Strain-difference in circadian murine chronotolerance to the antidepressant drug nomifensine

The anti-depressant drug nomifensine (8-amino-1,2,3,4-tetrahydro-methyl-4-phenylisoquinoline) was administered at several dose levels to mice of 2 inbred strains at one of 6 circadian times 4h apart under conditions standardized for light-dark synchronized rhythmometry. A circadian rhythm in tolerance to nomifensine reflected by differences in mortality was demonstrated for both C57 and DBA mice. An interstrain difference in tolerance was also observed.     

Synthetic tools for adrenocorticotropin receptor identification

Biotinylated photoaffinity derivatives of adrenocorticotropin (ACTH) are potentially useful tools for the identification of ACTH receptors. The hormone can be attached covalently to its receptor by photoactivation, and the presence of biotin in the molecule facilitates isolation of the solubilized hormone-receptor complex on columns of immobilized succinoylavidin (Suc-avidin). Six photoprobes of ACTH1-24 have been prepared by reacting ACTH1-24, [25-biocytin]ACTH1-25 amide, and [25-dethiobiocytin]ACTH1-25 amide with either 4- or 5-azido-2-nitrophenylsulfenyl (4-NAPS and 5-NAPS, respectively) chlorides in acetic acid. The homogeneity of the photoprobes was carefully monitored by thin-layer chromatography and amino acid analyses of acid hydrolysates. The presence of underivatized starting material in the photoprobes was critically scrutinized by high-pressure liquid chromatography and was estimated to be less than 0.5%. Both the 4- and 5-NAPS derivatives stimulated maximal steroidogenesis (as compared with ACTH1-24) in calf adrenal cortical cells. However, the potencies of the two isomers differed significantly. The ED50 for steroidogenesis with 5-NAPS-ACTH1-24 was 100-fold greater than the standard (ACTH1-24) while that for 4-NAPS-ACTH1-24 was only approximately 7 times greater. Although 4-NAPS-ACTH1-24 was capable of stimulating maximal adenosine cyclic 3',5'-phosphate (cAMP) production, the 5-NAPS derivative was usually not. The level of stimulation with the 5-NAPS derivative varied considerably from cell preparation to cell preparation. ACTH1-24-induced cAMP production was inhibited by 5-NAPS-ACTH1-24 or 5-NAPS-[25-dethiobiocytin]ACTH1-25 amide.(ABSTRACT TRUNCATED AT 250 WORDS)     

Strain- and sex-dependent circadian changes in abcc2 transporter expression: implications for irinotecan chronotolerance in mouse ileum

Background

ATP-binding cassette transporter abcc2 is involved in the cellular efflux of irinotecan. The drug is toxic for mouse ileum, where abcc2 is highly expressed. Here, we investigate whether circadian changes in local abcc2 expression participate in the circadian rhythm of irinotecan toxicity for ileum mucosa, and further assess whether genetic background or sex modify this relation.

Methodology/Principal Findings

Ileum mucosa was obtained every 3–4 h for 24 h in male and female B6D2F₁ and B6CBAF₁ mice synchronized with light from Zeitgeber Time (ZT)0 to ZT12 alternating with 12 h of darkness. Irinotecan (50 mg/kg i.v. daily for 4 days) was administered at the sex- and strain-specific times corresponding to least (ZT11-15) or largest drug-induced body weight loss (ZT23-03-07). Abcc2 expression was determined with qRT-PCR for mRNA and with immunohistochemistry and confocal microscopy for protein. Histopathologic lesions were graded in ileum tissues obtained 2, 4 or 6 days after treatment. Two- to six-fold circadian changes were demonstrated for mRNA and protein mean expressions of abcc2 in mouse ileum (p<0.05). ZT12 corresponded to high mRNA and protein expressions, with circadian waveforms differing according to genetic background and sex. The proportion of mice spared from ileum lesions varied three-fold according to irinotecan timing, with best tolerability at ZT11-15 (p = 0.00003). Irinotecan was also best tolerated in males (p = 0.05) and in B6CBAF₁ (p = 0.0006).

Conclusions/Significance

Strain- and sex-dependent circadian patterns in abcc2 expressions displayed robust relations with the chronotolerance of ileum mucosa for irinotecan. This finding has strong potential implications for improving the intestinal tolerability of anticancer drugs through circadian delivery.     

