Your search keyword '"Rachel A. Schlaak"' showing total 14 results

1. Differences in radiation-induced heart dysfunction in male versus female rats

Author

Neal Andruska, Rachel A. Schlaak, Anne Frei, Aronne M. Schottstaedt, Chieh-Yu Lin, Brian L. Fish, Tracy Gasperetti, Cedric Mpoy, Jamie L. Pipke, Lauren N. Pedersen, Michael J. Flister, Ali Javaheri, and Carmen Bergom

Subjects

Radiological and Ultrasound Technology, Radiology, Nuclear Medicine and imaging

Published

2023

2. Optimized cardiac functional MRI of small-animal models of cancer radiation therapy

Author

Elizabeth Gore, Carmen Bergom, Anne Frei, Rachel A. Schlaak, Jason Rubenstein, Matthew D. Budde, El-Sayed H. Ibrahim, and Dhiraj Baruah

Subjects

Cardiac function curve, Cancer radiation therapy, medicine.medical_treatment, Biomedical Engineering, Biophysics, Article, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Ventricular hypertrophy, Neoplasms, Small animal, Animals, Medicine, Radiology, Nuclear Medicine and imaging, Adult female, business.industry, Cancer, Heart, medicine.disease, Magnetic Resonance Imaging, Rats, Functional imaging, Radiation therapy, Disease Models, Animal, Female, business, Nuclear medicine, 030217 neurology & neurosurgery, Radiotherapy, Image-Guided

Abstract

Cardiac MRI of small animal models of cancer radiation therapy (RT) is a valuable tool for studying the effect of RT on the heart. However, standard cardiac MRI exams require long scanning times, which is challenging for sick animals that may not survive extended periods of imaging under anesthesia. The purpose of this study is to develop an optimized, fast MRI exam for comprehensive cardiac functional imaging of small-animal models of cancer RT. Ten adult female rats (2 non-irradiated and 8 irradiated) were scanned using the developed exam. Optimal imaging parameters were determined, which minimized scanning time while ensuring measurement accuracy and avoiding imaging artifacts. This optimized, fast MRI exam lasted for 30 min, which was tolerated by all animals. EF was normal in all imaged rats, although it was significantly increased in the irradiated rats, which also showed ventricular hypertrophy. However, myocardial strain was significantly reduced in the irradiated rats. In conclusion, a fast MRI exam has been developed for comprehensive cardiac functional imaging of rats in 30 min, with optimized imaging parameters to ensure accurate measurements and tolerance by irradiated rats. The generated strain measurements provide an early marker of regional cardiac dysfunction before global function is affected.

Published

2020

3. Cardiac Magnetic Resonance for Early Detection of Radiation Therapy-Induced Cardiotoxicity in a Small Animal Model

Author

Michael Brehler, Elizabeth Gore, Jadranka Stojanovska, Amanda Klaas, Jason Rubenstein, Michael J. Flister, Chieh Yu Lin, Carmen Bergom, Rachel A. Schlaak, Peter S. LaViolette, El-Sayed H. Ibrahim, Dhiraj Baruah, Angela Lemke, Jamie L. Pipke, Pierre Croisille, Zhiqiang Xu, and Anne Frei

Subjects

Cardiotoxicity, medicine.medical_specialty, Ejection fraction, business.industry, medicine.medical_treatment, cardiotoxicity, food and beverages, Early detection, Cancer, medicine.disease, left ventricular strain, radiation therapy, Radiation therapy, Radiation exposure, Oncology, inflammation, Internal medicine, Small animal, medicine, Cardiology, Cardiology and Cardiovascular Medicine, business, Cardiac magnetic resonance, Editorial Comment, Original Research

