Is it working? Scientists say gene variant indicates effectiveness of immunotherapy for allergies
While SLIT is beneficial for most people with allergic rhinitis — that is, those who suffer from inflammation of the inside of the nose after allergen exposure — the treatment is ineffective for about 20-30% of them. Unfortunately, there is currently no way of telling if SLIT will be effective for a patient short of trying it out and observing their response over a period of as long as two years, meaning that 20-30% of patients would have to tolerate all the side effects of the treatment for no benefit, for that long a period.
Against this backdrop, a team of researchers from Japan set out to find a biomarker that could be used to predict the responsiveness of a person to SLIT for Japanese cedar pollinosis. In their most recent paper, published online on 12th February 2022 in Allergy, they report a newly discovered association between a specific variant of the HLA-DPB1 gene and poor response to SLIT. This work was the result of a collaborative effort led by Prof. Shigeharu Fujieda and Dr. Masanori Kidoguchi of the University of Fukui, and Prof. Emiko Noguchi of the University of Tsukuba.
So, what is the HLA-DPB1 gene and why would it be related to one’s responsiveness to SLIT? This gene provides instructions for making a protein that plays a critical role in the immune system: helping it distinguish the body’s own proteins from proteins made by foreign invaders, such as bacteria and viruses. The protein encoded by the HLA-DPB1 gene forms a functional protein complex with the protein encoded by the HLA-DPA1 gene. However, these genes are highly polymorphic, meaning that a large number of genetic variants (alleles) exist. In previous studies, this research team had discovered that certain structural differences in the antigen-binding pockets between HLA-DPB1 alleles could make an individual more susceptible to Japanese cedar pollinosis and sensitization.
This led them to think that there might also be a connection between the alleles of HLA-DPB1 and an individual’s responsiveness to SLIT. To test their hypothesis, they enrolled over 200 patients with Japanese cedar pollinosis who underwent SLIT. The researchers determined the HLA-DPB1 alleles in these patients and conducted statistical analyses to see if they were related to their responsiveness to SLIT. “Our results suggest that patients carrying at least one HLA-DPB1*05:01 allele have an increased risk of being non-responders to SLIT in their second season of the immunotherapy,” says Prof. Fujieda. “This implies that differences in the antigen-binding pocket on the HLA-DPB1 protein may influence the effect of allergen immunotherapy,” he adds.
It is worth noting that this may be the first study ever to find an association between a genetic biomarker and an individual’s response to allergen immunotherapy. Genotyping the HLA-DPB1 gene could serve as a cost-effective biomarker to predict the responsiveness of a given patient to SLIT for Japanese cedar pollinosis, saving valuable time. Moreover, these findings may help researchers worldwide rethink how genetic biomarkers can be used both in research and clinical practice, as Prof. Fujieda remarks: “Our study could prompt updates in current international guidelines and consensus documents on the potential of genetic biomarkers.“
Let us hope immunotherapy keeps advancing until no one has to suffer the consequences of severe allergies.