Immudex

Immudex
Type	Private
Industry	Reagents and Diagnostics
Predecessor	Dako
Founded	2009
Headquarters	Copenhagen , Denmark
Area served	Copenhagen, Denmark ; Fairfax, Virginia
Key people	Helene Kähler Hjenner (CEO); Liselotte Brix (COO)
Products	MHC Dextramer
Website	www.immudex.com

Last updated August 20, 2022

Immudex is a Danish Reagents and Diagnostics company established in 2009. The company is operating from offices located in Copenhagen, Denmark, and in Fairfax, Virginia.^[1] Immudex specializes in the production of MHC Dextramers. MHC Dextramers are chemical reagents that are designed to detect antigen-specific T cells.^[2]^[3]

While some of the technology is currently only sold for Research use only (RUO), clinical applications are being actively pursued. Currently, Immudex has several development projects for clinically applicable MHC Dextramers. Even so, the first MHC Dextramers clinical reagent has been developed and approved for clinical in vitro diagnostics in Europe. Namely the CE-marked kit for enumeration of cytomegalovirus-specific T cells. Immudex primarily focuses on the identification of producing large quantities of CD8+ T cells by the means of MHC class I molecules. Even so, the research and development into the application of MHC class II Dextramers might expand the technology.

History

Originally, Immudex operated as an individual division within the much larger Danish pharmaceutical company Dako. Immudex was later spun out as a separate business, when the focus of Dako largely shifted to cancer diagnostics.^[1]^[4] Immudex currently have clients world wide with major markets in the United States and Europe. Patents for the MHC Dextramer technology were filed at Dako in 2001, and the Immudex division was launched in 2005.

In 2011, Immudex received the prestigious “Entrepreneur of the Year 2011” award in the Life Sciences category granted by Ernst & Young.^[5] Immudex received this award because of the commitment of the company, articulated in the company's "make it work and make it better" strategy to generate results for both practitioners and patients. The award is given to companies not only focused on financial growth, but also for softer values such as the entrepreneur's social responsibility and the ability to aspire an motivate the organization.

Dextramer technology

A large number of immunotherapies, currently in development, seek to induce, expand, activate or eliminate antigen-specific T cells. It is therefore important to be able to quantify and characterize the T cell responses before, during and after treatment in order to understand if the proposed change to the T cells has been effectuated.

The process of negative selection in the thymus guarantees that virtually all T cells have very weak affinity for self-antigens. Therefore, the study of these lymphocytes in autoimmune diseases and cancer has been difficult, until the fairly recent introduction of MHC multimers. Tetramers, which are among the most popular form of these multimer complexes, have four binding sites. The Tetramers were originally developed in Academia. Many further developments in this technology have taken place at biotechnology companies.^[6]

The Immudex MHC Dextramers, which represent the latest advancement in this field, provide an exponentially greater probability of successful identification of antigen-specific T cells. This can be done, because the MHC Dextramers have nine, or more binding sites per dextran backbone. Scientists have been optimistic about the potential of such technology, since it will help broaden the understanding of T cell responses and will in the future be clinically applicable to many different antigen-specific T cells.^[3]

Products

The MHC Dextramers are fluorescent MHC multimer reagents, developed for sensitive, specific and accurate detection of antigen-specific T cells by using Flow cytometry. The MHC Dextramers covers human, mouse, and monkey alleles that all display disease relevant antigenic peptides. The MHC Dextramers can thereby be used for monitoring antigen-specific T cell responses.

Virus Dextramer collection 1 - provides reagents for detection, quantification and isolation of virus specific T cells. It furthermore enables detection for CMV-, EBV-, influenza-, and BK virus specific CD8+ T cells.

Dextramer CMV kit - These MHC Dextramers provide a method for quantification of CMV-specific CD8+ T cells in whole blood samples as an aid in predicting and monitoring patients at risk of developing CMV-related disease.

Melanoma Dextramer collection 1 - comprises MHC Dextramers specific for 6 different melanoma-associated antigens and can be used for the detection, enumeration and isolation of melanoma-specific CD8+ T cells from blood or tumor tissue.

