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Tag: Antibodies

  • Study shows potential for universal flu vaccine with broad antibody response

    Study shows potential for universal flu vaccine with broad antibody response

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    A recent study published in the journal Nature Communications observed antibody breadth and effector functions as important immune correlates that can be used to develop universal influenza vaccines. This vaccine could be effective against all influenza virus strains, even those having pandemic potential.

    Study: Influenza antibody breadth and effector functions are immune correlates from acquisition of pandemic infection of children. Image Credit: Africa Studio / ShutterstockStudy: Influenza antibody breadth and effector functions are immune correlates from acquisition of pandemic infection of children. Image Credit: Africa Studio / Shutterstock

    Background

    Children are particularly vulnerable to influenza viruses that cause seasonal epidemics and sporadic pandemics. Seasonal influenza epidemics not only lead to an upsurge in hospital admissions but also increase mortality rates in older adults with comorbidities. Many studies have shown that seasonal influenza vaccines provide limited protection against influenza viruses that have the potential to cause a pandemic. However, the 2009 H1N1 pandemic (pH1N1) revealed the effectiveness of seasonal vaccines in protecting children and older adults from the infection. This protection could be due to cross-reactive antibody responses. 

    Compared to children, adults possess additional immune correlates, such as T-cell responses and non-neutralizing antibody functions. This is the reason why children require higher concentrations of HAI antibodies for an equivalent amount of immune protection from the infection. To design a next-generation vaccine, it is important to identify immune correlates of protection. In the context of pH1N1 infection, HA-stem-specific antibodies play a crucial role in providing protection, which is mediated by the Fc Receptor (FcR) function. 

    Some antibodies that can cross-react between pandemic, seasonal, and avian influenza viruses could reduce the severity of influenza virus infection. In this context, serum antibodies, particularly IgG, can facilitate effector functions, such as directing immune cells to kill infected cells, engulfing infected cells via antibody-dependent phagocytosis (ADCP), and promoting antibody-dependent cellular cytotoxicity (ADCC). These functions are mediated by Fc gamma receptors (FcγR) 3a and FcγR2a.

    Mechanistically, FcγR 3a and FcγR2a employ macrophages and natural killer (NK) cells to remove viruses-infected cells. Cross-reaction of ADCC antibodies has been associated with targeting conserved antigenic sites of influenza virus hemagglutinin (HA), the Nucleoprotein (NP), and Matrix 1 (M1).

    About the Study

    The current study identified several gaps in research regarding antibody effector functions. For instance, few studies have assessed the vaccine-induced ADCC changes, longitudinal durability of vaccine-induced antibody FcR binding and isotype changes, and the alterations in HA-specific antibody responses with vaccination and infection. The currently performed randomized placebo control trial (RCT) investigated the influenza-specific antibody breadth and function of seasonal (S1) H1N1 vaccination and pH1N1 infection.

    The antibody features, particularly HAI titer, from seasonal vaccination that could have helped in reducing or delaying contraction of pH1N1 were assessed using selected archived samples. These samples were collected from NCT00792051, a randomized placebo-controlled trial and its follow-up study that used school children between 6 and 17 years old. 

    A subset of children who received any influenza vaccination in Year 1 (V1) or not (placebo-V0) was selected for secondary analyses, which helped determine the effectiveness of vaccination against pH1N1 infection.

    Study Findings

    The current study indicated that non-neutralizing antibodies are highly cross-reactive between different influenza strains and subtypes, which could play an important role in reducing the incidence and severity of infection.

    Detecting antibody functions other than HAI is vital to developing next-generation vaccines. This study identified the serological correlates that play an important role in protecting children from pandemic infection. In 2009, when schools were closed for two months, H1N1 transmission was low. However, soon after schools reopened in September 2009, more than 50% of the students were infected within a few months. A very low community uptake of the monovalent pH1N1 vaccine has been documented.

    The half-life of different antibody subclasses alters significantly. The current study observed that seasonal vaccination enhances Fc effector functions of pH1N1 specific NP, HA, and neuraminidase (NA) antibodies. However, their function was short-term as it waned off within one year of vaccination. A greater antibody decline was observed in unvaccinated children.

    Seasonal vaccination did not boost FcR effector functions to other seasonal-specific antibody responses. Unvaccinated, uninfected children also exhibited increased FcR-mediated effector functions of pandemic-specific NA, HA, and NP antibodies. These children displayed a higher antibody level of NK cell function. pH1 antibodies against H3-HA responses were associated with cross-reactive avian H5-specific IgG, FcγR2a, and FcγR3a responses. This finding implies that cross-reactive responses are less focused and are not trained by seasonal virus exposure of other groups. 

    Considering the experimental results, vaccination and prior infection are not associated with the lack of infection in unvaccinated, uninfected children or susceptibility of V1S1 children. More research is required to understand the host factors leading to these outcomes.

    Results also indicated that group 2 H3 HA-specific IgG3 antibodies are negative predictors of infection. However, seasonal H1 and pH1-IgG3 antibodies before infection were positively associated and, therefore, protected against infection.

