Light Exposure at Night Disrupts Host/Cancer Circadian Regulatory Dynamics: Impact on the Warburg Effect, Lipid Signaling and Tumor Growth Prevention

This study was carried out in strict accordance with the recommendations in the Guide for the Care and Use of Laboratory Animals of the National Institutes of Health. The protocol was approved by the Tulane University Institutional Animal Care and Use Committee (NIH Assurance # A4499-01). All animals were maintained in a facility accredited by the Association for the Assessment and Accreditation of Laboratory Animal Care, International. All surgery was performed under ketamine/xylazine anesthesia, and all efforts were made to minimize suffering.

High-performance liquid chromatography (HPLC)-grade chloroform, ethyl ether, methanol, glacial acetic acid, heptane, hexane, and Sep-Pak C18 cartridges for HPLC extraction of samples were purchased from Fisher Chemical (Pittsburgh, PA). Free fatty acid, cholesterol ester, triglyceride, phospholipid, rapeseed oil methyl ester standards, as well as boron trifluoride-methanol, potassium chloride, sodium chloride, perchloric and trichloroacetic acids were purchased from Sigma Scientific (St. Louis, MO). The HPLC standards, (+/−) 5-HETE and 13(S)-HODE), as well as UltraPure Water were purchased from Cayman Chemical Co. (Ann Arbor, Michigan).

Weanling female nude rats (Hsd:RH-Foxn1[rnu]) between 35 and 50 g were housed in clear polycarbonate cages (2 rats/cage) in the laboratory facility light exposure chambers on a 12-hour light/12-hour dark (LD, 12∶12) cycle (lights on 0600–1800 hours or Zeitgeber time ZT0–ZT12 at 23°C and 45–50% humidity and allowed to acclimatize to these conditions for two weeks. Rats were provided water and food (Purina Prolab RMH 1000) ad libitum throughout the duration of the studies. Following the acclimatization period, animals were randomly separated into a control group of 36 rats that remained on the LD,12∶12 lighting regimen (complete darkness during the dark phase) and another group of 36 rats maintained on LD,12∶12 with exposure to dim LAN during the dark phase. The light intensity during the 12-hour light phase in both groups was provided by a one ballast/lamp system (GE Watt Miser, F34CW-RS-WM, 34-W bulb) in each chamber that provided a steady bright light stimulus at animal eye level of 141 µW/cm² (345 lux). In the chamber providing dim LAN, there was a second ballast/lamp system (GE Starcoat, F32T8-SP-11, 32-W bulb) that emitted steady dim light stimulus at animal eye level of 0.08 µW/cm² (0.2 lux) during the 12-hour dark phase [12]. Six weeks later, the animals were implanted with steroid receptor negative (SR−) MCF-7 human breast cancer xenografts in a tissue-isolated manner, as described previously [12]. These tumors had evolved over several passages from a subset of SR+ xenografts that had lost the expression of estrogen and progesterone receptors and became estrogen unresponsive. These xenografts were histopathologically characterized as poorly differentiated, grade 3, infiltrating ductal adenocarcinoma as previously described [12]. Over the course of circadian/tumor growth study, when tumors reached a sufficient size for measurement rats were subjected to light CO₂ narcosis, and tumor dimensions were measured through the skin with vernier calipers every two days; tumor dimensions were converted to estimated tumor weights using a linear regression formula and growth rates calculated as previously described [9], [12]. The final tumor weight in the tumor growth study was determined by weighing at the end of the experiment. At the end of each of the tumor growth periods, when tumors reached approximately 5–6 g for both control and LAN-exposed groups, subsets of 6 animals were randomly killed and their corresponding tumors were harvested every 4 hours over a single 24-hour period at 6 different circadian time points (e.g., 0800 hours = ZT2, 1200 hours = ZT6, 1600 hours = ZT10, 2000 hours = ZT14, 2400 hours = ZT18, and 0400 hours = ZT22) as previously described [28]. Due to the greatly accelerated tumor growth rates in the LAN group, xenografts (n = 36) reached the targeted harvest size of 5–6 g approximately two weeks prior to that of the xenografts (n = 36) in the LD 12∶12 control group.

