Genomic characterization of human brain metastases identifies drivers of metastatic lung adenocarcinoma

Shih, David; Nayyar, Naema; Bihun, Ivanna V.; Dagogo‐Jack, Ibiayi; Gill, Corey M.; Aquilanti, Elisa; Bertalan, Mia; Kaplan, Alexander; D’Andrea, Megan R.; Chukwueke, Ugonma; Ippen, Franziska M.; Alvarez‐Breckenridge, Christopher; Camarda, Nicholas D.; Lastrapes, Matthew; McCabe, Devin; Kuter, Ben; Kaufman, Benjamin; Strickland, Matthew R.; Martínez-Gutiérrez, Juan Carlos; Nagabhushan, Deepika; Sauvage, Magali de; White, Michael; Castro, Brandyn; Hoang, Kaitlin; Kaneb, Andrew; Batchelor, Emily; Paek, Sun Ha; Park, Sun Hye; Martinez‐Lage, Maria; Berghoff, Anna Sophie; Merrill, Parker; Gerstner, Elizabeth R.; Batchelor, Tracy T.; Frosch, Matthew P.; Frazier, Ryan P.; Borger, Darrell R.; Iafrate, A. John; Johnson, Bruce E.; Santagata, Sandro; Cahill, Daniel P.; Carter, Scott L.; Brastianos, Priscilla K.

doi:10.1038/s41588-020-0592-7

Cited by 194 publications

(177 citation statements)

References 41 publications

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“…Each Target Site is expressed from a strong promoter allowing it to be captured by single-cell RNA-sequencing. After amplifying and sequencing the 20 Target Site mRNAs, the reads were analyzed using the Cassiopeia processing pipeline (32). Briefly, this pipeline leverages unique molecular identifier (UMI) information and redundancy in sequencing reads to confidently call intBCs and indel alleles from the lineage data, which inform subsequent phylogenetic reconstruction ( Fig.…”

Section: Tracing Metastasis In a Mouse Xenograft Modelmentioning

confidence: 99%

“…from cells' static intBCs, as described above) but rather in reconstructing subclonal lineage dynamics (i.e. from cells' 20 continuously evolving indel alleles, as in retrospective approaches). As such, we next reconstructed highresolution phylogenetic trees using the Cassiopeia suite of phylogenetic inference algorithms (32) with modified parameters tailored to this dataset's unprecedented complexity and scale (Methods).…”

Section: Reconstructed Cancer Cell Phylogeniesmentioning

confidence: 99%

“…For example, non-metastatic populations result in all clades inhabiting a single tissue ( Fig. 3A-B, left); conversely, highly metastatic populations result in 20 closely related cells residing in different tissues ( Fig. 3A-B, right).…”

Section: Reconstructed Cancer Cell Phylogeniesmentioning

confidence: 99%

“…These "retrospective" tracing approaches are particularly valuable for studying the 5 subclonal dynamics of cancer in patient-derived samples, such as elucidating which mutations contribute to metastasis and when they occur (15)(16)(17)(18). However, these conclusions can be confounded by incomplete or impure bulk tumor sampling (19), sequencing artifacts (20), varying levels of intratumor heterogeneity, and non-neutral mutations (1,5); some of these technical limitations can be mitigated using single-cell resolution measurements or whole-genome sequencing. 10 The recent development of Cas9-enabled lineage tracing techniques with single-cell RNA readouts (21)(22)(23)(24) provides the potential to explore cancer progression at vastly larger scale and finer resolution than was previously possible.…”

mentioning

confidence: 99%

“…Then, as in retrospective tracing approaches, various computational approaches (27)(28)(29)(30)(31)(32) can reconstruct a phylogenetic tree that best models subclonal cellular relationships (e.g., by maximum-parsimony) from the observed alleles. Thus far, 20 Cas9-enabled tracing has been successfully applied to study important aspects of metazoan biology, like the cellular progenitor landscape in early mammalian embryogenesis (22,33) and neural development in zebrafish (21). Additionally, resources now exist for studying other phylogenetic processes in mouse (22,33), and analytical tools are available for computationally reconstructing and benchmarking trees from large lineage tracing datasets (32,34).…”

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confidence: 99%

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Single-cell lineages reveal the rates, routes, and drivers of metastasis in cancer xenografts