    Conclusions

    This study shows how universal influenza vaccines, effective against seasonal to pandemic viruses, can be developed. Antibody breadth and FcR effector functions are two important immune correlates that could be exploited to develop this vaccine.

    Journal reference:

    • Jia, J. Z. et al. (2024) Influenza antibody breadth and effector functions are immune correlates from acquisition of pandemic infection of children. Nature Communications. 15(1), 1-15. DOI: 10.1038/s41467-024-47590-0, https://www.nature.com/articles/s41467-024-47590-0

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  • New murine model sheds light on anti-MDA5 antibody-positive dermatomyositis

    New murine model sheds light on anti-MDA5 antibody-positive dermatomyositis

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    Some diseases involve autoimmune reactions, when the body begins to attack its own cells and proteins. The biological mechanisms underlying these diseases are often unknown, making treatment challenging. Now, a group at TMDU has created a murine model for a disease known as “anti-MDA5 antibody-positive dermatomyositis”. Use of this model has allowed them to identify components of the immune system that are vital in disease development, with implications for future treatments.

    Dermatomyositis is a member of a disease group known as idiopathic inflammatory myopathies, which cause typical rashes and muscle weakness, leading to disability and premature death. As part of the normal immune response, the body produces proteins known as antibodies, specific to individual “antigens”, or foreign substances. However, autoimmune reactions involve the abnormal production of antibodies to human proteins, called “autoantibodies”. Anti-MDA5 antibody-positive dermatomyositis involves the production of autoantibodies against the protein MDA5, causing rashes and lung inflammation and fibrosis, called interstitial lung disease (ILD). This often progresses very rapidly with a high mortality rate, and current anti-inflammatory treatments are ineffective.

    To develop a model of this disease in mice, we first triggered the production of anti-MDA5 autoantibodies. This resulted in the development of some lung inflammation but not full ILD.”


    Dr. Yuki Ichimura, lead author of the study

    Because MDA5 is involved in the body’s response to certain viruses, the team then mimicked a viral infection in the lungs. The mice producing anti-MDA5 antibodies developed significant lung inflammation and fibrosis, emulating the pathogenesis seen in human patients, successfully modeling the disease.

    The researchers then analyzed the specific immune responses occurring in the mice and investigated how these led to disease. Of the various cells involved in the immune response, they showed that cells called “CD4-positive T cells” are key for the development of ILD. Experimentally reducing the numbers of these cells lessened the lung damage observed. The involvement of these T cells is backed up by autopsy findings from the lungs of patients.

    The research team went on to identify elevated levels of a signaling molecule called interleukin-6 in the murine model. “Experimental reduction of interleukin-6 levels ameliorated the development of ILD,” explains senior author Dr. Naoko Okiyama, “indicating that medical intervention targeting interleukin-6 could be a potential treatment option for ILD.”

    The murine model developed in this study provides a key tool for investigating the mechanisms underlying anti-MDA5 antibody-positive dermatomyositis, the value of which is proved by the identification of key factors in the immune system involved in this highly progressive disease. Future work enabled by this study could aid in the development of more specific and effective therapies, improving treatment and quality of life.

    Source:

    Tokyo Medical and Dental University

    Journal reference:

    Ichimura, Y., et al. (2024). Autoimmunity against melanoma differentiation–associated gene 5 induces interstitial lung disease mimicking dermatomyositis in mice. Proceedings of the National Academy of Sciences. doi.org/10.1073/pnas.2313070121.

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  • Research identifies how leukemia develops resistance to first line treatments

    Research identifies how leukemia develops resistance to first line treatments

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    Relapses in a common form of leukemia may be preventable following new research which has identified how the cancer develops resistance to first line treatments.

    New research published in iScience by researchers from the University of Birmingham, the Institute of Cancer Research (ICR), Newcastle University, the Princess Maxima Centre of Pediatric oncology and the University of Virginia identified changes in a mutated form of acute myeloid leukemia (AML) samples from patients who relapsed after receiving FLT3 inhibitor treatment.

    The team found that the resistant cancer had up-regulated multiple other signalling pathways to overcome the drug’s action, and that the genetic change was able to be replicated in lab tests.

    These experiments revealed that by targeting RAS family proteins, using a small molecule inhibitor developed from a chemical library screen using the paratope of an inhibitory intracellular antibody by Terry Rabbitts’ team at the Weatherall Institute of Molecular Medicine University of Oxford and the ICR, increased signalling no longer rescued the cells from cell death.

    The team identified that the transcription factors AP-1 and RUNX1 were at the heart of mediating drug resistance. The two factors cooperate and bind to their target genes together, but only in the presence of growth factor signalling. The drugs targeting FLT3 rewire the cell, resulting in the upregulation of other signalling pathway associated genes, which then restored AP-1 and RUNX1 binding. Drugging RAS, which is a key component in multiple signalling pathways, prevented this restoration of RUNX1 binding, and therefore signalling from growth factors no longer rescued the cancer cells from death.

