Structural changes of eIF4E upon binding to the mRNA 5' monomethylguanosine and trimethylguanosine Cap

Recognition of the 5' cap by the eukaryotic initiation factor 4E (eIF4E) is the rate-limiting step in the ribosome recruitment to mRNAs. The regular cap consists of 7-monomethylguanosine (MMG) linked by a 5'-5' triphosphate bridge to the first transcribed nucleoside, while some primitive eukaryotes possess a N (2), N (2),7-trimethylguanosine (TMG) cap structure as a result of trans splicing. Mammalian eIF4E is highly specific to the MMG form of the cap in terms of association constants and thermodynamic driving force. We have investigated conformational changes of eIF4E induced by interaction with two cap analogues, 7-methyl-GTP and N (2), N (2),7-trimethyl-GTP. Hydrogen-deuterium exchange and electrospray mass spectrometry were applied to probe local dynamics of murine eIF4E in the apo and cap-bound forms. The data show that the cap binding induces long-range conformational changes in the protein, not only in the cap-binding pocket but also in a distant region of the 4E-BP/eIF4G binding site. Formation of the complex with 7-methyl-GTP makes the eIF4E structure more compact, while binding of N (2), N (2),7-trimethyl-GTP leads to higher solvent accessibility of the protein backbone in comparison with the apo form. The results suggest that the additional double methylation at the N (2)-amino group of the cap causes sterical effects upon binding to mammalian eIF4E which influence the overall solution dynamics of the protein, thus precluding formation of a tight complex.     

The g5R (D250) gene of African swine fever virus encodes a Nudix hydrolase that preferentially degrades diphosphoinositol polyphosphates.

The African swine fever virus (ASFV) g5R gene encodes a protein containing a Nudix hydrolase motif which in terms of sequence appears most closely related to the mammalian diadenosine tetraphosphate (Ap4A) hydrolases. However, purified recombinant g5R protein (g5Rp) showed a much wider range of nucleotide substrate specificity compared to eukaryotic Ap4A hydrolases, having highest activity with GTP, followed by adenosine 5'-pentaphosphate (p5A) and dGTP. Diadenosine and diguanosine nucleotides were substrates, but the enzyme showed no activity with cap analogues such as 7mGp3A. In common with eukaryotic diadenosine hexaphosphate (Ap6A) hydrolases, which prefer higher-order polyphosphates as substrates, g5Rp also hydrolyzes the diphosphoinositol polyphosphates PP-InsP5 and [PP]2-InsP4. A comparison of the kinetics of substrate utilization showed that the k(cat)/K(m) ratio for PP-InsP5 is 60-fold higher than that for GTP, which allows classification of g5R as a novel diphosphoinositol polyphosphate phosphohydrolase (DIPP). Unlike mammalian DIPP, g5Rp appeared to preferentially remove the 5-beta-phosphate from both PP-InsP5 and [PP]2-InsP4. ASFV infection led to a reduction in the levels of PP-InsP5, ATP and GTP by ca. 50% at late times postinfection. The measured intracellular concentrations of these compounds were comparable to the respective K(m) values of g5Rp, suggesting that one or all of these may be substrates for g5Rp during ASFV infection. Transfection of ASFV-infected Vero cells with a plasmid encoding epitope-tagged g5Rp suggested localization of this protein in the rough endoplasmic reticulum. These results suggest a possible role for g5Rp in regulating a stage of viral morphogenesis involving diphosphoinositol polyphosphate-mediated membrane trafficking.     

An Autoradiographic Study of the Developing Parietal Cell Population In Neonatal Pigs

Abstract. Autoradiographic labelling using tritiated thymidine ([³H]TdR) was used to examine the pattern of development of gastric parietal cells in newborn pigs. Specific objectives were to establish sites in the gland where cells with a characteristic parietal cell morphology first appear, the extent of their migration or displacement, and the kinetics of any development and migration that occurs. Five newly-born littermate piglets were given a virtually continuous label of [³H]TdR over 24 hr, sacrificed at 1, 3, 5, 7 and 10 days thereafter, and samples of the gastric mucosa taken. the percentage of labelled parietal cells as a function of position in the oxyntic gland was measured for each pig. A generalized log linear model was fitted to the data using the statistical package GLIM, confirming a significant trend for labelled cells to occupy higher sites in the oxyntic gland as the time since labelling of cells increased. Goodness of fit tests showed that the trend effect was highly unlikely to be due to the variability of cell distribution from animal to animal. the dynamics of the parietal cell population and the strengths of GLIM for analysing cell labelling data are discussed.     

Morphometry of nucleoli and expression of nucleolin analyzed by laser scanning cytometry in mitogenically stimulated lymphocytes.

BACKGROUND: Various attributes of nucleoli, including abundance of the nucleolar product (rRNA), correlate with cell-proliferative status and are useful markers for tumor diagnosis and prognosis. However, there is a paucity of methods that can quantitatively probe nucleolus. The aim of the present study was to utilize the morphometric capacity of the laser scanning cytometer (LSC) to analyze nucleoli and measure expression of the nucleolar protein nucleolin (NCL) in individual cells and correlate it with their state of proliferation. MATERIALS AND METHODS: Human lymphocytes were mitogenically stimulated, and at different time points their nucleoli were detected immunocytochemically using NCL Ab. The frequency of nucleoli per nucleus, their area, and the level of expression of NCL, separately in the nuclear and nucleolar compartments, were estimated in relation to the G(0) to G(1) transition and the cell cycle progression. RESULTS: During the first 24 h of stimulation, when the cells underwent G(0) to G(1) transition, their RNA content was increased nearly 8-fold, the level of NCL per nucleus also increased 8-fold, the NCL per nucleolus increased 12-fold, nucleolear area increased 3-fold, and NCL/nucleolar area increased nearly 4-fold. During the subsequent 24-48 h of stimulation, when cells were progressing through S, G(2), and M and reentering the next cycle, the number of nucleoli per nucleus was increased and a massive translocation of NCL from nucleoli to nucleoplasm was observed; its overall level per nucleus, however, still remained high, at 6-fold above of that of G(0) cells. CONCLUSIONS: While high expression of NCL in the nucleolar compartment correlates with the rate of rRNA accumulation in the cell and is a sensitive marker of the G(0) to G(1) transition, the cells progressing through the remainder of the cycle are better distinguished from G(0) cells by high overall level of NCL within the nucleus. Such an analysis, when applied to tumors, may be helpful in obtaining the quantitative parameters related to the kinetic status of the tumor-cell population and tumor prognosis. The capability of LSC to measure the protein translocation between nucleolus and nucleoplasm can be used to study the function and regulatory mechanisms of other proteins that reside in these compartments.     

mRNA decapping is promoted by an RNA-binding channel in Dcp2

Cap hydrolysis by Dcp2 is a critical step in several eukaryotic mRNA decay pathways. Processing requires access to cap-proximal nucleotides and the coordinated assembly of a decapping mRNP, but the mechanism of substrate recognition and regulation by protein interactions have remained elusive. Using NMR spectroscopy and kinetic analyses, we show that yeast Dcp2 resolves interactions with the cap and RNA body using a bipartite surface that forms a channel intersecting the catalytic and regulatory Dcp1-binding domains. The interaction with cap is weak but specific and requires binding of the RNA body to a dynamic interface. The catalytic step is stimulated by Dcp1 and its interaction domain, likely through a substrate-induced conformational change. Thus, activation of the decapping mRNP is restricted by access to 5'-proximal nucleotides, a feature that could act as a checkpoint in mRNA metabolism.