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Molecular Imaging and Biology
Published in: Molecular Imaging and Biology 1/2022

01-02-2022 | Metastasis | Research Article

Molecular Imaging Reveals a High Degree of Cross-Seeding of Spontaneous Metastases in a Novel Mouse Model of Synchronous Bilateral Breast Cancer

Authors: Shirley Liu, Nivin N Nyström, John J Kelly, Amanda M Hamilton, Yanghao Fu, John A Ronald

Published in: Molecular Imaging and Biology | Issue 1/2022

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Abstract

Purpose

Synchronous bilateral breast cancer (SBBC) patients present with cancer in both breasts at the time of diagnosis or within a short time interval. They show higher rates of metastasis and lower overall survival compared to women with unilateral breast cancer. Here we established the first preclinical SBBC model and used molecular imaging to visualize the patterns of metastasis from each primary tumor.

Procedures

We engineered human breast cancer cells to express either Akaluc or Antares2 for bioluminescence imaging (BLI) and tdTomato or zsGreen for ex vivo fluorescence microscopy. Both cell populations were implanted into contralateral mammary fat pads of mice (n=10), and dual-BLI was performed weekly for up to day 29 (n=3), 38 (n=4), or 42 (n=3). Primary tumors and lungs were fixed, and ex vivo fluorescence microscopy was used to analyze the cellular makeup of micrometastases.

Results

Signal from both Antares2 and Akaluc was first detected in the lungs on day 28 and was present in 9 of 10 mice at endpoint. Ex vivo fluorescence microscopy of the lungs revealed that for mice sacrificed on day 38, a significant percentage of micrometastases were composed of cancer cells from both primary tumors (mean 37%; range 27 to 45%), while two mice sacrificed on day 42 showed percentages of 51% and 70%.