    Professor Constanze Bonifer from the Institute of Cancer and Genomic Sciences at the University of Birmingham, who has just taken up a position at the University of Melbourne, and is one of the senior authors of the paper said:

    The pharmaceutical industry had high hopes that drugs targeting aberrant growth factor receptors such as the FLT3-ITD would prevent people from relapse. However, cancer cells are smart, and rewire their growth control machinery to use other growth factors present in the body. Targeting RAS family members prevents the cancer from rewiring and using different signalling pathways to escape cell death.”

    Targeting RAS blocks rewiring

    The small molecule inhibitors used to target RAS in this study were developed using intracellular antibody technology. This technology involves screening a large number of antibody fragments to identify those which bind to the target protein in cells and prevent their protein-protein interactions. Small molecule inhibitors are can be screened from chemical libraries that interact with the parts of the target protein where these antibody fragments bind (the paratope). Due to the unparalleled natural specificity of these antibody fragments, this technology (called Antibody derived or Abd technology) can be used to target difficult to drug proteins and identify new parts of the protein which can be targeted to prevent protein-protein interactions.

    Professor Terry Rabbitts from the Institute of Cancer Research who developed these drugs said:

    The strength of the Antibody-derived technology approach is that intracellular antibodies can selected to essentially any protein. In turn, their specific binding sites can be employed to select chemical compounds for drug discovery against hard to drug proteins. Mutant RAS was considered undruggable, but the Abd technology facilitated the development of the RAS-binding compounds used in the current study of cancer cell re-wiring. Abd technology will allow development of a new generation of drugs to hard-to-drug and intrinsically disordered proteins.

    AML with a FLT3-ITD mutation occurs in nearly 30% of all patients and is a highly aggressive disease with a poor prognosis. This genetic change causes the expression of a mutant growth factor receptor which is always active and therefore cancer cells expressing it grow uncontrollably. While inhibitors which specifically target the FLT3 protein are now in use in the clinic, patients treated with these inhibitors frequently relapse.

    This work was funded by Leukaemia Research UK, the Medical Research Council, Blood Cancer Research UK, the Royal Society, the Wellcome and Cancer Research UK. The first author, Daniel Coleman is a John Goldman Fellow of Leukaemia UK.

    Source:

    Journal reference:

    Daniel J.L., et al. (2024). Pharmacological inhibition of RAS overcomes FLT3 inhibitor resistance in FLT3-ITD+ AML through AP-1 and RUNX1. iScience. doi.org/10.1016/j.isci.2024.109576.

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  • Therapeutic potential of CD20 x CD3 bispecific antibodies

    Therapeutic potential of CD20 x CD3 bispecific antibodies

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    On Monday, March 25th, 2024, the U.S. FDA declined approval for Regeneron’s Odronextamab for two forms of lymphoma due to concerns over the progress of ongoing confirmatory trials. Cancer immunotherapy with CD3 bispecific antibodies (BsAbs) is a fast-developing field. As of March 2024, the FDA has approved three CD20 × CD3 BsAbs: mosunetuzumab (Lunsumio) for relapsed or refractory follicular lymphoma (R/R FL), glofitamab (Columvi) for relapsed or refractory diffuse B cell lymphoma (R/R DLBCL) or large B cell lymphoma (LBCL) with two or more prior therapies, and Epcoritamab (DuoBody®) for adult patients with relapsed or refractory diffuse large B-cell lymphoma (R/R DLBCL) after two or more systemic therapies. Progress in CD20 × CD3 bispecific antibody therapy underscores the need for ongoing research and advancement.

    Bispecific antibody. Image Credit: Sino Biological

    Bispecific antibodies mechanism of action

    CD20 × CD3 bispecific antibodies bind to both CD20 on malignant B cells and CD3 on T cells, bringing them into close proximity, which triggers T cell-mediated killing of the targeted B cells.

    • CD20 × CD3: Bridging T cells to CD20+ B-cell lymphomas

    CD20 × CD3 bispecific antibodies (bsAbs) have shown effectiveness in treating various lymphomas including non-Hodgkin lymphoma (NHL), by activating T cells to attack CD20-positive B-cell lymphomas. CD20, highly expressed in B-cell lymphomas but absent in normal tissues, makes anti-CD20 drugs the main treatment for these conditions. These drugs work through various mechanisms like antibody-dependent cytotoxicity (ADCC), complement-dependent cytotoxicity (CDC), and direct CD20 binding. The CD3/TCR complex facilitates the infiltration of cytotoxic T lymphocytes into cancerous cells, leading to cell death. Bispecific antibodies, targeting CD3, activate T cells to eliminate lymphoma cells by recognizing CD20. CD20 × CD3 bsAbs, engineered extensively, offer advantages like high specificity, moderate affinity, and minimal side effects. Their unique binding site allows them to effectively target CD20-positive cells, including those resistant to rituximab. 

    Sino Biological’s offering to support CD20 × CD3 bispecific antibody research

    Sino Biological partners with customers to accelerate drug discovery and development. As an international reagent supplier and service provider, Sino Biological is proud to provide a comprehensive suite of recombinant bispecific antibody production services and best-in class drug target reagents, with the ultimate goal of facilitating bispecific antibody development and screening.