Following two weeks of the lighting regimens described above, animals were subjected to a series of six low-volume blood draws via cardiocentesis to collect left ventricular arterial blood, as described previously [9], [10], [12], [28] over a period of 30 days prior to tumor implantation (see above). Briefly, blood collections were performed at designated 4-hour intervals over a 24-hour period beginning at ZT2 (0800 hours) with each animal being subjected to cardiocentesis only once every 5 days during the 30-day period prior to tumor implantation. This was done in order for the animals to restore their small blood volume loss and to minimize stress and decrease the potential effects of the procedure on feeding and morbidity/mortality. Animals were lightly anesthetized by CO₂ inhalation (70% CO₂/30% air); 1-ml samples were taken from the left ventricle by cardiac puncture (less than 5% total blood volume) via tuberculin syringe (25 gauge, 3/8 in; Becton-Dickinson, Franklin Lakes, NJ) moistened with sodium heparin (1,000 U/ml; Elkin-Sinn, Cherry Hill, NJ), as described previously. Blood sampling during the dark-phase (i.e., 2000, 2400, 0400 hrs) was carried out under a safelight red lamp (Kodak 1A, model B, catalogue #152 1517; 120 V, 15 W, Rochester, NY) in order to preserve the nocturnal melatonin surge [9], [10], [12], [28]. Animal red lamp exposure at eye level during the brief 45-sec cardiocentesis procedure was no greater than 0.48±0.01 lux (1.16±0.04 µW/cm²). There were no complications due to anesthesia or cardiocentesis during the blood sampling period; survival was 100% and the animals were immediately active following the procedure. Plasma samples were stored at −20°C until assayed for melatonin, insulin, glucose, lactate and total fatty acids.

Prior to initiation of the tumor perfusions, 3–4 adult nude female rats maintained on LD 12∶12 were anesthetized using ketamine-xylazine solution (89.1 mg/kg and 9.9 mg/kg, IP). Animals were heparinized via jugular injection of sodium heparin (25 mg/kg; Sargent Pharmaceuticals, Schaumburg, IL). Forty to 50 mls arterial blood was collected between 0600 and 0900 hrs (low melatonin levels) from the right carotid artery of donor rats via catheter for the tumor perfusion experiments (3 to 4 perfusions per group), pooled, filtered through a 2″×2″ cheesecloth pad (Kendall Curity Gauze Sponge; Tyco Healthcare, Mansfield, MA), stored in a reservoir under mineral oil (Cat. #M1180-500 ML; Sigma Scientific, St. Louis, MO) and chilled at 4°C in a reservoir on ice and gently mixed via mechanical stirrer (Model #6975-171; Corning, NY) [9], [10], [12], [28].

When (SR−) MCF-7 human breast cancer xenografts reached 5–6 gm estimated tumor weight, animals were prepared for arterial-venous difference measurements of total fatty acids (TFAs), LA, 13-HODE, glucose, lactate, pO₂, CO₂ and pH between 0600 and 1000 hrs when endogenous melatonin levels were low. Tissue-isolated xenografts were perfused in situ with rat donor whole-blood to which either synthetic melatonin (Sigma, St. Louis, MO) and/or 13(S)-HODE (Cayman Chemicals, Ann Arbor, MI), or MT₁/MT₂ melatonin receptor antagonist S20928 (a generous gift from Institute de Recherches Internationales Servier, Courbevoie Cedex, France) was added as previously described [9], [10], [12], [28]. Sets (3 or 4 tumors/perfusion) of tissue-isolated human breast cancer xenografts were perfused in situ for 1 hr as previously described [9], [10], [12], [28] with whole-blood collected from donor rats. Incorporation of [³H]thymidine into tumor DNA was initiated 20 minutes prior to the end of each perfusion by injecting 20 µl of physiological saline containing 2 µCi [methyl-³H]thymidine/gm (New England Nuclear, Perkin Elmer, Boston, MA) estimated tumor weight into the arterial catheter. At the completion of each perfusion, tumors were freeze-clamped under liquid nitrogen, weighed and store at −85°C until analysis.

