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SLEEP AND TEMPERATURE REGULATION

Circadian rhythm disorganization produces profound cardiovascular and renal disease in hamsters

¹University Health Network, Toronto, Ontario; ²Heart and Stroke/Richard Lewar Centre for Cardiovascular Excellence, ³Departments of Physiology, Medicine, and Psychology, and ⁴Centre for Biological Timing and Cognition, University of Toronto, Ontario, Canada

Submitted 16 November 2007 ; accepted in final form 12 February 2008

	ABSTRACT

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Sleep deprivation, shift work, and jet lag all disrupt normal biological rhythms and have major impacts on health; however, circadian disorganization has never been shown as a causal risk factor in organ disease. We now demonstrate devastating effects of rhythm disorganization on cardiovascular and renal integrity and that interventions based on circadian principles prevent disease pathology caused by a short-period mutation (tau) of the circadian system in hamsters. The point mutation in the circadian regulatory gene, casein kinase-1, produces early onset circadian entrainment with fragmented patterns of behavior in +/tau heterozygotes. Animals die at a younger age with cardiomyopathy, extensive fibrosis, and severely impaired contractility; they also have severe renal disease with proteinuria, tubular dilation, and cellular apoptosis. On light cycles appropriate for their genotype (22 h), cyclic behavioral patterns are normalized, cardiorenal phenotype is reversed, and hearts and kidneys show normal structure and function. Moreover, hypertrophy does not develop in animals whose suprachiasmatic nucleus was ablated as young adults. Circadian organization therefore is critical for normal health and longevity, whereas chronic global asynchrony is implicated in the etiology of cardiac and renal disease.

circadian; diurnal; tau hamsters; heart disease; renal disease; suprachiasmatic nucleus

Circadian rhythm disruption also has been linked with reduced longevity in golden hamsters carrying the circadian period mutation, tau (11). The mutant allele reduces the circadian period from 24 h in the wild type to 22 h in tau/+ heterozygotes (20). Importantly, it is the heterozygotes whose longevity is compromised. When these animals are entrained by 24-h light-dark (LD) cycles, they exhibit phase-advanced onsets of nocturnal behavior with significant fragmentation of diurnal activity (18). Conversely, longevity is increased in aged animals whose disturbed rhythms are reconsolidated by successful grafting of hypothalamic tissue containing the suprachiasmatic nucleus (SCN) (11). Nonetheless, other than the changes in rhythm integrity, the mechanisms underlying the effects on life expectancy have not been explored. Therefore, despite the acknowledged importance of rhythms in health and disease, there are virtually no experimental data prospectively demonstrating a causal link between circadian dysregulation and organ pathology. In this study, we hypothesize that altered circadian organization plays a role in genesis of severe cardiac and renal disease, leading to early death in +/tau mutant hamsters.

	MATERIALS AND METHODS

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Animal housing and locomotor behavior recording. All animals are housed at the University of Toronto zoology animal facility. This investigation conforms to the Guide for Care and Use of Laboratory Animals published by the United States National Institutes of Health (NIH Publication No. 85–23, revised 1996), and is approved by the Canadian Council on Animal Care. The hamsters (Mesocritetus auratus; tau) have been maintained in the breeding colony in a LD 14:10 cycle since 1991, and the colony is outbred every second generation with a wild type obtained from Charles River Laboratories. Activity is recorded from individual cages equipped with running wheels as required using the Dataquest II data acquisition system coupled with ActiView Biological Rhythm Analysis version 1.2 (Minimitter, Bend, OR). Genotype is confirmed by PCR analysis of the casein kinase 1 epsilon gene.

SCN ablation. Electrolytic lesions of the SCN are produced using electrodes aimed at the SCN placed stereotaxically on midline under deep pentobarbital anesthesia. Coordinates are as follows: anterior position +0.6 mm from bregma and –0.8 mm from dura. Lesions are small, and nearby structures (medial preoptic nucleus; subparaventricular zone, optic chiasm) are spared. Placement is verified by the lack of 24-h rhythmicity in subsequent behavioral records and by histological examination.

