Introduction

Oncology Letters

1792-1074 1792-1082

D.A. Spandidos

10.3892/ol.2017.7621

OL-0-0-7621

Articles

Paclitaxel-induced hypothermia and hypoperfusion increase breast cancer metastasis and angiogenesis in mice

Ami

Nozomi

1 2 Sato

Hideki

1 Hayakawa

Yoshihiro

1R&D Center, Terumo Corp., Nakai-machi, Kanagawa 259-0151, Japan 2Division of Pathogenic Biochemistry, Institute of Natural Medicine, University of Toyama, Toyama-shi, Toyama 930-0194, Japan

Correspondence to: Professor Yoshihiro Hayakawa, Division of Pathogenic Biochemistry, Institute of Natural Medicine, University of Toyama, 2630 Sugitani, Toyama-shi, Toyama 930-0194, Japan, E-mail: haya@imn.u-toyama.ac.jp

02 2018

14 12 2017

15 2 2330 2334 23062017 06112017

2018

This is an open access article distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivs License, which permits use and distribution in any medium, provided the original work is properly cited, the use is non-commercial and no modifications or adaptations are made.

Housing temperature has been shown to influence thermoregulation and behavior of preclinical cancer models; and anti-cancer drugs typically reduce peripheral blood flow and body temperature. In the present study, the effects of paclitaxel (PTX)-induced reduction of body temperature and peripheral blood flow on metastatic 4T1 breast cancer was investigated in a mouse model and the modification of these effects by thermoneutral temperature was also assessed. A single dose of PTX decreased the body temperature and peripheral blood flow in mice housed at a standard temperature (23°C). Furthermore, although lung metastasis and angiogenesis of inoculated 4T1 cells increased in mice pretreated with PTX, mice housed at a thermoneutral temperature (30°C) could compensate their body temperature and peripheral blood flow compared with control mice, and also suppressed 4T1 angiogenesis and metastasis to lung. The present results imply that maintenance of body temperature or efficient energy supply for thermogenesis may prevent tumor relapse or metastasis after chemotherapy.

chemotherapy body temperature peripheral blood flow angiogenesis metastasis

Introduction

To maintain body temperature, both energy intake and blood circulation are critically important. Anti-cancer drugs are known to induce peripheral neuropathy through nerve hypoperfusion and reduction of vasa nervorum density (1). In a mouse study, paclitaxel (PTX) and oxaliplatin induced mechanical allodynia along with peripheral hypoperfusion (2). Although blood flow is essential for all cells in the body to obtain nutrients and oxygen (3), solid tumors often require a greater blood supply to support their rapid growth; therefore, angiogenesis is critical for tumor growth (4). In this regard, angiogenesis inhibitors target tumors based by hampering blood supply, leading to tumor growth arrest. In contrast, chronic reduction in blood flow and low oxygen availability may result in tumor hypoxia, which has been implicated in tumor propagation by adapting cells to nutrient deprivation, or by facilitating proliferation, local invasion, and metastatic spread through induction of angiogenesis, lymphangiogenesis, and/or acquisition of epithelial-to-mesenchymal phenotypes (5–8).

Chemotherapy reportedly reduces body temperature (9,10) and hypothermia is known to suppress immunity by delaying and prolonging production of proinflammatory cytokines (11,12). Considering the role of the immune system in tumor surveillance, such immune suppression by hypothermia may increase risk of tumor cell progression (13). Indeed, transplant patients treated with immunosuppressive drugs (14), patients with chronic inflammation and infection, and elderly persons (15) are well known to have increased susceptibility to malignancies. Interestingly, housing temperature reportedly influences results of preclinical cancer models (16). Endogenous immune responses were suppressed under standard housing temperature (20–26°C) compared with thermoneutral temperature (30–32°C) because the energy needed for intact immune function is consumed to maintain body temperature (16).

In this study, we investigated effects on metastatic breast cancer by PTX-induced reductions in body temperature and peripheral blood flow in a mouse model, and the influence of thermoneutral temperature on these effects.