Additivity in murine circadian phototransduction

Additivity in the circadian phototransduction system of the mouse has not been tested directly. Because of this, accurate prediction of circadian phase shifts elicited by polychromatic light stimuli cannot be derived from the results of studies using monochromatic light stimuli. This limitation also makes it impossible to deduce the relative contributions of the photoreceptive mechanisms (rods, cones and melanopsin-containing retinal ganglion cells) underlying circadian phototransduction in the mouse. Using nearly monochromatic light stimuli of different spectral composition, and combinations thereof, we demonstrated that murine circadian phototransduction exhibits additivity. Based on the locomotor activity phase shifts elicited by these stimuli, we developed the first quantitative assessment of the relative contributions of conventional and novel photoreceptive mechanisms for circadian functioning in the mouse.     

In-vitro circadian rhythm of murine bone marrow progenitor production

Hematopoietic processes display 24h rhythms both in rodents and in human beings. We hypothesized these rhythms to be in part generated by a circadian oscillator within the bone marrow. The ability of murine bone marrow granulo-monocytic (GM) precursors to form colonies following colony-stimulating factor (rm GM-CSF) exposure was investigated in liquid culture samples obtained every 3 h for a span of up to 198 h. The CFU-GM count varied rhythmically over the first 4 d of culture, with a reproducible maximum in the early morning hours, similar to that observed in vivo. These experiments provide the first evidence that bone marrow progenitors sustain in vitro circadian rhythmicity, and they demonstrate the presence of a circadian time-keeping system within these cells. The results support the potential usefulness of bone marrow cultures for investigating chronopharmacologic effects of anticancer drugs and cytokines on this target system.     

In-vitro circadian rhythm of murine bone marrow progenitor production

Hematopoietic processes display 24h rhythms both in rodents and in human beings. We hypothesized these rhythms to be in part generated by a circadian oscillator within the bone marrow. The ability of murine bone marrow granulo-monocytic (GM) precursors to form colonies following colony-stimulating factor (rm GM-CSF) exposure was investigated in liquid culture samples obtained every 3 h for a span of up to 198 h. The CFU-GM count varied rhythmically over the first 4 d of culture, with a reproducible maximum in the early morning hours, similar to that observed in vivo. These experiments provide the first evidence that bone marrow progenitors sustain in vitro circadian rhythmicity, and they demonstrate the presence of a circadian time-keeping system within these cells. The results support the potential usefulness of bone marrow cultures for investigating chronopharmacologic effects of anticancer drugs and cytokines on this target system.     

Synthetic position 5 analogs of adrenocorticotropin fragments and their in vitro lipolytic activity.

Twenty-three analogs of the ACTH-(4-10)-heptapeptide sequence, which forms the "active core" of adrenocorticotropin (ACTH) and related hormones, have been synthesized by the solid-phase method. These analogs all contain structural modifications at or near the 5-glutamic acid residue of ACTH. The peptides were purified to electrophoretic and chromatographic homogeneity. The peptides were assayed for lipolytic activity in an isolated cell system derived from rabbit adipose tissue. In this system, it was determined that residue 5 plays a very important "spacer" role in the peptide, but that this spacer function is not very dependent on the nature of the side chain of the position 5 amino acid. It was found, however, that a number of analogs containing basic residues (arginine or lysine) in position 3 and/or position 5 of ACTH-(3-10) and ACTH-(4-10) fragments have 5 to 10 times the activity of the respective parent peptides. The presence of a latent anionic locus in the rabbit fat-cell receptor for ACTH is suggested by this study.     

Embryonic development and maternal regulation of murine circadian clock function

The importance of circadian clocks in the regulation of adult physiology in mammals is well established. In contrast, the ontogenesis of the circadian system and its role in embryonic development are still poorly understood. Although there is experimental evidence that the clock machinery is present prior to birth, data on gestational clock functionality are inconsistent. Moreover, little is known about the dependence of embryonic rhythms on maternal and environmental time cues and the role of circadian oscillations for embryonic development. The aim of this study was to test if fetal mouse tissues from early embryonic stages are capable of expressing endogenous, self-sustained circadian rhythms and their contribution to embryogenesis. Starting on embryonic day 13, we collected precursor tissues for suprachiasmatic nucleus (SCN), liver and kidney from embryos carrying the circadian reporter gene Per2::Luc and investigated rhythmicity and circadian traits of these tissues ex vivo. We found that even before the respective organs were fully developed, embryonic tissues were capable of expressing circadian rhythms. Period and amplitude of which were determined very early during development and phases of liver and kidney explants are not influenced by tissue preparation, whereas SCN explants phasing is strongly dependent on preparation time. Embryonic circadian rhythms also developed in the absence of maternal and environmental time signals. Morphological and histological comparison of offspring from matings of Clock-Δ19 mutant and wild-type mice revealed that both fetal and maternal clocks have distinct roles in embryogenesis. While genetic disruptions of maternal and embryonic clock function leads to increased fetal fat depots, abnormal ossification and organ development, Clock gene mutant newborns from mothers with a functional clock showed a larger body size compared to wild-type littermates. These data may contribute to the understanding of the ontogenesis of circadian clocks and the risk of disturbed maternal or embryonic circadian rhythms for embryonic development.     

