Simultaneous synthesis,translation, and storage of mRNA including histone mRNA in sea urchin eggs

The kinetics of accumulation of RNA labeled with uridine and the time course of change in the specific activity of the UTP pool were used to estimate the rate constants for synthesis and decay of RNA synthesized in unfertilized eggs of the sea urchin Lytechinus pictus. The rate of synthesis per haploid genome is similar to that in embryos. Most of the RNA is turning over with a half-life of about 5 hr, and an average of 11 pg of newly synthesized RNA accumulates at steady state. About 3.7% of the RNA in the polysomes of the egg is newly synthesized and this RNA has the heterogeneous size distribution expected for mRNA. Thus most, probably all, of the mRNA translated in the egg is also synthesized in the egg. Little, if any, of the RNA synthesized in the egg enters polysomes following fertilization. Thus the egg synthesizes a population of mRNA which is unstable and translated, but it also contains a more stable, untranslated population of previously synthesized, stored mRNA, which is translated only after fertilization. Since the two populations of mRNA code for the same abundant proteins (Brandhorst, B. P. (1976). Develop. Biol., 52, 310–317), there is a temporal separation in the metabolism and function of coexisting mRNA molecules of identical coding sequence. Among the mRNAs synthesized and translated in the egg are histone mRNAs having the same electrophoretic mobilities and rates of synthesis per genome as those synthesized in rapidly cleaving embryos. Thus the synthesis, entry into the cytoplasm, and translation of histone mRNA are not restricted to the S phase of the cell cycle or the period of cell division.     

IgG-coated erythrocytes augment LPS-stimulated TNF-alpha secretion, TNF-alpha mRNA levels, and TNF-alpha mRNA stability in macrophages

Previous studies have shown that IgG-coated erythrocytes (EIgG) augment the LPS-stimulated increase in serum TNF-alpha levels in animals and the LPS-stimulated secretion of TNF-alpha by isolated macrophages. The present study evaluated the mechanism for the effect of EIgG on LPS-stimulated TNF-alpha secretion in the murine macrophage cell line, RAW 264.7. Incubation of the macrophages with EIgG or IgG-coated glass beads caused a dose-dependent augmentation of LPS-stimulated TNF-alpha secretion. The addition of EIgG increased the rate of LPS-stimulated TNF-alpha protein secretion between 2 and 4 hr after LPS. Accordingly, EIgG increased the levels of TNF-alpha mRNA at 2 and 3 hr after LPS. The increase in the LPS-stimulated TNF-alpha mRNA levels caused by EIgG was associated with an increase in TNF-alpha mRNA stability. Thus, the augmentation of LPS-stimulated TNF-alpha secretion by EIgG was associated with an increase in TNF-alpha mRNA levels which at least partly resulted from an increase in the stability of TNF-alpha mRNA.     

mRNA at synapses,synaptic plasticity,and memory consolidation

Miller et al. (this issue of Neuron) report that deletion of the 3'UTR of alpha-CaMKII mRNA prevents dendritic delivery of the mRNA in transgenic mice and thus local synthesis of alpha-CaMKII protein in dendrites. 3'UTR mutant mice exhibit decreases in alpha-CaMKII protein in postsynaptic densities, and deficits in late phase LTP and in memory consolidation.     

Dendritic mRNA: transport, translation and function

Many cellular functions require the synthesis of a specific protein or functional cohort of proteins at a specific time and place in the cell. Local protein synthesis in neuronal dendrites is essential for understanding how neural activity patterns are transduced into persistent changes in synaptic connectivity during cortical development, memory storage and other long-term adaptive brain responses. Regional and temporal changes in protein levels are commonly coordinated by an asymmetric distribution of mRNAs. This Review attempts to integrate current knowledge of dendritic mRNA transport, storage and translation, placing particular emphasis on the coordination of regulation and function during activity-dependent synaptic plasticity in the adult mammalian brain.     

Insights into the mRNA cleavage mechanism by MazF, an mRNA interferase

MazF is an Escherichia coli toxin that is highly conserved among the prokaryotes and plays an important role in growth regulation. When MazF is induced, protein synthesis is effectively inhibited. However, the mechanism of MazF action has been controversial. Here we unequivocally demonstrate that MazF is an endoribonuclease that specifically cleaves mRNAs at ACA sequences. We then demonstrate its enzymatic specificity using short RNA substrates. MazF cleaves RNA at the 5'-end of ACA sequences, yielding a 2',3'-cyclic phosphate at one side and a free 5'-OH group at the other. Using DNA-RNA chimeric substrates containing XACA, the 2'-OH group of residue X was found absolutely essential for MazF cleavage, whereas all the other residues may be deoxyriboses. Therefore, MazF exhibits exquisite site specificity and has utility as an RNA-restriction enzyme for RNA structural studies or as an mRNA interferase to regulate cell growth in prokaryotic and eukaryotic cells.     

Cloning, mRNA Expression, and Chromosomal Mapping of Mouse and Human Preprocortistatin

Cortistatin is a 14-residue putative neuropeptide with strong structural similarity to somatostatin and is expressed predominantly in cortical GABAergic interneurons of rats. Administration of cortistatin into the brain ventricles specifically enhances slow-wave sleep, presumably by antagonizing the effects of acetylcholine on cortical excitability. Here we report the identification of cDNAs corresponding to mouse and human preprocortistatin and the mRNA distribution and gene mapping of mouse cortistatin. Analysis of the nucleotide and predicted amino acid sequences from rat and mouse reveals that the 14 C-terminal residues of preprocortistatin, which make up the sequence that is most similar to somatostatin, are conserved between species. Lack of conservation of other dibasic amino acid residues whose cleavage by prohormone convertases would give rise to additional peptides suggests that cortistatin-14 is the only active peptide derived from the precursor. As in the rat, mouse preprocortistatin mRNA is present in GABAergic interneurons in the cerebral cortex and hippocampus. The preprocortistatin gene maps to mouse chromosome 4, in a region showing conserved synteny with human 1p36. The human putative cortistatin peptide has an arginine for lysine substitution, compared to the rat and mouse products, and is N-terminally extended by 3 amino acids.     

