The lower hinge of immunoglobulin G (IgG), an overlooked part of the antibody, acts as a structural and functional control hub, according to a study by researchers at Science Tokyo. Deleting a single amino acid in this region transforms a full-length antibody into a stable half-IgG1 molecule with altered immune activity.

The findings provide a blueprint for engineering next-generation antibody therapies with precisely tailored immune effects for treating diseases such as cancer and autoimmune diseases.

Antibodies are Y-shaped proteins that help the immune system recognize and eliminate foreign threats such as bacteria and viruses. The dominant antibody in the bloodstream is immunoglobulin G (IgG), which accounts for about 75% of circulating antibodies. Its structure is divided into two main functional units connected by a flexible hinge that must work together seamlessly.

Complement inhibition showed promising clinical improvement in this single case of dysferlinopathy.

Dysferlinopathy is a rare autosomal recessively inherited myopathy, presenting as several phenotypes, including a proximal weakness dominant limb-girdle muscular dystrophy R2 phenotype and a distal weakness dominant Miyoshi distal myopathy phenotype.^1,2 Muscle weakness usually emerges in young adulthood, followed by a progressive motor decline over the first decade, which tends to be more rapid in individuals with earlier onset.³ Dysferlinopathy is caused by pathogenic variants of the DYSF gene that impair function of dysferlin, a protein that cooperates with others to repair membranes and restore skeletal muscle integrity after injury.⁴

To date, no effective treatment for dysferlinopathy has been clinically validated. Promising approaches, including exon skipping and gene editing targeting the DYSF gene, as well as myoblast transplantation, are still under investigation in preclinical models.⁵ Although dysferlinopathy often presents with inflammatory features on muscle pathology and is prone to misdiagnosis as myositis, it is characterized by the absence of focal MHC-I expression and complement C5b-9 deposition on nonnecrotic sarcolemma, which help distinguish it from other muscular dystrophies and inflammatory myopathies.^6,7 Specially, complement C3 gene knockout in dysferlin-deficient mice has been demonstrated being able to reverse muscle pathology and improve motor function in the previous animal research.

The rising incidence of cancer worldwide has led to an increasing number of surgeries that involve the removal of lymph nodes. Although these procedures play a major role in cancer staging and preventing the spread of malignancies, they sometimes come with severe long-term consequences.

Since lymph nodes do not naturally regenerate once removed, their absence can lead to a condition known as secondary lymphedema. It manifests as chronic swelling, discomfort, and reduced mobility in affected limbs or regions, severely affecting a patient’s quality of life.