProteoGenix’s extensive 20+ years of experience, where we prioritize delivering exceptional results while keeping your budget in mind.

How Long Does It Take to Develop an Antibody Drug Conjugate?

At ProteoGenix, we understand that timing is everything. That’s why we aim to complete each ADC conjugation service in a timely manner with the highest priority. The duration of the process largely hinges on the specific conjugation approach selected for your project. Typically, the timeline can vary from a few weeks to several months, depending on various factors.

However, the antibody-drug conjugate
service timeline can be streamlined by providing the antibody sequence to our antibody experts, if available. In such cases, the process may take a few weeks, as we can readily proceed with the ADC development using your provided antibody.

On the other hand, if the antibody needs to be produced or developed by ProteoGenix, the timeline may extend to a few months. Our experienced team will work diligently to ensure the efficient production and characterization of each antibody before advancing to the ADC conjugation phase.

Rest assured that regardless of the timeline, our priority is delivering reliable, high-quality ADC solutions that align with your research or therapeutic objectives. We are committed to working closely with you throughout the development process as our Ph.D. account managers stay on constant communication about the progression of each project.

How to choose the right Conjugation Strategy for your Antibody Drug Conjugation Development?

We offer two distinct approaches for each ADC conjugation service: chemical conjugation or enzymatic conjugation. Each method holds unique principles that play a pivotal role in determining the most suitable strategy for your specific project.

Chemical conjugation involves the covalent attachment of payloads to antibodies using specialized chemical linkers. On the other hand, enzymatic conjugation leverages enzymatic reactions to achieve the conjugation of payloads to antibodies.

Understanding the differences between these approaches is crucial for making an informed decision. Below is a table comparing key differences between chemical conjugation and enzymatic conjugation.

ADC Conjugate Variables Chemical Conjugation Enzymatic Conjugation
Conjugation Site Site-specific Site-specific
Conjugation Step 2-steps 1-step
Antibody Format Full IgG Full IgG, scFv, Fab or VHH
Drug-Antibody Ratio 1, 2 or 4 1, 2, 4 or 2+2
Linker Type Cleavable and non-cleavable Cleavable and non-cleavable
Payload Type Drug Drug, DNA, RNA or fluorochrome
Conjugation Efficiency Mid efficiency High efficiency
Batch-to-Batch Consistency Mid consistency High consistency
Production Time ++ +++
Pricing +++ +++

Several factors influence the choice of conjugation strategy using our antibody-drug conjugation service. First and foremost, the customer’s budget is a critical consideration. While enzymatic conjugation may be faster than chemical conjugation, the latter can offer distinct advantages for specific applications.

The timeline of the customer’s project is also a key factor. Enzymatic methods, due to their swifter nature, may be preferred for time-sensitive projects. Additionally, whether the customer provides the antibody or requires ProteoGenix to develop and produce it can impact the choice of strategy.

The number of linkers and payloads, as well as the desired Drug-to-Antibody Ratio (DAR), also influence the selection. Different strategies may yield varying results in terms of efficiency and performance, which is why we generally recommend testing both approaches in parallel.

At ProteoGenix, our expert team is dedicated to guiding you through this decision-making process through our free consultation service. We work closely with you to understand your unique requirements and objectives, ensuring that the chosen conjugation strategy aligns seamlessly with your project goals.

How is the quality of your ADCs controlled?

ProteoGenix’s antibody experts are committed to delivering ADCs of exceptional quality and performance that can only be maintained by rigorous quality control protocols. Our antibody-drug conjugate service offers a comprehensive bioanalysis of ADCs designed to ensure the highest standards are met throughout the development process.

  • HPLC-HIC, HPLC-SEC, and SDS-PAGE: These techniques play a crucial role in confirming DAR and detecting any aggregated or degraded antibody. High-Performance Liquid Chromatography (HPLC) combined with Hydrophobic Interaction Chromatography (HIC) helps analyze hydrophobic interactions, while HPLC with Size-Exclusion Chromatography (SEC) assesses the size distribution of molecules. Sodium Dodecyl Sulfate Polyacrylamide Gel Electrophoresis (SDS-PAGE) allows for protein separation based on molecular weight.