Cancer Testis Antigen CD1d Dextramer - These MHC Dextramers are flow cytometry reagents for the identification and sorting of Natural killer cells (NKT), as well as an extensive range of single reagents for detection of cancer- and viral-specific T cells. The CD1d/α-GalCer displays human CD1d molecules loaded with α-GalCer.

Development Projects

Though Immudex specializes in MHC Dextramer technology, the company is also pursuing development projects in diagnostics for Lyme disease/Borreliosis, based on the detection of Borrelia-specific T cells in diseased patients.

Clinical application of the CE-market Dextramer CMV kit has been approved for the European market. The CMV kit will also be attempted approved for the US market through a number of clinical trials and S10K approval. The CMV kit is intended for identification and enumerication of CMV-specific CD8+ T cells in whole blood samples. Furthermore, the MHC Dextramer CMV kit can be used for the assessment of CMV-specific immune status in HLA-matched patients.

Knowledge of the level of viral-specific T cells allow evaluation of the patients preparedness for fighting the viral infection and thereby avoid unnecessary antiviral treatment. CMV infections are often unnoticed by healthy people, but can be life threatening for immune compromised individuals, such as HIV-infected persons and organ-transplant recipients.

Collaborations and partnerships

In 2013, Immudex entered into a co-distribution and co-promotional partnership with JPT Peptide Technologies.^[7] The goal of this partnership is to synergistically combine JPT's innovative peptide technologies along with existing products with Immudex's sophisticated MHC Dextramer products. This product combination will provide a comprehensive portfolio of high quality T cell relevant products and services for the immunotherapy and vaccine community.^[8]

International Proficiency Panels

Proficiency panel testing comprises an interlaboratory system for the regular testing of accuracy that the participating laboratories can achieve. The MHC multimer panel tests the proficiency of a given laboratory in performing the flow cytometry based MHC multimer assay on blood and in performing an ELISpot Assay.^[9]

In the fall of 2013 Immudex entered an agreement with the US cancer Immunotherapy consortium (CIC) and the European Association for Cancer Immunotherapy (CIMIT). The agreement dictates that Immudex will provide MHC-peptide multimers and Elispot proficiency panels to laboratories worldwide, independently of their background and associations.

CIC and CIMT originally established proficiency panel programs to offer an external validation of assay performance and to enhance assay harmonization. Over the years, more than one hundred laboratories have participated. Not only from the cancer field, but also from other immunological fields utilizing immune monitoring. As a result, two frequently used immune monitoring methods, have now reached a high degree of harmonization.

Immudex, specialized in the detection of antigen-specific T cells has been an active participant in the proficiency panel process and is globally recognized for its expertise in immune monitoring. Thus Immudex was the logical choice as a partner for proficiency panels.

Immudex will continue the external validation program established by CIC and CIMT under the successfully implemented harmonization guidelines and will promote a more widespread use of these technologies in the development of new cancer immunotherapies and vaccines against other diseases such as HIV, TB, diabetes and others.^[10]

Related Research Articles

Antigen Molecule triggering an immune response (antibody production) in the host

In immunology, an antigen (Ag) is a molecule or molecular structure or any foreign particulate matter or a pollen grain that can bind to a specific antibody or T-cell receptor. The presence of antigens in the body may trigger an immune response. The term antigen originally referred to a substance that is an antibody generator. Antigens can be proteins, peptides, polysaccharides, lipids, or nucleic acids.

Natural killer cells, also known as NK cells or large granular lymphocytes (LGL), are a type of cytotoxic lymphocyte critical to the innate immune system that belong to the rapidly expanding family of known innate lymphoid cells (ILC) and represent 5–20% of all circulating lymphocytes in humans. The role of NK cells is analogous to that of cytotoxic T cells in the vertebrate adaptive immune response. NK cells provide rapid responses to virus-infected cell and other intracellular pathogens acting at around 3 days after infection, and respond to tumor formation. Typically, immune cells detect the major histocompatibility complex (MHC) presented on infected cell surfaces, triggering cytokine release, causing the death of the infected cell by lysis or apoptosis. NK cells are unique, however, as they have the ability to recognize and kill stressed cells in the absence of antibodies and MHC, allowing for a much faster immune reaction. They were named "natural killers" because of the notion that they do not require activation to kill cells that are missing "self" markers of MHC class 1. This role is especially important because harmful cells that are missing MHC I markers cannot be detected and destroyed by other immune cells, such as T lymphocyte cells.

