Invasive growth associated with cold-inducible RNA-binding protein expression drives recurrence of surgically resected brain metastases

Dankner, Matthew; Caron, Maxime; Al‐Saadi, Tariq; Yu, Wenqing; Ouellet, Véronique; Ezzeddine, Rima; Maritan, Sarah M.; Annis, Matthew G.; Le, Phuong Uyen; Nadaf, Javad; Neubarth, Noah; Savage, Paul; Zuo, Dongmei; Couturier, Céline; Monlong, Jean; Djambazian, Haïg; Altoukhi, Huda; Bourque, Guillaume; Ragoussis, Jiannis; Diaz, Roberto J.; Park, Morag; Guiot, Marie‐Christine; Lam, Stephanie; Petrecca, Kevin; Siegel, Peter M.

doi:10.1093/neuonc/noab002

Cited by 21 publications

(25 citation statements)

References 26 publications

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“…The ability of MDA-MB-231 cells to form LM upon intracranial injection was confirmed by Allen et al, who observed leptomeningeal dissemination when MDA-MB-231, but not MDA-MB-468 cells, were implanted [44]. These findings were expanded upon using a cohort of patient-derived xenograft models of brain metastases injected intracranially, which show differential propensity to form LM based upon the invasion pattern in the brain metastatic lesion (minimally versus highly invasive) and expression of CIRBP [45]. This suggests that cellular processes and molecular mediators that are present in only a subset of cancers may be involved in leading established parenchymal brain metastases to subsequently colonize the leptomeninges.…”

Section: Applying Pre-clinical Animal Models Of Lm To Study Its Undermentioning

confidence: 78%

“…The converse may also be true, where leptomeningeal deposits can be observed invading into the brain parenchyma ( Figure 2). Metastatic cancer cells have been shown to cycle between the brain parenchyma and leptomeningeal compartments in rodent models [44], with cold-inducible RNA-binding protein (CIRBP) and cyclooxygenase-2 representing candidate genes implicated in this process [44,45]. It is possible that shuttling between the brain and leptomeningeal anatomical compartments is uniquely driven by invasion across the glia limitans, however, other possibilities remain.…”

Section: Defining Lm By the Route Of Entrymentioning

confidence: 99%

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The Underlying Biology and Therapeutic Vulnerabilities of Leptomeningeal Metastases in Adult Solid Cancers

Dankner

Lam

Degenhard

et al. 2021

Cancers

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Metastasis to the central nervous system occurs in approximately 20% of patients with advanced solid cancers such as lung cancer, breast cancer, and melanoma. While central nervous system metastases most commonly form in the brain parenchyma, metastatic cancer cells may also reside in the subarachnoid space surrounding the brain and spinal cord to form tumors called leptomeningeal metastases. Leptomeningeal metastasis involves cancer cells that reach the subarachnoid space and proliferate in the cerebrospinal fluid compartment within the leptomeninges, a sequela associated with a myriad of symptoms and poor prognosis. Cancer cells exposed to cerebrospinal fluid in the leptomeninges must contend with a unique microenvironment from those that establish within the brain or other organs. Leptomeningeal lesions provide a formidable clinical challenge due to their often-diffuse infiltration within the subarachnoid space. The molecular mechanisms that promote the establishment of leptomeningeal metastases have begun to be elucidated, demonstrating that it is a biological entity distinct from parenchymal brain metastases and is associated with specific molecular drivers. In this review, we outline the current state of knowledge pertaining to the diagnosis, treatment, and molecular underpinnings of leptomeningeal metastasis.

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Section: Applying Pre-clinical Animal Models Of Lm To Study Its Undermentioning

confidence: 78%

Section: Defining Lm By the Route Of Entrymentioning

confidence: 99%

The Underlying Biology and Therapeutic Vulnerabilities of Leptomeningeal Metastases in Adult Solid Cancers

Dankner

Lam

Degenhard

et al. 2021

Cancers

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“…Mechanical dissociation in the operating room decreases processing time in the laboratory and aids in streamlining experimentation (Figure 2E) Dependent of the location of the brain metastasis, often a rim of the surrounding tissue within the parenchyma can be resected as well. Recent data also demonstrates heterogeneity between regions of metastatic tumors and invasion into the peritumoral border (33,34). Therefore, even with metastatic tumor regional information is routinely annotated with the tumor tissue.…”

Section: Intraoperative Considerationsmentioning

confidence: 99%

Brain Tumor Biobank Development for Precision Medicine: Role of the Neurosurgeon

et al. 2021

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Neuro-oncology biobanks are critical for the implementation of a precision medicine program. In this perspective, we review our first year experience of a brain tumor biobank with integrated next generation sequencing. From our experience, we describe the critical role of the neurosurgeon in diagnosis, research, and precision medicine efforts. In the first year of implementation of the biobank, 117 patients (Female: 62; Male: 55) had 125 brain tumor surgeries. 75% of patients had tumors biobanked, and 16% were of minority race/ethnicity. Tumors biobanked were as follows: diffuse gliomas (45%), brain metastases (29%), meningioma (21%), and other (5%). Among biobanked patients, 100% also had next generation sequencing. Eleven patients qualified for targeted therapy based on identification of actionable gene mutations. One patient with a hereditary cancer predisposition syndrome was also identified. An iterative quality improvement process was implemented to streamline the workflow between the operating room, pathology, and the research laboratory. Dedicated tumor bank personnel in the department of neurosurgery greatly improved standard operating procedure. Intraoperative selection and processing of tumor tissue by the neurosurgeon was integral to increasing success with cell culture assays. Currently, our institutional protocol integrates standard histopathological diagnosis, next generation sequencing, and functional assays on surgical specimens to develop precision medicine protocols for our patients. This perspective reviews the critical role of neurosurgeons in brain tumor biobank implementation and success as well as future directions for enhancing precision medicine efforts.

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“…Compatibility with in vitro passage is not granted and efficacy has been estimated between 24% and 48.8% depending on the amount of viable cancer cells in the surgical sample, ability of the cells to form colonies in the first culture, and the degree of senescence affecting cancer cells. 24 Most brain metastatic PDX models are derived from either systemic 25 or intracranial 26 inoculation, but few models have been reported to spontaneously metastasize from orthotopic (subdermal for melanoma 21 or mammary fat-pad for breast cancer 27 ) injection. Of note, a brain-metastatic SCLC PDX model has recently been established from subcutaneous injection.…”

Section: Patient-derived Xenograft (Pdx) Modelsmentioning

confidence: 99%

Animal models of brain metastasis

Miarka

Valiente

2021

Neuro-Oncology Advances

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Modeling of metastatic disease in animal models is a critical resource to study the complexity of this multi-step process in a relevant system. Available models of metastatic disease to the brain are still far from ideal but they allow to address specific aspects of the biology or mimic clinically relevant scenarios. We not only review experimental models and their potential improvements but also discuss specific answers that could be obtained from them on unsolved aspects of clinical management.

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Invasive growth associated with cold-inducible RNA-binding protein expression drives recurrence of surgically resected brain metastases

Cited by 21 publications

References 26 publications

The Underlying Biology and Therapeutic Vulnerabilities of Leptomeningeal Metastases in Adult Solid Cancers

The Underlying Biology and Therapeutic Vulnerabilities of Leptomeningeal Metastases in Adult Solid Cancers

Brain Tumor Biobank Development for Precision Medicine: Role of the Neurosurgeon

Animal models of brain metastasis

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