Localization and quantification of hormones, ligands, and mRNA with affinity-gold probes

The application of immunogold techniques to localize pituitary hormones produces label that can be quantified and correlated with different secretory states. This report focuses on three major applications of the technology. In the first set of studies, immunogold labels for adrenocorticotropin (ACTH) or luteinizing hormone (LH beta) and follicle-stimulating hormone (FSH beta) were applied to ultrathin sections of pituitaries from adrenalectomized rats or from rats in different stages of the estrous cycle. During the first week after adrenalectomy, ACTH cell area increased. The concentration of immunoperoxidase label (amount of label/area of the corticotropes) decreased. Counts of gold markers showed that there were no changes in the concentration of antigens per granule. Three weeks after adrenalectomy, the amount of immunoperoxidase label increased along with the concentration of that label. The concentration of gold label for ACTH on granules also increased. All changes correlated well with increases in serum ACTH stimulated by adrenalectomy. In the studies of cycling rats, gonadotropes showed increases in the number of gold markers for LH beta or FSH beta per granule area just before an elevation in serum levels. There were also increases in the proportion of granules that contained only LH beta or FSH beta (monohormonal) before the rise in secretion. Thus, nonparallel release of gonadotropins might be attributed to changes in the ratio of gonadotropins packaged per granule. In the second series of studies, avidin-gold labels were used to identify sites of binding of biotinylated ligands. These studies illustrate and quantify binding by biotinylated gonadotropin-releasing hormone (GnRH) to ovarian or pituitary target cells. Triple-labeling protocols (avidin-peroxidase followed by immunogold) show that the target cells in the pituitary contain gonadotropins. In the third set of studies, avidin gold or avidin peroxidase was used to label sites of hybridization of a biotinylated cRNA probe to gonadotropin beta subunit mRNA. The sites of hybridization appear on rough endoplasmic reticulum; however, further work is needed to improve cell ultrastructure and perserve antigens. Triple-labeling protocols (avidin-peroxidase followed by immunogold) show the feasibility of the technique as well as the need for further refinement. To summarize, these studies describe multiple applications of gold labels for the localization of antigens, ligands, and mRNA. The labels are sensitive for detection of antigens and ligands and easily quantified. Quantitative analyses show changes in concentration of gold label that correlate well with secretory states.     

Expression profiles of mouse Kell, XK, and XPLAC mRNA.

Kell and XK are related because in red cells they exist as a disulfide-bonded complex. Kell is an endothelin-3-converting enzyme, and XK is predicted to be a transporter. Absence of XK, which is accompanied by reduced Kell on red cells, results in acanthocytosis and late-onset forms of central nervous system and neuromuscular abnormalities that characterize the McLeod syndrome. In this study, expression of mouse XK, XPLAC, a homolog of XK, and Kell were compared by in situ hybridization histochemistry (ISHH) and RT-PCR. ISHH showed that Kell and XK are coexpressed in erythroid tissues. ISHH detected XK, but not Kell, mRNA in testis, but RT-PCR indicated that both Kell and XK are coexpressed. XK, but not Kell, was significantly expressed in brain, spinal cord, small intestine, heart, stomach, bladder, and kidney. ISHH did not detect XK in skeletal muscle but RT-PCR did. In brain, XK was predominantly expressed in neuronal rather than in supportive cells. By contrast, XPLAC was predominantly expressed in the thymus. Coexpression of Kell and XK in erythroid tissues and the different expressions in non-erythroid tissues suggest that XK may have a complementary hematological function with Kell and a separate role in other tissues.     

Properties of rat and mouse beta-glucuronidase mRNA and cDNA, including evidence for sequence polymorphism and genetic regulation of mRNA levels

cDNA clones containing partial sequences for beta-glucuronidase (beta G) were constructed from rat preputial gland RNA and identified by their ability to selectively hybridize beta G mRNA. One such rat clone was used to isolate several cross-hybridizing clones from a mouse-cDNA library prepared from kidney RNA from androgen-treated animals. Together, the set of mouse clones spans about 2.0 kb of the 2.6-kb beta G mRNA. Using these cDNA clones as probes, a genomic polymorphism for DNA restriction fragment size was found that proved to be genetically linked to the beta G gene complex. A fragment of beta G cDNA was subcloned into a vector carrying an SP6 polymerase promoter to provide a template for the in vitro synthesis of single-stranded RNA complementary to beta G mRNA. This provided an extremely sensitive probe for the assay of beta G mRNA sequences. Using either nick-translated cDNA or transcribed RNA as a hybridization probe, we found that mouse beta G RNA levels are strongly induced by testosterone, and that induction by testosterone is pituitary-dependent. During the lag period preceding induction, during the induction period itself, and during deinduction following removal of testosterone, beta G mRNA levels paralleled rates of beta G synthesis previously measured by in vivo pulse-labelling experiments. Genetic variation in the extent of induction affected either the level of beta G mRNA or its efficiency of translation depending on the strain of mice tested.