During the course of this study arterial whole blood samples were taken for measurements of pH, pO₂, pCO₂, glucose and lactate levels, and hematocrit using an iSTAT1 Analyzer and CG4+ and CG8+ cartridges (Abbott Laboratories, East Windsor, NJ). Values for glucose and lactate are reported as mg/dL and mmol/L, and for pO₂ and pCO₂ as mm Hg. Minimum detection levels for pH, pO₂ and pCO₂, glucose and lactate values were, respectively, 0.01, 0.1 mm Hg, 0.1 mm Hg, 0.2 mg/dL and 0.01 mmol/L.

Arterial plasma melatonin levels were measured via radioimmunoassay using the melatonin rat ¹²⁵I – radioimmunoassay kit (Labor Diagnostika Nord, Nordham, Germany) and analyzed using a Packard Cobra 5005 Automated Gamma Counter (Palo Alto, CA), as previously described [10], [12]. Arterial plasma insulin levels were measured using an ELISA kit (Diagnostic Systems Labs., Webster, TX).

Arterial plasma free fatty acids (FFA), triglycerides (TGA), phospholipids (PL), and cholesterol esters (CE) were extracted from 0.1 ml samples, as previously described [9]–[10], [12], [28]. Prior to extraction heptadecanoic acid (100 µg), which had been dissolved in chloroform (Fisher Scientific, Fair Lawn, NJ), was used as an internal standard. Methyl esters of fatty acids (FAs) were analyzed using a Hewlett Packard (Palo Alto, CA) model 5890A Gas Chromatograph fitted with a flame ionization detector (model #7673 A) auto-injector (model #7673 S), and integrator (model #3396A). All separations were carried out using a 0.25-mm×30-m capillary column (model #2380; Supelco, Inc., Bellefonte, PA) at 190°C, with helium as the carrier gas (linear rate 20 cm/s; split 100∶1). Injection port and detector were adjusted to 220°C. All methyl esters were identified on the basis of their retention time, compared with that of known standards. Minimum detectable limit for the assay was 0.05 µg/ml.

Frozen tumors were pulverized and manually homogenized in 50 mM Hepes, pH 7.5, 150 mM NaCl, 1% NP-40, 0.1% SDS, 0.1% sodium deoxycholate, 1 mM Na3VO4, 100 nM okadaic acid, and 1× protease inhibitor cocktail Set I (Calbiochem/EMD Biosciences, Billerica, MA). Tumor lysates were centrifuged at 15,300×g for 20 minutes. Supernatants were aliquoted and stored at −80°C. Protein concentrations of the supernatants were determined using a protein assay kit (Bio-Rad Laboratories, Inc., Hercules, CA). Total protein (80 µg per sample) was electrophoretically separated on a 10% SDS-polyacrylamide gel and electroblotted onto a Hybond membrane. After incubation with 5% non-fat milk in Tris-buffered saline containing 0.1% Tween, the immunoblots were probed with antibodies to phospho-AKT (Ser⁴⁷³), c-MYC (Cell Signaling Tech., Inc., Danvers, MA) or HIF-1α (BD Biosciences, San Jose, CA). The same blots were stripped and re-probed with antibodies to AKT (Cell Signaling Technology, Inc.), tubulin or GAPDH (glyceraldehyde-3-phosphate dehydrogenase) (Millipore Corp., Billerica, MA).

The presence of significant tumor rhythms over the 24-hour period and the degree of their robustness in either the circadian-regulated control or –disrupted LAN-exposed groups were determined by cosinor analysis using Periodogram (VBScript) software. Raw individual tumor data collected over a single 24-hour period were analyzed by this method with a fixed 24-hour period. Statistical differences between mean values in the LAN-exposed group versus the control group at each circadian time point were assessed using an unpaired Student’s t test. Statistical differences among group means in the tumor perfusion studies were determined by a one-way ANOVA followed by Bonferroni’s Multiple Comparison Test to make the following multiple comparisons among all groups: control versus melatonin; control versus melatonin +13-HODE; control versus 13-HODE; melatonin versus melatonin +13-HODE; melatonin +13-HODE versus 13-HODE; and melatonin versus 13-HODE. Differences in the slopes of regression lines (i.e., tumor growth rates) among groups were determined by regression analyses and tests for parallelism (Student’s t test). Differences were considered to be statistically significant at p < 0.05. Student’s t test, one-way ANOVA followed by Bonferroni’s post hoc test, and linear regression analyses were all carried out using GraphPad Prism 5 software.

