Glioblastoma extracellular vesicles influence glial cell hyaluronic acid deposition to promote invasiveness

  1. Dominik Koessinger
  2. David Novo
  3. Anna Koessinger
  4. America Campos
  5. Jasmine Peters
  6. Louise Dutton
  7. Peggy Paschke
  8. Désirée Zerbst
  9. Madeleine Moore
  10. Louise Mitchell
  11. Matthew Neilson
  12. Katrina Stevenson
  13. Anthony Chalmers
  14. Stephen Tait
  15. Joanna Birch
  16. Jim Norman
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Abstract

Background

Infiltration of glioblastoma (GBM) throughout the brain leads to its inevitable recurrence following standard-of-care treatments, such as surgical resection, chemo- and radio-therapy. A deeper understanding of the mechanisms invoked by GMB to infiltrate the brain is needed to develop approaches to contain the disease and reduce recurrence. The aim of this study was to discover mechanisms through which extracellular vesicles (EVs) released by GBM influence the brain microenvironment to facilitate infiltration, and to determine how altered extracellular matrix (ECM) deposition by glial cells might contribute to this.

Methods

CRISPR was used to delete genes, previously established to drive carcinoma invasiveness and EV production, from patient-derived primary and GBM cell lines. We purified and characterised EVs released by these cells, assessed their capacity to foster pro-migratory microenvironments in mouse brain slices, and evaluated the contribution made by astrocyte-derived extracellular matrix (ECM) to this. Finally, we determined how CRISPR-mediated deletion of genes, which we had found to control EV-mediated communication between GBM cells and astrocytes, influenced GBM infiltration when orthotopically injected into CD1-nude mice.

Results

GBM cells expressing a p53 mutant (p53273H) with established pro-invasive gain-of-function release EVs containing a sialomucin, podocalyxin (PODXL), which encourages astrocytes to deposit ECM with increased levels of hyaluronic acid (HA). This HA-rich ECM, in turn, promotes migration of GBM cells. Consistently, CRISPR-mediated deletion ofPODXLopposes infiltration of GBMin vivo.

Conclusions

This work describes several key components of an EV-mediated mechanism though which GBM cells educate astrocytes to support infiltration of the surrounding healthy brain tissue.

KEY POINTS

The p53R273Honcogene encourages GBM cells to release EVs containing podocalyxin. Podocalyxin-containing EVs from GBM increase hyaluronic acid production by astrocytes. Hyaluronic acid production by astrocytes drives GBM migration.

IMPORTANCE OF THE STUDY

The infiltrative behaviour of glioblastoma (GBM) leads to widespread dissemination of cancer cells throughout the brain. Thus, even following successful resection of the primary tumour these disseminated cells inevitably contribute to post-surgical relapse. In this study, we have discovered a new mechanism through which GBM can release small extracellular vesicles (EVs) to reprogramme extracellular matrix (ECM) production by astrocytes in a way that supports increased invasive behaviour of the GBM cells. Moreover, we have discovered several key components of the pathway which contribute to this EV-mediated GBM-glial cell communication. Principal amongst these, we show that a particular mutant of the p53 tumour suppressor, p53273Hdrives the release of EVs which foster the deposition of pro-invasive ECM by astrocytes. This study provides mechanistic insight into why brain tumours expressing p53273Hare associated with particularly poor patient survival and highlights the possibility of deploying agents which target astrocyte ECM deposition to reduce the morbidity of p53273H- expressing GBM.

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