Materials and methods <sec> <title>Animals

Female BALB/c mice (7 weeks old; CLEA Japan, Tokyo, Japan) were used. We used 6–7 animals in each study group, which were housed 6–7 mice per cage under controlled temperature and humidity (23±2°C, 50±10%), on a 12-h light/dark cycle. Mice had access to tap water and food ad libitum. All experiments were approved and performed according to the guidelines of the Committee for Animal Experiments at Terumo Corporation and the Care and Use Committee of Laboratory Animals of the University of Toyama.

Reagents and cells

PTX (Taxol^®; Bristol-Myers Squibb, Tokyo, Japan), formulated at 6 mg/ml, was dissolved in a vehicle of 13.3% absolute anhydrous ethanol (Wako Pure Chemical, Osaka, Japan), 13.3% Cremophore^® EL (Sigma-Aldrich Japan, Tokyo, Japan) and 73.4% saline (Otsuka Pharmaceutical Factory, Tokushima, Japan). We obtained pGL4.50 [luc2P/CMV-RE/Hygro] vector and D-Luciferin from Promega (Sunnyvale, CA, USA). Mouse mammary carcinoma 4T1 cells that expressed the luciferase gene (4T1-Luc2 cells) were established and maintained as described before (17).

Measurement of body temperature and peripheral blood flow

Rectal temperature was measured three times for each animal, using a rectal probe (RET-3; Physitemp, Clifton, NJ, USA) and meter (BAT-12R; Physitemp), from which averaged values were obtained. Body temperatures were measured at approximately 9:00 a.m. Blood flow of ventral tail artery was recorded using laser Doppler blood flowmeter (ALF21R; ADMEDEC, Tokyo, Japan). Blood flow was measured three times for about 30 sec. Values for the 10-second interval between 10 and 20 sec from the starting point were averaged. Peripheral blood flow was measured at about 10:00 a.m. Mice were injected with PTX (8 or 12 mg/kg) intraperitoneally (i.p.) on day 1. Body temperature was measured on day 1 before PTX injection, and once a day until day 10. Peripheral blood flow was measured on day 1 before PTX injection, and on days 3, 5, 7 and 10. All measurements were conducted at 23°C. Mice were divided into three groups according to their body temperatures on day 1.

Thermoneutral housing

To keep animals at thermoneutral temperature, mice were housed at 30°C in a cooled incubator (MIR-154; Panasonic, Osaka, Japan) with 12-h light/dark cycle.

Experimental lung metastasis model

Six days after 4T1-Luc2 cell inoculation, mice were injected with D-luciferin (150 mg/kg) intraperitoneally. Twenty min later, these mice were sacrificed and their lungs were removed. Lung luminescence was measured with an imaging system (IVIS Spectrum; Caliper Life Science, Hopkinton, MA, USA) (17).

Matrigel plug angiogenesis assay

Seven days after injection of 4T1-Luc2 cells/Matrigel matrix, the mice were injected intravenously with 100 µl of 1% Evans blue dye (Sigma-Aldrich Japan). After 30 min, mice were cardiac-perfused with phosphate-buffered saline (Life Technologies Japan, Tokyo, Japan) containing 2 mM EDTA (Nacalai Tesque, Kyoto, Japan) under 3% isoflurane [isoflurane inhalation solution (Pfizer, Tokyo, Japan)] anesthesia. Matrigel plugs were removed and incubated with formamide (Wako Pure Chemical, Osaka, Japan) at 37°C for 48 h to elute the Evans blue dye. The amount of Evans blue dye was quantified by use of a spectrometer (620 nm) (18).

Statistical analysis

Data are expressed as mean ± standard error of the mean (SEM). Data were analyzed with a two-way analysis of variance followed by post hoc analysis with the Bonferroni's test. In the metastatic and angiogenesis assay, data were analyzed with one-way analysis of variance followed by post hoc analysis with Tukey's test. Statistical analysis was performed using Prism (version 6.07; GraphPad Software, Inc., La Jolla, CA, USA) (19).

Results <sec> <title>Effect of PTX on body temperature and peripheral blood flow

Significant reduction in body temperature was observed after a single injection of PTX (12 mg/kg) into Balb/c mice during days 4–8 at 23°C (Fig. 1A). Peripheral blood flow was also reduced by about 25% compared with untreated mice during days 3–7 after a single injection of PTX (12 mg/kg; Fig. 1B).