Echocardiography. Echocardiography is performed in a blinded manner on all hamsters at 4 and at 17 mo of age. All animals are housed on a 24-h LD cycle (14:10) throughout, or for those on alternative cycles they are returned to LD 14:10 3 wk before final cardiovascular assessments. Animals are anesthetized with 2% isoflurane gas delivered through a nose cone and are maintained at a body temperature of 37°C using a heating pad. Transthoracic echocardiography is performed with Sequoia (Acuson, Mountain View, CA) using a 13-MHz linear array probe. Two-dimensional M-mode images are acquired while the animal is in a semiconscious state (0.75% isoflurane) using High Resolution Zoom with a sweep speed of 200 mm/s, from the short axis view at the papillary muscle level. Measurements include left ventricular (LV) end-diastolic (LVEDD) and end-systolic (LVESD) diameter, LV diastolic anterior and posterior wall thickness, percent fractional shortening (%FS), and heart rate.

Hemodynamic studies. In vivo hemodynamic measurements are performed in a blinded manner on animals anesthetized with 1.5% isoflurane gas. Body temperature and heart rate are continuously monitored and maintained. The right common carotid artery is exposed and cannulated using a 1.4-Fr. microtip catheter (Millar), which is then fed to the proximal aorta and left ventricle for respective measurements. Data are acquired using the MP100 hardware imaging system and analyzed using Acqknowledge version 3.7.3 (Biopac Systems). Data are analyzed for aortic systolic and diastolic blood pressure, mean arterial blood pressure, LV pressure measurements [LV end-systolic and end-diastolic (LVEDP) pressure], and the maximum (LVdP/dt_max) and minimum first derivatives of LV pressure.

Histology and pathological assessment of hamsters. Animals are anesthetized and killed, and tissues were collected. For histological assessment, tissues are fixed in 10% formalin and paraffin-embedded. Heart sections taken at the level of the papillary muscle are stained with hematoxylin and eosin (H&E; Sigma), Massons trichrome, or Picrosirius red (PSR; Fluka). Kidney sections are stained with H&E, PSR, or Period acid-Schiff. We determined in a blinded manner the general tissue morphology, myocyte cross-sectional area, and extent of interstitial fibrosis. Sections are digitally imaged using the Nikon microphot-FXA microscope, along with the Nikon ACT-1 version 2.62, or ImageJ 1.33u (National Institute of Health) software.

Electron microscopy glomerular analyses. Glomerulosclerosis, tubular hyperplasia, and renal fibrosis are assessed using pathological cross sections. For electron microscopy of renal glomeruli, kidneys are fixed in buffered 1% glutaraldehyde-4% formaldehyde, postfixed in 1% osmium tetroxide, and embedded in Epon-araldite. Ultrathin sections stained with uranyl acetate and lead citrate are examined using a transmission electron microscope (1200EX-II; Jeol Peabody).

In situ end labeling assay (terminal uridine deoxynucleotidyl transferase dUTP nick end labeling). DNA-damaged cells are detected by terminal uridine deoxynucleotidyl transferase dUTP nick end labeling (TUNEL) assay, adapted to an automated in situ hybridization instrument (Discovery Ventana Medical Systems, Tucson, AZ). We use 5-µm-thick deparaffinized tissue sections, digestion with Protease I (Ventana Medical), recombinant terminal deoxynucleotidyl transferase (GIBCO-BRL), and Biotin 16-dUTP (Roche Diagnostics), in accordance with well-established protocols. Colormetric visualization uses avidin-horseradish peroxidase and 3,3'-diaminobenzidine, with hematoxylin counterstain.

Immunohistochemistry. Immunohistochemistry for CD3 (Dako, Carpinteria, CA) is performed on the NEXES autoimmunostainer (Ventana Medical Systems) at a dilution of 1:200, in accordance with the manufacturer's specifications. Immunodetection is carried out using a 1:100 dilution of biotinylated anti-rabbit IgG (Vector Laboratories, Burlingame, CA) and the Ventana 3–3'-diaminobenzidine detection system. Tissue sections are heated before immunostaining, blocked with endogenous biotin (Ventana Avidin/Biotin Block), and finally counterstained with hematoxylin.