Membrane-associated proteins of adriamycin sensitive and resistant murine leukemic P388 cells

We have isolated an 84-fold adriamycin resistant subline, P388/R84, from mouse leukemia P388 cells by serial cultivation in methylcellulose in the presence of increasing drug concentrations. Electrophoresis of detergent soluble fractions of radiolabeled sensitive and resistant cells suggested marked alterations in the protein fractions of 160, 100, 60, 45, and 30 kd. In resistant clones labeled with 125I an increase in 160 and 100 kd proteins was accompanied by concomitant reduction in the 60, 45, and 30 kd proteins. In 35S methionine-labeled resistant cells, similar increases in the 160 and 100 kd components were observed but in contrast to 125I-labeled cells the 30 kd component was also higher. Alterations in surface proteins were confirmed in experiments where the cell extracts were adsorbed to concanavalin A polymers and extracted with 0.26 M methyl-alpha-D-mannopyranoside. Our data confirm earlier reported observations on cell-surface protein changes in cells resistant to anthracyclines and alkaloids.     

In vivo liver and lung targeting of adriamycin encapsulated in glutaraldehyde-treated murine erythrocytes

Treatment of adriamycin-loaded erythrocytes from B6D2F1 mice with 0.1% glutaraldehyde produced the following effects: a considerable decrease in the in vitro leakage of the unmodified drug and a selective liver (and, to a lesser extent, lung) uptake of the encapsulated drug (70% of the injected dose) compared to drug leakage from, and tissue distribution of, carrier erythrocytes not treated with glutaraldehyde. The liver vascular bed was not saturated by five daily intravenous injections of 20 microliters of glutaraldehyde-treated erythrocytes, which allows a total dosage of 200 micrograms of the drug (half the LD50 value) to be administered. No appreciable liver damage results from extensive and prolonged uptake of glutaraldehyde-treated carrier erythrocytes. Entrapment of adriamycin within erythrocytes along with glutaraldehyde treatment of the carrier cells seems to be a promising therapeutic strategy against liver (and lung) tumors.     

Synthetic lipopeptide analogs of bacterial lipoprotein are potent polyclonal activators for murine B lymphocytes

The lipoprotein from the outer membrane of Escherichia coli and other Enterobacteriaceae is a potent polyclonal activator for B lymphocytes. To determine the molecular structure responsible for the biologic activity of lipoprotein, a well-defined series of analogs of its N-terminal part was synthesized: S-(2,3-bis(palmitoyloxy)-(2-RS)-propyl)-N-palmitoyl-(R)-cysteine, -cysteine methyl ester, -cysteinyl-serine, -cysteinyl-seryl-serine, -cysteinyl-seryl-seryl-asparagine, and -cysteinyl-seryl-seryl-asparaginyl-alanine. All compounds were tested for mitogenic activity toward spleen cells from BALB/c, LPS-non-responder C3H/HeJ, and congenitally athymic C3H/Tif/Bom/nu/nu mice, measuring the incorporation of [3H]thymidine into DNA. Lymphocyte activation was confirmed by determination of the incorporation of [3H]uridine into RNA and [3H]leucine into protein. The synthetic lipopeptides were also investigated for their ability to stimulate B lymphocytes into immunoglobulin secretion, as shown by a hemolytic plaque assay. Throughout our studies, the compounds carrying two to five amino acids exhibited strong stimulation activity toward B lymphocytes comparable to native lipoprotein. In contrast, products containing only one amino acid, cysteine or cysteine methyl ester, were only marginally active, indicating that to obtain full biologic activity the presence of the hydrophilic dipeptide structure is necessary. All compounds exhibited only a marginal effect on thymocytes. Thus, a series of defined synthetic fragments of a bacterial outer membrane component exhibits a pronounced mitogenic and polyclonally stimulating activity towards B lymphocytes. The substances will be valuable tools for more detailed investigations on the molecular mechanisms of B cell activation.     