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  • Research suggests booster doses may be necessary for monkeypox immunity

    Research suggests booster doses may be necessary for monkeypox immunity

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    New research to be presented at this year’s European Congress of Clinical Microbiology and Infectious Diseases (ECCMID 2024) in Barcelona, Spain (27-30 April) shows that even in men who receives two doses of mpox vaccine intradermally, their level of antibodies to the virus falls to low or zero within the first few months if they have not received a previous smallpox vaccine.

    The authors, who include Dr Klara Sonden, deputy state epidemiologist of the of Public Health Agency of Sweden and affiliated to Karolinska Institute, Stockholm, Sweden, says that their study shows that booster vaccination may be needed long-term for such individuals, and that scientific evidence is needed for the background to any decisions.

    Since May 2022, an mpox outbreak has emerged globally, spreading mainly among men who have sex with men (MSM). It was classified as a Public Health Emergency of International Concern (PHEIC). In Sweden, a vaccine against smallpox based on the live Modified Vaccinia Virus Ankara (MVA-BN), has been offered intradermally to risk groups. Intradermal administration means 0.1 ml in the skin, one-fifth of the dose needed for subcutaneous administration. This was used as a dose-saving strategy as supplies were initially limited.

    The vaccine has been shown to be efficacious in studies using real-world data from the 2022 and onward outbreak among MSM, with limited number of breakthrough infections and milder disease reported when breakthrough infections occur so far. The aim of this cohort study was to assess dynamics of, and factors affecting neutralizing antibodies against mpox virus (MPXV) following MVA-BN vaccination.

    A total of 100 MSM attending the sexual health clinic “Venhälsan”, Stockholm, Sweden, eligible to receive the vaccine MVA-BN were included in the study. Following the initial serum sample drawn before dose 1, serum samples were further collected before dose 2, and 28 days and three months after the second dose. These samples were tested to establish titers (levels) of MPXV-neutralising antibodies. Titers were compared in individuals with or without previous smallpox vaccination and patients with past natural infection were included as positive controls.

    10 individuals were of uncertain status regarding smallpox vaccination (due to being born in many different countries in the time period 1977-1980 when vaccination was de-escalated globally) and 23 individuals were previously smallpox vaccinated. The other 67 individuals had no history of smallpox vaccination.

    A total of 312 samples from four time points from the 100 individuals included in the study were analyzed. In addition to the study population, anonymized age and sex matched controls from blood donors were included as negative controls (n=20) and previously MPXV-infected individuals as positive controls (n=20). The controls gave one blood sample each.

    Within the study group, previous smallpox vaccination was associated with significantly higher antibody titers, and 15/23 of these individuals had pre-existing neutralising antibodies (ie, the B-cell memory was still present thanks to their previous smallpox vaccination).

    Among those without prior smallpox vaccination, fewer than half of the group showed any detectable neutralizing antibodies at all 28 days after the second vaccination, with those who did exhibit responses having a median titer (standard unit of measurement of antibodies) of 20. In contrast, for previously vaccinated individuals, the median titer 28 days after a single dose of the MVA-BN vaccine was 40.

    The authors say: “Our findings corroborate other studies showing that mpox vaccination results in neutralising antibodies only in a proportion of vaccinees, and that a significant decline occurs already during the first month post-vaccination Immunity after previous MPXV infection mounts a higher and more robust neutralising response. In conclusion, the findings merits the study of booster doses.

    They continue: “Our results indicate a rapid decline in neutralising antibodies after two doses and are in line with other recent studies. These results, together with the continued spread of mpox in MSM populations in Europe has prompted the consideration of a booster dose. Such a recommendation needs to be based on scientific evidence. However, as far as we know, no clinical trial has studied or is studying a 3rd MVA-BN dose (from an analysis of clinicaltrials.gov March 2024), but a booster dose is common practice for inactivated vaccines. The MVA-BN is a live, non-replicating vaccine and therefore likely equivalent to an inactivated vaccine. Studies are essential to inform public health policy, and the largest STI clinic in Sweden is planning to perform a randomised clinical trial of a booster dose with immunological parameters as the primary outcome in the comparison with those who have had the two doses of the regular full 0.5 subcutaneous dose (sc) (0.5ml), two doses of the dose-saving intradermal dose (id) (0.1ml), or one dose sc/one dose id, and those with no booster dose.”

    They add that despite this, the Mpox cases in Sweden have been few and mostly imported during 2023 (12 cases) and 2024 (5 cases) and the vast majority have been among unvaccinated individuals. Data collection is ongoing regarding the occurrence of breakthrough infections in Sweden. Breakthrough cases have been reported in the scientific literature among individuals that have received different vaccination strategies (i.e. sc/sc, id/sc, id/id) (Hazra et al).

    The results presented here indicate that long-term protective immunity might need a booster dose for its maintenance. Since the current situation regarding mpox in Sweden is stable with minimal transmission any change in policy should be backed by results from clinical trials. Currently we will focus on finding unvaccinated individuals who are at risk of getting mpox and offer them vaccination, and we believe that this as well as the previously administered vaccinations will contribute to lowering the risk for new outbreaks of mpox in Sweden in future.”