Quinn

Jones

Okimoto

et al. 2020

Preprint

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N.Y.).One Sentence Summary: Detailed single-cell phylogenies capture the frequency, tissue routes, and seeding patterns of metastasis in vivo. Abstract:25 2 Consequential events in cancer progression are typically rare and occur in the unobserved past. Detailed cell phylogenies can capture the history and chronology of such transient events -including metastasis. Here, we applied our Cas9-based lineage tracer to study metastatic progression in a lung cancer xenograft mouse model, revealing the underlying rates, routes, and patterns of metastasis. We report deeply resolved phylogenies for tens of thousands of metastatically disseminated cancer cells. We observe surprisingly diverse metastatic phenotypes, 5 ranging from metastasis-incompetent to highly aggressive populations, and these differences are associated with characteristic changes in transcriptional state, including differential expression of metastasis-related genes like IFI27 and ID3. We further show that metastases transit via tissue routes that are diverse, complex, and multidirectional, and identify examples of reseeding, seeding cascades, and parallel seeding topologies. More broadly, we demonstrate the power of next-generation lineage tracers to record cancer evolution at high resolution 10 and vast scale. Main Text:Cancer progression is governed by evolutionary principles (reviewed in (1)), which leave clear phylogenetic signatures upon every step of this process (2, 3), from early acquisition of oncogenic mutations (i.e., the relationships between normal and malignantly transformed cells (4)), to metastatic colonization of distant 15 tissues (i.e., the relationship between the primary tumor and metastases (5)), and finally adaptation to therapeutic challenges (i.e., the relationship between sensitive and resistant clones (6)). Metastasis is a particularly important step in cancer progression to study because it is chiefly responsible for disease relapse and mortality (7). Yet because metastatic events are intrinsically rare, transient, and stochastic (8,9), they are challenging to monitor in real time. Analogous to the cell fate maps that have played an essential role in deepening our understanding of 20 organismal development and cell type differentiation (10, 11), accurately reconstructed phylogenetic trees of tumors and metastases can reveal key features of this process, such as the clonality, timing, frequency, origins, and destinations of metastatic seeding (12).Lineage tracing techniques allow one to map the genealogy of related cells, providing a critical tool for exploring the phylogenetic principles of biological processes like cancer progression and metastasis. Classical

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Section: Tracing Metastasis In a Mouse Xenograft Modelmentioning

confidence: 99%

Section: Reconstructed Cancer Cell Phylogeniesmentioning

confidence: 99%

Section: Reconstructed Cancer Cell Phylogeniesmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Single-cell lineages reveal the rates, routes, and drivers of metastasis in cancer xenografts

Quinn

Jones

Okimoto

et al. 2020

Preprint

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Molecular Features of Resected Melanoma Brain Metastases, Clinical Outcomes, and Responses to Immunotherapy