The human leukocyte antigen (HLA) system or complex is a complex of genes on chromosome 6 in humans which encode cell-surface proteins responsible for the regulation of the immune system. The HLA system is also known as the human version of the major histocompatibility complex (MHC) found in many animals.

A cancer vaccine is a vaccine that either treats existing cancer or prevents development of cancer. Vaccines that treat existing cancer are known as therapeutic cancer vaccines or tumor antigen vaccines. Some of the vaccines are "autologous", being prepared from samples taken from the patient, and are specific to that patient.

Hybridoma technology is a method for producing large numbers of identical antibodies. This process starts by injecting a mouse with an antigen that provokes an immune response. A type of white blood cell, the B cell, produces antibodies that bind to the injected antigen. These antibody producing B-cells are then harvested from the mouse and, in turn, fused with immortal B cell cancer cells, a myeloma, to produce a hybrid cell line called a hybridoma, which has both the antibody-producing ability of the B-cell and the longevity and reproductivity of the myeloma. The hybridomas can be grown in culture, each culture starting with one viable hybridoma cell, producing cultures each of which consists of genetically identical hybridomas which produce one antibody per culture (monoclonal) rather than mixtures of different antibodies (polyclonal). The myeloma cell line that is used in this process is selected for its ability to grow in tissue culture and for an absence of antibody synthesis. In contrast to polyclonal antibodies, which are mixtures of many different antibody molecules, the monoclonal antibodies produced by each hybridoma line are all chemically identical.

Cancer immunotherapy is the stimulation of the immune system to treat cancer, improving on the immune system's natural ability to fight the disease. It is an application of the fundamental research of cancer immunology and a growing subspeciality of oncology.

An antigen-presenting cell (APC) or accessory cell is a cell that displays antigen bound by major histocompatibility complex (MHC) proteins on its surface; this process is known as antigen presentation. T cells may recognize these complexes using their T cell receptors (TCRs). APCs process antigens and present them to T-cells.

Cross-presentation is the ability of certain professional antigen-presenting cells (mostly dendritic cells) to take up, process and present extracellular antigens with MHC class I molecules to CD8 T cells (cytotoxic T cells). Cross-priming, the result of this process, describes the stimulation of naive cytotoxic CD8⁺ T cells into activated cytotoxic CD8⁺ T cells. This process is necessary for immunity against most tumors and against viruses that infect dendritic cells and sabotage their presentation of virus antigens. Cross presentation is also required for the induction of cytotoxic immunity by vaccination with protein antigens, for example, tumour vaccination.

A tetrameric protein is a protein with a quaternary structure of four subunits (tetrameric). Homotetramers have four identical subunits, and heterotetramers are complexes of different subunits. A tetramer can be assembled as dimer of dimers with two homodimer subunits, or two heterodimer subunits.

Antibody-dependent cellular cytotoxicity (ADCC), also referred to as antibody-dependent cell-mediated cytotoxicity, is a mechanism of cell-mediated immune defense whereby an effector cell of the immune system actively lyses a target cell, whose membrane-surface antigens have been bound by specific antibodies. It is one of the mechanisms through which antibodies, as part of the humoral immune response, can act to limit and contain infection.

A tetramer assay is a procedure that uses tetrameric proteins to detect and quantify T cells that are specific for a given antigen within a blood sample. The tetramers used in the assay are made up of four major histocompatibility complex (MHC) molecules, which are found on the surface of most cells in the body. MHC molecules present peptides to T-cells as a way to communicate the presence of viruses, bacteria, cancerous mutations, or other antigens in a cell. If a T-cell's receptor matches the peptide being presented by an MHC molecule, an immune response is triggered. Thus, MHC tetramers that are bioengineered to present a specific peptide can be used to find T-cells with receptors that match that peptide. The tetramers are labeled with a fluorophore, allowing tetramer-bound T-cells to be analyzed with flow cytometry. Quantification and sorting of T-cells by flow cytometry enables researchers to investigate immune response to viral infection and vaccine administration as well as functionality of antigen-specific T-cells. Generally, if a person's immune system has encountered a pathogen, the individual will possess T cells with specificity toward some peptide on that pathogen. Hence, if a tetramer stain specific for a pathogenic peptide results in a positive signal, this may indicate that the person's immune system has encountered and built a response to that pathogen.