    Dr. Klara Sonden, deputy state epidemiologist

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  • New treatment rejuvenates elderly defenses

    New treatment rejuvenates elderly defenses

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    In a recent study published in Nature, researchers developed a treatment to restore the immunological system to a younger condition, with fewer myeloid-biased output-hematopoietic stem cells (my-HSCs), more HSCs, and a balanced generation of myeloid and lymphoid lineage cells (bal-HSCs).

    Study: Depleting myeloid-biased haematopoietic stem cells rejuvenates aged immunity. Image Credit: Lightspring / Shutterstock.com Study: Depleting myeloid-biased haematopoietic stem cells rejuvenates aged immunity. Image Credit: Lightspring / Shutterstock.com

    The effects of aging on the immune system

    The aging immune system is associated with reduced lymphopoiesis, increased inflammation, and myeloid diseases due to alterations in self-renewing HSCs. During childhood, bal-HSCs predominate, thereby facilitating lymphopoiesis and adaptive immune responses.

    Age increases my-HSCs, which reduces lymphopoiesis and enhances myelopoiesis. Myeloid-HSC origin and possible interconversions are unclear; however, removing my-HSCs in aged mice may reverse the aging phenotype.

    About the study

    The researchers investigated whether antibody-regulated reduction of my-HSCs may cure age-related immunological reductions by restricting myeloid cell-induced inflammation and restoring lymphopoiesis. To this end, the impact of reduced my-HSCs on the hematopoietic system, immunological phenotypes, and functional responses to incident infections was assessed.

    Several cell-surface antigen molecules were developed and validated to identify potential targets for therapeutic my-HSC reduction. The levels of my-HSCs and balanced-HSCs were determined using antibodies and flow cytometry.

    Several my-HSC antigens, including neogenin 1 (NEO1), cluster of differentiation 62p (CD62p), and CD150, were subsequently targeted to determine their role in reducing my-HSC levels. Separate antibody-conditioning treatments were then developed for my-HSC depletion for each target, with a focus on cell clearance regulators such as anti-phagocytic signals, isotype, and antibody density.

    To establish the role of CD150 targeting, the ability of CD150-targeted antibodies to reduce my-HSCs in vivo was assessed. To target CD62p or NEO1, goat anti-mouse NEO1 antisera was mixed with anti-CD47 and anti-KIT antibodies.

    Gene expression analysis of pure total HSCs extracted from 11-month-old mice was performed to confirm alterations in HSC composition following my-HSC elimination. Transplant tests using pure HSCs were also performed to compare the myeloid and lymphoid lineage potential in recipient mice.
    After antibody conditioning, myeloid and common lymphocyte progenitors (CLPs) were measured in murine bone marrow. These analyses were performed after one week to assess acute effects, as well as after eight and sixteen weeks to determine long-term effects. The impact of this treatment on non-self-renewing progenitors was also evaluated after eight weeks.

    T-cell subsets were analyzed using canonical markers or cluster-based analysis. The effects of my-HSC depletion in aged animals on pro-inflammatory mediators and functional immunity to infection were also examined by analyzing mouse immune responses to a live-attenuated virus and subsequent challenge with a pathogenic viral infection using the mouse Friend retrovirus (FV) model.

    Study findings

    Antibody-mediated reduction of my-HSCs in elderly mice restored young immune system characteristics, such as increased CLPs, naïve T-cells, and B-cells, while lowering immunological decline indicators associated with aging. Depletion of my-HSCs in old mice increased primary and secondary adaptive immune responses to viral infection.

    Twelve potential genes that encode cell-surface proteins significantly expressed in aged HSCs and my-HSCs were identified. Moreover, CD150, CD4, CD6, CD62p20, and NEO1 were identified as markers for my-HSCs.

    Antibodies to CD41 and NEO1 enhanced the frequency of my-HSC staining, thus indicating myeloid bias. CD62p targeting resulted in the highest my-HSC enrichment.

    The most abundant protein molecules on my-HSCs were NEO1, CD41, and CD62p. Flow cytometry analysis did not identify any surface protein strongly expressed by the subgroups, except CD41, which was highly expressed by megakaryocyte progenitor cells.

    Anti-CD150 antibodies significantly reduced my-HSCs in mice, thereby increasing naïve T-cell and mature B-cell levels. In aged mice, CD4+ T lymphocytes with an exhausted phenotype (PD1+ CD62L-) grew more than those with a non-exhausted phenotype (PD1- CD62L+).

    Antibody training reduced CD4+ PD1+ CD62L- cells as compared to CD4+ PD1- CD62L+. Aged mice also acquired age-associated B-cells associated with impaired humoral immunity.

    Antibody training reduced the levels of pro-inflammatory proteins including interleukin-1 alpha (IL-1α), and C‐X‐C motif chemokine ligand 5 (CXCL5), which were higher in elderly animals. Aged animals with my-HSC depletion exhibited higher virus-specific CD8+ T-cell responses in the spleen following vaccination, thus indicating a better initial response to live-attenuated viral infection.

