Your search keyword '"Haley Axelrod"' showing total 5 results

1. A novel Bcr-Abl–mTOR–eIF4A axis regulates IRES-mediated translation of LEF-1

Author

Becky Pinjou Tsai, Judith Jimenez, Sharon Lim, Kerry D. Fitzgerald, Min Zhang, Charles T. H. Chuah, Haley Axelrod, Luke Nelson, S. Tiong Ong, Bert L. Semler, and Marian L. Waterman

Subjects

lef-1, bcr-abl, ires, mtor, eif4a, pp242, Biology (General), QH301-705.5

Abstract

Internal ribosome entry sites (IRESs) in cellular mRNAs direct expression of growth-promoting factors through an alternative translation mechanism that has yet to be fully defined. Lymphoid enhancer factor-1 (LEF-1), a Wnt-mediating transcription factor important for cell survival and metastasis in cancer, is produced via IRES-directed translation, and its mRNA is frequently upregulated in malignancies, including chronic myeloid leukaemia (CML). In this study, we determined that LEF1 expression is regulated by Bcr-Abl, the oncogenic protein that drives haematopoietic cell transformation to CML. We have previously shown that the LEF1 5′ untranslated region recruits a complex of proteins to its IRES, including the translation initiation factor eIF4A. In this report, we use two small molecule inhibitors, PP242 (dual mTOR (mammalian target of rapamycin) kinase inhibitor) and hippuristanol (eIF4A inhibitor), to define IRES regulation via a Bcr-Abl–mTOR–eIF4A axis in CML cell lines and primary patient leukaemias. We found that LEF1 and other IRESs are uniquely sensitive to the activities of Bcr-Abl/mTOR. Most notably, we discovered that eIF4A, an RNA helicase, elicits potent non-canonical effects on the LEF1 IRES. Hippuristanol inhibition of eIF4A stalls translation of IRES mRNA and triggers dissociation from polyribosomes. We propose that a combination drug strategy which targets mTOR and IRES-driven translation disrupts key factors that contribute to growth and proliferation in CML.

Published

2014

2. Abstract 2141: Development of a highly-sensitive targeted cell-free DNA epigenomic assay for early-stage multi-cancer screening

Author

Anton Valouev, Elena Zotenko, Matthew Snyder, Charbel Eid, Ngan Nguyen, Jun Min, Yupeng He, Ariel Jaimovich, Haley Axelrod, Prashanthi Natarajan, Anna Hartwig, Noam Vardi, Tam Banh, Andrew Kennedy, William Greenleaf, Stefanie Mortimer, Sven Duenwald, Darya Chudova, and AmirAli Talasaz

Subjects

Cancer Research, Oncology

Abstract

Background: A blood-based cancer screening test must exhibit performance metrics optimized for the cancer of interest based on associated clinical diagnostic pathways and demonstrate an ability to detect disease at an early stage when intervention has a meaningful impact on individual and net population health outcomes. We evaluated the performance of a blood-based cancer screening assay in select tumor types where we believe cancer screening can save lives. The assay interrogates cell-free DNA (cfDNA) methylation signatures for early-stage cancer (stage I/II) detection and tissue of origin identification. Methods: Whole blood samples from individuals with (N > 1,500) and without (N > 1,800) cancer were obtained from multiple cohorts. Plasma-derived cfDNA was profiled using a custom assay that enriches fragments with dense CpG methylation and further depletes uninformative background molecules. A broad genomic panel (16 Mb) targeting regions with low rates of methylation in healthy individuals was used to capture and sequence tumor-associated molecules while maintaining high sensitivity at low sequencing cost per sample. A cross-validated analysis was used to estimate out of sample performance of the predictive model. Classification thresholds corresponding to 90% and 95% specificities were established using a set of samples from individuals without a cancer diagnosis. Results: To evaluate the performance of this screening assay in cancers with guideline-directed screening protocols, colorectal and lung cancers, detection was assessed at 90% specificity. At this threshold, sensitivity for stage I/II colorectal and lung cancer was 90% and 87%, respectively. For other cancers with no current guideline-directed screening paradigms, pancreatic and bladder cancers, a specificity threshold of 95% was applied. Sensitivity was 73% and 52% for stage I/II pancreatic and bladder cancer, respectively. Tissue of origin prediction evaluated at 98% specificity had accurate identification in 99% of colorectal, 94% of lung, 88% of bladder, and 86% of pancreatic cancers. Conclusions: This multi-cancer targeted screening assay provides robust and sensitive detection of early-stage cancer at thresholds optimized for current screening paradigms with accurate tissue of origin identification. The assay is undergoing further expansion of its detection capabilities to include additional cancer types where screening can save lives. Clinical evaluation in registrational screening trials is ongoing (NCT05117840). Citation Format: Anton Valouev, Elena Zotenko, Matthew Snyder, Charbel Eid, Ngan Nguyen, Jun Min, Yupeng He, Ariel Jaimovich, Haley Axelrod, Prashanthi Natarajan, Anna Hartwig, Noam Vardi, Tam Banh, Andrew Kennedy, William Greenleaf, Stefanie Mortimer, Sven Duenwald, Darya Chudova, AmirAli Talasaz. Development of a highly-sensitive targeted cell-free DNA epigenomic assay for early-stage multi-cancer screening [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 2141.