Abstract

Over half of all cancer patients receive radiation therapy (RT). However, radiation exposure to the heart can cause cardiotoxicity. Nevertheless, there is a paucity of data on RT-induced cardiac damage, with limited understanding of safe regional RT doses, early detection, prevention and management. A common initial feature of cardiotoxicity is asymptomatic dysfunction, which if left untreated may progress to heart failure. The current paradigm for cardiotoxicity detection and management relies primarily upon assessment of ejection fraction (EF). However, cardiac injury can occur without a clear change in EF.To identify magnetic resonance imaging (MRI) markers of early RT-induced cardiac dysfunction.We investigated the effect of RT on global and regional cardiac function and myocardial T1/T2 values at two timepoints post-RT using cardiac MRI in a rat model of localized cardiac RT. Rats who received image-guided whole-heart radiation of 24Gy were compared to sham-treated rats.The rats maintained normal global cardiac function post-RT. However, a deterioration in strain was particularly notable at 10-weeks post RT, and changes in circumferential strain were larger than changes in radial or longitudinal strain. Compared to sham, circumferential strain changes occurred at the basal, mid-ventricular and apical levels (p0.05 for all at both 8-weeks and 10-weeks post-RT), most of the radial strain changes occurred at the mid-ventricular (p=0.044 at 8-weeks post-RT) and basal (p=0.018 at 10-weeks post-RT) levels, and most of the longitudinal strain changes occurred at the apical (p=0.002 at 8-weeks post-RT) and basal (p=0.035 at 10-weeks post-RT) levels. Regionally, lateral myocardial segments showed the greatest worsening in strain measurements, and histologic changes supported these findings. Despite worsened myocardial strain post-RT, myocardial tissue displacement measures were maintained, or even increased. T1/T2 measurements showed small non-significant changes post-RT compared to values in non-irradiated rats.Our findings suggest MRI regional myocardial strain is a sensitive imaging biomarker for detecting RT-induced subclinical cardiac dysfunction prior to compromise of global cardiac function.

Published

2021

4. The Role of Mitochondrial Dysfunction in Radiation-Induced Heart Disease: From Bench to Bedside

Author

Katie Livingston, Rachel A. Schlaak, Lindsay L. Puckett, and Carmen Bergom

Subjects

0301 basic medicine, Cardiac function curve, lcsh:Diseases of the circulatory (Cardiovascular) system, Mitochondrial DNA, Heart disease, Mini Review, radiation-induced cardiovascular toxicity, cardiomyocyte, Disease, Cardiovascular Medicine, 030204 cardiovascular system & hematology, Mitochondrion, medicine.disease_cause, Bioinformatics, radiation-adverse effects, Coronary artery disease, 03 medical and health sciences, Pericarditis, 0302 clinical medicine, medicine, oxidative stress, business.industry, apoptosis, medicine.disease, mitochondria, radiation, 030104 developmental biology, lcsh:RC666-701, endothelial cell, Cardiology and Cardiovascular Medicine, business, Oxidative stress

Abstract

Radiation is a key modality in the treatment of many cancers; however, it can also affect normal tissues adjacent to the tumor, leading to toxic effects. Radiation to the thoracic region, such as that received as part of treatment for breast and lung cancer, can result in incidental dose to the heart, leading to cardiac dysfunction, such as pericarditis, coronary artery disease, ischemic heart disease, conduction defects, and valvular dysfunction. The underlying mechanisms for these morbidities are currently being studied but are not entirely understood. There has been increasing focus on the role of radiation-induced mitochondrial dysfunction and the ensuing impact on various cardiac functions in both preclinical models and in humans. Cardiomyocyte mitochondria are critical to cardiac function, and mitochondria make up a substantial part of a cardiomyocyte's volume. Mitochondrial dysfunction can also alter other cell types in the heart. This review summarizes several factors related to radiation-induced mitochondrial dysfunction in cardiomyocytes and endothelial cells. These factors include mitochondrial DNA mutations, oxidative stress, alterations in various mitochondrial function-related transcription factors, and apoptosis. Through improved understanding of mitochondria-dependent mechanisms of radiation-induced heart dysfunction, potential therapeutic targets can be developed to assist in prevention and treatment of radiation-induced heart damage.

Published

2020

5. Abstract P2-11-18: The use of consomic animal models to identify genetic factors that modulate radiation-induced cardiac toxicity

Author

A.M. Schottstaedt, Carmen Bergom, Meetha Medhora, Jennifer L. Strande, Michael J. Flister, Brian L. Fish, Anne Frei, Rachel A. Schlaak, Tracy Gasperetti, and Leanne Harmann

Subjects

Oncology, Cancer Research, medicine.medical_specialty, business.industry, medicine.medical_treatment, Cancer, medicine.disease, Radiation therapy, Radiation sensitivity, Therapeutic index, Breast cancer, Gene mapping, Internal medicine, Toxicity, medicine, Radiosensitivity, business