Trogocytosis is when a cell nibbles another cell. It is a process whereby lymphocytes conjugated to antigen-presenting cells extract surface molecules from these cells and express them on their own surface. The molecular reorganization occurring at the interface between the lymphocyte and the antigen-presenting cell during conjugation is also called "immunological synapse".

The Streptamer technology allows the reversible isolation and staining of antigen-specific T cells. This technology combines a current T cell isolation method with the Strep-tag technology. In principle, the T cells are separated by establishing a specific interaction between the T cell of interest and a molecule that is conjugated to a marker, which enables the isolation. The reversibility of this interaction and the low temperatures at which it is performed allows for the isolation and characterization of functional T cells. Because T cells remain phenotypically and functionally indistinguishable from untreated cells, this method offers modern strategies in clinical and basic T cell research.

Cytometry by time of flight, or CyTOF, is an application of mass cytometry used to quantify labeled targets on the surface and interior of single cells. CyTOF allows the quantification of multiple cellular components simultaneously using an ICP-MS detector.

Immunomics is the study of immune system regulation and response to pathogens using genome-wide approaches. With the rise of genomic and proteomic technologies, scientists have been able to visualize biological networks and infer interrelationships between genes and/or proteins; recently, these technologies have been used to help better understand how the immune system functions and how it is regulated. Two thirds of the genome is active in one or more immune cell types and less than 1% of genes are uniquely expressed in a given type of cell. Therefore, it is critical that the expression patterns of these immune cell types be deciphered in the context of a network, and not as an individual, so that their roles be correctly characterized and related to one another. Defects of the immune system such as autoimmune diseases, immunodeficiency, and malignancies can benefit from genomic insights on pathological processes. For example, analyzing the systematic variation of gene expression can relate these patterns with specific diseases and gene networks important for immune functions.

MHC multimers are oligomeric forms of MHC molecules, designed to identify and isolate T-cells with high affinity to specific antigens amid a large group of unrelated T-cells. Multimers generally range in size from dimers to octamers; however, some companies use even higher quantities of MHC per multimer. Multimers may be used to display class 1 MHC, class 2 MHC, or nonclassical molecules from species such as monkeys, mice, and humans.

Immunodominance is the immunological phenomenon in which immune responses are mounted against only a few of the antigenic peptides out of the many produced. That is, despite multiple allelic variations of MHC molecules and multiple peptides presented on antigen presenting cells, the immune response is skewed to only specific combinations of the two. Immunodominance is evident for both antibody-mediated immunity and cell-mediated immunity. Epitopes that are not targeted or targeted to a lower degree during an immune response are known as subdominant epitopes. The impact of immunodominance is immunodomination, where immunodominant epitopes will curtail immune responses against non-dominant epitopes. Antigen-presenting cells such as dendritic cells, can have up to six different types of MHC molecules for antigen presentation. There is a potential for generation of hundreds to thousands of different peptides from the proteins of pathogens. Yet, the effector cell population that is reactive against the pathogen is dominated by cells that recognize only a certain class of MHC bound to only certain pathogen-derived peptides presented by that MHC class. Antigens from a particular pathogen can be of variable immunogenicity, with the antigen that stimulates the strongest response being the immunodominant one. The different levels of immunogenicity amongst antigens forms what is known as dominance hierarchy.

Immunology is the study of the immune system during health and disease. Below is a list of immunology-related articles.