Proteomics and mass spectrometry: protein analyses, SDS-PAGE, trypsin digestion, and electron spray ionization in an LCQ DECA XP ion trap mass spectrometer. Protein content of each sample is determined using the Bradford Assay method (Bio-Rad Laboratories). Urinary protein content is analyzed on 10–20% tricine gels (Invitrogen) stained with Coomassie dye for 20 min. Selected bands are prepared for mass spectrometry/mass spectrometry (MS/MS) by excision from the gel and digested overnight in 50 µl buffer containing 50 mM HN₄HCO₃, 10% acetonitrile, and 10 ng/µl sequencing-grade trypsin (Roche). The MS/MS analysis of tryptic peptides is performed using a LCQ DECA XP ion trap (Thermo Finnigan). Buffer A for liquid chromatography contains 0.1% formic acid, and buffer B contains 99.9% acetonitrile and 0.1% acetic acid. Samples are injected at a rate of 10 µl/min on a Vydac reverse-phase column (0.2 x 150 mM; Grace Vydac, Hesperia, CA) over 5 min in 5% buffer B using an Agilent 1100 Series CAP-LC. Peptides are eluted over a 10–65% buffer B gradient for 40 min at a rate of 2 µl/min for detection by LCQ DECA XP mass spectrometry. Data analysis is performed by Sequest (Lisle, IL) software with raw files searched against hamster, murine, and human databases on NCBI (www.ncbi.nlm.nih.gov/). Positive identifications are made when two or more peptides with Xcorr > 2.5 (+2 ions) or 3.7 (+3 ions) match to the same protein. Protein identification is validated as required, using Western blot analysis on nitrocellulose membrane and chemiluminescent detection (Amersham Biosciences).

Plasma biochemistry and kidney function analysis. Blood samples are collected from anesthetized hamsters at zeitgeber 1–16, and 200 µl of plasma are used for measurement of plasma Na⁺, K⁺, Cl^–, ionized Ca (Ca²⁺), lactate, glucose, urea, and creatinine using a Stat Profile M7 Analyzer (Nova Biomedical, Waltham, MA).

Statistical analyses. Data are expressed as means ± SE. Statistical comparisons are made either by use of the independent Student's t-test for comparing individual groups or by one-way ANOVA followed by Tukey's multiple test for comparisons of more than two groups. Analysis is performed using SPSS statistical software (version 12.0.0). Results of P < 0.05 are considered statistically significant.

	RESULTS

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We postulated that chronic circadian disorganization like that seen in tau/+ animals on 24-h LD cycles results in pervasive physiological impairments leading to an early demise. To test this, we focus specifically on the cardiovascular system where robust diurnal or circadian cycling of gene expression already has been shown (14, 21, 23, 24) and wherein a pathological effect of rhythm disturbance has been implicated in human beings (7, 16). All animals are genotyped using an ear tip for DNA analyses (genotyping; Fig. 1A) and phenotyped using conventional behavioral analyses [tau/+ (Fig. 1B, left) and wild types (Fig. 1B, right)].

View larger version (55K): [in this window] [in a new window]   Fig. 1. Development of profound cardiac hypertrophy in hamsters carrying the circadian period mutation (tau/+). A: representative genotype vs. circadian phenotype shows wild type (wt), tau/+, and tau/tau hamsters analyzed for the mutation in the casein kinase-1- (ck1), on 1% ethidium bromide (EtBr) agarose gel analysis. B: representative phenotype by activity analysis shows earlier-onset and fractured activity pattern in tau/+ hamsters (left) entrained to a 14:10-h light-dark (LD) cycle and a reduced 22- circadian period in total darkness (DD; <4 lux) compared with wt (24 h, right). C: representative images of hearts from tau/+ show extensive pathology, widespread myocyte hypertrophy (C, left Masson's trichrome), and myocardial fibrosis (C, right Picrosirius red). D: representative images from wt hearts (D, left and D, right) shown at the same magnification, which have no obvious signs of pathology. E: digital quantification demonstrates significant myocardial fibrosis (n = 10, P < 0.01) in tau/+ heart. F: increased myocyte cross-sectional area (MCSA) (n = 40, P < 0.05) in tau/+ hearts. G: increased heart weight in tau/+ animals. H: heart-to-body weight ratio consistent with development of gross cardiac hypertrophy. Values are listed in Tables 1–3.

