Cellular immune endophenotypes separating early and late-onset myasthenia gravis
Jakob Theorell, Nicolas Ruffin, Andrew Fower, Chiara Sorini, Philip Ambrose, Valentina Damato, Lahiru Handunnetthi, Isabel Leite, Sarosh R. Irani, Susanna Brauner, Adam E. Handel, Fredrik Piehl
Jakob Theorell, Nicolas Ruffin, Andrew Fower, Chiara Sorini, Philip Ambrose, Valentina Damato, Lahiru Handunnetthi, Isabel Leite, Sarosh R. Irani, Susanna Brauner, Adam E. Handel, Fredrik Piehl
View: Text | PDF
Research Article Immunology Neuroscience

Cellular immune endophenotypes separating early and late-onset myasthenia gravis

Abstract

The 2 main subgroups of autoimmune myasthenia gravis, a neuromuscular junction disorder associated with muscle weakness, are early- and late-onset forms, defined by onset before or after 50 years of age. Both carry acetylcholine-receptor autoantibodies but differ in sex ratios, genetics, and occurrence of disease-specific thymus inflammation. To distinguish the 2 forms by cellular immune phenotyping, we applied multimodal techniques, including deep spectral cytometric phenotyping and single-cell sequencing. Analysis of 2 independent cohorts identified immunological differences driven by 3 main lymphocyte populations. Lower frequencies of mucosa-associated invariant T cells and naive CD8+ T cells were observed in late-onset myasthenia, suggesting enhanced immune senescence. A highly differentiated, canonical NK cell population was reduced in early-onset myasthenia and negatively correlated with the degree of thymic hyperplasia. Using only the frequency of these 3 populations, correct myasthenia subgroup assignment could be predicted with 90% accuracy. These distinct immunocellular endophenotypes for early- and late-onset disease suggest differences in immunopathogenic processes. Along with demographic factors and other disease subgroup–specific features, the frequency of the identified cell subpopulations may improve clinical classification.

Authors

Jakob Theorell, Nicolas Ruffin, Andrew Fower, Chiara Sorini, Philip Ambrose, Valentina Damato, Lahiru Handunnetthi, Isabel Leite, Sarosh R. Irani, Susanna Brauner, Adam E. Handel, Fredrik Piehl

×

Figure 2

Identification and characterization of significantly different cell populations.

Options: View larger image (or click on image) Download as PowerPoint
Identification and characterization of significantly different cell popu...
(A) Overview of analyzed clusters and their respective significance in the iterative process. Dark red indicates significance in all 3 tests, which was the selection criterion for discriminatory clusters. Gray indicates that less than 50 cells were present in the SE data, so no comparisons were made. For all clusters where the significance was restricted to 1 or 2 populations, these came from the UK cohort. (B) Individual frequencies of the identified significantly different cell populations in the UK and SE cohorts. Mann-Whitney U tests were 1-sided for all comparisons, given that the cell populations were preidentified as over- or underrepresented in EOMG or LOMG compared with the other groups. *P = 0.05–0.005, **P = 0.005–0.0005, and ***P < 0.0005. As clusters have only been selected if all 3 independent comparisons had 1-tailed P values lower than 0.05, the false-positive error rate is 1/8,000, and with only 11 comparisons in total, no further adjustment for multiple comparisons was therefore included. (C) Selected surface markers defining the individual clusters in the UK dataset. The gray fields indicate gates that are sufficient to identify the significant cluster.