Importance of 6 p.m. in Hamster Timekeeping Evidenced by Computer Analysis of Wheel-Running Activity

We addressed the question whether the clock signal for hamsters to become active occurs at sundown throughout summer or at some constant time after noon (p.m. time). Ten female golden hamsters housed in wheel cages in a windowless room were exposed to 24-h light/dark (LD) cycles simulating the equinoxes (LD 12: 12), when the sun sets at 6 p.m. and rises at 6 a.m., and summer (LD 14: 10, 16: 8, and 18: 6), when the sun sets after 6 p.m. and rises before 6 a.m. The onset of behavioral estrus, a mask-free phase marker of the same clock that controls wheel-running, was observed every 4 days, and wheel revolutions were recorded every 5 min for 52 days. Computer analysis of the 5-min values averaged for all 10 hamsters revealed a clear onset of running for each LD exposure. Time in the windowless room is referenced to mid-L (room “noon”) of the LD cycles. Although L-off ranged from 6 p.m. in LD 12: 12 (6 h after mid-L) to 9 p.m. in LD 18: 6, estrus began close to 4 p.m. and running close to 6 p.m. in every LD cycle. In a second study, 13 females not tested for estrus began running closer to 7 p.m. in LD 16: 8 (L-off, 8 p.m.), but when L-off was advanced to 4 p.m. they also began running on that day at 6 p.m. Testing for estrus may have made the first group of hamsters less fearful of light and therefore more responsive to a 6 p.m. clock signal to become active. It is conceivable that these nocturnal rodents voluntarily suppress, to varying degrees, overt activity from 6 p.m. standard time to sundown to avoid predators. It is noteworthy that 6 p.m. room time also marks the onset of the clock's 12-h light-sensitive period underlying hamster timekeeping.     

Synergistic Inhibition by Benzodiazepine and Barbiturate Drugs of the Clock Control of Ovulation in Hamsters

A surge of pituitary luteinizing hormone (LH) into the bloodstream occurs in hamsters every 4 days between 1:30 p.m. and 3 p.m. in response to a signal from a biological clock. This surge initiates behavioral estrus ∼2 h later and ovulation ∼12 h later. Phenobarbital at a dose ≥100 mg/kg consistently blocks LH release. Barbiturate and benzodiazepine drugs have separate binding sites in the GABA_A receptor/chloride channel complex. Binding of either drug increases GABA-mediated chloride conductance, which suppresses the postsynaptic neuron. Barbiturate binding also increases benzodiazepine binding. This suggested that these drugs might synergize to inhibit LH release. A combination of triazolam and phenobarbital at doses of 10 mg/kg injected s.c. at 1:30 p.m. inhibited ovulation and extended the 4-day vaginal cycle in all treated hamsters. Either drug dose injected alone at 1:30 p.m., or the combination at 3 p.m., was completely ineffective. Bicuculline prevented inhibition by the combination at 1:30 p.m. The clock signal for LH release may act by antagonizing GABA transmission, which may be chronically inhibiting LH release. The combination delimited a 75-min period (1:30-2:45 p.m.) within which the clock signal for LH release occurred in all individuals (ET₅₀ = 2:08 p.m.). This period appears to arise from individuals with different but constant clock settings rather than from a 75-min variation in the clock setting of the individual.     

Human malarial disease: a consequence of inflammatory cytokine release

Malaria causes an acute systemic human disease that bears many similarities, both clinically and mechanistically, to those caused by bacteria, rickettsia, and viruses. Over the past few decades, a literature has emerged that argues for most of the pathology seen in all of these infectious diseases being explained by activation of the inflammatory system, with the balance between the pro and anti-inflammatory cytokines being tipped towards the onset of systemic inflammation. Although not often expressed in energy terms, there is, when reduced to biochemical essentials, wide agreement that infection with falciparum malaria is often fatal because mitochondria are unable to generate enough ATP to maintain normal cellular function. Most, however, would contend that this largely occurs because sequestered parasitized red cells prevent sufficient oxygen getting to where it is needed. This review considers the evidence that an equally or more important way ATP deficency arises in malaria, as well as these other infectious diseases, is an inability of mitochondria, through the effects of inflammatory cytokines on their function, to utilise available oxygen. This activity of these cytokines, plus their capacity to control the pathways through which oxygen supply to mitochondria are restricted (particularly through directing sequestration and driving anaemia), combine to make falciparum malaria primarily an inflammatory cytokine-driven disease.     

Cholera toxin: mitogen for Harderian glands of golden hamsters

1. Within 2 days, a single injection of 10 micrograms cholera toxin induces a 6-20-fold increase in mitotic activity in the Harderian glands of male and female golden hamsters. 2. Neither hypophysectomy nor ovariectomy had any influence on this response. 3. The cellular proliferation does not appear to involve cAMP nor is it the result of stress, nor a release from an early mitotic block. 4. Nuclear polyploidy increases within a few hours after treatment. 5. DNA density per unit area increases within 24 hr and is maintained for at least 3 days.