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Tag: Autoantibodies

  • Blood test may predict MS development, UCSF research reveals

    Blood test may predict MS development, UCSF research reveals

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    In a discovery that could hasten treatment for patients with multiple sclerosis (MS), UC San Francisco scientists have discovered a harbinger in the blood of some people who later went on to develop the disease. 

    In about 1 in 10 cases of MS, the body begins producing a distinctive set of antibodies against its own proteins years before symptoms emerge. These autoantibodies appear to bind to both human cells and common pathogens, possibly explaining the immune attacks on the brain and spinal cord that are the hallmark of MS.

    The findings were published in Nature Medicine on April 19.

    MS can lead to a devastating loss of motor control, although new treatments can slow the progress of the disease and, for example, preserve a patient’s ability to walk. The scientists hope the autoantibodies they have discovered will one day be detected with a simple blood test, giving patients a head start on receiving treatment.

    Over the last few decades, there’s been a move in the field to treat MS earlier and more aggressively with newer, more potent therapies. A diagnostic result like this makes such early intervention more likely, giving patients hope for a better life.” 


    Michael Wilson, MD, senior author of the paper, UCSF neurologist

    Linking infections with autoimmune disease 

    Autoimmune diseases like MS are believed to result, in part, from rare immune reactions to common infections.

    In 2014, Wilson joined forces with Joe DeRisi, PhD, president of the Chan Zuckerberg Biohub SF and a senior author of the paper, to develop better tools for unmasking the culprits behind autoimmune disease. They took a technique in which viruses are engineered to display bits of proteins like flags on their surface, called phage display immunoprecipitation sequencing (PhIP-Seq), and further optimized it to screen human blood for autoantibodies. 

    PhIP-Seq detects autoantibodies against more than 10,000 human proteins, enough to investigate nearly any autoimmune disease. In 2019, they successfully used it to discover a rare autoimmune disease that seemed to arise from testicular cancer. 

    MS affects more than 900,000 people in the US. Its early symptoms, like dizziness, spasms, and fatigue, can resemble other conditions, and diagnosis requires careful analysis of brain MRI scans.

    The phage display system, the scientists reasoned, could reveal the autoantibodies behind the immune attacks of MS and create new opportunities to understand and treat the disease. 

    The project was spearheaded by first co-authors Colin Zamecnik, PhD, a postdoctoral researcher in DeRisi’s and Wilson’s labs; and Gavin Sowa, MD, MS, former UCSF medical student and now internal medicine resident at Northwestern University. 

    They partnered with Mitch Wallin, MD, MPH, from the University of Maryland and a senior author of the paper, to search for autoantibodies in the blood of people with MS. These samples were obtained from the U.S. Department of Defense Serum Repository, which stores blood taken from armed service members when they apply to join the military. 

    The group analyzed blood from 250 MS patients collected after their diagnosis, plus samples taken five or more years earlier when they joined the military. The researchers also looked at comparable blood samples from 250 healthy veterans.

    Between the large number of subjects and the before-and-after timing of the samples, it was “a phenomenal cohort of individuals to look at to see how this kind of autoimmunity develops over the course of clinical onset of this disease,” said Zamecnik. 

    A consistent signature of MS  

    Using a mere one-thousandth of a milliliter of blood from each time point, the scientists thought they would see a jump in autoantibodies as the first symptoms of MS appeared. 

    Instead, they found that 10% of the MS patients had a striking abundance of autoantibodies years before their diagnosis. 

    The dozen or so autoantibodies all stuck to a chemical pattern that resembled one found in common viruses, including Epstein-Barr Virus (EBV), which infects more than 85% of all people, yet has been flagged in previous studies as a contributing cause for MS.

    Years before diagnosis, this subset of MS patients had other signs of an immune war in the brain. Ahmed Abdelhak, MD, co-author of the paper and a postdoctoral researcher in the UCSF laboratory of Ari Green, MD, found that patients with these autoantibodies had elevated levels of neurofilament light (Nfl), a protein that gets released as neurons break down. 

    Perhaps, the researchers speculated, the immune system was mistaking friendly human proteins for some viral foe, leading to a lifetime of MS. 

    “When we analyze healthy people using our technology, everybody looks unique, with their own fingerprint of immunological experience, like a snowflake,” DeRisi said. “It’s when the immunological signature of a person looks like someone else, and they stop looking like snowflakes that we begin to suspect something is wrong, and that’s what we found in these MS patients.” 