Conclusions

A high degree of metastatic cross-seeding of cancer cells derived from bilateral tumors may contribute to faster metastatic growth and intratumoral heterogeneity. We posit that our work will help understand treatment resistance and optimal planning of SBBC treatment.
Appendix
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Literature
1.
Pan B, Xu Y, Zhou YD, Yao R, Wu HW, Zhu QL, Wang CJ, Mao F, Lin Y, Shen SJ, Sun Q (2019) The prognostic comparison among unilateral, bilateral, synchronous bilateral, and metachronous bilateral breast cancer: a meta-analysis of studies from recent decade (2008-2018). Cancer Med 8(6):2908–2918CrossRef
2.
Jobsen JJ, van der Palen J, Ong F, Riemersma S, Struikmans H (2015) Bilateral breast cancer, synchronous and metachronous; differences and outcome. Breast Cancer Res Treat 153(2):277–283CrossRef
3.
Ozturk A, Alco G, Sarsenov D, Ilgun S, Ordu C, Koksal U, Nur Pilanci K, Erdogan Z, Izci F, Elbuken F, Agacayak F, Aktepe F, Ozmen V (2018) Synchronous and metachronous bilateral breast cancer: a long-term experience. J BUON 23(6):1591–1600PubMed
4.
Beckmann KR, Buckingham J, Craft P, Dahlstrom JE, Zhang Y, Roder D, Stuart-Harris R (2011) Clinical characteristics and outcomes of bilateral breast cancer in an Australian cohort. Breast. 20(2):158–164CrossRef
5.
Eliyatkin N, Zengel B, Yagci A, Comut E, Postaci H, Uslu A, Aktas S (2015) Properties of synchronous versus metachronous bilateral breast carcinoma with long time follow up. Asian Pac J Cancer Prev 16(12):4921–4926CrossRef
6.
Kheirelseid EA, Jumustafa H, Miller N, Curran C, Sweeney K, Malone C et al (2011) Bilateral breast cancer: analysis of incidence, outcome, survival and disease characteristics. Breast Cancer Res Treat 126(1):131–140CrossRef
7.
Mejdahl MK, Wohlfahrt J, Holm M, Balslev E, Knoop AS, Tjønneland A, Melbye M, Kroman N (2019) Breast cancer mortality in synchronous bilateral breast cancer patients. Br J Cancer 120(7):761–767CrossRef
8.
Aslakson CJ, Miller FR (1992) Selective events in the metastatic process defined by analysis of the sequential dissemination of subpopulations of a mouse mammary tumor. Cancer Res 52(6):1399–1405PubMed
9.
Liu L, Zhang SX, Liao W, Farhoodi HP, Wong CW, Chen CC et al (2017) Mechanoresponsive stem cells to target cancer metastases through biophysical cues. Sci Transl Med 9(400)
10.
Lu J, Liu X, Liao YP, Wang X, Ahmed A, Jiang W, Ji Y, Meng H, Nel AE (2018) Breast cancer chemo-immunotherapy through liposomal delivery of an immunogenic cell death stimulus plus interference in the IDO-1 pathway. ACS Nano 12(11):11041–11061CrossRef
11.
Park MK, Lee CH, Lee H (2018) Mouse models of breast cancer in preclinical research. Lab Anim Res 34(4):160–165CrossRef
12.
Price JE, Polyzos A, Zhang RD, Daniels LM (1990) Tumorigenicity and metastasis of human breast carcinoma cell lines in nude mice. Cancer Res 50(3):717–721PubMed
13.
Dothager RS, Flentie K, Moss B, Pan MH, Kesarwala A, Piwnica-Worms D (2009) Advances in bioluminescence imaging of live animal models. Curr Opin Biotechnol 20(1):45–53CrossRef
14.
Chu J, Oh Y, Sens A, Ataie N, Dana H, Macklin JJ, Laviv T, Welf ES, Dean KM, Zhang F, Kim BB, Tang CT, Hu M, Baird MA, Davidson MW, Kay MA, Fiolka R, Yasuda R, Kim DS, Ng HL, Lin MZ (2016) A bright cyan-excitable orange fluorescent protein facilitates dual-emission microscopy and enhances bioluminescence imaging in vivo. Nat Biotechnol 34(7):760–767CrossRef
15.
Yeh HW, Karmach O, Ji A, Carter D, Martins-Green MM, Ai HW (2017) Red-shifted luciferase-luciferin pairs for enhanced bioluminescence imaging. Nat Methods 14(10):971–974CrossRef
16.
Iwano S, Sugiyama M, Hama H, Watakabe A, Hasegawa N, Kuchimaru T, Tanaka KZ, Takahashi M, Ishida Y, Hata J, Shimozono S, Namiki K, Fukano T, Kiyama M, Okano H, Kizaka-Kondoh S, McHugh TJ, Yamamori T, Hioki H, Maki S, Miyawaki A (2018) Single-cell bioluminescence imaging of deep tissue in freely moving animals. Science. 359(6378):935–939CrossRef
17.
Kang JH, Chung JK (2008) Molecular-genetic imaging based on reporter gene expression. J Nucl Med 49(Suppl 2):164S–179SCrossRef
18.