 

  • Binding Analysis: To assess the binding capacity and antibody affinity, we employ various methods, including Enzyme-Linked Immunosorbent Assay (ELISA), Surface Plasmon Resonance (SPR) using Biacore systems for antibody KD determination, and Fluorescence-Activated Cell Sorting (FACS). These techniques enable us to understand the interaction between the ADC and its target.

 

  • Stability: Differential Scanning Calorimetry (DSC) is utilized to investigate the stability of ADCs under different conditions, allowing us to understand their behavior over time.

 

  • Crossreactivity: We assess ADC crossreactivity potential using bioinformatics tools to predict unintended binding to related proteins, ensuring safety and specificity in cancer immonotherapy therapy.

Main components and mechanism
of action of ADCs

ADCs consist of the following components:

  • Antibody carrier: monoclonal antibody, bispecific antibody, antibody fragment
  • Linker: cleavable or non-cleavable linker
  • Payload: small drugs, toxins, antibiotics, or enzymes, among others

These complex molecules combine the specificity of immunotherapies with the potency of cytotoxic agents. In the past decades, ADCs have found great success in the treatment of cancer, particularly, hematological conditions. With the continued improvement of linker chemistry and conjugation methods, ADCs will soon be viable tools to fight a larger number of malignancies.

Given the structure of ADCs, they are designed to target membrane-bound receptors that are abundant, specific to cancer cells, and efficiently recycled after cellular internalization. The major mechanism of action of ADCs involves the following steps:

  • Biding of the antibody carrier to the specific membrane-bound receptor
  • Internalization of the ADC complex by receptor-mediated clathrin-dependent endocytosis
  • Maturation of the endosome and fusion with the lysosome
  • Lysosomal degradation of the ADC and release of the cytotoxic payload
ADC mechanism of action

An alternative mechanism of action relies on the release of the payload in the tumor microenvironment. With the use of cleavable linkers, it is possible to trigger the release of the payload via chemical signals, conditions, or enzymes. By releasing the payload in the extracellular matrix, cytotoxic agents are free to diffuse more quickly through solid tumors, thus averting the antigen barrier, and targeting cancer cells with significant mutations in the selected receptor (bystander effect).

The continued refinement of linker chemistry and conjugation methods is paving the way for ADCs to become effective tools in combatting a wider range of cancer types. With ongoing research and clinical trials, ADCs hold immense promise in offering more precise, less toxic, and potentially life-saving treatments for cancer patients.

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Key principles of ADC development

Common Antibody Conjugation Strategies Used In Adc Development

Multiple strategies have been developed to conjugate linker-payload pairs to antibody carriers. The efficiency of these methodologies directly influences the load and distribution of payloads along the antibody backbone and the heterogeneity of the resulting ADC.

  • Chemical conjugation: it is the most commonly used conjugation method and relies on exposed and reactive functional residues on the surface of the antibody carrier. The two most common residues used for this conjugation strategy are cysteine (reactive with thiol groups inserted on the payload) and lysine (amine groups). Of the two reactive residues, cysteine was proven to allow superior control over DAR and drug load distribution properties due to the lower occurrence of accessible residues on the antibody surface. The unique advantage of this method is that it does not require antibody engineering prior to drug conjugation.
  • Enzymatic conjugation: enzymes can modify an antibody in a site or sequence-specific manner. Most enzymatic-based antibody conjugation strategies are based on the use of sortase A. This enzyme cleaves threonine-glycine bonds and attaches an oligoglycine molecule at the site. Microbial transglutaminase has also been successfully used to attach payloads to glycans on the Fc fragment of the antibody carrier.
  • Site-specific conjugation: a number of site-specific conjugation methods have been developed in the past years as a way to improve the homogeneity of final ADC products. These methods rely on the engineering of specific residues along the antibody backbone allowing a stricter control of DAR and drug load distribution.
  • Click chemistry conjugation: click chemistry is defined as an efficient and high-yield process making use of inexpensive reagents and requiring only mild conditions. Both payload-linker pairs and the antibody backbone are engineered to carry a specific, self-reacting tag. Once these components are put in contact, the reaction occurs naturally and quickly. Click chemistry allows very precise control over the DAR and drug distribution in the antibody backbone, significantly increasing the homogeneity of ADC products.