    A test to speed patients toward the right therapies 

    To confirm their findings, the team analyzed blood samples from patients in the UCSF ORIGINS study. These patients all had neurological symptoms and many, but not all, went on to be diagnosed with MS. 

    Once again, 10% of the patients in the ORIGINS study who were diagnosed with MS had the same autoantibody pattern. The pattern was 100% predictive of an MS diagnosis. Across both the Department of Defense group and the ORIGINS group, every patient with this autoantibody pattern had MS. 

    “Diagnosis is not always straightforward for MS, because we haven’t had disease-specific biomarkers,” Wilson said. “We’re excited to have anything that can give more diagnostic certainty earlier on, to have a concrete discussion about whether to start treatment for each patient.” 

    Many questions remain about MS, ranging from what’s instigating the immune response in some MS patients to how the disease develops in the other 90% of patients. But the researchers believe they now have a definitive sign that MS is brewing. 

    “Imagine if we could diagnose MS before some patients reach the clinic,” said Stephen Hauser, MD, director of the UCSF Weill Institute for Neurosciences and a senior author of the paper. “It enhances our chances of moving from suppression to cure.” 

    Source:

    University of California – San Francisco

    Journal reference:

    Zamecnik, C. R., et al. (2024). An autoantibody signature predictive for multiple sclerosis. Nature Medicine. doi.org/10.1038/s41591-024-02938-3.

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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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  • Researchers find new clues to understanding the progression of primary membranous nephropathy

    Researchers find new clues to understanding the progression of primary membranous nephropathy

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    No therapies currently exist that can halt the progression of chronic kidney disease in children or restore the ability of kidney cells to filter blood. Recently, researchers at the GOFARR Laboratory for Organ Regenerative Research and Cell Therapeutics in Urology in The Saban Research Institute of Children’s Hospital Los Angeles found new clues to understanding how chronic kidney disease progresses. By mapping the underlying genetic drivers of a type of chronic kidney disease called primary membranous nephropathy, they seek disease markers that could point the way to developing new treatments for children. In a paper published in the journal JCI Insight, the research team found that an unexpected mechanism was responsible for the loss of the kidney cells’ ability to filter toxins from blood.

    We have a good idea of what happens in the process of various types of chronic kidney failure, but we still don’t know precisely why and where it happens. Our goal was to scrutinize the molecular processes of any underlying mechanisms that could cause kidney podocytes to fail and lose their blood filtering capacity. Membranous nephropathy, which affects adults, can serve as a disease model for other chronic kidney disease processes that affect children and adults alike. The glomerulus-on-a-chip platform that we developed at the GOFARR lab allowed us to agnostically query different pathways involved in disease progression and measure their impact.”


    Stefano Da Sacco, PhD, Investigator, Urology Research at CHLA and study senior author

    A different culprit entirely

    In membranous nephropathy, infection-fighting autoantibodies destroy the kidney’s glomerular structures that contain the specialized podocytes that maintain the kidney’s filtration barrier. The researchers modeled membranous nephropathy caused by anti-phospholipase A2 receptor (PLA2R) antibodies. PLA2R is a target antigen recognized by the body’s immune system in about 70% of adults with membranous nephropathy. (Another antigen, SEMA3B, is prevalent in the rare pediatric cases that make up between 1% to 3% of total membranous nephropathy patients.) As the anti-phospholipase A2 receptor autoantibodies bind to the target PLA2R antigen-;which resides on the surface of kidney podocytes-;they trigger a cascade of events that leads to podocyte injury, destroying the kidney glomerular cells’ capacity to filter toxins from blood.

    Previously, researchers believed that the membrane-attack-complex (MAC) was the sole driver of podocyte injury, and that inhibiting it was key to halting disease progression. The GOFARR research team discovered instead that signaling in the C3a/C3aR pathway plays a critical role in the progression of membranous nephropathy. The team tested this insight both in vitro and using the glomerulus-on-a chip-tissue model, showing that administering a C3aR antagonist could preserve the podocyte’s ability to filter blood. When Dr. Da Sacco’s team specifically blocked signaling in the C3aR gene pathway by silencing the C3aR gene in podocytes, they observed that the system retained filtration capabilities. But when the researchers prevented MAC formation, podocyte function kept deteriorating.