Thermoneutral temperature reversed body temperature reduction and decreased blood flow induced by PTX

To find whether thermoneutral temperature could compensate for reduced body temperature and peripheral blood flow induced by PTX, mice were housed at either 23°C or 30°C after being injected with PTX. Although PTX treatment reduced both body temperature and peripheral blood flow of mice housed at 23°C (Fig. 2A and B), PTX-treated mice housed at 30°C showed no reductions in either body temperature or peripheral blood flow (Fig. 2C and D). These data indicate that thermoneutral temperature can compensate for PTX-induced reductions of body temperature and peripheral blood flow.

Thermoneutral temperature reverses PTX's metastasis-promoting effect

We next examined whether body temperature reduction caused by PTX treatment enhanced in vivo malignant behaviors such as metastasis or angiogenesis, using murine metastatic mammary cancer cell line 4T1. Mice were treated with PTX and housed at either 23°C or 30°C for the next 4 days, and then intravenously injected with 4T1-Luc2 cells. Upon 4T1-Luc2 cell inoculation, all mice were housed at 23°C. As shown in Fig. 3, pre-treatment with PTX significantly increased metastatic lung colonization by 4T1-Luc2 cells among mice housed at 23°C. In contrast, the mice housed at 30°C did not show such enhanced metastatic colonization (Fig. 3).

To evaluate angiogenesis, we used a Matrigel plug assay with 4T1-Luc2 cells under the same treatment and housing conditions as the metastasis assay. We observed induction of more angiogenesis in the PTX-treated group compared with the vehicle-treated group, although the difference was not statistically significant (P=0.0557). The mice housed at 30°C showed less angiogenesis in the 4T1-Luc2/Matrigel plug compared with mice housed at 23°C (Fig. 4). These results indicate the potential advantage of thermoneutral housing temperature to prevent the metastasis- and angiogenesis-promoting effects of PTX.

Discussion

Mammalian body temperature is generally regulated by a balance between heat loss and generation (20,21). Several body reactions defend against cold, such as thermoregulatory behaviors to reduce the loss of heat generated during basal metabolism, cutaneous vasoconstriction to conserve heat in the body core, and heat production, including activation of brown adipose tissue (BAT), and shivering behavior in skeletal muscle (21–23). In this study, we observed reduced peripheral blood flow followed by reduced body temperature after single injections of PTX. These reductions were lasted about 8 days, then recovered. Compared with the vehicle-treated group, significant blood flow reduction was observed in the low-dose PTX-treated group, although body temperature was comparable between the two groups over the same time period (days 5–7). Therefore, we presume that PTX reduces peripheral blood flow as a compensatory mechanism for reduction of body temperature. Importantly, supplying exogenous heat by housing the PTX-treated mice at 30°C compensated reductions in both body temperature and peripheral blood flow. These results suggest that impaired heat generation is a mechanism of PTX-induced body-temperature reduction. Considering that BAT activity is known to decrease after treatment with taxanes in breast cancer patients (24), PTX-induced reduction of body temperature might involve inhibiting BAT activity. BAT activity is reported to be involved in psychological stress-induced hyperthermia (25). We observed a slight elevation of body temperature on day 7 in Fig. 2A. We don't know the exact reason which caused the elevation of body temperature. However, the degree of rise in body temperature of control group was greater than that of PTX-treated group, which might be because of the inhibiting BAT activity by PTX. In any case, the exact mechanism through which PTX treatment reduces body temperature remains to be elucidated.

Thermoneutral temperature refers to the temperature at which the energy expenditure required to maintain body temperature is lowest; for mice, this is usually 30–32°C (16,26,27). By housing mice at thermoneutral temperature, the malignancy-promoting effects of PTX were suppressed as body temperature and peripheral blood flow were compensated. Notably, we excluded the possibility that the reduced lung metastasis by 4T1 cells was a direct anti-cancer effect of PTX because the 4T1 inoculations in our study were timed at 4 days after the PTX injections, so that the administered PTX should have been mostly cleared by then (28). Importantly, tumor formation, growth, and metastasis of cancer cells are reportedly reduced by keeping mice at thermoneutral temperature through modulating immune responses (27). Body temperature fell by 1–2°C with tumor growth, which exhausted the mice's ability to maintain normal body temperature at standard housing condition (27), whereas thermoneutral housing supplied sufficient heat to allow them to conserve energy needed to maintain an intact immune system. Indeed, anesthesia-induced hypothermia (30–32°C) is known to increase lung metastasis from mammary adenocarcinoma cells by suppressing natural killer cell activity (29). In obese mice, body temperature is reportedly 1–2°C lower than in control mice (30,31); treatment with leptin (an important regulator of energy balance) suppresses lung metastasis (32) and increases body temperature (33). Taken together, these studies suggest that reduced body temperature suppresses immune-system cancer surveillance, and facilitates tumor progression. Thus thermoneutral temperature may compensate such immune suppression.