Western diet affects the murine circadian system possibly through the gastrointestinal microbiota

Consumption of a high-fat diet characteristic of human Western diet has been shown to affect the circadian system of laboratory rodents. The present study confirms an effect of Western diet on the circadian system of mice, specifically a shortening of the free-running circadian period of running-wheel activity, in addition to increased weight gain. Decimation of the gut microbiota by broad spectrum antibiotic treatment reversed the effect of Western-diet feeding on the free-running period, which suggests that the effect of Western-diet feeding on the circadian system is mediated by the gastrointestinal microbiota. This finding is particularly relevant in view of recent studies describing a relationship between gut microbes, circadian clock function, and obesity.     

Level of protein kinase C activity correlates directly with resistance to adriamycin in murine fibrosarcoma cells

In this report, we demonstrate a direct correlation between protein kinase C (PKC) activity and adriamycin (ADR) resistance in mouse fibrosarcoma cells. PKC activity was measured in four murine UV-2237M fibrosarcoma cell lines that differed in the degrees to which they expressed resistance to ADR, which is an inhibitor of PKC. A comparison of the four cell lines revealed a positive correlation between the level of PKC activity and resistance to ADR. Incubation of the cells with the PKC inhibitor H-7 produced a partial reversal of ADR resistance. Taken together, these results suggest a role for PKC in the mechanism of ADR resistance.     

Circadian rhythms in murine pups develop in absence of a functional maternal circadian clock

A genetic approach was used to investigate whether the emergence of circadian rhythms in murine pups is dependent on a functional maternal clock. Arrhythmic females bearing either the mPer1Brdm1/Per2Brdm1 or mPer2Brdm1/Cry1-/- double-mutant genotype were crossed with wild-type males under constant darkness. The heterozygous offspring have the genetic constitution for a functional circadian clock. Individual pups born to arrhythmic mPer1Brdm1/Per2Brdm1 and mPer2Brdm1/Cry1-/- mothers in constant darkness without external zeitgeber developed normal circadian rhythms, but their clocks were less synchronized to each other compared to wild-type animals. These findings indicate that development of circadian rhythms does not depend on a functional circadian clock in maternal tissue, extending previous findings obtained from pups born to SCN-lesioned mothers.     

Estimation of circadian variations in cell cycle phase durations in murine epidermal basal cells

Circadian variations in the proliferative activity of squamous epithelia are well known. However, circadian variations in the duration of the various cell cycle phases (S, G2 and mitosis) have been disputed. The percent labelled mitoses method, which is traditionally used to obtain duration of cell cycle phases, is poorly suited for identification of circadian variations. Therefore methods combining changes in compartment size (cell cycle phase) and cellular flux through the compartments have been used. Three different methods using such data are presented. These incorporate various simplifying assumptions that cause methodological errors. Limits for use of the different methods are indicated. The use of all three methods gives comparable and pronounced circadian variations in the duration of S and G2 phase. These results are also compatible with circadian variations in the mitotic duration, but they may also represent artefacts due to sensitivity to model errors.     

In vitro evaluation of the chemosensitivity of an experimental murine leukemia rendered resistant in vivo to adriamycin

The results obtained using a rapid assay for in vitro chemosensitivity detection of leukemias are presented. The assay, performed according to the technique already described, involves in vitro incubation of a tumor cell suspension with various concentrations of antitumor drugs for 1 h and evaluation of drug-induced cell damage by addition to the cultured cells of 125I-deoxyuridine 48 h after pharmacological treatment. Results are expressed as percent inhibition of the isotope incorporation with respect to untreated controls. Preliminary results demonstrated that this assay is able to evidence differential chemosensitivity exhibited in vivo by murine leukemias. The present study reports the results obtained using comparatively P388 and P388/ADR, a subline of P388 murine leukemia with acquired resistance to Adriamycin in vivo. We found that P388/ADR exhibited resistance to ADR and DNR at all the concentrations tested, whereas P388 was highly sensitive. Cross-resistance of P388/ADR was also found to some structurally dissimilar agents, i.e. VCR and Act-D. These in vitro results correlate well with much data in the literature concerning the characteristics of resistance and cross-resistance exhibited in vivo by P388/ADR. These results suggest the possibility of using a similar in vitro assay for predicting the in vivo drug resistance of human leukemias.