Artificial antigen presenting cells (aAPCs) are engineered platforms for T-cell activation. aAPCs are used as a new technology and approach to cancer immunotherapy. Immunotherapy aims to utilize the body's own defense mechanism—the immune system—to recognize mutated cancer cells and to kill them the way the immune system would recognize and kill a virus or other micro-organisms causing infectious diseases. Antigen presenting cells are the sentinels of the immune system and patrol the body for pathogens. When they encounter foreign pathogens, the antigen presenting cells activate the T cells—“the soldiers of the immune system”— by delivering stimulatory signals that alert there is foreign material in the body with specific cell surface molecules (epitopes). aAPCs are synthetic versions of these sentinel cells and are made by attaching the specific T-cell stimulating signals to various macro and micro biocompatible surfaces like micron-sized beads. This can potentially reduce the cost while allowing control over generating large numbers of functional pathogen-specific T cells for therapy. Activated and stimulated T cells can be studied in this biomimetic contex and used for adoptive transfer as an immunotherapy.

IBA Lifesciences is a biotechnology company providing products and custom specific services for life science applications in academia and industry worldwide. IBA focusses on two business segments: cell selection and protein purification.

References

1 2 "Immudex, a new spin-out from Dako" (PDF) (Press release). Immudex ApS. October 9, 2009. Archived (PDF) from the original on January 3, 2014. Retrieved January 3, 2014.
↑ Bakker, Arnold H.; Schumacher, Ton N. M. (August 2005). "MHC Multimer Technology: Current Status and Future Prospects" (PDF). Curr. Opin. Immunol. 17 (4): 428–33. doi:10.1016/j.coi.2005.06.008. Archived (PDF) from the original on January 4, 2014. Retrieved January 3, 2014.
1 2 Davis MM, Altman JD, Newell EW. “Interrogating the repertoire: broadening the scope of peptide-MHC multimer analysis”. Nat Rev Immunol. 2011 Jul 15;11(8):551-8. doi: 10.1038/nri3020.
↑ Børsen, Oct. 9th, 2009, Tom Frovst. "Milliardpotentiale i Dako-satsning". Copenhagen, DK. pg. 8.
↑ Ernst & Young, Nov. 24th, 2011. "Immudex vinder kategorien Life Sciences Entrepreneur Of The Year 2011". Copenhagen, DK
↑ Altman, J.D. et al. “Phenotypic analysis of antigen-specific T lymphocytes.” Science, 274 (5284): October 1996, 94-96.
↑ "Products & Services". Gen. Eng. Biotechnol. News. Vol. 33, no. 21. December 2013. p. 14.
↑ "JPT and Immudex announces Partnership Agreement" (PDF). Immudex. May 2015.
↑ "ATCC proficiency".
↑ "Immudex takes on proficiency panels" (PDF).

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[apple-1] 1 2 "Immudex, a new spin-out from Dako" (PDF) (Press release). Immudex ApS. October 9, 2009. Archived (PDF) from the original on January 3, 2014. Retrieved January 3, 2014.

[2] Bakker, Arnold H.; Schumacher, Ton N. M. (August 2005). "MHC Multimer Technology: Current Status and Future Prospects" (PDF). Curr. Opin. Immunol. 17 (4): 428–33. doi:10.1016/j.coi.2005.06.008. Archived (PDF) from the original on January 4, 2014. Retrieved January 3, 2014.

[baboon-3] 1 2 Davis MM, Altman JD, Newell EW. “Interrogating the repertoire: broadening the scope of peptide-MHC multimer analysis”. Nat Rev Immunol. 2011 Jul 15;11(8):551-8. doi: 10.1038/nri3020.

[4] Børsen, Oct. 9th, 2009, Tom Frovst. "Milliardpotentiale i Dako-satsning". Copenhagen, DK. pg. 8.

[5] Ernst & Young, Nov. 24th, 2011. "Immudex vinder kategorien Life Sciences Entrepreneur Of The Year 2011". Copenhagen, DK

[6] Altman, J.D. et al. “Phenotypic analysis of antigen-specific T lymphocytes.” Science, 274 (5284): October 1996, 94-96.

[7] "Products & Services". Gen. Eng. Biotechnol. News. Vol. 33, no. 21. December 2013. p. 14.

[8] "JPT and Immudex announces Partnership Agreement" (PDF). Immudex. May 2015.

[9] "ATCC proficiency".

[10] "Immudex takes on proficiency panels" (PDF).

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