To achieve distant metastasis, cancer cells must enter the circulation and be exposed to the fluid shear stress in the blood stream, which is influenced by such factors as fluid rate and viscosity (34). Although increased fluid shear force can support cancer cells migrating and binding to the vascular endothelium (35), it also affects tumor cell survival. As we saw, PTX promotes increased metastatic lung colonization by 4T1-Luc2 cells along with reduced peripheral blood flow. Reduced fluid shear force might be a mechanism that affects lung metastasis in PTX-treated mice.

Hypoxia can also influence tumor cells, as a stressor that impairs growth or as a trigger for malignant processes, including angiogenesis. Angiogenesis has a critical function in tumor metastasis because its permeable and heterogeneous vasculature facilitates extravasation, circulation, and relocation of tumor cells (3,4,6). Thus, hypoxia caused by PTX-induced peripheral blood flow reduction might be a complicating factor in metastasis.

In this study, we investigated the influence of reduction of body temperature and peripheral blood flow by PTX on metastasis and angiogenesis. Further studies will be necessary to clarify the mechanism how PTX reduces body temperature or the mechanism how reduced body temperature affects the other systems such as the immune-system.

In summary, we propose that dysregulation of body temperature and peripheral blood flow by PTX treatment might decrease fluid shear force, increase tumor hypoxia, and/or suppress immunity, thus promoting metastasis or angiogenesis. Maintenance of body temperature or energy supply for thermogenesis may help prevent tumor relapse or metastasis after chemotherapy.

Acknowledgements

The authors thank Keisuke Ogura for his technical support.

References 1

Kirchmair

Tietz

Panagiotou

Walter

Silver

Yoon

Schratzberger

Weber

Kusano

Weinberg

Therapeutic angiogenesis inhibits or rescues chemotherapy-induced peripheral neuropathy: Taxol- and thalidomide-induced injury of vasa nervorum is ameliorated by VEGF

Mol Ther1569752007

10.1038/sj.mt.6300019

17164777

Gauchan

Andoh

Kato

Sasaki

Kuraishi

Effects of the prostaglandin E1 analog limaprost on mechanical allodynia caused by chemotherapeutic agents in mice

J Pharmacol Sci1094694722009

10.1254/jphs.08325SC

19276613

Paduch

The role of lymphangiogenesis and angiogenesis in tumor metastasis

Cell Oncol (Dordr)393974102016

10.1007/s13402-016-0281-9

27126599

Gupta

Qin

Mechanism and its regulation of tumor-induced angiogenesis

World J Gastroenterol9114411552003

10.3748/wjg.v9.i6.1144

12800214

Vaupel

Harrison

Tumor hypoxia: Causative factors, compensatory mechanisms, and cellular response

Oncologist9Suppl 5S4S92004

10.1634/theoncologist.9-90005-4

Muz

de la Puente

Azab

The role of hypoxia in cancer progression, angiogenesis, metastasis, and resistance to therapy

Hypoxia (Auckl)383922015

10.2147/HP.S93413

27774485

Morfoisse

Renaud

Hantelys

Prats

Garmy-Susini

Role of hypoxia and vascular endothelial growth factors in lymphangiogenesis

Mol Cell Oncol2e10248212015

10.1080/23723556.2015.1024821

27308508

Cao

Shang

Zhang

Miele

Sarkar

Wang

Zhou

Tumor cell-mediated neovascularization and lymphangiogenesis contrive tumor progression and cancer metastasis

Biochim Biophys Acta18362732862013

23933263

Guindon

Hohmann

Use of sodium bicarbonate to promote weight gain, maintain body temperature, normalize renal functions and minimize mortality in rodents receiving the chemotherapeutic agent cisplatin