    Conclusions

    Rising my-HSC levels during aging may result in inadequate adaptive immunological and inflammatory responses. Thus, depleting my-HSCs may improve immune responses by enhancing the synthesis of new T- and B-cells while decreasing the production of inflammatory myeloid cells. In the current study, my-HSC depletion in older animals allowed bal-HSCs to recover youthful immunological characteristics such as enhanced lymphocyte progenitors and naïve cells and decreased lymphocyte dysfunction or exhaustion indicators and inflammatory mediators.

    Further research could refine conditioning techniques and examine the impact on differentiated cells, such as regulatory T-cells.

    Journal reference:

    • Ross, J. B., Myers, L. M., Noh, J. J., et al. (2024). Depleting myeloid-biased haematopoietic stem cells rejuvenates aged immunity. Nature. doi:10.1038/s41586-024-07238-x

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  • Bio-Rad launches validated antibodies for rare cell and circulating tumor cell enumeration

    Bio-Rad launches validated antibodies for rare cell and circulating tumor cell enumeration

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    Bio-Rad Laboratories, Inc. (NYSE: BIO and BIO.B), a global leader in life science research and clinical diagnostics products, today announced the launch of validated antibodies for rare cell and circulating tumor cell (CTC) enumeration. Validated for use with Bio-Rad’s Celselect Slides Enumeration Stain Kits, the antibodies are specific to CTC surface markers to enable the sensitive and specific identification of target cell populations, enhancing the study of tumor heterogeneity and disease progression at various stages. 

    Bio-Rad’s Genesis Cell Isolation System is a customizable benchtop solution that uses unbiased size-based cell selection to gently and efficiently capture a wide range of CTCs and other rare cells from liquid biopsy samples. After capture, the enriched cells can be recovered for downstream analysis, or immuno-stained on-slide for immunofluorescence applications such as enumeration and identification of various CTC types. 

    The enumeration of captured CTCs provides valuable insights into the surface markers that indicate cancer type and progression and is critical to understanding the mechanisms of cancer metastasis. For successful enumeration, the antibody reagents require careful selection to ensure not only sensitivity and specificity to the target cell surface marker, but also compatibility with the staining method. Bio-Rad’s new range of validated primary and secondary antibodies enables accurate immunostaining of captured CTCs, supporting cancer researchers working in this field. 

    CTC analysis is a promising tool for the study of tumor heterogeneity and disease progression, offering real-time data and unique insights into cancer metastasis,” said Stephen Kulisch, Vice President of Marketing for Bio-Rad’s Digital Biology Group. “The introduction of validated antibodies for target cell identification reflects Bio-Rad’s growing single-cell oncology product portfolio and is a testament to our commitment to deliver highly efficient rare cell capture, enrichment, enumeration, and recovery for cancer researchers.”  

    To learn more about the new validated antibodies, visit bio-rad-antibodies.com/val-abs

    BIO-RAD and CELSELECT SLIDES are trademarks of Bio-Rad Laboratories, Inc. in certain jurisdictions.  

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  • Severity of current SARS-CoV-2 variants is not linked to the number of mutations

    Severity of current SARS-CoV-2 variants is not linked to the number of mutations

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    New research from UNC Charlotte’s Center for Computational Intelligence to Predict Health and Environmental Risks (CIPHER) has found that the two most prevalent strains of the virus that cause COVID-19, SARS-CoV-2 variants BA.2.86 and JN.1, are not significantly better than their predecessor Omicron at evading immune responses and causing infections despite having a high number of mutations compared to previous variants.

    When first identified, Omicron offshoots BA.2.86 and its close relative JN.1 raised significant public health concerns. These concerns were tied to the fact that the original Omicron variant was highly mutated, resulting in both immune evasion and breakthrough infection, as well as more infectious and highly-mutated compared to earlier variants.

    There was some speculation that large numbers of new mutations in BA.2.86 and JN.1 conferred a greater ability of these variants to evade the human immune system and be more transmissible. Extensive computational analyses conducted by a team of UNC Charlotte scholars and students determined that these variants only had small, statistically insignificant changes in immune evasion and transmissibility infection capacity compared to earlier variants, including Omicron.

    These results really surprised me. The fact that Omicron, with its large set of mutations, led to greater immune evasion and a surge in cases and hospitalizations was predictable. However, BA.2.86 and JN.1 have yet another large set of mutations, and while we have seen some signals of increased prevalence of these two variants in wastewater and genomic surveillance, there has not been an accompanying large surge in cases or hospital burden.”


    Daniel Janies, Co-Director of CIPHER and the Carol Grotnes Belk Distinguished Professor of Bioinformatics and Genomics in the College of Computing and Informatics

    To assess the immune evasion of BA.2.86 and JN.1, the UNC Charlotte research team performed an extensive in silico analysis on the Receptor Binding Domain (RBD; the region of the viral genome against which vaccines are designed) of SARS-CoV-2, comparing the two newer variants to previous variants to calculate the relative binding affinity of neutralizing antibodies to the RBD from vaccinated patients, infected patients and therapeutic sources. In addition to antibody analysis, researchers calculated the relative binding affinity of BA.2.86 and JN.1 to Angiotensin Converting Enzyme-2 (ACE2) in comparison to previous variants.

