A long-term study on female mice fed on a genetically modified soybean: effects on liver ageing.

Liver represents a suitable model for monitoring the effects of a diet, due to its key role in controlling the whole metabolism. Although no direct evidence has been reported so far that genetically modified (GM) food may affect health, previous studies on hepatocytes from young female mice fed on GM soybean demonstrated nuclear modifications involving transcription and splicing pathways. In this study, the effects of this diet were studied on liver of old female mice in order to elucidate possible interference with ageing. The morpho-functional characteristics of the liver of 24-month-old mice, fed from weaning on control or GM soybean, were investigated by combining a proteomic approach with ultrastructural, morphometrical and immunoelectron microscopical analyses. Several proteins belonging to hepatocyte metabolism, stress response, calcium signalling and mitochondria were differentially expressed in GM-fed mice, indicating a more marked expression of senescence markers in comparison to controls. Moreover, hepatocytes of GM-fed mice showed mitochondrial and nuclear modifications indicative of reduced metabolic rate. This study demonstrates that GM soybean intake can influence some liver features during ageing and, although the mechanisms remain unknown, underlines the importance to investigate the long-term consequences of GM-diets and the potential synergistic effects with ageing, xenobiotics and/or stress conditions.

Hibernation as a far-reaching program for the modulation of RNA transcription.

In eukaryotic cells, pre-mRNAs undergo several transformation steps to generate mature mRNAs ready to be exported to the cytoplasm. The molecular and structural apparatus for mRNA production is generally able to promptly respond to variations of metabolic demands. Hibernating mammals, which periodically enter a hypometabolic state, represent an interesting physiological model to investigate the adaptive morpho-functional modifications of the pre-mRNA transcriptional and processing machinery under extreme metabolic conditions. In this study, the subnuclear distribution of some transcriptional, splicing, and cleavage factors was investigated by ultrastructural immunocytochemistry in cell nuclei of the liver (a highly metabolizing organ involved in multiple regulatory functions) and the brown adipose tissue (responsible for nonshivering thermogenesis) from euthermic, hibernating, and arousing hazel dormice (Muscardinus avellanarius). Our observations demonstrate that, during hibernation, transcriptional activity significantly decreases and pre-mRNA processing factors undergo an intranuclear redistribution moving to domains usually devoid of such molecules; moreover, in hepatocytes, there is a preferential accumulation of pre-mRNAs at the splicing stage, whereas, in brown adipocytes, pre-mRNAs are mainly stored at the cleavage stage. Upon arousal, the pre-mRNAs at the cleavage stage are immediately utilized, while the maturation of pre-mRNAs at the splicing stage seems to be restored before transcription had taken place. Our data suggest a programmed intranuclear reorganization of the RNA maturation machinery aimed at efficiently and rapidly restoring the pre-mRNA processing, and, consequently, the specific cellular activities upon arousal. Once again natural hibernation appears as a highly programmed hypometabolic state rather than a simple fall of metabolic and physiological functions.

Effects of ageing on the fine distribution of the circadian CLOCK protein in reticular formation neurons.

Many biochemical, physiological and behavioural processes, from bacteria to human, exhibit roughly 24 h cyclic oscillations defined as circadian rhythms. However, during ageing, numerous aspects of the circadian biology undergo alterations; in particular, the sleep pattern changes, with more frequent awakenings and shorter sleep time. The basic mechanism of the circadian clock relies on intracellular molecular pathways involving interlocking transcriptional/translational feedback loops, and CLOCK protein, a transcription factor, is essential for normal circadian rhythms. In this study, the fine distribution of CLOCK protein has been analysed, in adult and old rats, at different phases of the daily cycle in the neurons of the medullary reticular formation, involved in the control of the sleep-wake cycle. The results demonstrate quali-quantitative modifications of CLOCK protein in the neurons of old animals, suggesting that such a deregulation of the intracellular clock mechanism may play some role in the degeneration of the sleep-wake circadian cycle.

Influence of temperature on the liver circadian clock in the ruin lizard Podarcis sicula.

Reptiles represent an interesting animal model to investigate the influence of temperature on molecular circadian clocks. The ruin lizard Podarcis sicula lives in a continental climate and it is subjected to wide range of environmental temperatures during the course of the year. As consequence, ruin lizard daily activity pattern includes either the hibernation or periods of inactivity determined by hypothermia. Here we showed the rhythmic expression of two clock genes, lPer2 and lClock, in the liver of active lizards exposed to summer photo-thermoperiodic conditions. Interestingly, the exposition of lizards to hypothermic conditions, typical of winter season, induced a strong dampening of clock genes mRNA rhythmicity with a coincident decrease of levels. We also examined the qualitative and quantitative distribution of lPER2 and lCLOCK protein in different cellular compartments during the 24-h cycle. In the liver of active lizards both proteins showed a rhythmic expression profile in all cellular compartments. After 3 days at 6 degrees C, some temporal fluctuations of the lCLOCK and lPER2 are still detectable, although, with some marked modifications in respect to the values detected in the liver of active lizards. Besides demonstrating the influence of low temperature on the lizard liver circadian oscillators, present results could provide new essential information for comparative studies on the influence of temperature on the circadian system across vertebrate classes.

The effect of the enkephalin DADLE on transcription does not depend on opioid receptors.