    “By probing what is actually happening at the molecular level, we found that an entirely different pathway than we initially thought was the main driver for primary membranous neuropathy,” says Dr. Da Sacco, Assistant Professor of Research Urology at the Keck School of Medicine of USC. “We had previous knowledge that this pathway could cause damage to podocytes, but no confirmation that it was important in membranous nephropathy. We were a bit surprised and greatly encouraged. Finding what causes podocytes to fail is a step toward preventing-;and eventually reversing-;kidney deterioration. Our patients need better treatment options.”

    This work was supported by grants from NIH/NIDDK (RO1, R01DK123234) and by the GOFARR Foundation from the Schenkman Family.

    Source:

    Children’s Hospital Los Angeles

    Journal reference:

    Zhang, Q., et al. (2024). C3aR-initiated signaling is a critical mechanism of podocyte injury in membranous nephropathy. JCI Insight. doi.org/10.1172/jci.insight.172976.

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  • New study pinpoints key markers for Long COVID diagnosis

    New study pinpoints key markers for Long COVID diagnosis

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    In a recent preprint* uploaded to the medRxiv server, an international team of researchers conducted a large-scale systems-level immunological screening of more than 1,000 confirmed COVID-19 patients to identify diagnostic markers of Long-term COVID-19. The analyses using multiple orthogonal detection methods reveal elevated serologic responses as a highlight of Long COVID and that its correlated memory CD8+ T cell clonal expansion is a more reliable and sensitive marker of the condition than conventional antigen (SARS-CoV-2 RNA and protein) detection approaches.

    Study: Restrained memory CD8+ T cell responses favors viral persistence and elevated IgG responses in patients with severe Long COVID. Image Credit: Lightspring / ShutterstockStudy: Restrained memory CD8+ T cell responses favors viral persistence and elevated IgG responses in patients with severe Long COVID. Image Credit: Lightspring / Shutterstock

    *Important notice: medRxiv publishes preliminary scientific reports that are not peer-reviewed and, therefore, should not be regarded as conclusive, guide clinical practice/health-related behavior, or treated as established information.

    COVID-19 and the need for Long COVID diagnosis

    The ongoing Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) caused Coronavirus disease 2019 (COVID-19) viral pandemic is one of the worst in human memory, estimated to have infected more than 700 million individuals since its discovery in Wuhan, China, in late 2019. While global legislative policy and the widespread development and dissemination of anti-COVID-19 vaccines have substantially reduced the disease burden, with reports of vaccination efforts saving 70% of patients or more, survivors of the pandemic are plagued by a hitherto unknown condition – Long COVID.

    Also called the ‘Post COVID-19 condition’, ‘chronic COVID syndrome,’ and clinically, ‘post-acute sequelae of COVID-19 (PASC)’, Long COVID presents itself as perhaps the worst legacy of the pandemic. The now well-established yet poorly understood condition is characterized by the persistence or development of COVID-19-associated symptoms that may persist for months or even years following initial infection recovery. These symptoms include severe cognitive decline (brain fog), chronic fatigue, and multiple organ damage, resulting in significant economic and quality of life (QoL) losses in patients.

    Alarmingly, research has revealed that despite vaccination efforts substantially reducing adverse Long COVID outcomes, between 30 and 60% of all COVID-19 infections result in Long COVID, with an estimated 350+ million individuals suffering from the condition. Unfortunately, extensive global scientific efforts remain unable to elucidate the mechanisms underpinning Long COVID, hampering the development of diagnostic assays and clinical interventions for patients.

    About the study

    In the present study, researchers screened more than 1000 prospective patients enrolled at Long COVID clinics in Belgium and Sweden to elucidate the shared mechanisms of Long COVID pathology and subsequently develop a sensitive and reliable diagnostic test for the condition. Only subjects with a clinically confirmed mild or moderate COVID-19 infection were included. Severe cases were excluded due to overlapping symptoms with those of the post-intensive care syndrome.

    Patients without objective measures of disease-associated organ damage (e.g., magnetic resonance imaging [MRI], pulsatile arterial tonometry [EndoPAT], and postural orthostatic tachycardia syndrome [POTS]) were excluded. Inclusion and exclusion criteria resulted in a final sample cohort of 121 patients from Belgium (n = 31) and Sweden (n = 90).

    Experimental procedures included the enzyme-linked immunosorbent assay (ELISA) for detecting and measuring patients’ antibody responses against SARS-CoV-2. Since these standard ELISAs were not observed to elucidate differences in immunoglobulin A (IgA) and IgM despite clear case-convalescent control differences in IgG titers, single-molecule array (SIMOA) assays were employed. The SPEAR immunoassay was used to detect the presence of persistent SARS-CoV-2 spike proteins in patients’ plasma samples.

