Differential expression of hypothalamic, metabolic and inflammatory genes in response to short-term calorie restriction in juvenile obese- and lean-prone JCR rats.

BACKGROUND: Childhood obesity is an important early predictor of adult obesity and associated comorbidities. Common forms of obesity are underpinned by both environmental and genetic factors. However, the rising prevalence of obesity in genetically stable populations strongly suggests that contemporary lifestyle is a premier factor to the disease. In pediatric population, the current treatment/prevention options for obesity are lifestyle interventions such as caloric restriction (CR) and increase physical activity. In obese individuals, CR improves many metabolic parameters in peripheral tissues. Little is known about the effect of CR on the hypothalamus. This study aimed to assess the effect of CR on hypothalamic metabolic gene expression of young obese- and lean-prone animals. METHODS: Male juvenile JCR:LA-cp obese-prone rats were freely fed (Obese-FF) or pair fed (Obese-FR) to lean-prone, free-feeding animals (Lean-FF). A group of lean-prone rats (Lean-FR) were matched for relative average degree of CR to Obese-FR rats. RESULTS: In free-feeding conditions, obese-prone rats consumed more energy than lean-prone rats (P<0.001) and showed greater increases in body weight, fat mass, plasma glucose, insulin and lipids (P<0.01). These metabolic differences were associated with alterations of feeding-related neuropeptides expression in the hypothalamus, as well as pro-inflammatory cytokines and oxidative stress markers. When submitted to the same degree of CR, the two genotypes responded differently; hypothalamic inflammatory and oxidative stress gene expression was improved in Obese-FR, while it was worsened in Lean-FR rats. CONCLUSIONS: We demonstrate in JCR rats that the metabolic and inflammatory response of the brain to CR is genotype dependent.

Cytosolic StAR-related lipid transfer domain 4 (STARD4) protein influences keratinocyte lipid phenotype and differentiation status.

BACKGROUND: Terminally differentiating keratinocytes actively synthesize and accumulate cholesterol, which is a key constituent of intercellular lipid lamellae which contribute to the epidermal permeability barrier. While the pathway for cholesterol biosynthesis is established, intracellular transport mechanisms for this lipid are poorly understood, despite their importance in regulating organelle sterol content, keratinocyte differentiation status and the activity of lipid-responsive transcription factors involved in skin health, repair and disease. Recent data implicate proteins containing a steroidogenic acute regulatory protein (StAR)-related lipid transfer (START) domain in cellular cholesterol homeostasis. OBJECTIVES: To investigate gene expression of cytosolic, cholesterol-binding StAR-related lipid transfer domain 4 (STARD4) protein in primary human keratinocytes and differentiating HaCaT keratinocytes and, by overexpression of this protein, the function of STARD4 in HaCaT keratinocyte lipid phenotype and differentiation status. METHODS: Quantitative polymerase chain reaction was utilized to measure gene expression of STARD4 relative to the housekeeping gene GAPDH. Following transient (48 h) overexpression of STARD4, keratinocyte lipid mass and lipogenesis were measured, along with expression of genes involved in cholesterol homeostasis and those encoding a range of keratinocyte differentiation markers. RESULTS: Cholesterol-binding protein STARD4 is expressed in both primary and immortalized HaCaT keratinocytes, and is repressed during Ca(2+) -dependent differentiation of the latter. Transient overexpression of STARD4 reduces endogenous [(14) C]cholesterol and cholesteryl ester biosynthesis, and triggers increased expression of SREBF2, ABCG4 and LOR, while repressing expression of ABCA1. CONCLUSIONS: The cytosolic cholesterol-sensing protein STARD4 modulates both keratinocyte cholesterol homeostasis and differentiation status, increasing the efficiency of cholesterol trafficking within the cell, and amplifying and 'fine-tuning' cellular responses to this sterol. Modulation of expression of STARD4, and other members of the START family of lipid trafficking proteins, may prove useful in resolving imbalances in lipid metabolism associated with loss of epidermal barrier function in psoriasis and atopic dermatitis.

Tissue resistivities and current pathways and their importance in pre-slaughter stunning of chickens.

The failure of commercial pre-slaughter electrical stunning to stun effectively all birds may be, in part, a result of the current following slightly different paths through the tissues of different birds. Resistivity can be used to predict current pathways, and methods are presented for determining the resistivity of a tissue in freshly-killed or anaesthetized adult fowls. A variety of tissues were tested including comb, skeletal muscle, epithelium, brain, skull bone, heart and liver. The resistivity of a particular tissue varied little between birds, with the exception of skull bone in which resistivity differed markedly from bird to bird. This variation in skull bone resistivity may explain why some birds are inadequately stunned, since in these individuals the current density in the brain is likely to be insufficient to induce an adequate epileptic seizure.