Abstract

Purpose/Objectives: Radiation therapy is used by more than 50% of breast cancer patients, but radiation doses can be limited by normal tissue side effects. For example, breast cancer radiation therapy can improve breast cancer-specific survival, but increase cardiac deaths in those with left-sided cancers. Identifying genetic factors that can enhance tumor radiation sensitivity while decreasing normal tissue toxicities has the potential to improve the therapeutic ratio of radiation therapy – leading to more cures and less long-term toxicities. The use of animal models with differing genetic backgrounds to assess radiation toxicity, followed by genetic mapping of radiosensitivity phenotypes, has the potential to identify new targets that can predict cardiac toxicity from radiation therapy. This project examines how genetic host factors alter normal tissue toxicity risks from breast cancer radiation. Materials/Methods: Inbred female SS rats and SS.BN3 consomic rats, that are genetically identical to SS rats except that chromosome 3 is inherited from the BN strain, have previously been shown to exhibit different vascular dynamics and breast tumor growth. For this study, adult female SS and SS.BN3 rats received image-guided whole heart radiation to a dose of 21 Gy (3 fields, AP and 2 laterals). Cardiac troponin was serially measured at 2, 6, and 12 weeks, and echocardiograms with strain analysis were performed at baseline and 3 months. The Student's t-test was used to compare values. Results: The SS female rats exhibited enhanced cardiac toxicity compared to SS.BN3 rats, with cardiac troponin levels elevated at 12 weeks (0.32 ng/ml vs.0.08 ng/ml for SS vs. SS.BN3, p=0.01), and moderate to severe pericardial effusions seen in 6 of 9 SS rats vs. 2 of 7 SS.BN3 rats. At 3 months post-radiation, echocardiograms revealed increased left ventricular posterior wall thickness at end diastole (LVPWd) in SS vs. SS.BN3 rats (0.25 vs. 0.20 cm, p=0.002) and increased left ventricular mass (LVM) in SS vs. SS.BN3 rats (1.54 vs. 1.28 g, p Conclusions: These results demonstrate that genetic variant on rat chromosome 3 alter the radiosensitivity to single fraction cardiac radiation therapy. Gene expression analysis and genetic mapping will be performed to identify the causative target(s). These models will also be expanded to test whether similar results are seen with fractionated cardiac radiation therapy. This project has the potential to enhance the effectiveness and toxicity profile of radiation therapy in breast cancer. Citation Format: Bergom C, Schlaak R, Frei A, Fish BL, Harmann L, Gasperetti T, Schottstaedt AM, Flister MJ, Medhora M, Strande JL. The use of consomic animal models to identify genetic factors that modulate radiation-induced cardiac toxicity [abstract]. In: Proceedings of the 2017 San Antonio Breast Cancer Symposium; 2017 Dec 5-9; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2018;78(4 Suppl):Abstract nr P2-11-18.

Published

2018

6. Differences in Radiation-Induced Cardiotoxicity Between Age-Matched Male and Female Rats Largely Due to Differences in Lung Doses

Author

Meetha Medhora, Leanne Harmann, Carmen Bergom, Rachel A. Schlaak, Anne Frei, A.M. Schottstaedt, T. Gasparetti, and Brian L. Fish

Subjects

Cancer Research, Cardiotoxicity, Radiation, Lung, medicine.anatomical_structure, Oncology, business.industry, Medicine, Physiology, Radiology, Nuclear Medicine and imaging, Radiation induced, business

Published

2020

7. Abstract IA004: Genetic variants in the tumor microenvironment alter radiation responses in breast cancer

Author

Carmen Bergom, M.W. Straza, Rachel A. Schlaak, Angela Lemke, Amy Rymaszewski, Shirng-Wern Tsaih, Michael J. Flister, and Anne Frei

Subjects

Cancer Research, Tumor microenvironment, Breast cancer, Oncology, medicine, Genetic variants, Cancer research, Biology, medicine.disease