Published

2022

3. Development of a highly sensitive multicancer, targeted, cell-free DNA epigenomic assay for integrated screening of lung and colorectal cancer

Author

Anton Valouev, Elena Zotenko, Matthew Snyder, Charbel Eid, Ngan Nguyen, Jun Min, Yupeng He, Ariel Jaimovich, Haley Axelrod, Prashanthi Natarajan, Kathryn Pendleton, Anna Hartwig, Noam Vardi, Tam Banh, Drew Kennedy, William Greenleaf, Stefanie Mortimer, Sven Duenwald, Darya Chudova, and AmirAli Talasaz

Subjects

Cancer Research, Oncology

Abstract

3542 Background: Cancer screening in asymptomatic individuals who meet guideline criteria has yielded reductions in cancer death rates. However, adherence to screening guidelines remains below targets set forth by leading health-care organizations. A blood-based multi-cancer screening assay with clinically meaningful sensitivity and specificity, in cancer types where early detection and intervention can save lives, that is integrated with existing clinical pathways may increase access to and adherence with guideline recommendations, ensuring more individuals benefit from these proven interventions. We evaluated the performance of a blood-based multi-cancer screening assay that interrogates cell-free DNA (cfDNA) methylation signatures for cancer detection and tissue of origin prediction in a set of tumor types where cancer screening can save lives. Methods: Whole blood from 1,607 individuals with and 3,298 individuals without cancer was obtained from multiple unique cohorts. Plasma-derived cfDNA was profiled using a custom assay that enriches fragments with dense CpG methylation and further depletes uninformative background molecules containing unmethylated CpGs. We utilized a broad genomic panel (16 Mb) targeting regions with low rates of methylation in individuals without cancer. The panel captures tumor-associated molecules and allows for high sensitivity of detection at low sequencing costs. A cross-validated analysis was used to estimate the performance of the predictive model upon the sample set. Classification thresholds corresponding to 90%, 95%, and 98% specificities were established using samples from individuals without a cancer diagnosis. Results: At 90% specificity, overall sensitivity for lung cancer detection was 92.1% (95% CI: 80-100%; 90.2% in Stage I/II disease (N = 82) and 93.1% in Stage III/IV disease (N = 159)) and 93.1% (CI: 88-98%) for CRC detection (92% in Stage I/II disease (N = 743) and 94.5% in Stage III/IV disease (N = 623)). Tissue of origin prediction evaluated at 98% specificity yielded accurate identification in 99% of CRC and 98% of lung cancers. Lung cancer histology was known for approximately 74% of the cohort. Across Stage I – IV cancers, at 90% specificity, sensitivity was 97.3% in lung squamous cancer (N = 73) and 86.8% in lung adenocarcinoma (N = 106). At 95% and 98% specificity thresholds, overall sensitivity was 86.3% (CI: 75-98%) and 66.4% (CI: 56-77%) for lung cancer and 85.7% (CI:81-91%) and 71.6% (CI: 67-76%) for CRC, respectively. Conclusions: This blood-based multi-cancer screening assay yields clinically meaningful sensitivity and specificity for early-stage cancers. This assay is undergoing further development to expand detection capabilities to additional cancer types where screening can save lives. Clinical evaluation in registrational screening trials is ongoing (SHIELD; NCT05117840).

Published

2022

4. Validation of a multi-modal blood-based test for the detection of colorectal cancer with sub single molecule sensitivity

Author

Kevin D'Auria, Yunpei Chang, Michael Multhaup, Haley Axelrod, Lu Zheng, Jordan Burke, William Young Greenwald, Yupeng He, Kathryn Pendleton, Nathan McDonald, Victoria M. Raymond, Anna Hartwig, Sven Duenwald, Darya Chudova, and AmirAli Talasaz