    Since these assays revealed that antigen responses were only depicted by about 10% of the study cohort, suggesting its unreliability and poor sensitivity as a diagnostic tool, researchers used a 51-parameter-panel mass cytometry assay to investigate possible immunological correlates. The Olinks assay was further conducted to measure levels of cytokines and other plasma proteins in patients’ plasma samples.

    “Autoantibodies to type-I IFN have been associated with life-threatening COVID-19 pneumonia due to impaired IFN-I-mediated inhibition of viral replication. Such autoantibodies increase in frequency with age, are more common in males than females for unknown reason, and could explain up to 20% of COVID-19 deaths. The reasons for the development of anti-cytokine autoantibodies are unknown in most cases, but most, if not all, patients with inborn errors of central tolerance due to AIRE deficiency in cis (APECED or APS1) or in trans (mutations of the alternative NF-kB pathway) all carry these autoantibodies and are highly susceptible to severe SARSCoV-2 infections.”

    To investigate the above, single-cell T-cell receptor (TCR) and message RNA (mRNA) sequencing of peripheral blood mononuclear cells (PBMCs) was carried out. Memory CD8 T cell TCR sequences were then clustered using the GLIPH methodology.

    Study findings

    The present study reveals that, while IgG response to SARS-CoV-2 spike (receptor binding domain [RDB]) proteins as measured by the SIMAO assay can be used as a sensitive Long COVID marker, IgA and IgM cannot due to their detection in ~10% of afflicted patients. This suggests that memory CD8+ T cells were restrained, and their clonal expansion is restricted by SARS-CoV-2, inconsistent with the previously hypothesized exhausted phenotype pathology.

    Strong and persistent Long COVID symptoms despite high IgG tirtes suggest differences between the initial and long-term adaptive responses of patients’ immunity to SARS-CoV-2.

    “A strong initial adaptive response might increase the chance of viral clearance and reduce the risk of Long COVID, while a sustained and elevated long-term response to SARSCoV-2 with elevated titers occur once a viral reservoir has been established leading to chronic antigen stimulation.”

    Results highlight that in Long COVID cases, the elevated serologic response was inversely correlated to expanding CD8+ T cell populations, elucidating the role of the restrained antiviral T cell response as a crucial component of Long COVID pathology. Current and future work aimed at understanding the genetic basis of this revelation may allow for the development of clinical therapeutics capable of treating this hitherto incurable condition.

    Conclusions

    The present study uses a combination of ELISA, SIMOA, and sequencing assays to investigate the associations between circulating immunoglobulin titers and Long COVID pathology, with the dual aim of elucidating Long COVID’s mechanism of action and progressing the discovery of a universal Long COVID diagnostic test. Their findings reveal that contrary to expectation, IgG titers in Long COVID patients increase following initial infection recovery, suggesting chronic antigen stimulation.

    IgA and IgM titers, in contrast, were extremely low and detectable in only 10% of cases, making them unreliable in Long COVID diagnosis.

    *Important notice: medRxiv publishes preliminary scientific reports that are not peer-reviewed and, therefore, should not be regarded as conclusive, guide clinical practice/health-related behavior, or treated as established information.

    Journal reference:

    • Preliminary scientific report.
      Lucie Rodriguez, Ziyang Tan, Lakshmi Kanth Tadepally, Jun Wang, Hugo Barcenilla, Zoe Swank, Fanglei Zuo, Hassan Abolhassani, Ana Jimena Pavlovitch-Bedzyk, Chunlin Wang, Laura Gonzalez, Constantin Habimana Mugabo, Anette Johnsson, Yang Chen, Anna James, Jaromir Mikes, Linn Kleberg, Christopher Sundling, Mikael Bjornson, Malin Nygren-Bonnier, Marcus Stahlberg, MIchael Runold, Sofia Bjorkander, Erik Melen, Isabelle Meyts, Johan Van Weyenbergh, Qiang Pan Hammarstrom, Mark M Davis, David R. Walt, Nils Landegren, COVID Human Genetic Effort, Alessandro Aiuti, Giorgio Casari, Jean-Laurent Casanova, MARC JAMOULLE, Judith Bruchfeld, Petter Brodin. Restrained memory CD8+ T cell responses favors viral persistence and elevated IgG responses in patients with severe Long COVID. medRxiv (2024), DOI – 10.1101/2024.02.11.24302636, https://www.medrxiv.org/content/10.1101/2024.02.11.24302636v1


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