Abstract

Objectives: The tumor microenvironment (TME) can impact breast cancer tumor growth, progression, and treatment responses. Data suggests that genetic variants in not only breast cancer cells, but also in the TME, can also alter these processes. We have utilized a Consomic Xenograft Model (CXM), which maps germline variants that impact only the TME, as well as a species-specific RNA-seq (SSRS) protocol which allows detection of expression changes in the malignant and nonmalignant cellular compartments of tumor xenografts, in parallel to identify genetic variants in the TME that affect radiation sensitivity. Materials/Methods: Human triple negative breast cancer MDA-MD-231 cells were implanted into immunodeficient (IL2RG KO) consomic rat strains that are genetically identical except for chromosome 3 is inherited from a separate strain (SS and SS.BN3 strains). On day 10, tumors were treated with 3 daily ionizing radiation (IR) treatments of 4 Gy or sham, and tumor growth was monitored. Tumors were also harvested for hypoxia staining using pimonidazole or for RNA-seq. RNA-Seq was performed and a custom SSRS protocol was used to align both rat and human transcripts. This yielded transcript and gene level estimated fold-change and adjusted p-values for human- and rat-derived transcripts separately. E077 mammary tumor cells were implanted into adult female immune competent C57/Bl6 mice. On day 5, tumors were treated with 5 daily IR treatments of 5 Gy or sham. Either vehicle or a mAb to the Notch ligand Dll4 (Genentech) was given twice weekly. Chi-square, Fisher’s exact, and Kolmogorov-Smirnov tests and empirical cumulative distribution plots for differential expression significance values were performed. Results: Using CXM, we discovered that BN strain-derived genetic variant(s) on rat chromosome 3 are important for tumor IR sensitivity, as human breast cancer xenografts in the consomic strain (SS.BN3) were significantly more IR sensitive than SS rat strain tumors (supra-additive). Vascular gene pathways were differentially expressed, and tumor vascular phenotypes were distinct, with SS.BN3 tumors with increased but poorly functioning blood vessels. Hypoxia was similar at baseline, but increased in SS.BN3 tumors following IR. These results were consistent with less Dll4 expression in the SS.BN3 TME. The use of a Dll4-targeted mAb in mice demonstrated that targeting Dll4 enhanced mammary tumor IR responses. Conclusion: CXM demonstrated TME genetic variants can affect IR sensitivity of genetically identical tumor cells. Using SSRS, we identified candidate genes on rat chromosome 3 that may potentially influence IR sensitivity, and our studies ultimately led to identification of the Notch ligand Dll4 as a target to enhance breast cancer IR responses. Future studies will investigate the possibility of the Dll4 pathway as a therapeutic target, as well as interrogate other pathways responsible for changes in IR sensitivity seen in the CXM model. Determining TME factors that affect the IR sensitivity will allow more tailored and effective treatments. Citation Format: Carmen Bergom, Michael W. Straza, Amy Rymaszewski, Anne Frei, Angela Lemke, Rachel A. Schlaak, Shirng-Wern Tsaih, Michael J. Flister. Genetic variants in the tumor microenvironment alter radiation responses in breast cancer [abstract]. In: Proceedings of the AACR Virtual Special Conference on the Evolving Tumor Microenvironment in Cancer Progression: Mechanisms and Emerging Therapeutic Opportunities; in association with the Tumor Microenvironment (TME) Working Group; 2021 Jan 11-12. Philadelphia (PA): AACR; Cancer Res 2021;81(5 Suppl):Abstract nr IA004.

Published

2021

8. Assessment of Functional Enrichment of Genes Associated with Radiation Cardiosensitivity in Rat Pre-Clinical Models in Human Genome-wide Association Study (GWAS) of Heart Failure

Author

Rachel A. Schlaak, S.L. Kerns, Carmen Bergom, O. El Charif, Anne Frei, and Shirng-Wern Tsaih

Subjects

Cancer Research, Radiation, business.industry, Association (object-oriented programming), Genome-wide association study, Computational biology, medicine.disease, Oncology, Heart failure, medicine, Radiology, Nuclear Medicine and imaging, Human genome, business, Gene

Published

2020

9. Acquired Immunity Is Not Essential for Radiation-Induced Heart Dysfunction but Exerts a Complex Impact on Injury

Author

Brian L. Fish, Benjamin N. Gantner, Rachel A. Schlaak, Carmen Bergom, Hallgeir Rui, Leanne Harmann, Yunguang Sun, Tracy Gasperetti, Michael J. Flister, Anne Frei, and Jamie L. Pipke

Subjects

lymphocytes, 0301 basic medicine, Cancer Research, radiation-induced heart disease, medicine.medical_treatment, cardiotoxicity, T cells, Pharmacology, lcsh:RC254-282, Article, 03 medical and health sciences, 0302 clinical medicine, Immune system, Immunity, Genetic model, medicine, Receptor, immuno-oncology, Cardiotoxicity, Ejection fraction, business.industry, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Acquired immune system, cardiac radiation, IL-2 receptor gamma knockout, radiation, Radiation therapy, 030104 developmental biology, Oncology, 030220 oncology & carcinogenesis, immune-compromised, business