We then exclude the possibility that the cardiac phenotype in the tau/+ animals is the result of a pleiotropic gene effect. Consistent with this notion, cardiopathology was restricted to the heterozygotes. The homozygous tau/tau hamsters (period = 20 h) retain consolidated patterns of behavior, are unable to synchronize with 24-h days (and thus do not show the same circadian dysregulation as the tau/+ hamsters do), and importantly, do not develop pathology nor declining cardiac function like heterozygotes. Furthermore, young tau/+ hamsters (4 mo of age and easily assessed by actigraphy) appear healthy, with all cardiovascular parameters including cardiac pathology, hemodynamics, and echocardiography similar to the wild types (Table 2, also see Fig. 4 below). Although this does not definitively disclude congenital conditions, they are certainly not obvious. Moreover, it suggests the cardiomyopathy that develops in tau/+ animals does so only over an extended period of circadian dysregulation. In the aggregate then, abnormal circadian entrainment appears to act as a procardiomyopathic stimulus, and the heart decompensates over time.

View larger version (54K): [in this window] [in a new window]   Fig. 4. Rescue of circadian disturbance protects against the cardiac disease phenotype. A: representative locomotor activity showing a tau of 22 h for tau/+ in 12:10 LD. B: normal cardiac histological sections from aged tau/+ maintained on a phenotype-appropriate 22-h LD; these animals exhibit healthy myocardium (Masson's trichrome). C: renal pathology is also normal, as shown here from aged tau/+ maintained on a phenotype-appropriate 22-h LD cycle (Periodic acid stain). D: renal histological sections from aged tau/+ on 22-h LD, further revealing no evidence of fibrosis or collagen deposition; the kidneys appear normal (Picrosirius red). E-H: cardiac indexes in aged tau/+ maintained in 22-h LD. E: normal left ventricular end-diastolic dimensions (LVEDD, mm) in 22 h tau/+ at 17 mo of age. F: normal left ventricular end-systolic dimensions (LVESD, mm) in 22 h tau/+ at 17 mo of age. G: normal mean arterial blood pressure (MABP, mmHg) with no evidence of hypotension in 22 h tau/+ at 17 mo of age. H: %fractional shortening (%FS) in 22 h tau/+ revealing normal contractility, consistent with hemodynamic and morphometric parameters. All phenotypes tested are shown, with black lines = 22 h tau/+, red = 24 h tau/+, blue = tau/tau, and green = wt. Results are plotted as means ± SE at 4 and 17 mo of age (see Tables 1–3 for data). Plasma and/or urinary biochemistry levels remain normal in tau/+ maintained on the 22-h LD cycle compared with the abnormal levels for tau/+ on 24-h LD (as in Fig. 3A and Table 3). *P < 0.01 evaluated by ANOVA.

View larger version (127K): [in this window] [in a new window]   Fig. 2. The tau/+ have severe heart disease and evidence of underlying kidney disease. Renal pathology in tau/+ (left) vs. wt (right), showing tubular dilatation in tau/+ kidney (Periodic acid stain; A), and widespread fibrosis with collagen deposition in tau/+ kidney (Picrosirius red) (B). C: electron microscopy shows glomerular ischemia but no evidence of immune-type deposits in tau/+ kidney. This is consistent with development of primary renal disease and helps exclude infection or autoimmune activity as cause.

View larger version (39K): [in this window] [in a new window]   Fig. 3. Mass spectrometry proteomics and apoptosis in tau/+ kidneys. A: proteinuria in tau/+ urine by 17 mo of age (open bars = 4 mo, filled bars = 17 mo of age). B: representative urine samples analyzed by gel electrophoresis revealing the presence of both high- and low-molecular-mass proteins in the tau/+ urine. First lane is marker, and subsequent lanes represent different animals. Arrow top right is albumin, arrow on bottom right points to an 15-kDa protein band appearing characteristically in urine of tau/+ animals. This band is excised, trypsin digested, and subject to mass spectrometry (MS) analyses. C: representative MS/MS spectrum for the 15-kDa band, identified by MS as cytochrome c, a marker of apoptosis. D: terminal uridine deoxynucleotidyl transferase dUTP nick end labeling (TUNEL) staining revealing apoptosis in tau/+ mutant kidney (n > 3). Apoptosis was detected in kidney sections taken from the aging tau heterozygote hamsters. Apoptosis was not detected in age-matched wild-type kidney sections. Inset, positive control using murine thymus.