Neurosci Lett54441462013

10.1016/j.neulet.2013.03.033

23570729

Guindon

Deng

Fan

Wager-Miller

Hohmann

Optimization of a cisplatin model of chemotherapy-induced peripheral neuropathy in mice: Use of vitamin C and sodium bicarbonate pretreatments to reduce nephrotoxicity and improve animal health status

Mol Pain10562014

10.1186/1744-8069-10-56

25189223

Fairchild

Viscardi

Hester

Singh

Hasday

Effects of hypothermia and hyperthermia on cytokine production by cultured human mononuclear phagocytes from adults and newborns

J Interf cytokine Res20104910552000

10.1089/107999000750053708

Sahdo

Evans

Arnemo

Fröbert

Särndahl

Blanc

Body temperature during hibernation is highly correlated with a decrease in circulating innate immune cells in the brown bear (Ursus arctos): A common feature among hibernators?

Int J Med Sci105085142013

10.7150/ijms.4476

23532623

Ribatti

The concept of immune surveillance against tumors. The first theories

Oncotarget8717571802017

27764780

Peto

Cancer epidemiology in the last century and the next decade

Nature4113903952001

10.1038/35077256

11357148

Melvold

Sticca

Basic and tumor immunology: A review

Surg Oncol Clin N Am16711–735vii2007

Hylander

Repasky

Thermoneutrality, mice, and cancer: A heated opinion

Trends Cancer21661752016

10.1016/j.trecan.2016.03.005

28741570

Lou

Takahashi

Irimura

Saiki

Hayakawa

Identification of Hirsutine as an anti-metastatic phytochemical by targeting NF-κB activation

Int J Oncol45208520912014

10.3892/ijo.2014.2624

25175557

Suehiro

Hamakubo

Kodama

Aird

Minami

Vascular endothelial growth factor activation of endothelial cells is mediated by early growth response-3

Blood115252025322010

10.1182/blood-2009-07-233478

19965691

Lin

Chiang

Hsu

Lin

Liou

Lin

Short-time focused ultrasound hyperthermia enhances liposomal doxorubicin delivery and antitumor efficacy for brain metastasis of breast cancer

Int J Nanomedicine9448544942014

10.2147/IJN.S68347

25278753

Alawi

Aubdool

Liang

Wilde

Vepa

Psefteli

Brain

Keeble

The sympathetic nervous system is controlled by transient receptor potential vanilloid 1 in the regulation of body temperature

FASEB J29428542982015

10.1096/fj.15-272526

26136480

Feketa

Marrelli

Induction of therapeutic hypothermia by pharmacological modulation of temperature-sensitive TRP channels: Theoretical framework and practical considerations

Temperature (Austin)22442572015

10.1080/23328940.2015.1024383

27227027

Morrison

Central control of body temperature

F1000Res5pii: F10002016

10.12688/f1000research.7958.1

27239289

Ootsuka

Tanaka

Control of cutaneous blood flow by central nervous system

Temperature (Austin)23924052015

10.1080/23328940.2015.1069437

27227053

Gadea

Thivat

Merlin

Paulon

Kwiatkowski

Chadeyras

Coudert

Boirie

Morio

Durando

Brown adipose tissue activity in relation to weight gain during chemotherapy in breast cancer patients: A pilot study

Nutr Cancer66109210962014

10.1080/01635581.2014.948212

25157743

Kataoka

Hioki

Kaneko

Nakamura

Psychological stress activates a dorsomedial hypothalamus-medullary raphe circuit driving brown adipose tissue thermogenesis and hyperthermia

Cell Metab203463582014

10.1016/j.cmet.2014.05.018

24981837

Lodhi

Semenkovich

Why we should put clothes on mice

Cell Metab91111122009

10.1016/j.cmet.2009.01.004

19187768

Kokolus

Capitano

Lee

Eng

Waight

Hylander

Sexton

Hong

Gordon

Abrams

Repasky

Baseline tumor growth and immune control in laboratory mice are significantly influenced by subthermoneutral housing temperature

Proc Natl Acad Sci USA11020176201812013

10.1073/pnas.1304291110

24248371

Zhang

Xia

Liu

Comparative study on pharmacokinetics and tissue distribution of a novel microemulsion based on the paclitaxel/L-OH lipid complex and paclitaxel injection in cremophor

