Eliminating animal facility light-at-night contamination and its effect on circadian regulation of rodent physiology, tumor growth, and metabolism: a challenge in the relocation of a cancer research laboratory.

Appropriate laboratory animal facility lighting and lighting protocols are essential for maintaining the health and wellbeing of laboratory animals and ensuring the credible outcome of scientific investigations. Our recent experience in relocating to a new laboratory facility illustrates the importance of these considerations. Previous studies in our laboratory demonstrated that animal room contamination with light-at-night (LAN) of as little as 0.2 lx at rodent eye level during an otherwise normal dark-phase disrupted host circadian rhythms and stimulated the metabolism and proliferation of human cancer xenografts in rats. Here we examined how simple improvements in facility design at our new location completely eliminated dark-phase LAN contamination and restored normal circadian rhythms in nontumor-bearing rats and normal tumor metabolism and growth in host rats bearing tissue-isolated MCF7(SR(-)) human breast tumor xenografts or 7288CTC rodent hepatomas. Reducing LAN contamination in the animal quarters from 24.5 ± 2.5 lx to nondetectable levels (complete darkness) restored normal circadian regulation of rodent arterial blood melatonin, glucose, total fatty and linoleic acid concentrations, tumor uptake of O(2), glucose, total fatty acid and CO(2) production and tumor levels of cAMP, triglycerides, free fatty acids, phospholipids, and cholesterol esters, as well as extracellular-signal-regulated kinase, mitogen-activated protein kinase, serine-threonine protein kinase, glycogen synthase kinase 3ß, γ-histone 2AX, and proliferating cell nuclear antigen.

Spontaneous thymoma rat as a model for myasthenic weakness caused by anti-ryanodine receptor antibodies.

The mechanism of muscle weakness in myasthenia gravis and its possible relation to antibodies that are directed against the ryanodine receptor (RyR) were studied by the use of the spontaneous thymoma rat (Buffalo/Mna strain). The present study focused on the motor dysfunction as complicated by impaired subcellular machineries and noted particularly in patients with thymus abnormalities. Rats began to develop skeletal muscle weakness soon after birth and worsened progressively. Rats aged 3 months showed a benign thymoma characterized by proliferative lymphocytes; epithelial cells were stained with anti-RyR peptide antibody. The rat serum contained anti-RyR antibodies, but no anti-acetylcholine receptor antibodies. The electrophysiological study in muscle showed a reduction of contractile force without abnormality in synaptic transmission and membrane properties, suggesting a defect in excitation-contraction coupling. Hypothetically, thymic epithelial cells and skeletal muscles share a common RyR antigen, so that anti-RyR antibodies that target the thymic tissue may react with a homologous target in the muscle.

Genetic regulation of slowly progressing mild muscle atrophy in fast-twitch muscles of BUF/Mna rats.

BUF/Mna strain rats spontaneously develop slowly progressing mild-moderate muscle atrophy of extensor digitorum longus, tibialis, and extraocular muscles, which consist mainly of fast-twitch type fibers, at nearly 100% incidence. They have lighter extensor digitorum longus muscles than soleus muscles, when alive for more than 6 weeks. Genetic segregation of the development of the muscle atrophy was studied by crossing the BUF/ Mna strain with three other strains, ACI/NMs, WKY/NCrj, and BDIX, which were free of muscle atrophy. Two autosomal dominant susceptible genes, Mas-1 and Mas-2, determine the development of the muscle atrophy in these combinations of crosses.

Effects of a protein-free diet or food restriction on the immune system of Wistar and Buffalo rats at different ages.

The effects of a protein-free diet or food restriction on the immune system were examined in two rat strains, Wistar and Buffalo, in different age-groups. Unlike Wistar rats, Buffalo rats have an unusually hyperplastic thymus and a large number of peripheral T cells. The protein-free diet (PFD) in rats resulted in marked thymic involution together with a reduction of splenic T cells, both in number and in antibody response to sheep red blood cells. The depressive effect of the PFD on the immune system was more serious in young immature rats than in older rats, but less serious in Buffalo rats having enhanced T cell functions regardless of age. Thymic involution was also accelerated in both strains of rats by feeding them a restricted amount of the control diet containing well-balanced nutrients (food restriction, FR). In the FR experiment, no significant change was observed in immune functions of Wistar rats. A slight reduction was observed in the immune functions of Buffalo rats with FR, but absolute levels were distinctly higher in Buffalo rats than in Wistar rats even after FR. These results suggested (1) that the thymic function is sensitive to protein deficiency; (2) that a well-balanced dietary condition is necessary for immunological maturation in the early stage of life and preservation of immune functions at older age; (3) that animals having higher immune functions are more resistant to malnutrition than ordinary ones.

Methacholine-induced airway reactivity of inbred rats.

Dose-response curves to inhaled aerosolized methacholine chloride (MCh) were obtained in anesthetized spontaneously breathing rats. Thirty rats (10/strain), randomly selected from highly inbred ACI, Lewis (L), and Brown Norway (BN) strains and 40 rats (20/strain) from similarly inbred Wistar-Furth (WF) and Buffalo (Buf) strains were studied. Airway responses were quantitated from changes in pulmonary resistance (RL) and airway reactivity was calculated as the dose of MCh required to increase RL to 150% (ED150RL) and 200% (ED200RL) of base line. There were no statistically significant differences in ED150RL and ED200RL among the five rat strains. Large interindividual variability was present as evidenced by 128-fold differences in ED150RL and ED200RL between the least and most sensitive animal of the same strain. In contrast, seven animals studied repeatedly on different days had values of ED150RL that differed by an average of only 2.9-fold (range 1.6-5.3). Thirteen rats that were studied on two occasions separated by an interval of 3 mo showed no systematic changes in airway reactivity. We conclude that airway reactivity to inhaled methacholine in anesthetized nose-breathing rats is not strain related, and despite animals of a given strain being genetically identical, the variability in airway reactivity within strains suggests that environmental rather than genetic factors are the major determinants of that reactivity.

Decreased thyroid function and high plasma prolactin levels in rats of the Buffalo strain.

Rats of the inbred Buffalo strain have previously been reported to be susceptible to thyroiditis, as defined by histology. We have studied the endocrinology of the pituitary-thyroid axis of this strain by making direct measurements of the plasma concentrations of TSH and T4 in untreated, adult Buffalo rats of both sexes. Plasma PRL levels were also measured. All hormone determinations were by RIA. In addition, relative thyroid weights were noted and, in many cases, preliminary assessment of thyroid histology was made. Our principle findings were as follows. 1) Decreased thyroid function, in addition to the previously reported histological abnormalities, was found to occur spontaneously among the rats studied. Indications of decreased function included elevations of plasma TSH and thyroid weight and depressions of plasma T4. We estimated the incidence of unequivocal thyroid disease as approximately 3% in each sex. 2) Basal plasma PRL concentrations of Buffalo rats averaged three to four times higher than those of outbred CD rats. Our findings strongly suggest that rats of the Buffalo strain will provide a good model for the study of thyroid failure of varying degrees and concomitant changes in the circulating levels of pituitary hormones.