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.

Altered RNA structural constituents in aging and vitamin E deficiency.

Ribonucleoprotein (RNP) containing structural constituents in hepatocyte nuclei of adult, old and adult, vitamin E-deficient rats were investigated to assess the effect of aging and increased oxidative stress on nuclear functions. Fibrillar centres (FCs), dense fibrillar (DFC) and granular (GC) components of nucleoli as well as perichromatin granules (PGs) in the nucleoplasm were preferentially evidenced by the ethylenediaminetetracetic acid (EDTA) method and measured by computer-assisted morphometric procedures. FCs size and the percentage of nucleolar surface occupied by FCs significantly decreased during aging and vitamin E-deficiency. The percentage of nucleolar surface occupied by GC and DFC remained unchanged in adult and old rats, but in vitamin E-deficient animals GC increased and DFC decreased significantly. PG density significantly changed in aging and vitamin E-deficiency. Functionally, FCs, DFC and GC constitute sites of transcription and processing of ribosomal RNA while PGs are involved in intranuclear storage and transport of messenger RNA. Thus, the present structural changes during aging and vitamin E-deficiency correlate with a decay of nuclear responsiveness to cellular metabolic needs. Considering the antioxidant action of alpha-tocopherol, our data lend further support to the importance of free radical production and control in the aging process.

Ultrastructural analysis of pancreatic acinar cells from mice fed on genetically modified soybean.

No direct evidence that genetically modified (GM) food may represent a possible danger for health has been reported so far; however, the scientific literature in this field is quite poor. Therefore, we investigated the possible effects of a diet containing GM soybean on mouse exocrine pancreas by means of ultrastructural, morphometrical and immunocytochemical analyses. Our observations demonstrate that, although no structural modification occurs in pancreatic acinar cells of mice fed on GM soybean, quantitative changes of some cellular constituents take place in comparison to control animals. In particular, a diet containing significant amount of GM food seems to influence the zymogen synthesis and processing.

Ultrastructural morphometrical and immunocytochemical analyses of hepatocyte nuclei from mice fed on genetically modified soybean.

No direct evidence that genetically modified (GM) food may represent a possible danger for health has been reported so far; however, the scientific literature in this field is still quite poor. Therefore, we carried out an ultrastructural morphometrical and immunocytochemical study on hepatocytes from mice fed on GM soybean, in order to investigate eventual modifications of nuclear components of these cells involved in multiple metabolic pathways related to food processing. Our observations demonstrate significant modifications of some nuclear features in GM-fed mice. In particular, GM fed-mice show irregularly shaped nuclei, which generally represents an index of high metabolic rate, and a higher number of nuclear pores, suggestive of intense molecular trafficking. Moreover, the roundish nucleoli of control animals change in more irregular nucleoli with numerous small fibrillar centres and abundant dense fibrillar component in GM-fed mice, modifications typical of increased metabolic rate. Accordingly, nucleoplasmic (snRNPs and SC-35) and nucleolar (fibrillarin) splicing factors are more abundant in hepatocyte nuclei of GM-fed than in control mice. In conclusion, our data suggest that GM soybean intake can influence hepatocyte nuclear features in young and adult mice; however, the mechanisms responsible for such alterations remain unknown.

Quantification of G6PD in small and large intestine of rat during aging.

Numerous studies have demonstrated a decrease in glucose-6-phosphate dehydrogenase (G6PD) activity during aging in many cell types, including red blood cells, fibroblasts and lens cells. Moreover, the intracellular activity of G6PD has been shown to be regulated by binding to cell organelles. To investigate whether binding of G6PD to cell organelles is related with the decrease in its activity during aging, distribution patterns of G6PD activity and protein were assessed in small (SI) and large (LI) intestine of 3-month-old and 28-month-old rats. Enzyme activity, as measured spectrophotometrically, did not show any significant change with aging in SI or LI. Enzyme histochemistry, performed by subtracting activity staining of 6-phosphogluconate dehydrogenase (6PGD) from that of G6PD, showed a lower net G6PD activity in SI and LI epithelium of old rats in comparison with young rats. G6PD activity did not change significantly with aging in the muscularis externa of SI and LI. Immunoelectron microscopic analysis of G6PD protein allowed us to measure the density of G6PD molecules in cellular compartments, and the fraction of enzyme bound to cell organelles. In SI and LI epithelia, density of G6PD molecules was higher in old rats than in young rats; however, the fraction of enzyme bound to cell organelles also increased with aging. These data suggest that G6PD activity in epithelium of SI and LI decreases with aging due to the accumulation of significant amounts of enzyme bound to cell organelles, a condition which makes it less active than the soluble enzyme.

Atobe J. H., Hirata M. H., Hoshino-Shimizu S., Schmal M. R., Mamizuka E. M. One-step heminested PCR for amplification of Neisseria meningitidis DNA in cerebrospinal fluid. J Clin Lab Anal 14:193-199, 2000.

On page 195, in Fig. 1, the labels of boxes RW01 and DG74 are switched. The label RW01 in the right box should read DG74 (1540-1521 position), and the label DG74 in the left box should read RW01 (1189-1170 position). Also in Fig. 1, the primer DG74 listed in the "Primers" box above the legend should read 5'-AGGAGGTGATCCAACCGCA-3', and not 5'-AGGAGGTGATCCAACGCGA-3' as printed. The publisher regrets the error.