Dull T, Zufferey R, Kelly M, Mandel RJ, Nguyen M, Trono D, Naldini L (1998) A third-generation lentivirus vector with a conditional packaging system. J Virol 72(11):8463–8471CrossRef
19.
Nyström NN, Hamilton AM, Xia W, Liu S, Scholl TJ, Ronald JA (2019) Longitudinal visualization of viable cancer cell intratumoral distribution in mouse models using Oatp1a1-enhanced magnetic resonance imaging. Investig Radiol 54(5):302–311CrossRef
20.
Stacer AC, Nyati S, Moudgil P, Iyengar R, Luker KE, Rehemtulla A, Luker GD (2013) NanoLuc reporter for dual luciferase imaging in living animals. Mol Imaging 12(7):1–13CrossRef
21.
Puchalapalli M, Zeng X, Mu L, Anderson A, Hix Glickman L, Zhang M, Sayyad MR, Mosticone Wangensteen S, Clevenger CV, Koblinski JE (2016) NSG mice provide a better spontaneous model of breast cancer metastasis than athymic (nude) mice. PLoS One 11(9):e0163521CrossRef
22.
Iorns E, Drews-Elger K, Ward TM, Dean S, Clarke J, Berry D, Ashry DE, Lippman M (2012) A new mouse model for the study of human breast cancer metastasis. PLoS One 7(10):e47995CrossRef
23.
Kim MY, Oskarsson T, Acharyya S, Nguyen DX, Zhang XH, Norton L et al (2009) Tumor self-seeding by circulating cancer cells. Cell. 139(7):1315–1326CrossRef
24.
Wang WC, Zhang XF, Peng J, Li XF, Wang AL, Bie YQ et al (2018) Survival mechanisms and influence factors of circulating tumor cells. Biomed Res Int 2018:6304701PubMedPubMedCentral
25.
Dondossola E, Dobroff AS, Marchiò S, Cardó-Vila M, Hosoya H, Libutti SK, Corti A, Sidman RL, Arap W, Pasqualini R (2016) Self-targeting of TNF-releasing cancer cells in preclinical models of primary and metastatic tumors. Proc Natl Acad Sci U S A 113(8):2223–2228CrossRef
26.
Reinshagen C, Bhere D, Choi SH, Hutten S, Nesterenko I, Wakimoto H et al (2018) CRISPR-enhanced engineering of therapy-sensitive cancer cells for self-targeting of primary and metastatic tumors. Sci Transl Med 10(449)
27.
Parkins KM, Dubois VP, Kelly JJ, Chen Y, Knier NN, Foster PJ, Ronald JA (2020) Engineering circulating tumor cells as novel cancer theranostics. Theranostics. 10(17):7925–7937CrossRef
28.
Ding S, Sun X, Lu S, Wang Z, Chen X, Shen K (2021) Association of molecular subtype concordance and survival outcome in synchronous and metachronous bilateral breast cancer. Breast. 57:71–79CrossRef
29.
Baretta Z, Olopade OI, Huo D (2015) Heterogeneity in hormone-receptor status and survival outcomes among women with synchronous and metachronous bilateral breast cancers. Breast. 24(2):131–136CrossRef
30.
Dhadlie S, Whitfield J, Hendahewa R (2018) Synchronous bilateral breast cancer: a case report of heterogeneous estrogen receptor status. Int J Surg Case Rep 53:102–106CrossRef
31.
Schwentner L, Wolters R, Wischnewsky M, Kreienberg R, Wöckel A (2012) Survival of patients with bilateral versus unilateral breast cancer and impact of guideline adherent adjuvant treatment: a multi-centre cohort study of 5292 patients. Breast. 21(2):171–177CrossRef
32.
Paschall AV, Liu K (2016) An orthotopic mouse model of spontaneous breast cancer metastasis. J Vis Exp 114:54040
33.
Eyre R, Alférez DG, Spence K, Kamal M, Shaw FL, Simões BM, Santiago-Gómez A, Sarmiento-Castro A, Bramley M, Absar M, Saad Z, Chatterjee S, Kirwan C, Gandhi A, Armstrong AC, Wardley AM, O’Brien CS, Farnie G, Howell SJ, Clarke RB (2016) Patient-derived mammosphere and xenograft tumour initiation correlates with progression to metastasis. J Mammary Gland Biol Neoplasia 21(3-4):99–109CrossRef
34.
Bao L, Messer K, Schwab R, Harismendy O, Pu M, Crain B, Yost S, Frazer KA, Rana B, Hasteh F, Wallace A, Parker BA (2015) Mutational profiling can establish clonal or independent origin in synchronous bilateral breast and other tumors. PLoS One 10(11):e0142487CrossRef
Metadata
Title
Molecular Imaging Reveals a High Degree of Cross-Seeding of Spontaneous Metastases in a Novel Mouse Model of Synchronous Bilateral Breast Cancer
Authors
Shirley Liu
Nivin N Nyström
John J Kelly
Amanda M Hamilton
Yanghao Fu
John A Ronald
Publication date
01-02-2022
Publisher
Springer International Publishing
Published in
Molecular Imaging and Biology / Issue 1/2022
Print ISSN: 1536-1632
Electronic ISSN: 1860-2002
DOI
https://doi.org/10.1007/s11307-021-01630-z

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