Water in the Avian Egg Overall Budget of Incubation

The loss of mass in eggs during incubation was examined andevidence is presented to show that this is essentially due toloss of water. The mean fraction of water lost by diffusionthroughout incubation is 0.150 ± 0.025 S D per gram ofegg and 0.162 ± 0.026 S D per gram of egg content for81 species. The water fraction of fresh eggs and of hatchingeggs was examined in 32 species divided according to maturityat hatching, and found to be very similar within each category(83% in altricial 83% in semi-altricial 78% in semi-precocial72% in precocial eggs). The 11% difference between the altricialand precocial categories is statistically significant. Duringincubation, dry matter is metabolized increasing the water fractionwhich is further increased by metabolic water production. Hence,water loss during incubation is mandatory if the relative watercontent of an egg at the end of incubation is to remain essentiallythe same as at the beginning. Equations are developed whichallow one to estimate the difference between diffusive waterloss and the total water loss in altricial and piecocial eggscaused by additional water loss during pipping and hatching.     

Host and Viral Translational Mechanisms during Cricket Paralysis Virus Infection

The dicistrovirus is a positive-strand single-stranded RNA virus that possesses two internal ribosome entry sites (IRES) that direct translation of distinct open reading frames encoding the viral structural and nonstructural proteins. Through an unusual mechanism, the intergenic region (IGR) IRES responsible for viral structural protein expression mimics a tRNA to directly recruit the ribosome and set the ribosome into translational elongation. In this study, we explored the mechanism of host translational shutoff in Drosophila S2 cells infected by the dicistrovirus, cricket paralysis virus (CrPV). CrPV infection of S2 cells results in host translational shutoff concomitant with an increase in viral protein synthesis. CrPV infection resulted in the dissociation of eukaryotic translation initiation factor 4G (eIF4G) and eIF4E early in infection and the induction of deIF2α phosphorylation at 3 h postinfection, which lags after the initial inhibition of host translation. Forced dephosphorylation of deIF2α by overexpression of dGADD34, which activates protein phosphatase I, did not prevent translational shutoff nor alter virus production, demonstrating that deIF2α phosphorylation is dispensable for host translational shutoff. However, premature induction of deIF2α phosphorylation by thapsigargin treatment early in infection reduced viral protein synthesis and replication. Finally, translation mediated by the 5′ untranslated region (5′UTR) and the IGR IRES were resistant to impairment of eIF4F or eIF2 in translation extracts. These results support a model by which the alteration of the deIF4F complex contribute to the shutoff of host translation during CrPV infection, thereby promoting viral protein synthesis via the CrPV 5′UTR and IGR IRES.For productive viral protein expression, viruses have to compete for and hijack the host translational machinery (45). Some viruses such as poliovirus, vesicular stomatitis virus (VSV), and influenza virus selectively antagonize the translation apparatus to shut off host translation, resulting in the release of ribosomes from host mRNAs and the inhibition of antiviral responses. On the other hand, the host cell can counteract through antiviral mechanisms to shutdown viral translation. For instance, viral RNA replication intermediates can trigger PKR, leading to an inhibition of overall translation. To bypass the block in translation, viruses have evolved unique mechanisms to preferentially recruit the ribosome for viral protein synthesis. Thus, the control of the translational machinery during infection is a major focal point in the battle between the host and the virus and often, elucidation of these viral translational shutoff strategies reveals key targets of translational regulation.The majority of cellular mRNAs initiate translation through the recruitment of the cap-binding complex, eukaryotic translation initiation factor 4F (eIF4F), to the 5′ cap of the mRNA (56). eIF4F consists of the cap-binding protein eIF4E, the RNA helicase, eIF4A, and the adaptor protein eIF4G. eIF4G acts as a bridge to join eIF4E and the 40S subunit via eIF3. With the ternary eIF2-Met-tRNA_i-GTP complex bound, the 40S subunit scans in a 5′-to-3′ direction until an AUG start codon is encountered. Here, eIF5 mediates GTP hydrolysis on the ternary complex, releasing the eIFs and subsequently leading