We first examined potential circadian dynamics and their disruption by LAN in a number of host factors including plasma levels of melatonin, total FAs (TFAs), LA, glucose, lactate and insulin in rats bearing tissue-isolated, steroid receptor negative (SR−) MCF-7 human breast cancer xenografts on an light/dark (LD) 12∶12 cycle [12]. Plasma melatonin levels were low throughout the light phase and markedly increased to peak amplitude in the middle of the dark phase (Fig. 1A). Exposure of animals to dim LAN induced an 88% suppression in the nocturnal melatonin amplitude without affecting its circadian phase (Fig. 1A). Plasma TFA (Fig. 1B) and LA (Fig. 1C) rhythms in LD controls, which are dependent upon circadian SCN-driven nocturnal feeding activity, were preserved in LAN-exposed rats indicating that circadian disruption was limited to suppression of the nocturnal melatonin signal. Circadian control of both blood glucose and insulin levels independent of the effects of food intake has been reported in rats [29]. Plasma glucose levels increased after lights on to peak at the mid-light phase followed by a decline until lights off (Fig. 1D). Following lights off, glucose concentrations initially increased then decreased to a nadir at the mid-dark phase followed by a second increase during the end of the dark period. Plasma lactate concentrations in animals maintained in LD 12∶12 were generally low throughout the light phase followed by an increase during the dark period to reach a peak two hours before lights on (Fig. 1E). Under dim LAN conditions, rats became hyperglycemic with arrhythmic blood glucose levels remaining markedly elevated at 50% above control levels (Fig. 1D) whereas arrhythmic blood lactate levels remained consistently lower than controls throughout the 24-hour period (Fig. 1E). Circulating insulin levels exhibited a daily oscillation under LD 12∶12 (Fig. 1F) that generally mirrored the pattern of circulating IGF-1 concentrations previously reported [28]. LAN-exposed rats became markedly hyperinsulinemic with insulin levels retaining an oscillatory pattern similar to that observed in the LD 12∶12 controls (Fig. 1F); circulating IGF-1 levels were also circadian-disrupted and elevated under LAN conditions [28].

We next tested whether tumor xenografts themselves exhibited circadian rhythms in tumor cAMP levels, LA uptake, 13-HODE formation and the Warburg effect that could be disrupted by LAN-induced melatonin suppression. In the present study, the Warburg effect is identified as the tumor uptake of arterial blood glucose coupled with the release of lactate into the tumor venous blood [1]–[4]. Under LD, 12∶12 conditions, tumor cAMP levels (Fig. 2A), TFA uptake (Fig. 2B), LA (Fig. 2C) uptake, and 13-HODE formation (Fig. 2D), increased during the light phase to reach a peak two hours before lights off followed by a decrease during the dark phase to reach a nadir two hours before lights on. Tumor glucose uptake (Fig. 2E) and lactate production (Fig. 2F) followed a similar daily rhythmic pattern by increasing during the light phase to reach a peak two hours prior to lights off. During the dark period there was a progressive decline in these parameters with glucose uptake reaching a nadir at the end of the dark phase and lactate production decreasing to a trough at the mid-dark period followed by a rise until two hours before lights off. Under LAN conditions, however, not only were these rhythms completely absent, but the levels of each of these parameters remained significantly elevated over the 24-hour period.

We also addressed whether AKT, c-MYC and/or HIF-1α, key transcriptional regulators of the Warburg effect, exhibit circadian rhythmicity that is disrupted by dim LAN. As a pivotal stimulatory signal for tumor cell survival/proliferation, and glucose and LA metabolism, AKT activation [e.g., phosphorylation at serine 473 (s473)] was highest during the light phase and decreased thereafter to a nadir during the mid-dark phase. HIF-1α expression levels were low during the light phase followed by an increase to peak expression during the dark phase (Fig. 3 E&F). However, under dim LAN exposure, the rhythmic expression of both phospho-AKT (pAKT^s473) and HIF-1α was completely disrupted (Fig. 3 A&B and E&F). Tumor c-MYC expression was greatly elevated during the entire light phase followed by a marked decrease to a nadir during the second half of the dark phase (Fig. 3 C&D). In response to LAN-induced melatonin suppression, however, a significant, but less robust rhythmic expression of c-MYC persisted over the 24-hour period (Figs. 3 C E&F).