We then test the notion that circadian rhythm disruption alone can be responsible for the abnormal cardiorenal phenotype by maintaining tau/+ hamsters from 4 mo of age (a time at which heart disease is not yet evident). In one experiment, we raise animals in a phenotype-appropriate 22-h LD cycle (12:10). We retained 10 h of darkness to ensure that a consolidation of nocturnal-type behavior is not an artifact of exposure to very short nights. Behavioral analysis demonstrates that temporal profiles in tau/+ are similar in 12:10 LD as in total darkness where the endogenous period of ca. 22 h is expressed (Fig. 4A). At 17 mo of age, animals are reexamined, and remarkably the abnormal cardiac and renal phenotypes are both completely absent. This is confirmed by gross morphology, histopathology, plasma biochemistry, urinalysis, and cardiac function using echocardiography and in vivo hemodynamics. Thus all measurements taken from the tau/+ group on 22-h days are similar to the wild type and are statistically and "clinically" different from the tau/+ group raised on 24-h days (for pathology see Fig. 4, B-D; for pathophysiology see Fig. 4, E-H; data for 22 h tau/+ are listed in Table 1).

In a second experiment, we ablate the SCN, thereby removing the influence of the master circadian oscillator over the peripheral oscillators in heart and kidney. Physiological parameters were not measured in these animals, since the circadian phase of cardiovascular rhythm cannot be determined. However, heart weight-to-body weight ratios are significantly higher in tau/+ than wild-type animals held in the 14:10 LD condition, as expected. However, arrhythmic SCN-lesioned tau/+ animals have significantly lower ratios than the intact tau/+ animals and are not different from the wild type (Fig. 5).

View larger version (22K): [in this window] [in a new window]   Fig. 5. Suprachiasmatic nucleus (SCN) lesions prevent or reverse circadian rhythm-related cardiac hypertrophy. The SCN in young adult hamsters (6 mo of age) carrying the tau mutation (+/tau) are electrically ablated, and then animals are maintained in a 14:10 LD cycle thereafter. When animals are close to death as determined by animal care staff, they are removed and killed, and the heart-to-body weight ratio (HW/BW) is determined. Control animals are wt and intact tau/+ housed side by side in the same lighting conditions; n = 6/group. A: HW/BW ratios for wt, +/tau (intact), and +/tau (SCN ablation). The effectiveness of SCN lesions are verified by the lack of rhythmic wheel running behavior. B: actogram showing the immediate (4 mo) and long-term (16 mo) result of the lesion. Animals are housed in 14:10 LD following surgery.

	DISCUSSION

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It is important to recognize that the key factor in producing cardiovascular disease may not be disruption of the tissue molecular clock per se but the global disturbance or desynchrony that results from the presence of oscillators that are attempting to operate at two distinct periods. That is, in the tau/+ heterozygotes, rhythms in peripheral tissues are being produced not only by the intrinsic 22-h molecular oscillator but also by 24 h signals from the SCN, which is being driven by the LD cycle. When the SCN is influenced by a 22-h LD cycle, cardiovascular disease does not develop, as our data show.

The alternative, that the mutated casein kinase epsilon gene causes the cardiorenal pathology, seems unlikely. Reversal of disease phenotype following manipulations by circadian principles would not be likely if it was a gene effect, nor would disease pathophysiology be confined to the heterozygote phenotype. The rationale is best illustrated both by the pathological findings and also the physiological parameters represented in Fig. 4. These show that it is only the tau/+ animals, and only those aged in the desynchronous 24-h environment, that develop cardiorenal disease. Additional support comes from when tau/+ hamsters are influenced by constant light; longevity is similar to the wild type (7). Finally, we further show here that, when the SCN is ablated in tau/+ heterozygotes, the influence of the SCN is removed, and presumably the peripheral oscillators become free to operate at their intrinsic period defined by their molecular clock. Thus, collectively, the findings in this study show that, in the absence of the SCN, the peripheral oscillators are free to operate as though they are in constant conditions. In the presence of disruptive signals from the SCN, this disturbs organ structure and function, producing cardiorenal disease and leading to reduced longevity.