Vasudevan,

Delley,

Chen

et al. 2023

JAMA Netw Open

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ImportanceCentral nervous system (CNS)–penetrant systemic therapies have significantly advanced care for patients with melanoma brain metastases. However, improved understanding of the molecular landscape and microenvironment of these lesions is needed to both optimize patient selection and advance treatment approaches.ObjectiveTo evaluate how bulk and single-cell genomic features of melanoma brain metastases are associated with clinical outcome and treatment response.Design, Setting, and ParticipantsThis cohort study analyzed bulk DNA sequencing and single nuclear RNA-sequencing data from resected melanoma brain metastases and included 94 consecutive patients with a histopathologically confirmed diagnosis of melanoma brain metastasis who underwent surgical resection at a single National Comprehensive Cancer Network cancer center in San Francisco, California, from January 1, 2009, to December 31, 2022.ExposureA Clinical Laboratory Improvement Amendments–certified targeted sequencing assay was used to analyze tumor resection specimens, with a focus on BRAF V600E alteration. For frozen pathologic specimens from CNS treatment-naive patients undergoing surgical resection, commercial single nuclear RNA sequencing approaches were used.Main Outcomes and MeasuresThe primary outcome was overall survival (OS). Secondary outcomes included CNS progression-free survival (PFS), microenvironmental composition with decreased T-cell and macrophage populations, and responses to immunotherapy.ResultsTo correlate molecular status with clinical outcome, Kaplan-Meier survival analysis of 94 consecutive patients (median age, 64 years [range, 24-82 years]; 70 men [74%]) with targeted BRAF alteration testing showed worse median intracranial PFS (BRAF variant: 3.6 months [IQR, 0.1-30.6 months]; BRAF wildtype: 11.0 months [IQR, 0.8-81.5 months]; P &lt; .001) and OS (BRAF variant: 9.8 months [IQR, 2.5-69.4 months]; BRAF wildtype: 23.2 months [IQR, 1.1-102.5 months]; P = .005; log-rank test) in BRAF V600E variant tumors. Multivariable Cox proportional hazards regression analysis revealed that BRAF V600E status was an independent variable significantly associated with both PFS (hazard ratio [HR], 2.65; 95% CI, 1.54-4.57; P &lt; .001) and OS (HR, 1.96; 95% CI, 1.08-3.55; P = .03). For the 45 patients with resected melanoma brain metastases undergoing targeted DNA sequencing, molecular classification recapitulated The Cancer Genome Atlas groups (NRAS variant, BRAF variant, NF1 variant, and triple wildtype) with no subtype enrichment within the brain metastasis cohort. On a molecular level, BRAF V600E variant lesions were found to have a significantly decreased tumor mutation burden. Moreover, single nuclear RNA sequencing of treatment-naive BRAF V600E variant (n = 3) brain metastases compared with BRAF wildtype (n = 3) brain metastases revealed increased immune cell populations in BRAF wildtype tumors (mean [SD], 11% [4.1%] vs 3% [1.6%] CD45-positive cells; P = .04). Survival analysis of postoperative immunotherapy responses by BRAF status revealed that BRAF wildtype lesions were associated with a response to checkpoint inhibition (median OS: with immunotherapy, undefined; without immunotherapy, 13.0 months [range, 1.1-61.7 months]; P = .001; log-rank test) while BRAF variant lesions (median OS: with immunotherapy, 9.8 months [range, 2.9-39.8 months]; without immunotherapy, 9.5 months [range, 2.5-67.2 months]; P = .81; log-rank test) were not.Conclusions and RelevanceThis molecular analysis of patients with resected melanoma brain metastases found that BRAF V600E alteration is an important translational biomarker associated with worse clinical outcomes, differential microenvironmental composition, and benefit from immunotherapy. Patients with BRAF V600E variant melanoma brain metastases may thus benefit from alternative CNS-penetrant systemic regimens.

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Co‐occurrence of CDKN2A/B and IFN‐I homozygous deletions correlates with an immunosuppressive phenotype and poor prognosis in lung adenocarcinoma

Peng

Chen

Song³

et al. 2022

Molecular Oncology

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Homozygous deletion (HD) of CDKN2A and CDKN2B (CDKN2A/BHD) is the most frequent copy‐number variation (CNV) in lung adenocarcinoma (LUAD). CDKN2A/BHD has been associated with poor outcomes in LUAD; however, the mechanisms of its prognostic effect remain unknown. We analyzed genome, transcriptome, and clinical data from 517 patients with LUAD from the Cancer Genome Atlas (TCGA) and from 788 primary LUAD tumor and matched control samples from the MSK‐IMPACT clinical cohort. CDKN2A/BHD was present in 19.1% of the TCGA‐LUAD cohort and in 5.7% of the MSK‐IMPACT cohort. CDKN2A/BHD patients had shorter disease‐free survival and overall survival compared with CDKN2A/BWT individuals in both cohorts. Differences in clinical features did not influence the outcomes in the CDKN2A/BHD population. Mutation analyses showed that overall tumor mutational burden and mutations in classical drivers such as EGFR and RB1 were not associated with CDKN2A/BHD. In contrast, homozygous deletion of type I interferons (IFN‐IHD) frequently co‐occurred with CDKN2A/BHD. CDKN2A/B and IFN‐I are co‐located in the same p21.3 region of chromosome 9. The co‐occurrence of CDKN2A/BHD and IFN‐IHD was not related to whole‐genome doubling, chromosome instability, or aneuploidy. Patients with co‐occurring CDKN2A/BHD and IFN‐IHD had shorter disease‐free survival and overall survival compared with CDKN2A/BWT patients. CDKN2A/BHDIFN‐IHD had downregulated several key immune response pathways, suggesting that poor prognosis in CDKN2A/BHD LUAD could potentially be attributed to an immunosuppressive tumor microenvironment as a result of IFN‐I depletion.

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Genomic characterization of human brain metastases identifies drivers of metastatic lung adenocarcinoma

Cited by 194 publications

References 41 publications

Single-cell lineages reveal the rates, routes, and drivers of metastasis in cancer xenografts

Single-cell lineages reveal the rates, routes, and drivers of metastasis in cancer xenografts

Molecular Features of Resected Melanoma Brain Metastases, Clinical Outcomes, and Responses to Immunotherapy

Co‐occurrence of CDKN2A/B and IFN‐I homozygous deletions correlates with an immunosuppressive phenotype and poor prognosis in lung adenocarcinoma

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