The Essentials of Antibody Engineering

Ana Reis, PhD Ana Reis, PhD 8 min read

In the realm of biotherapeutics, antibody engineering stands out as a pivotal discipline driving innovation and progress. Ever since the remarkable specificity and affinity of antibodies were discovered, efforts to harness them as novel therapeutic agents across diverse pathological conditions commenced. Over time, a wide range of strategies emerged, paving the way for the creation of engineered antibodies tailored to specific targets and suitable for clinical use.

This article delves into the fundamentals of antibody engineering, its significance in the development of biotherapeutics, and its vast potential in various clinical applications.

What Is Antibody Engineering?

Antibodies, also known as immunoglobulins, are Y-shaped proteins naturally produced by the immune system to identify and neutralize harmful substances, such as viruses and bacteria. Antibody engineering involves the manipulation of these proteins (monoclonal antibodies) at the molecular level and modifying their sequences or structures to enhance their efficacy, specificity, and functionality for therapeutic purposes.

Since the introduction of hybridoma technology in 1975, antibody development has experienced significant and rapid advancement. The first engineered antibodies were approved for marketing by the US Food and Drug Administration (FDA) in 1997. Since then, around 300 programs for developing therapeutic antibodies have been described in industrial and academic laboratories.

Here’s how it works:

  • Generation: Recombinant antibodies can be produced using recombinant DNA expression systems, wherein genes encoding antibody molecules are inserted into host organisms, typically mammalian cells, to manufacture large quantities of specific antibodies.
  • Modification: Through genetic engineering techniques, specific regions of the antibody, such as the variable regions responsible for binding to target molecules, can be modified to enhance affinity, stability, or other desired properties.
  • Selection: Antibody engineering often involves screening techniques, such as phage display, yeast display, or B cell isolation to identify antibodies with the desired characteristics from vast libraries of antibody variants (such as naïve and immune libraries) or the B cell that produces the antibody.
  • Optimization: Once candidate antibodies are identified, further optimization steps may be undertaken to improve pharmacokinetic properties, reduce immunogenicity, or enhance other attributes crucial for therapeutic efficacy.

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Benefits of Antibody Engineering

Antibody engineering is at the center of overcoming challenges in drug development and expanding therapeutic options.

  • Reducing Immunogenicity: One of the primary challenges in the development of therapeutic antibodies is the potential for immunogenicity when the patient’s immune system attacks the antibody. Antibody engineering strategies aim to mitigate this risk by designing antibodies with humanized sequences or by incorporating specific modifications to reduce immunogenic potential.
  • Enhancing Specificity: Engineering antibodies for high specificity towards the target molecule is essential to minimize off-target effects and maximize therapeutic efficacy. Rational design approaches, coupled with advanced screening techniques, enable the generation of antibodies with precise binding characteristics tailored to the intended therapeutic application.
  • Diversification of Therapeutic Agents: The versatility of antibody engineering allows for the generation of a wide array of therapeutic agents, including monoclonal antibodies, antibody-drug conjugates, and bispecific molecules. This diversity opens up new avenues for research and addressing previously unmet medical needs.
  • Enabling Personalized Medicine: By tailoring antibody therapeutics to individual patient profiles, precision medicine approaches can be realized. Treatment strategies can be customized based on genetic, molecular, and clinical characteristics. This personalized custom antibody approach holds promise for improving treatment outcomes and minimizing adverse effects.

Why Is Antibody Engineering Important? Applications of Engineered Antibodies

Monoclonal antibodies (mAbs) are widely used to treat cancer, autoimmune diseases, infectious diseases, and more. Antibody engineering plays a crucial role in advancing the field of biotherapeutics and has significant implications for various clinical applications. 

Here’s why it’s indispensable:

Cancer Therapeutics 

The development of antibody therapeutics has revolutionized cancer therapy by offering targeted approaches with reduced off-target effects. Advances in antibody engineering have led to the development of highly specific antibodies that can selectively target tumor antigens while sparing healthy tissues. Through engineering interventions, improvements in tumor penetration can be achieved by altering the antibody’s structure, thereby facilitating better access to tumor cells and enhancing treatment efficacy.

Bispecific antibodies designed to engage immune effector functions for enhanced tumor cell killing have shown promising results in clinical trials for various malignancies. Moreover, they can lead to the rapid clearance of antibodies from the body by providing them with characteristics that promote efficient elimination. This reduces the likelihood of adverse effects, including cytotoxic activity, and enables repeated administration.

Tailored formats such as antibody-drug conjugates (ADCs) or bispecific antibodies can be engineered to capitalize on distinctive mechanisms of action, allowing for targeted drug delivery or simultaneous binding to multiple targets. This broadens the therapeutic scope of antibodies, unlocking new avenues for treatment strategies.

Autoimmune Disorders

Engineered antibodies offer promising treatments for autoimmune diseases by selectively targeting aberrant immune responses while preserving normal immune function. By modulating the immune response, therapeutic antibodies can effectively alleviate symptoms and halt disease progression in autoimmune disorders.

Engineered antibodies with improved pharmacokinetic profiles and reduced immunogenicity offer new therapeutic options for patients with conditions like rheumatoid arthritis, multiple sclerosis, inflammatory bowel disease, and psoriasis. 

Infectious Diseases

Engineered antibodies have emerged as potential therapeutics for infectious diseases, including viral infections such as HIV, influenza, and SARS-CoV-2. Neutralizing antibodies designed to bind to viral surface proteins can prevent viral entry into host cells or enhance the immune clearance of infected cells, offering therapeutic interventions against infectious pathogens.