Yao Xue Xue Bao48169817042013(In Chinese)

24475708

Ben-Eliyahu

Shakhar

Rosenne

Levinson

Beilin

Hypothermia in barbiturate-anesthetized rats suppresses natural killer cell activity and compromises resistance to tumor metastasis: A role for adrenergic mechanisms

Anesthesiology917327401999

10.1097/00000542-199909000-00026

10485785

Jürgens

Schürmann

Kluge

Ortmann

Klaus

Joost

Tschöp

Hyperphagia, lower body temperature, and reduced running wheel activity precede development of morbid obesity in New Zealand obese mice

Physiol Genomics252342412006

10.1152/physiolgenomics.00252.2005

16614459

Klaus

Münzberg

Trüloff

Heldmaier

Physiology of transgenic mice with brown fat ablation: Obesity is due to lowered body temperature

Am J Physiol274R287R2931998

9486283

Mori

Sakurai

Choo

Obi

Koizumi

Yoshida

Shimada

Saiki

Severe pulmonary metastasis in obese and diabetic mice

Int J Cancer119276027672006

10.1002/ijc.22248

16998795

Luheshi

Gardner

Rushforth

Loudon

Rothwell

Leptin actions on food intake and body temperature are mediated by IL-1

Proc Natl Acad Sci USA96704770521999

10.1073/pnas.96.12.7047

10359836

Kon

Maeda

Shiga

Erythrocyte deformation in shear flow: Influences of internal viscosity, membrane stiffness, and hematocrit

Blood697277341987

2434160

Mitchell

King

Fluid shear stress sensitizes cancer cells to receptor-mediated apoptosis via trimeric death receptors

New J Phys15150082013

10.1088/1367-2630/15/1/015008

Figure 1.

Effect of paclitaxel on body temperature and peripheral blood flow at standard housing temperature (23°C). Mice were treated with paclitaxel (8 or 12 mg/kg, i.p.) on day 1; (A) body temperature and (B) ventral artery blood flow were measured at the indicated days after treatment. Data are expressed as mean ± SEM (n=6). *P<0.05, **P<0.01, ***P<0,001, ****P<0.0001, compared with vehicle-treated group (Bonferroni's post test).

Figure 2.

Effect of thermoneutral housing on paclitaxel-induced reduction of body temperature and peripheral blood flow. Mice were treated with paclitaxel (12 mg/kg) on day 1. Body temperature (A and C) and ventral artery blood flow (B and D) were measured at the indicated days after treatment. Groups of mice were housed at either standard (A and B; at 23°C) or thermoneutral (C and D; at 30°C) temperature after paclitaxel treatment. Data are expressed as mean ± SEM (n=6). *P<0.05, **P<0.01, ***P<0,001, ****P<0.0001, compared with vehicle-treated group (Bonferroni's post test).

Figure 3.

Effect of thermoneutral housing on pro-metastatic effect of paclitaxel. Mice were treated with paclitaxel (12 mg/kg), housed at either 23°C or 30°C for the next 4 days, and then given an intravenous injection of 5×10⁵ 4T1-Luc2 cells. Six days after tumor inoculation, mice were sacrificed and lung metastases were measured by the IVIS system. Open column, vehicle-treated mice at 23°C; black column, paclitaxel-treated mice (12 mg/kg) at 23°C; gray column, paclitaxel-treated mice (12 mg/kg) at 30°C. Data are expressed as mean ± SEM (n=7). *P<0.05, **P<0.01, compared usingTukey's post test.

Figure 4.

Effect of thermoneutral housing on paclitaxel's pro-angiogenic effect. Mice were treated with paclitaxel (12 mg/kg) and housed at either 23°C or 30°C for the next 4 days. They were then each given a subcutaneous injection of 5×10⁴ 4T1-Luc2 cells with Matrigel matrix. Seven days after the 4T1-Luc2 cells/Matrigel matrix inoculation, mice were injected with Evans blue dye, to quantify the extent of angiogenesis. Open column, vehicle-treated mice at 23°C; black column, paclitaxel-treated mice (12 mg/kg) at 23°C; gray column, paclitaxel-treated mice (12 mg/kg) at 30°C. Data are expressed as mean ± SEM (n=6–7). **P<0.01, compared using Tukey's post test.