Best Linker Chemistries Used for ADC Development

Antibody-drug conjugation services use chemical linkers that connect the payload (cytotoxic drugs) to the monoclonal antibodies. Linkers consist of an antibody-binding and a payload-binding domain. Their properties heavily influence the stability, safety, aggregation profile, therapeutic widow, and mechanism of action of ADCs.
Linkers are broadly classified as cleavable or non-cleavable. A list of the most commonly used linkers can be found in the table below.

Linker chemistry Subclass Groups Examples FDA or EMA approved ADCs
Cleavable Acid cleavable linkers Hydrazone- disulfides 4-(4′-acetylphenoxy) butanoic acid (acetyl butyrate) linker [AcBut linker] Gemtuzumab ozogamicin; Inotuzumab ozogamicin
Cleavable Acid cleavable linkers PEGylated PEG8- and triazole-containing PABC-peptide-mc linker [CL2A linker] Sacituzumab govitecan
Cleavable Enzyme cleavable linkers Peptide linkers Valine-Citrulline [Val-Cit linker] Valine-Alanine [Val-Ala linker] Brentuximab vedotin; Polatuzumab vedotin; Loncastuximab tesirine
Noncleavable linkers _ Thioether linkers Succinimidyl-4-(N- maleimidomethyl) cyclohexane-1-carboxylate linker [SMCC linker] Maleimidocaproyl linker [MC linker] Belantamab mafodotin; Ado- trastuzumab emtansine

Selecting the best linker for a specific ADC ultimately depends on several factors including the abundance of the target antigen, toxicity of the payload, and nature of the tumor (solid versus hematological tumor). For instance, cleavable linkers are more suitable when targeting low abundance target and solid tumors, given that these linkers are able to release their warheads on the tumor microenvironment allowing the rapid diffusion of the small drugs without the need for internalization.

Best Linker Enzymes Used for ADC Development

Our antibody-drug conjugation service uses enzymes to link the payload (cytotoxic drugs) to monoclonal antibodies.

The best enzyme linkers for ADC development facilitate the targeted coupling of cytotoxic drugs to monoclonal antibodies. Enzymes create specific connections between the drug and the antibody, ensuring precise delivery to tumor cells while sparing healthy tissues.

This approach enhances the therapeutic efficacy and minimizes off-target effects, making it a promising strategy for advanced cancer treatments. Below are examples of enzymes used to link payloads to monoclonal antibodies.

  • Enzymatic Linking Method
  • Enzymatic Linking Method
  • Thiol-Maleimide Reaction
  • Involves conjugation of a cysteine residue on the antibody with a maleimide group on the cytotoxic drug.
  • Lysine-Selective Coupling
  • Links the drug to exposed lysine residues on the antibody's surface.
  • Glycan-Modification Approach
  • Targets glycan residues on the antibody, providing unique conjugation sites.
  • Sortase-Mediated Conjugation
  • Utilizes sortase enzyme to couple the drug to a specific peptide tag on the antibody.
  • Transglutaminase Conjugation
  • Involves transglutaminase enzyme to link the drug to glutamine residues on the antibody.

Major Cytotoxic Payloads Of Adcs

Suitable payloads for ADCs are typically defined as efficient at killing cancer cells at the nanomolar and picomolar range. They also must be fairly soluble to avoid excessive aggregation, non-immunogenic, and possess reactive sites available for conjugation with a linker.

