Craniopharyngioma (CP) is a rare brain tumour that develops in the regions close to the hypothalamus and pituitary gland.

The CP tumours lead to complications like defective vision, neuronal defects, diabetes, and developmental problems.

There are two primary subtypes of CPs: adamantinomatous craniopharyngioma (ACP) and papillary craniopharyngioma (PCP).

These two subtypes are distinguished by their distinct genetic profiles.

ACP is typically characterised by mutations in the CTNNB1 gene, while PCP is primarily associated with BRAF gene mutations.

The primary course of action for treating CP is surgical intervention.

However, the tumour's invasive nature and its location near critical structures present a significant challenge in terms of surgical intervention.

As the tumour progresses, it infiltrates the surrounding tissue, resulting in significant neurological impairments.

Therefore, surgery alone is insufficient to address the complex challenges posed by CPs.

It is essential to have a comprehensive understanding of the tumour's biological characteristics and molecular progression in order to ensure successful tumour extraction while preserving surrounding healthy tissue.

Against this backdrop, Professor Tomoaki Tanaka collaborated with Professor Yoshinori Higuchi and Dr. Takashi Kono from the Graduate School of Medicine at Chiba University in Japan to conduct a study to elucidate the underlying biological processes involved in this tumour.

The study was made available online on September 30, 2024, and was published in Volume 27 Issue 11 of the journal iScience on November 15, 2024.

To this end, they utilised single-cell RNA sequencing, a technique that reveals differences in gene expression across individual cells, and analysed 10 cases of CPs.

In an interview, Prof. Tanaka, the senior author of the study, explained the motivation behind it.

He said, “Despite being histologically benign, these tumours can significantly impact critical brain structures." "Our goal was to develop more targeted and less invasive therapeutic approaches that could significantly improve patient outcomes and quality of life.”

The single-cell analysis revealed a diverse range of cell types within the tumour microenvironment (TME), including tumour cells, immune cells, and fibroblasts, with varying proportions across cases.

The tumour cells were classified into two main subtypes: Type 1, which is predominant in ACP, and Type 2, which is dominant in PCP.

The single-cell gene expression data from the ACP and PCP subtypes was clustered to reveal distinct cell types within the tumours.

The study identified cell types linked to the development of epithelial cells and the immune response in both ACP and PCP tumours.

However, the cell types involved in tumour calcification were particularly prevalent in ACP, while the cell cycle-associated genes were predominant in the PCP type.

Further, the research team observed a notable diversity in macrophage types between the two tumour types.

The pro-inflammatory M1 macrophages and inflammation-related markers were found to be higher in ACP, while the anti-inflammatory M2 macrophages were higher in PCP.

Accordingly, a higher ratio of M1 and M2 macrophages was correlated with the occurrence of diabetes and pituitary insufficiency.

Additionally, the study identified a prominent cell-cell interaction between cell surface proteins CD44-secreted phosphoprotein 1 (SPP1).

This SPP1–CD44 signal from classical M2 inhibited the sustained proliferation of T cells.

This study presents a comprehensive map of cell types within CP tumours and reports a significant relationship between immune cells and clinical symptoms.

Prof. Tanaka highlighted the clinical implications of their findings, stating, “These findings open up the possibility of personalised treatment approaches for patients with CP based on their specific tumour subtype and immune cell composition. Understanding these differences will also assist clinicians in predicting which patients are at higher risk for complications like diabetes insipidus.”

Going ahead, these findings can enable the creation of new targeted therapies that precisely influence the tumour microenvironment and immune cell interactions, ultimately leading to more effective treatments with reduced adverse effects.

Source: Chiba University