    The team found minor changes in binding affinity for neutralizing antibodies and ACE2 for BA.2.86 and JN.1 in comparison to previous SARS-CoV-2 variants. However, those changes were not statistically significant. Therefore, they concluded that BA.2.86 and JN.1 have no significant increase in immune evasion or infection capacity to previous variants. In explaining their results, the researchers caution that genomic surveillance, which counts mutations or relative prevalence of a variant, does not necessarily reveal the functional and health impacts of the variant.

    In a study awaiting publication outlining their research, the team discusses the benefits of their approach to understand the function of variants and the need for future studies to assess variation outside of the RBD for future analysis. Future studies in this area will benefit from an increased focus on antibodies derived from memory B-cells that produce antibodies in response to SARS-CoV-2.

    “In patients whose immune systems have been exposed to a previous Omicron variant, memory B-cells may provide significant protection for the newer Omicron variants BA.2.86 and JN.1,” said Shirish Yasa, a current Charlotte bioinformatics and computer science senior who helped conduct this research. “This protection conferred by memory B-cell-derived antibodies is a process not yet well studied. An increase in Omicron targeting memory B-cells via vaccination and prior infection could be a significant factor in the overall reductions we have seen in hospitalizations and deaths for patients exposed to the descendents of the original Omicron variant.”

    This research contributes to the functional understanding of SARS-CoV-2 variants BA.2.86 and JN.1, building on the studies of genomic surveillance. Moreover, this UNC Charlotte effort has introduced new methodologies for functional computational immunology, which will help in the ongoing efforts to mitigate the consequences of the COVID-19 pandemic.

    Source:

     University of North Carolina at Charlotte

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  • New fluid biomarker may one day detect ALS and FTD before symptoms appear

    New fluid biomarker may one day detect ALS and FTD before symptoms appear

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    Two progressively degenerative diseases, amyotrophic lateral sclerosis (ALS, commonly known as Lou Gehrig’s disease) and frontotemporal dementia (FTD, recently in the news with the diagnoses of actor Bruce Willis and talk show host Wendy Williams), are linked by more than the fact that they both damage nerve cells critical to normal functioning -; the former affecting nerves in the brain and spinal cord leading to loss of movement, the latter eroding the brain regions controlling personality, behavior and language.

    Research studies have repeatedly shown that in patients with ALS or FTD, the function of TAR DNA-binding protein 43, more commonly called TDP-43, becomes corrupted. When this happens, pieces of the genetic material called ribonucleic acid (RNA) can no longer be properly spliced together to form the coded instructions needed to direct the manufacture of other proteins required for healthy nerve growth and function. The RNA strands become riddled with erroneous code sequences called “cryptic exons” that instead affect proteins believed to be associated with increased risk for ALS and FTD development.

    Until now, it was unknown if this abnormality occurred early or late in the clinical courses of ALS and FTD. In a study in the February 2024 issue of the journal Nature Medicine (first posted online Jan. 25, 2024),Johns Hopkins Medicine researchers tell how they answered that long-pondered question.

    We developed a method for locating a specific cryptic exon-linked protein, hepatoma-derived growth factor-like 2 [HDGFL2], that is associated with the loss of TDP-43’s function. By doing so, we believe we’ve discovered a biomarker that could potentially be used to detect ALS and FTD in their earliest stages -; even before symptoms appear.”


    Philip Wong, Ph.D., senior study author, professor of pathology and neuroscience, Johns Hopkins University School of Medicine

    The hunt for the biomarker began with the researchers first identifying cryptic exon-linked proteins associated with TDP-43 function loss. Then, using fragments from those proteins known as cryptic peptides, they created monoclonal (laboratory-made) antibodies specific to each one. Placed into patient samples of blood or cerebrospinal fluid (the protective fluid that surrounds the brain and central nervous system), the monoclonal antibodies will seek and lock onto only the cryptic peptides for which they were designed, making those proteins detectable.

    “Of all the cryptic peptides for which we made monoclonal antibodies, the one that worked best was the one designed for the cryptic HDGFL2 protein,” says study lead author Katie Irwin, an M.D./Ph.D. student at the Johns Hopkins University School of Medicine. “We used that monoclonal antibody to develop an extremely sensitive detection test for the cryptic HDGFL2 protein in body fluids.”

    After validating their detection method in the lab, the researchers used it to test blood and cerebrospinal fluid samples from three different collections, encompassing people with the most common forms of familial (genetic) ALS and FTD linked to a mutation in the C9orf72 gene, sporadic (not defined as genetic) forms of ALS and FTD, and healthy controls. The collections also contained biofluid samples from patients with ALS and FTD prior to their diagnoses, meaning that the researchers could look for cryptic HDGFL2 at both presymptomatic and symptomatic stages of the diseases.

    “Our test found cryptic HDGFL2 in the presymptomatic stages of patients who were genetically predisposed to ALS and FTD, and were expected to go on to develop the diseases, giving the method credibility as a potential preclinical biomarker for predicting risk of ALS and FTD,” says Irwin. “And we discovered that the test also could detect elevated levels of cryptic HDGFL2 in fluids from people with sporadic disease cases where no family history of ALS or FTD was known.”