The major cytotoxic payloads belong to two families: tubulin inhibitors (maytansinoids, auristatins, or taxol derivates) and DNA-modifying agents (mainly calicheamicins). Most of these agents are also too toxic for system administration in a mono-therapeutic regimen. Tubulin inhibitors have an extensive and solid track record as payloads of ADCs. They act during the cell cycle, causing cell death via mitotic arrest. Most ADCs in the clinic carry tubulin inhibitors as payloads. In contrast, DNA-modifying agents can act independently of the cell growth cycle, causing the cleavage of the DNA molecule and leading to cell death by apoptosis.

More recently, alternative payloads such as camptothecin derivates and pyrrolobenzodiazepines (PBD) dimers have been gaining ground over more conventional drug classes.

Payload class Mechanism of action Examples FDA or EMA approved ADCs
Auristatins Tubulin polymerase inhibitor Monomethyl auristatin E (MMAE) and Monomethyl auristatin F (MMAF) Brentuximab vedotin; Polatuzumab vedotin; Enfortumab vedotin; Belantamab mafodotin; Tisotumab vedotin
Calicheamicins DNA cleavage Calicheamicin and derivates Gemtuzumab ozogamicin; Inotuzumab ozogamicin
Camptothecin Topoisomerase inhibitor exatecan derivate (Dxd) and irinotecan derivate (SN-38) Trastuzumab deruxtecan; Sacituzumab govitecan
Maytansines Tubulin depolymerization Maytansinoids (DM1 and DM4) Trastuzumab emtansine
Pyrrolobenzodiazepines (PBD) dimers DNA minor groove cross-linker PBD derivates Loncastuximab tesirine
Protein toxins Several Pseudomonas exotoxin (PE) and diphtheria toxin (DT) Moxetumomab pasudotox
Duocarymycins DNA minor groove alkylating agent CC-1065 and duocarmycin SA None so far
Amatoxins RNA polymerase II inhibitor α-Amanitin None so far
Antibiotics Several 4-dimethylamino piperidino-hydroxybenzoxazino rifamycin (dmDNA31) None so far
Enzymes Several β-glucuronidase, urease, among others None so far

Comprehensive bioanalysis of ADCs

Key Properties Of Adcs

What makes the bioanalysis of ADCs so challenging is the heterogeneous nature of these products – particularly relevant when conventional chemical conjugation methods (cysteine and lysine) are used. Heterogeneity is known to influence a number of ADC properties such as stability and therapeutic effectiveness, for this reason, extensive analysis of ADC products is essential to ascertain their success in later stages of development.

The major properties of ADCs and common bioanalytical methods used for their study include:

  • Drug-to-antibody ratio (DAR): ultraviolet-visible (UV/Vis) spectroscopy, cathepsin-B enzyme-based digestion method, hydrophobic interaction chromatography (HIC), reversed-phase high-performance liquid chromatography (RP-HPLC), and mass spectrometry (MS)
  • Drug load distribution: capillary electrophoresis (CE), HIC, RP-HPLC, and MS
  • Unconjugated antibody: CE, ELISA HIC, RP-HPLC, and MS
  • Degradation/biotransformation: LC-MS/MS (can be preceded by enrichment and proteolytic degradation steps to increase analytical resolution
  • Free drug content: LC-MS/MS
  • Charge variants: ion-exchange chromatography (IEX) and imaged capillary isoelectric focusing (iCIEF)
  • Stability and aggregation profile: size-exclusion chromatography (SEC), LC-MS, and CE
  • Post-translational modifications: LC-MS/MS
  • Pharmacokinetics: using animal models, the pharmacokinetics (studies the fate of the ADC in an organism) can be estimated by measuring the serum after treatment and quantifying: total and conjugated antibodies; free and conjugated drug; and biotransformation pathways (LC-MS coupled with protein digestion)

Of all the properties mentioned above, DAR and drug load distribution remain the most important. For their bioanalysis, the most widely used methods during early development include UV/Vis, HIC, and RP-HPLC, or LC-MS.