Diagnostic Tools

Antibodies are essential components of diagnostic assays used for detecting disease markers, pathogens, and drug levels. Thus, antibody engineering plays a pivotal role in enhancing an antibody’s diagnostic capabilities. Utilizing various engineering techniques, antibodies can undergo optimization tailored for diverse diagnostic assays, such as Western blot, flow cytometry, immunofluorescence, and ELISA assays.

Through modifications in specificity and affinity, engineering endeavors aim to elevate antibody performance in identifying and quantifying specific molecules or cells within a sample. This includes enhancing sensitivity to detect targets with low abundance. Moreover, engineering interventions seek to refine antibody selectivity, diminishing cross-reactivity with non-target molecules, thereby bolstering the precision and trustworthiness of diagnostic outcomes.

Antibody labeling also facilitates the integration of fluorescent or enzyme labels, enabling their utilization in fluorescence-based or enzyme-linked assays, which broadens the applicability of antibody-based diagnostics and enhances their capabilities.

Antibody Engineering Techniques

The objective of antibody engineering is to enhance the functional properties of antibodies, including their biochemical and biophysical properties, to make them efficacious therapeutics and convenient research tools. It is done using various methods and techniques.

1.  Antibody Humanization

Early therapeutic antibodies were often derived from mice or other non-human sources. The human immune system recognizes them as non-self, leading to an immune response. This response can neutralize the therapeutic antibody, reducing its efficacy and causing adverse effects resulting in the rapid cleared from the bloodstream.

Antibody humanization involves altering antibodies sourced from non-human species, such as mice, to closely resemble human antibodies and reduce their immunogenicity in humans. This adaptation is critical in the creation of antibody-based treatments, as fully humanized antibodies are less prone to eliciting detrimental immune responses in patients, thus enhancing their safety and efficacy.

Humanizing antibodies preserve their specificity and binding strength to their targets while diminishing the likelihood of negative reactions. Consequently, this facilitates the creation of more effective therapies for diverse diseases, enhancing patient outcomes. 

2. Affinity Maturation

Enhancing antibody binding affinity improves an antibodies therapeutic efficacy, termed affinity maturation. Affinity maturation is a key player in protein engineering, ensuring that antibodies reach their full therapeutic potential by improving their affinity through somatic mutation of immunoglobulin genes in B cells.

Affinity maturation optimizes antibody affinity, the strength of binding between an antibody and its target molecule, with the goal of elevating the antibody’s capacity to precisely identify and attach to its target with heightened affinity.

This progression is significant in therapeutic development, as antibodies with high affinity have enhanced therapeutic effectiveness through heightened target interaction and potency. Techniques like phage display and yeast surface display allow screening for high-affinity variants.

3. Bispecific Antibody Development

Bispecific antibodies are antibodies engineered to simultaneously bind two different target proteins. This distinctive attribute enables them to facilitate interactions between disparate molecules or cells, resulting in a range of therapeutic advantages, which is why they are often used for cancer immunotherapy and redirecting immune cells.

They achieve their therapeutic effects through several mechanisms, including directing immune cells to selectively eliminate cancer cells, thus simultaneously obstructing multiple disease pathways within the tumor microenvironment, delivering therapeutic payloads to precise sites, etc.

Due to these features, bispecific antibodies present a versatile strategy for enhancing treatment outcomes by improving specificity, efficacy, and therapeutic alternatives for a variety of diseases. Various formats exist for bispecific antibodies, including IgG-like molecules, antibody fragments, and fusion proteins, and they can all be tailored to meet specific therapeutic needs.

4. Antibody Drug Conjugates

An antibody-drug conjugate (ADC) is a distinct form of bioconjugate integrating an antibody with a potent therapeutic agent. The antibody portion identifies and attaches to particular target molecules present in diseased cells, whereas the associated drug payload administers a potent therapeutic impact, such as hindering cell growth or prompting cell death.

ADCs harbor promising therapeutic applications across a spectrum of diseases, notably cancer. They possess the capability to precisely transport cytotoxic drugs to cancerous cells, thereby minimizing harm to healthy cells and heightening treatment efficacy. This antibody engineering technique represents a targeted strategy within precision medicine, amplifying the therapeutic margin and mitigating adverse effects.

The Promise of Antibody Engineering: Revolutionizing Precision Medicine

Antibody engineering stands at the forefront of molecular biology and drug development, driving innovation and shaping the landscape of biotherapeutics. Its impact spans across a multitude of clinical applications, from cancer therapy to the management of autoimmune disorders, offering new hope and possibilities for patients worldwide. 

As research continues to unravel the complexities of the immune response and molecular interactions, the future of antibody engineering remains bright, promising further breakthroughs and advancements. As a leading antibody engineering company, ProteoGenix’s comprehensive one-stop antibody engineering services come with stringent go-no-go guarantees, ensuring your investment is safeguarded every step of the way.

The best part? We handle all the heavy lifting while you retain full intellectual property rights for each engineered antibody we craft. You can trust us to consistently deliver superior results from discovery to pre-clinical trials, with a range of pricing options to suit your project’s needs. Take the first step towards accelerating your antibody engineering project by booking a call today. 

 

 

 

 

 

 

 

 


Author Author: Ana Reis, PhD

Ana Reis is a scientific content manager at ProteoGenix. She has a PhD degree in biotechnology and a master's degree in science communication. Throughout her academic career, she has co-authored dozens of scientific articles on topics ranging from bioinformatics to chemical engineering.