In light of the above findings, we postulated the occurrence of corresponding circadian changes in tumor proliferative activity and DNA content. We found that tumor [³H]thymidine incorporation into DNA (Fig. 2G) as well as DNA content (Fig. 2H) increased during the light phase shortly after lights on to reach a peak two hours prior to lights off. During the dark phase, however, both [³H]thymidine incorporation and DNA content decreased to a nadir two hours before lights on (Figs. 2 G&H). The circadian oscillations in [³H]thymidine incorporation and DNA content suggest that tumor cell number increased during the light phase due to increased proliferative activity while during the dark phase cell number decreased suggesting that apoptotic cell loss was occurring in parallel with decreased cell proliferation. Our results are consistent with previous studies in transplantable mouse mammary cancer showing that gross tumor sizes and growth rates actually fluctuate in a circadian manner throughout each day of the period of net tumor growth [30]. In response to LAN, the daily oscillation in proliferative activity and DNA content was nullified as these parameters remained persistently elevated throughout the 24-hour period (Fig. 2 G&H). Under circadian-regulated conditions, tumor growth increased steadily over a two-week period whereas under circadian-disrupted conditions the growth rate increased by two-fold over the controls (Fig. 2I).

We next took the first preliminary step to elucidate a plausible mechanism by which the host circadian system regulates circadian tumor LA uptake/metabolism, aerobic glycolysis, signaling and growth via melatonin-induced inhibition of 13-HODE formation and the ability of 13-HODE to activate AKT. As a first step, we tested whether a high physiological nocturnal concentration of melatonin would decrease the expression of phospho-Akt (pAKT^s473) via a melatonin receptor-mediated mechanism. A one hour perfusion of tissue-isolated human breast cancer xenografts in situ with rat whole blood containing melatonin (1 nM) resulted in a down-regulation of pAKT^s473 accompanied by a marked reduction in total AKT protein. These effects were prevented by tumor co-perfusion with non-selective MT₁/MT₂ melatonin receptor antagonist S20928 indicating that melatonin-induced down-regulation of pAKT^s473 was melatonin receptor mediated (Fig. 4 A&B) most likely via the MT₁ melatonin receptor [12], [27]. These results are consistent with the postulate that melatonin inhibits LA uptake, 13-HODE formation and proliferative activity in tissue-isolated human breast cancer xenografts via suppression of AKT phosphorylation activity.

Since a physiological nocturnal melatonin concentration, reduces both p-Akt^s473 and 13-HODE formation, we proposed that the elevated production of 13-HODE during the light phase may serve as an important new fatty acid metabolic signaling link to activation of the Warburg effect via its ability to activate AKT in cancer cells. During the dark phase, melatonin may indirectly inhibit the Warburg effect via its suppression of 13-HODE formation and subsequently its ability to stimulate aerobic glycolysis via activating AKT. To test this postulate, xenografts were perfused for one hour in situ with a lower physiological nocturnal concentration of melatonin (500 pM) in the absence or presence of 13-HODE followed by the assessment of pAKT^s473, c-MYC and HIF-1 αexpression. Melatonin down-regulated pAkt^s473 (Fig. 4 C&D), had no effect on c-MYC (Fig. 4 E&F) and up-regulated HIF1-α expression (Fig. 4 G&H). The lack of an acute effect on c-MYC may have been due to the inability of a short perfusion time to influence c-myc gene expression. Melatonin also significantly suppressed tumor cAMP levels, LA uptake, 13-HODE production, the Warburg effect, (e.g., reductions in tumor glucose uptake, lactate release, O₂ uptake and CO₂ production), [³H]thymidine incorporation and DNA content; co-perfusion of melatonin with 13-HODE negated these effects (Tables 1 and 2).