Weight loss in tumour-bearing mice is not associated with changes in resistin gene expression in white adipose tissue

Resistin, a product of white adipose tissue, is postulated to induce insulin resistance in obesity and regulate adipocyte differentiation. The aim of this study was to examine resistin gene expression in adipose tissue from mice bearing the MAC16 adenocarcinoma, which induces cancer cachexia with marked wasting of adipose tissue and skeletal muscle mass. MAC16-bearing mice lost weight progressively over the period following tumour transplantation, while the weight of control mice remained stable. Leptin mRNA in gonadal fat was 50% lower in MAC16 mice than in controls (p<0.05). Plasma insulin concentrations were also significantly lower in the MAC16 group (p<0.05). However, resistin mRNA level in gonadal fat in MAC16 mice was similar to controls (94% of controls). Thus, despite severe weight loss and significant falls in leptin expression and insulin concentration, resistin gene expression appears unchanged in white adipose tissue of mice with MAC16 tumour. Maintenance of resistin production may help inhibit the formation of new adipocytes in cancer cachexia.

Circannual rhythms of maturation in the female rainbow trout and their entrainment by changes in photoperiod

The importance of endogenous rhythms in the photoperiodic control of the annual reproduction cycle in female rainbow trout was investigated. The effect of photoperiod regimes on the different stages of maturation was assessed by recording the timing of ovulation and from quantifying associated changes in serum oestradiol-17,testosterone and total calcium. Maintained under constant 6L:18D and constant temperature for up to four years, rainbow trout exhibited an endogenous rhythm of maturation with a periodicity of approximately one year. This rhythm of maturation appears to be driven by an autonomous circannual oscillator or clock which can be dissociated from the neuroendocrine mechanisms controlling gonadal maturation. Under conditions of constant 18L:6D or LL the periodicity of the maturation rhythm was 5.5-6 months; it is suggested that this periodicity may be caused by a splitting or uncoupling of at least two circannual clocks involved in the control of maturation. Abrupt changes in the length of the photoperiod act as a zeitgeber to entrain the endogenous rhythm of maturation. Whether the timing of maturation is advanced or delayed depends primarily on the direction of the change in photoperiod and its timing in relation to the phase of the rhythm, with the magnitude of the alteration in photoperiod having only a supplementary effect. The effect of specific changes in photoperiod on the entrainment of the maturation cycle can be described in terms of a phase-response curve. Photic information is transduced, probably by the pineal gland, into a daily rhythm of melatonin; exposure of rainbow trout to skeleton and resonance photoperiod regimes indicated that daylength measurement is effected by endogenous circadian clock(s) rather than by hour-glass mechanisms. A gating mechanism is closely associated with the circannual clock which determines the timing of onset of maturation in virgin female rainbow trout, only allowing fish that have attained a threshold stage of development to undergo gonadal maturation. Collectively the results support the hypothesis that the female rainbow trout exhibits an endogenous circannual rhythm of maturation which can be entrained by changes in photoperiod.

Familial adrenal hypoplasia syndromes

The adrenal cortex secretes steroid hormones, including glucocorticoids and mineralocorticoids. Glucocorticoids control body homeostasis, stress, and immune responses, while mineralocorticoids regulate the water and electrolyte balance. A spectrum of genetic defects can disrupt the normal adrenal development, causing adrenal hypoplasia and various forms of adrenal insufficiency, which usually present in infancy or childhood with or without mineralocorticoid deficiency and with or without gonadal dysfunction. The genetic causes of adrenal hypoplasia can be broadly categorized into adrenal hypoplasia due to adrenocorticotropic hormone resistance syndromes (i.e., familial glucocorticoid deficiency and triple A syndrome) and adrenal hypoplasia due to primary defects in the development of the adrenal glands (i.e., X-linked adrenal hypoplasia congenita and primary adrenal hypoplasia caused by steroidogenic factor 1 mutations).