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The presence of autoantibodies is a defining feature of many autoimmune diseases. The number of unique autoantibody clones is conceivably limited by immune tolerance mechanisms, but unknown due to limitations of the currently applied technologies. Here, we introduce an autoantigen-specific liquid chromatography-mass spectrometry-based IgG1 Fab profiling approach using the anti-citrullinated protein antibody (ACPA) repertoire in rheumatoid arthritis (RA) as an example. We show that each patient harbors a unique and diverse ACPA IgG1 repertoire dominated by only a few antibody clones. In contrast to the total plasma IgG1 antibody repertoire, the ACPA IgG1 sub-repertoire is characterised by an expansion of antibodies that harbor one, two or even more Fab glycans, and different glycovariants of the same clone can be detected. Together, our data indicate that the autoantibody response in a prominent human autoimmune disease is complex, unique to each patient and dominated by a relatively low number of clones. Although many autoimmune diseases are characterized by the presence of autoantibodies, complete characterisation of autoantibody repertoires is lacking. Here, the authors introduce an autoantigen-specific Fab profiling method to show that the autoantibody repertoire in rheumatoid arthritis is diverse yet dominated only by a few clones.

Existing assays to measure antibody cross-reactivity against different SARS-CoV-2 spike (S) protein variants lack the discriminatory power to provide insights at the level of individual clones. Using a mass spectrometry-based approach we are able to monitor individual donors’ IgG1 clonal responses following a SARS-CoV-2 infection. We monitor the plasma clonal IgG1 profiles of 8 donors who had experienced an infection by either the wild type Wuhan Hu-1 virus or one of 3 VOCs (Alpha, Beta and Gamma). In these donors we chart the full plasma IgG1 repertoires as well as the IgG1 repertoires targeting the SARS-CoV-2 spike protein trimer VOC antigens. The plasma of each donor contains numerous anti-spike IgG1 antibodies, accounting for <0.1% up to almost 10% of all IgG1s. Some of these antibodies are VOC-specific whereas others do recognize multiple or even all VOCs. We show that in these polyclonal responses, each clone exhibits a distinct cross-reactivity and also distinct virus neutralization capacity. These observations support the need for a more personalized look at the antibody clonal responses to infectious diseases. Profiling antibody repertoires using proteomic approaches may provide a way of screening for antibody cross-reactivity against SARS-CoV-2 variants. Here the authors use a IgG1 specific cleavage method to analyse the IgG1 repertoire within recovered patients and relate this to antibody binding and neutralisation.

Recently, a mass spectrometry-based approach was introduced to directly assess the IgG1 immunoglobulin clonal repertoires in plasma. Here we expanded upon this approach by describing a mass spectrometry-based technique to assess specifically the clonal repertoire of another important class of immunoglobulin molecules, IgA1, and show it is efficiently and robustly applicable to either milk or plasma samples. Focusing on two individual healthy donors, whose milk was sampled longitudinally during the first 16 weeks of lactation, we demonstrate that the total repertoire of milk sIgA1 is dominated by only 50-500 clones, even though the human body theoretically can generate several orders of magnitude more clones. We show that in each donor the sIgA1 repertoire only changes marginally and quite gradually over the monitored 16-week period of lactation. Furthermore, the observed overlap in clonal repertoires between the two individual donors is close to non-existent. Mothers provide protection to their newborn infants directly by the transfer of antibodies via breastfeeding. The approach introduced here, can be used to visualize the clonal repertoire transferred from mother to infant and to detect changes in-time in that repertoire adapting to changes in maternal physiology.

IntroductionMaturity-onset diabetes of the young (MODY) and neonatal diabetes mellitus (NDM) are the most prevalent causes of monogenic diabetes. MODY is an autosomal dominant condition with onset in childhood and young adulthood, while NDM is defined with diabetes onset within 6 months of age and can be caused by dominant, recessive, X-linked genes or by chromosomal abnormalities. Here, we describe a rare case of monogenic diabetes in a patient who is homozygous for an INS gene variant.Research design and methodsThe index patient, a male diagnosed with type 2 diabetes, was treated with low-dose insulin and metformin. Blood plasma was collected under fasting conditions for analysis. MODY screening was performed using a next-generation sequencing panel. In silico analysis of the insulin variant’s three-dimensional structure and its interaction with the insulin receptor was conducted. Insulin receptor affinity and downstream signaling potency were evaluated in vitro.ResultsAuto-immune diabetes was excluded. A homozygous missense variant of the INS gene (c.130G>A, p.Gly44Arg) was identified in the patient. The combination of three different insulin assays showed that the biosynthesis of proinsulin into insulin was intact. In silico analysis of the mutant insulin 3D structure revealed that the INS variant is likely to affect insulin receptor binding and subsequent in vitro analysis suggested reduced potency in downstream signaling.ConclusionsThe homozygous c.130G>A variant in the INS gene results in reduced insulin receptor binding and signaling potency. This, combined with pancreatic β-cell apoptosis or dedifferentiation supposedly, has contributed in the late-onset of monogenic diabetes in the index patient.