How To Optimize The Therapeutic Efficacy Of Adcs

Due to the complexity and inherent heterogeneity of ADC products, it can be challenging to ensure their success during clinical development. However, focusing on optimizing a number of key properties is known to significantly increase their odds of receiving marketing approval:

  • Antibody affinity: once a highly specific target has been chosen, an antibody with optimal affinity should be produced. One would assume that the higher the affinity, the better the antibody-drug conjugate. However, this is rarely true. For instance, high-affinity antibodies can have a positive effect on the internalization rate but limit solid tumor penetration due to the site-barrier effect. Thus, optimal antibody affinity has to be determined by taking into account the therapeutic application.
  • Linker stability: the linker is a crucial component of an ADC as it covalently tethers the antibody to the payload. Properties of a good linker include:
    • Stability in blood circulation to prevent the off-target payload release and limit toxic side effects
    • Fast release of the payload within or in the extracellular matrix of cancer cells
  • DAR: DAR is the average number of drug molecules attached to an antibody in an ADC product. According to many studies, an average DAR of 4 is considered optimal for anti-cancer therapies. However, this may vary according to the target and the disease. For instance, higher DAR values can be considered when targeting tumor-associated antigens with low-expression or slow internalization kinetics. But since these ADCs have a high propensity for aggregation and fast clearance, the extensive characterization of their pharmacokinetic profile is vital to ensure their success in the clinic.
  • Drug load distribution: unlike DAR, drug loading is the distribution of drugs per antibody in an ADC product, often represented by an interval of values. The broader the interval, the more heterogeneous the ADC product. Highly heterogeneous drug loadings can induce modifications in terms of toxicity and/or therapeutic index of the ADC product. Moreover, it makes it harder to characterize its fate in the organism given that different ADC species will undergo different degradation pathways. Narrowing the drug load distribution in a given ADC product is thus key to ensuring a better therapeutic effect.
  • Aggregation: high DAR values and hydrophobicity contribute to a higher aggregation of ADCs. In turn, aggregation decreases the therapeutic potency of these biopharmaceuticals. For this reason, the use of lower DAR, conjugation with more soluble payloads, and PEGylation of ADCs are only a few of the strategies that can be used to mitigate aggregation.
  • Free drug: reducing the percentage of free drug in a given ADC product is vital to limit the toxicity of these complex therapeutics. High percentages of free drug can be caused by poor linker chemistry and, thus, can be mitigated by engineering linkers for higher stability in circulation.

Successes and trends
in therapeutic ADC development

Major Targets Of Therapeutic ADCs

Dozens of ADCs have reached the clinic since the approval of Mylotarg (gemtuzumab ozogamicin) in 2020. The current and future major cancer targets of these immunotherapeutics include:

  • HER2 – also known as receptor tyrosine-protein kinase erbB-2, CD340 (cluster of differentiation 340), proto-oncogene Neu, or ERBB2 protein. Found in 30% of breast cancer patients and linked with poor prognosis and aggressive forms of the disease.
  • CD22 – it is a transmembrane glycoprotein associated with B cell malignancies such as non-Hodgkin lymphoma, and acute lymphoblastic leukemia, among others.
  • Tissue factor (TF) – frequently expressed by cancer cells and is known to promote tumor growth, angiogenesis, metastasis, and thrombosis.
  • Hepatocyte growth factor receptor (HGFR) or c-Met – a membrane receptor with tyrosine kinase activity. Amplification of c-Met receptors has been reported in different types of cancer, often leading to cancer cell transformation, tumor progression, and treatment resistance.
  • Folate receptor alpha (FRα) – a glycosyl-phosphatidylinositol (GPI) membrane-bound glycoprotein overexpressed in several types of cancer cells with a putative role in cancer progression.

The improvement of linker chemistry and conjugation strategies has been promoting the development of ADCs with different structures or mechanisms of action. Multiple trends are expected to mark the next generation of these complex biopharmaceuticals including:

  • Dual-targeting (bispecific antibody carrier) or dual-drug systems (two different payloads)
  • Probody drug conjugates (only activated by specific enzymes)
  • Shifting of chemical and enzymatic conjugation towards less heterogeneity-prone methods such as site-specific and click chemistry
  • Creation of fast-releasing linkers for the efficient and safe targeting of solid tumors
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