Abstract

While radiation therapy (RT) can improve cancer outcomes, it can lead to radiation-induced heart dysfunction (RIHD) in patients with thoracic tumors. This study examines the role of adaptive immune cells in RIHD. In Salt-Sensitive (SS) rats, image-guided whole-heart RT increased cardiac T-cell infiltration. We analyzed the functional requirement for these cells in RIHD using a genetic model of T- and B-cell deficiency (interleukin-2 receptor gamma chain knockout (IL2RG&minus, /&minus, )) and observed a complex role for these cells. Surprisingly, while IL2RG deficiency conferred protection from cardiac hypertrophy, it worsened heart function via echocardiogram three months after a large single RT dose, including increased end-systolic volume (ESV) and reduced ejection fraction (EF) and fractional shortening (FS) (p &lt, 0.05). Fractionated RT, however, did not yield similarly increased injury. Our results indicate that T cells are not uniformly required for RIHD in this model, nor do they account for our previously reported differences in cardiac RT sensitivity between SS and SS.BN3 rats. The increasing use of immunotherapies in conjunction with traditional cancer treatments demands better models to study the interactions between immunity and RT for effective therapy. We present a model that reveals complex roles for adaptive immune cells in cardiac injury that vary depending on clinically relevant factors, including RT dose/fractionation, sex, and genetic background.

Published

2020

10. Consomic Rat Models Identify Genetic Factors that Modulate Radiation-Induced Cardiac Toxicity and Inflammation

Author

A.M. Schottstaedt, C.A. Mascari, Michael J. Flister, Meetha Medhora, Tracy Gasperetti, Carmen Bergom, Jennifer L. Strande, Rachel A. Schlaak, Anne Frei, Leanne Harmann, and Brian L. Fish

Subjects

Cancer Research, Radiation, Oncology, business.industry, Cardiac toxicity, Rat model, Medicine, Radiology, Nuclear Medicine and imaging, Inflammation, Radiation induced, medicine.symptom, Pharmacology, business

Published

2018

11. Identification of Pathways and Genetic Variants Important for Radiation-Induced Cardiotoxicity Using Genetic Mapping

Author

Q. Liu, Leanne Harmann, Meetha Medhora, Michael J. Flister, Brian L. Fish, A.M. Schottstaedt, Rachel A. Schlaak, Yunguang Sun, Carmen Bergom, Anne Frei, Hallgeir Rui, T. Gasparetti, and Jennifer L. Strande

Subjects

Cancer Research, Cardiotoxicity, Radiation, Oncology, Gene mapping, business.industry, Genetic variants, Medicine, Radiology, Nuclear Medicine and imaging, Identification (biology), Radiation induced, Computational biology, business

Published

2019

12. Abstract 4165: Novel genetic rat models to identify factors that modulate cardiac and tumor radiation sensitivity

Author

Brian L. Fish, A.M. Schottstaedt, Tracy Gasperetti, Meetha Medhora, Rachel A. Schlaak, Carmen Bergom, Anne Frei, Jennifer L. Strande, Michael J. Flister, and Leanne Harmann

Subjects

Cancer Research, Radiation sensitivity, Oncology, Rat model, Cancer research, Biology

Abstract

Purpose/Objectives: Over 50% of breast cancer patients receive radiation therapy, but radiation doses can be limited by normal tissue toxicity. Radiation therapy can improve breast cancer-specific survival, but cardiac morbidity can be increased in patients with left-sided tumors. We used rat genetic models to identify targets to improve the therapeutic ratio of radiation. We assessed the radiation responsiveness of mammary tumors and the heart in genetically similar consomic rats conducive to genetic mapping. Materials/Methods: Female SS rats and SS.BN3 consomic rats, which are genetically identical to SS rats except that chromosome 3 is inherited from the BN strain, have previously been shown to exhibit different vascular dynamics and breast tumor growth. Human MDA-MD-231 cells or syngeneic mammary tumor cells developed from DMBA-induced mammary tumors were implanted orthotopically into immunodeficient or immunocompetent SS and SS.BN3 rats, respectively, and tumors were treated locally with mock or 5x4 Gy. To examine cardiac toxicity, adult female SS and SS.BN3 rats received image-guided localized whole-heart radiation to a dose of 24 Gy or 9 Gy x 5 (AP and 2 lateral fields, weighted 1:1:1). Echocardiograms with strain analysis were performed at baseline, 3 months and 5 months. The Student's t-test was used to compare values. Results: The BN strain-derived genetic variant(s) on rat chromosome 3 is important for tumor radiation sensitivity. Tumors in SS.BN3 rats were significantly more radiosensitive than tumors in the parental SS strain. A supra-additive effect was seen with both tumor cell lines, with recurrence-free survival of 30% vs. 67% at 137 days in SS vs SS.BN3 rats (p=0.02) in xenografts, and recurrence-free survival of 9% vs. 100% at 141 days in SS vs. SS.BN3 rats (p Conclusions: These results demonstrate that genetic variants on rat chromosome 3 alter the sensitivity to radiation therapy, enhancing tumor responses to radiation and protecting the heart, thus improving the therapeutic ratio. Gene expression analysis and genetic mapping will be performed to identify the causative target(s). This project has the potential to enhance the effectiveness and toxicity profile of radiation therapy in breast cancer. Citation Format: Rachel A. Schlaak, Anne Frei, Aronne M. Schottstaedt, Brian L. Fish, Leanne Harmann, Tracy Gasperetti, Michael J. Flister, Meetha Medhora, Jennifer L. Strande, Carmen R. Bergom. Novel genetic rat models to identify factors that modulate cardiac and tumor radiation sensitivity [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 4165.