[D-Ala(2),D-Leu(5)] enkephalin (DADLE) is a synthetic peptide capable of inducing a hibernation-like state in mammals in vivo and in cultured cells in vitro. The effects of DADLE seem to be due to its binding to opioid receptors; however, it inhibits the growth of LNCaP cells, devoid of opioid receptors. We have investigated the effects of DADLE on this cell line using transmission electron microscopy, immunocytochemistry and cytometry, in order to elucidate the general mechanism(s) by which this enkephalin affects cell metabolism. We demonstrated that, similar to cell lines provided with opioid receptors, in LNCaP cells DADLE induces structural modifications of cytoplasmic and nuclear constituents, as well as a decrease in transcription and proliferation. However, DADLE does not provoke an increase in apoptotic or necrotic cell fraction, and, after removing the enkephalin from the culture medium, all effects disappear. We also demonstrated that DADLE molecules enter the cytoplasm and the nucleus of LNCaP cells, mostly binding to perichromatin fibrils and dense fibrillar component, where transcription and early splicing of pre-mRNAs and pre-rRNAs occur. In conclusion, our data demonstrate that the effect of DADLE on transcription and on cultured cells does not depend on opioid receptors. DADLE can, therefore, be envisaged as an extremely promising molecule to be used for inducing a reversible hypometabolic state in various cultured cells, without provoking cell damage or death.

Aging affects the distribution of the circadian CLOCK protein in rat hepatocytes.

Several biochemical, physiological, and behavioral processes exhibit cyclic oscillations of about 24 h, which have been defined as circadian rhythms. In mammals, the primary circadian pacemaker resides in the suprachiasmatic nuclei; however, cell-autonomous circadian oscillators occur also in extraneural tissues, including the liver. CLOCK protein is a transcription factor essential for normal circadian rhythms and recent studies have demonstrated that it undergoes intranuclear redistribution in hepatocytes, along the daily cycle. It is known that aging leads to a progressive deterioration of the circadian rhythm at the behavioral, physiological, and cellular levels; in addition, aging affects the organization of nuclear structural components involved in transcription and splicing. In this view, we carried out ultrastructural immunocytochemical analyses on hepatocytes of adult and old rats, so as to investigate possible qualitative and quantitative modifications of CLOCK protein, in relation to the aging process. Our observations demonstrated that most CLOCK protein was always located in the cell nucleus, where it accumulated on perichromatin fibrils (the sites of premRNA transcription and early splicing); in addition, CLOCK showed daily oscillations in the different nuclear compartments, but these oscillations differed significantly between adult and old animals. This unusual distribution of CLOCK protein during aging could be related to the prolonged diurnal activity of old animals and/or to altered nuclear pathways.

Ultrastructural and immunocytochemical analyses of opioid treatment effects on PC3 prostatic cancer cells.

Some opioid peptides are able to inhibit the growth of human prostatic cancer cells; in particular, the [D-Ala(2),D-Leu(5)] enkephalin (DADLE) reduces PC3 cell growth. In order to understand how DADLE decreases cell proliferation, we investigated, by electron microscopy, its effects on PC3 cellular components. PC3 cells were incubated with DADLE and processed for both ultrastructural morphology and immunoelectron microscopy. Some cells were incubated with BrU to determine the transcriptional rate. BrU and DADLE molecules were detected by immunogold techniques and the labeling was quantitatively evaluated. Modifications of some cytoplasmic and nuclear components were observed in DADLE-treated cells. Moreover, treated cells incorporated lower amounts of BrU than control cells. DADLE molecules were located in the cytoplasm and in the nucleus, especially on mRNA transcription and early splicing sites. Our data suggest that DADLE is able to slow down the synthetic activity of PC3 cells, perhaps interfering with nuclear functions.

Aging and vitamin E deficiency are responsible for altered RNA pathways.

Fibrillar centers (FCs), dense fibrillar (DFC) and granular (GC) components in nucleoli, and perichromatin granules (PGs) in nucleoplasm were measured by morphometry. FC size and their nucleolar surface fraction significantly decreased in aging and vitamin E deficiency. The GC and DFC nucleolar fraction was unchanged in adult and old rats, but in vitamin E-deficient animals GC increased and DFC decreased significantly. PG density significantly increased in aging and decreased in vitamin E deficiency. The quantitative evaluation of immunolabeled transcription and splicing factors revealed that polymerase II and SC-35 significantly decreased in old and vitamin E-deficient versus adult animals. Fibrillarin and snRNPs did not change between adult and old rats, but were significantly lower in vitamin E-deficient rats. These data document altered RNA pathways in aging and vitamin E deficiency. Considering the antioxidant role of vitamin E, they lend further support to the importance of free radical production and control in the aging process.

Immunocytochemical analysis of the circadian clock protein in mouse hepatocytes.

Many biochemical, physiological, and behavioral processes in organisms ranging from prokaryotes to humans exhibit circadian rhythms, defined as cyclic oscillations of about 24 hours. The mechanism of the cellular circadian clock relies on interlocking positive and negative transcriptional/translational feedback loops based on the regulated expression of several genes. Clock is one of these genes and its transcript, CLOCK protein, is a transcription factor belonging to the bHLH-PAS family. In mammals the clock gene is expressed in several tissues, including the liver. In the present study, we analyzed by means of quali-quantitative immunoelectron microscopy the fine intracellular distribution of the CLOCK protein in mouse hepatocytes during the daily cycle. We demonstrated that CLOCK protein is mostly located in the cell nucleus, where it accumulates on perichromatin fibrils, representing the in situ form of nascent pre-mRNA, while condensed chromatin and nucleoli contain lower amounts of protein. Moreover, we found that CLOCK protein shows circadian oscillations in these nuclear compartments, peaking in late afternoon. At this time the hepatic transcriptional rate reaches the maximal level, thus suggesting an important role of CLOCK protein in the regulation of liver gene expression.