Subjects

Cancer Research, Oncology

Abstract

3627 Background: Blood-based colorectal cancer (CRC) screening tests can improve adherence to screening guidelines. Yet, current commercially available options have poor sensitivity and specificity inhibiting incorporation into routine clinical care. Here we report the validation of a blood-based test for the detection of colorectal cancer and advanced neoplasia. Methods: This blood-based test aims to detect colorectal neoplasia by identifying tumor-associated biomarkers including genomic or epigenomic (methylation and fragmentomics) signatures in cell-free DNA (cfDNA). cfDNA is partitioned based on methylation level, enriched for informative genomic regions, and sequenced. This novel workflow enables high-fidelity analysis of multi-modal information in majority of extracted cfDNA molecules. Results are integrated into a binary “detected” versus “not-detected” result using a proprietary bioinformatic pipeline (Guardant Health, USA). The assay was trained on samples obtained from >6,000 unique individuals (2,685 cancer-free and 1,698 with advanced colorectal neoplasia (ACN) for training, 1,072 cancer-free and 551 with ACN for threshold setting). The thresholds were frozen prior to validation targeting a specificity of > 91.5%. Each aspect of the validation study followed Nex-StoCT CLIA working group and CLSI guidelines. Results: Limit of detection (LoD) was established across six dilutions. Even for low cfDNA mass inputs of less than 4ng, the 95% LoD was determined to be less than 1 tumor-derived genomic equivalent (0.5), indicating over at least 10-fold increase in assay sensitivity compared to best-in-class assays for somatic mutation detection. Precision studies in 60 positive and negative replicates from clinical samples yielded >90% average positive and negative percent agreement both within and between batches. Endogenous interference studies yielded > 90% positive and negative percent agreement between reference control and common endogenous substances, including albumin, bilirubin, hemoglobin, triglycerides, and genomic DNA, in clinical positive and negative samples and minimally manipulated samples. The clinical validation of the test was conducted in > 300 cases (biobanked pre-operative cohort for CRC cases and screening cohort for advanced adenoma and negative cases). Conclusions: Here we present the validation of a multi-modal blood-based test for the detection of colorectal cancer. This test is currently being evaluated in a registrational study (ECLIPSE: NCT04136002).

Published

2022

5. Analytical validation of a tissue agnostic ctDNA MRD assay using tumor specific methylation and somatic variant profiles in early-stage CRC

Author

Farsheed Ghadiri, Anna Hartwig, Dustin Hite, Marisa Juntilla, Mahmoud Dahdouli, Jordan E. Burke, Tracy Nance, Sweta Sharma, Darya Chudova, AmirAli Talasaz, Jessica Kurata, Carlo Artieri, Saiyou Ohshima, Yupeng He, Oscar Westesson, Ariel Jaimovich, Haley Axelrod, Arthur Baca, and Yu Kong

Subjects

Cancer Research, business.industry, Colorectal cancer, Somatic cell, Tumor specific, Methylation, medicine.disease, Minimal residual disease, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Oncology, chemistry, 030220 oncology & carcinogenesis, Cancer research, Medicine, Liquid biopsy, Stage (cooking), business, DNA, 030215 immunology

Abstract

e15549 Background: Liquid biopsy is a candidate for detection of minimal residual disease (MRD) in early colorectal cancer. Detection of circulating tumor (ct)DNA in early stage cancer is challenging given the low abundance of ctDNA molecules. We developed a tissue agnostic MRD Test to optimize sensitivity and specificity of ctDNA detection by integrating tumor-specific genomic mutation and DNA methylation signatures coupled to noise-reduction of non-tumor background cfDNA signals. Methods: This MRD Test was developed following CLIA, Nex-StoCT Working Group, and AMP/CAP guidance and validation principles. Using a single input plasma sample, data from somatic and epigenomic targeted capture panels are integrated to generate a final test result: ctDNA detected or ctDNA not detected. ctDNA detected is defined by the presence of mutation or epigenomic classifier inputs exceeding a defined threshold. Quality control (QC) measures were implemented in both process and final sequencing results. Analytical specificity, sensitivity, and accuracy were determined using 130 samples. Results: The MRD Test specificity was 95% (70/74) using colonoscopy screened negative samples.A retrospective review of the clinical histories of these false positive samples showed high risk clinical features such as smoking, family history of CRC, and sub-optimal bowel prep prior to the colonoscopy. Analytical sensitivity (LoD) was established by diluting late stage CRC samples at two clinically relevant cfDNA inputs at three dilutions (30ng or 10ng, ranging 0.1% to 0.75% tumor fraction). The 95% LoD was determined to be 0.3% for 10ng and < 0.1% for 30ng, the lowest level tested for each input. Accuracy was determined by diluting advanced CRC samples to 0.5-0.75% MAF tested at 30ng or 10ng cfDNA with a detection result of 100% (38/38). Conclusions: We present a CLIA validated assay with performance characteristics sufficient to detect residual disease in Stage II/III CRC post-curative intent therapy. This assay is currently being used in multiple interventional clinical trials.

Published

2020