Published

2018

13. (P06) Identifying Genetic Factors Influencing Radiation-Induced Cardiac Toxicity Using Novel Genetic Rat Models

Author

Brian L. Fish, Meetha Medhora, Rachel A. Schlaak, Leanne Harmann, A.M. Schottstaedt, Carmen Bergom, Anne Frei, Michael J. Flister, Jennifer L. Strande, and Tracy Gasperetti

Subjects

Cancer Research, Radiation, Oncology, business.industry, Cardiac toxicity, Rat model, Medicine, Radiology, Nuclear Medicine and imaging, Radiation induced, Pharmacology, business

Published

2018

14. Abstract 5898: The consomic xenograft model identifies genetic changes in the tumor microenvironment that alter the growth and metastasis of head and neck cancers

Author

Rachel A. Schlaak, Amy Rymaszewski, Carmen Bergom, Kwangok P. Nickel, R.J. Kimple, Anirban Chatterjee, Amit Joshi, Anne Frei, M.W. Straza, and Michael J. Flister

Subjects

Oncology, Cancer Research, medicine.medical_specialty, Tumor microenvironment, business.industry, Internal medicine, medicine, Head and neck, medicine.disease, business, Metastasis

Abstract

Background: The tumor microenvironment (TME) is known to impact tumor growth, metastatic potential, and treatment response. Nearly all studies of head and neck cancer (HNC) have focused on somatic mutations in the malignant cells. We hypothesized that genetic determinants limited to the microenvironment would influence HNC growth and metastatic potential. Approach: To demonstrate the impact of genetic differences in the TME on HNC cell line in vivo growth we utilized a novel tool, the consomic xenograft model (CXM). A consomic rat has an entire chromosome substituted into the isogenic background of another inbred strain by selective breeding. Use of immunodeficient (IL2Rγ-/-) consomic rats allows one to study the influence of stromal genetics on tumor biology without the confounding effect of differences in the immune system through the orthotopic implantation of cancer cells into different consomic rat strains. In this system, any differences in tumor growth or metastases are due to differences in the TME rather than cancer cells or immune response. We utilized SS and SS.BN3 consomic rat strains, previously shown to affect the growth of breast tumors, to study the effects of the TME on HNC tumor growth using two well-characterized HPV negative HNC cell lines, SCC-6 (base of tongue derived) and SCC-22b (derived from a hypopharyngeal cancer that had metastasized to lymph nodes). Both cell lines were modified to stably express luciferase. HNC cells were inoculated into the tongue of SS and SS.BN3 animals and tumor growth was monitored by biophotonic imaging after luciferin injection. Results: A significant difference in the tumor growth was seen between rat strains for both cell lines, with the SS.BN3 rats exhibiting less tumor growth and metastasis. Median luciferase activity from baseline increased by 4.1-fold vs. 1.1 fold in SCC-6 tumors in SS vs SS.BN3 rats, respectively (p Conclusions: The use of the CXM model demonstrates an important role for the TME in the growth and metastatic spread of HNC cell lines. This model allows for future congenic mapping to identify the causative genetic variants in the TME mediating the HNC changes in tumor growth and metastasis. Citation Format: Michael W. Straza, Amy Rymaszewski, Kwangok P. Nickel, Anne Frei, Anirban Chatterjee, Rachel Schlaak, Amit Joshi, Michael Flister, Randy J. Kimple, Carmen Bergom. The consomic xenograft model identifies genetic changes in the tumor microenvironment that alter the growth and metastasis of head and neck cancers [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 5898. doi:10.1158/1538-7445.AM2017-5898

Published

2017