Circulating CALLA-positive lymphocytes exhibit circadian rhythms in man

Circadian rhythm of cell division

The existence of circadian oscillations in the level of hormones, in numerous physiological parameters, in toxicity and in behavior is now fully recognized in all living organisms. In contrast, the synchronisation and regulation of cell proliferation by circadian rhythms in vivo is only starting to be appreciated. This article reviews the experimental evidence for circadian synchronisation of cell division in different mammalian tissues (mainly the gastro-intestinal tract and hemapoietic system), including tumoral tissues. The possible causes of this coupling of the cell cycle phases to the circadian rhythm are discussed. Testing of novel antitumour agents using murine models should take into consideration the temporal difference between murine and human circadian control of proliferation (the peak of DNA synthesis occurs during the activity period, i.e. during daytime in man, and at night-time in mice and rats). Experimental and clinical data clearly support the important implications of the circadian control of the cell cycle in the optimisation of cancer chemotherapy, both for reducing toxicity and increasing the antitumour effects.

Variation in cell yield and proliferative activity of positive selected human CD34+ bone marrow cells along the circadian time scale

Variations in cell yield and proliferative activity of human bone marrow (BM) progenitor cells were determined with flow cytometry along the 24-h (circadian) time scale. Equal volumes of BM were aspirated every 5 h, altogether 5 times in 5 healthy men. An average 6-fold higher yield of positive selected CD34+ cells occurred in each subject when BM was aspirated during the daytime and late afternoon, while a lower yield occurred during the night. Using all CD34+ cell yield data normalized to percentage of mean, a significant time-effect was found by ANOVA (p = 0.02) and a significant circadian rhythm was detected by the least-squares fit of a 24 h cosine (p = 0.02). The 95% confidence limits of the acrophase (time of highest values) were computed to be at midday between 10:24 and 14:48 h. A highly significant correlation (p = 0.001) was found between proliferation of positive selected CD34+ cells and the more mature myeloid precursor cells from the same BM aspirates, suggesting a common temporal pattern along the circadian time scale. However, no correlation was demonstrated between proliferation and cell yield of CD34+ selected cells, suggesting that mechanisms other than variation in proliferation may cause the circadian rhythm in stem cell yield. These circadian variations in stem cell yield and proliferation suggest that proper timing within 24 h may potentially be important regarding outcome from progenitor cell harvesting and treatment with haematopoietic growth factors.

Persistent T lymphocyte rhythms despite suppressed circadian clock outputs in rats

Circadian rhythms in circulating leukocyte and lymphocyte counts persisted with halved amplitudes in constant light (LL) of 300 lx intensity for 8 wk, whereas circadian rhythms in body temperature, locomotor activity, and plasma catecholamines were completely suppressed. Subsequent exposure to constant darkness (DD) normalized all circadian rhythms within 2 wk. Rhythms in circulating T lymphocyte subsets were studied in LL or DD using double labeling with monoclonal antibodies and flow cytometry. Circadian rhythms were suppressed for leukocytes and lymphocytes but were maintained for both T helper cells (Th) and T cytotoxic cells (Ts) lymphocytes after 11 wk in LL. A group 24-h rhythm was only validated for total lymphocytes after 16 wk in LL. However, individual total, Th, and Ts lymphocytes maintained their usual respective phase relationships in each rat. The alteration of immune cell circulatory rhythms likely stemmed from a progressive loss of circadian synchronization among rats kept in LL. Conversely, after 11 or 16 wk in DD, leukocytes and lymphocyte subsets circadian rhythms were maintained. Thus catecholamines do not drive circulatory T cell rhythms. The loss of coupling between T lymphocyte rhythms and three major outputs of the circadian system further supports the hypothesis of an independent immunologic oscillator.

Timed treatment of the arthritic diseases: a review and hypothesis

Evidence has been accumulating regarding the importance of biological rhythms in the diagnosis and treatment of a variety of diseases and disorders. Increasingly, the arthritides have shown statistically quantifiable rhythmic parameters. Included in the latter group are joint pain and joint size. In addition, a number of drugs used to treat rheumatic diseases have varying therapeutic and toxic effects based on the time of day of administration. Among these drug classes are nonsteroidal antiinflammatory drugs, glucocorticoids, and a number of cytostatic agents. In the last group of agents, experience in treating malignant disease suggests that time-specified treatment may reduce the toxic effects of low-dose cytostatic treatment of rheumatoid arthritis (RA) and related diseases. This article reviews that evidence and suggests a rationale for the timed treatment of RA with methotrexate.

Effect of enkephalins on bone marrow cells

Mouse bone marrow cells were incubated with methionine- or leucine-enkephalin (10(-15)-10(-6) M) before seeding into soft agar cultures. In marrow samples harvested at different times, enkephalins decreased GM colony count on average by 30-40%. In individual experiments, however, the same concentration of enkephalins caused even stimulation, or at other times had effect. In view of the circadian periodicity of neuroendocrine functions and hematopoietic activity, the enkephalin effect on bone marrow cells was tested on marrow samples harvested at fixed time points (6 am, 6 pm), using enkephalin concentrations in the physiological range (10(-12)-10(-9) M). The seeding efficiency of the 6-pm cell population was on average 50% above that of the 6-am population. The 6-pm cell population was also more susceptible to the inhibitory effect of the enkephalins (35% inhibition) than the 6-am population (15% inhibition), and the variability in response was considerably reduced. With progenitor cell-enriched population, obtained by fluorescence-activated cell sorting (FACS) of 6-am bone marrow samples, in 3 out of 6 experiments Met- and Leu-enkephalin showed 30-35% inhibition of GM colony formation over a wide range of concentrations (10(-15)-10(-6)). In the other 3 experiments, suppression as well as stimulation or no alteration in colony count were observed. This variability probably reflected quality (purity) of the progenitor cell population, and may indicate that the enkephalins affected hematopoietic cells via a population of accessory cells.

When should the immune clock be reset? From circadian pharmacodynamics to temporally optimized drug delivery

Immune defenses are organized along both 24-h and yearly time scales. Two circadian systems have been isolated in man, which can be desynchronized: (1) the circulation of T, B, or NK lymphocyte subsets in peripheral blood and (2) the density of epitope molecules (CD3, CD4, ...) at their surface, which may relate to cell reactivity to antigen exposure. The in vitro response of murine splenocytes to interleukin 2, interferon (IFN), or cyclosporin A strongly depended upon circadian time of exposure. Temporally optimized delivery of biologic response modifiers (BRM) may be guided by immunologic marker rhythms. An alternative yet complementary strategy was sought with IFN: since high doses were shown as more effective than low doses against several malignancies, this drug was given at the presumed less toxic time, so that its dose could be increased. Continuous drug delivery was circadian modulated in 8 cancer patients. Dose intensities twice to fourfold higher than those usually recommended were safely infused to ambulatory patients. Chronotherapy with BRM may represent a necessary step for optimizing the immunologic control of malignancies.