The downstream biochemical effects of clock disruption in heart and kidney are not defined. As yet, we have only embryonic knowledge of the steps by which clock time is actually translated into the molecular events that control cell structure and function and, in particular, in the cardiorenal system. One possible candidate link is through perturbation of the glycogen synthase kinase-3β (GSK3β) system; it plays an important regulatory role in cardiac hypertrophy through the stabilization or degradation of β-catenin via ubiquitination and the 26S proteasome (1, 8–10). We speculate on the GSK3β molecule as one potential avenue for future investigation, since it has also most recently been reported to be involved in modulation of the circadian molecular clock pathways; however, further investigation is beyond the scope of this study. Additional and possibly congruent pathways may involve the cardiomyocyte clock and myocardial metabolism, as is being pursued by others (4). Finally, we recently report that circadian rhythm disruption exacerbates preexisting heart disease in a murine model of pressure overload hypertrophy (15), mediated in part by altered rhythmic gene expression. It is also likely that altered autonomic bias, and especially cardiac sympathetic tone, and cycling of neurohormones relevant to the cardiovascular system play a role; these clearly warrant future investigation. Further support of this notion of an autonomic bias or possibly even sympathetic neurotransmitters acting on cardiomyocytes has been suggested by studies using myocyte culture in vitro (3). Moreover, neuro/hormonal factors are also implicated as major contributors to the circadian timing of onset of adverse cardiovascular events such as myocardial infarction and sudden cardiac death. Thus, taken together, our findings support the notion that, not only is physiology rhythmic, but they furthermore illustrate that the processes that trigger compensatory changes in cardiovascular disease are rhythmic as well.

Circadian coordination of daily physiology is critical to the integrity of peripheral organs such as the heart and kidney. The results of these studies suggest that the long-term disruption of circadian rhythms, for example in shift workers, transoceanic flight attendants, or patients with sleep disturbances, can ultimately result in heart and kidney disease. These results have enormous implications for public health and the pathogenesis of cardiac and renal disease; they indicate that maintaining normal circadian rhythms may be an important long-term lifestyle measure for the prevention of these diseases.

Perspectives and Significance

Circadian rhythmicity has been extensively characterized at the level of the SCN, followed by recent investigations that add focus to the peripheral system. It is widely suggested that circadian rhythms of behavior and physiology play a crucial role in integrative physiology, and concomitant organ health and integrity. The cardiovascular system is of particular interest as downstream target of circadian regulation, as has been indicated in numerous epidemiological and clinical physiology reports. We now demonstrate experimentally that normal cardiac physiology, and conversely development of cardiac pathophysiology, may be explained by coincidence between internal and external circadian cues. This is shown in tau/+ hamsters, in which there is desynchrony between the 22-h internal endogenous clock system and entrainment to the external 24-h LD environment. Furthermore, these data support the very recent notion demonstrated using algae and plants (13, 17, 22) that circadian regulation is integral to the fitness and growth of an organism. Thus this study shows that circadian dysregulation (desynchrony between the internal circadian clock system and entrainment to normal LD) can play an etiological role in the development of cardiac disease.

	GRANTS

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This work was supported by the A. Ephriam and Shirley Diamond Cardiomyopathy Research Fund, a grant from the Heart and Stroke Foundation of Ontario (T4479) to M. J. Sole and a grant from the Natural Sciences and Engineering Research Council of Canada to M. R. Ralph.

	ACKNOWLEDGMENTS

 
We thank Dr. Z. Jia, J. Chalmers, O. Rawashdeh, and K. Varano for technical assistance.

Present address for M. R. Ralph: Centre for Biologic Timing and Cognition, Department of Psychology, SSH 4017, University of Toronto, Ontario, Canada (e-mail: ralph.mr{at}gmail.com).

	FOOTNOTES

 

Address for reprint requests and other correspondence: M. J. Sole, 4N-488 Toronto General Hospital, 585 Univ. Ave., Toronto, Ont., Canada M5G 2N2 (e-mail: michael.sole{at}uhn.on.ca)

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

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