    Wong says that having a biomarker capable of detecting cryptic HDGFL2 in the biofluids of presymptomatic patients enables them to compare its findings to results using an established biomarker for ALS and FTD.

    “The current biomarker for ALS and FTD looks for structural components of central nervous system [brain and spinal cord] nerves called neurofilaments that are shed into the biofluids, but only after symptoms begin appearing,” explains Wong. “If we use it and our cryptic HDGFL2 biomarker to determine both presymptomatic and symptomatic ALS and FTD, we can map the course of these diseases and obtain greater insight into each of their stages.”

    Wong says that knowledge could help steer patients into clinical trials for new ALS and FTD therapies earlier and “at a time when it might truly make a difference.”

    Irwin says she and her colleagues are gathering biofluid samples from around the world from patients with FTD, genetic ALS and sporadic ALS.

    “We hope to support the effectiveness, reliability and sensitivity of our biomarker by testing it on thousands of patient samples, and once validated, encourage its use as a clinical tool,” she says. “We also plan to explore the use of our biomarker for determining the effectiveness of therapies in preclinical ALS and FTD by looking for reductions in cryptic HDGFL2 levels -; and restoration of TDP-43 function -; after treatment.”

    Along with Wong and Irwin, the members of the study team from Johns Hopkins Medicine are Kyra Bowden, Kerstin Braunstein, Koping Chang, Pei Jasin, Jonathan Ling, Abhay Moghekar, Esther Oh, Irika Sinha, Bryan Traynor and Juan Troncoso. Other team members are Dan Bartlett and Denitza Raitcheva from Biogen, James Berry and Mark Garret from Massachusetts General Hospital, and Timothy Miller from the Washington University School of Medicine in St. Louis.

    Funding for the study came from National Institutes of Health grants R01NS095969, UH3NS115608 and R33NS115161; the Robert Packard Center for ALS Research at Johns Hopkins; the Target ALS Foundation; ALS Finding a Cure; the ALS Association; U.S. Food and Drug Administration grant 1U01FD008129; the Alzheimer’s Association; the Institute for Data-Intensive Engineering and Science; the Intramural Research Program of NIH (National Institute on Aging/National Institute on Neurological Disorders and Stroke grant 1ZIAAG000933); and the Karen Toffler Charitable Trust.

    Ling and Wong are inventors on a provisional patent application submitted by The Johns Hopkins University that covers the use of TDP-43-associated cryptic exon-derived neoepitopes as biomarkers. Traynor holds patents on the clinical testing and therapeutic intervention for the hexanucleotide repeat expansion of C9orf72. Bartlett is an employee and shareholder of Biogen. At the time of the study, Raitcheva was an employee and shareholder of Biogen.

    Source:

    Journal reference:

    Irwin, K. E., et al. (2024). A fluid biomarker reveals loss of TDP-43 splicing repression in presymptomatic ALS–FTD. Nature Medicine. doi.org/10.1038/s41591-023-02788-5.

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  • Nuclera appoints Joseph Bertelsen as Chief Commercial Officer

    Nuclera appoints Joseph Bertelsen as Chief Commercial Officer

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    Nuclera, the biotechnology company enabling rapid protein expression and purification screening through its benchtop protein platform, today announced the appointment of Joseph Bertelsen as Chief Commercial Officer (CCO). With over 20 years’ commercial leadership experience in the life science tools and drug development industries, Joseph brings an extensive sales record that will be instrumental to the commercial launch strategy and explosive adoption of Nuclera’s eProtein Discovery™ platform.

    Joseph joins Nuclera from the Institute for Protein Innovation, a research institute focused on providing synthetic antibodies and protein expertise, where he was the Director of Commercialization responsible for establishing a sustainable antibody distribution entity. Joseph has held numerous senior positions at protein-focused companies driving strategies to maximize industry impact and profitability.

    Prior roles include SVP of Global Sales and Marketing at Diagenode (acquired by Hologic), a life sciences company providing tools for molecular epigenetics research and infectious disease diagnostics, and Director of Sales at Abcam, a company specializing in the production and distribution of research antibodies. Joseph has a MSc in Pharmaceutical Medicine from Hibernia College, Ireland, and a BSc in Chemical Engineering from Michigan State University.

    Nuclera is disrupting the protein market with their technology allowing researchers to more easily and quickly have access to proteins for their research. Their benchtop technology has the potential to greatly reduce costs and timelines associated with the drug discovery process. I’m excited to be joining the team at such an exciting phase of the journey to drive adoption of Nuclera’s eProtein Discovery.”

    Joseph Bertelsen, Chief Commercial Officer

    “Appointing our first Chief Commercial Officer marks an exciting step in Nuclera’s journey. With Joe’s strong track record and experience in achieving revenue growth, I look forward to partnering with him on rapidly increasing the number of protein makers that use our eProtein Discovery system to make proteins accessible.”

    Dr Michael Chen, CEO and co-founder, Nuclera

    For more information about Nuclera’s eProtein Discovery platform, please visit: https://www.nuclera.com/system/

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