to 60S subunit joining to assemble an elongation-competent 80S ribosome. The ternary eIF2-Met-tRNA_i-GTP complex is reactivated for another round of translation by exchange of GDP for GTP, which is mediated by the guanine nucleotide exchange factor, eIF2B. The 3′ poly(A) tail of the mRNA also stimulates translational initiation by binding to the poly(A) binding protein (PABP), which in turn interacts with eIF4G at the 5′end, resulting in a circularized mRNA. PABP has been proposed to enhance eIF4E affinity for the 5′cap and promote 60S joining, indicating that PABP functions at multiple steps of translational initiation (33).A common tactic viruses use to inhibit host translation is to selectively target eIFs. One of the best studied is the cleavage of eIF4G by viral proteases during picornavirus infection. In humans, two isoforms, eIF4GI and eIF4GII, are cleaved early in poliovirus infection by the viral protease 2A, where cleavage of eIFGII correlates more precisely with host translation shutoff (20). Cleavage of eIF4G produces an amino-terminal fragment that binds to eIF4E and a C-terminal fragment that binds to eIF4A and eIF3 (26, 39, 42). PABP is also cleaved by the viral protease 3C during poliovirus infection, thus contributing to shutoff of both host and viral translation and thereby enabling the switch from viral translation to replication (3, 31, 38). Another major target is the availability of the cap-binding protein eIF4E, which is regulated by binding to the repressor protein 4E-BP (21, 41). 4E-BP and eIF4G compete for an overlapping site on eIF4E (42). In its hypophosphorylated state, 4E-BP binds to and sequesters eIF4E, preventing eIF4G recruitment. Dephosphorylation and activation of 4E-BP has been observed during poliovirus, encephalomyocarditis (EMCV), and VSV infections (7, 18).During virus infection, host antiviral responses are triggered that also inhibit translation to counteract viral protein synthesis. An integral antiviral response is phosphorylation at Ser⁵¹ of eIF2α, which reduces the pool of the ternary complex by blocking the eIF2B-dependent exchange of GDP to GTP. In mammals, four known eIF2α kinases exist including the endoplasmic reticulum (ER)-stress-inducible PERK, GCN2, which senses the accumulation of deacylated tRNAs during amino acid starvation conditions; the heme-regulated kinase HRI; and the interferon-inducible double-stranded RNA-binding PKR (64). In mammalian cells, PKR is activated by binding to double-stranded viral RNA replication intermediates, leading to eIF2α phosphorylation and inhibition of overall host and viral translation. PERK and GCN2 have also been shown to be activated during virus infections by VSV and members of the alphavirus family (2, 6, 43, 65, 79). Often, viruses rely on the ER for synthesis and proper folding of viral proteins. The large burden on the ER activates PERK to phosphorylate eIF2α, thereby inhibiting global protein synthesis to reduce the load on the ER (23). Some viruses such as HCV and herpes simplex viruses have adapted to responses that induce eIF2α phosphorylation by producing viral proteins that counteract PKR or modulate the ER stress response (27, 76). Thus, virus infection can trigger several eIF2α kinases that lead to translational shutoff to counteract viral protein synthesis.To circumvent these translation blocks, viruses such as poliovirus and hepatitis C virus utilize internal ribosome entry sites (IRES), which are RNA elements that directly recruit ribosomes in a cap-independent manner and require only a subset of canonical eIFs (15, 25). It is generally thought that IRES-containing viral mRNAs can be translated under conditions when specific eIFs are compromised during infection. Except for a few cases, the specific mechanisms and factors that lead to IRES stimulation is poorly understood. For example, poliovirus and the related EMCV possess an IRES that allows viral translation despite cleavage of eIF4G during infection or inhibiting eIF4E by 4E-BP binding. This type of IRES can still bind to the central domain of eIF4G and mediate 40S subunit recruitment (11, 37, 57).One of the most unique and simplest IRES is found within the intergenic region (IGR) of the Dicistroviridae family (for extensive reviews, see references 28, 36, and 49). Members of this family include the cricket paralysis virus (CrPV), drosophila C virus (DCV), taura syndrome virus, the Plautia stali intestine virus (PSIV), the Rhopalosiphum padi virus (RhPV), and several bee viruses such as the black queen cell virus and the Israeli acute paralysis virus, which has been recently linked to colony collapse disorder (10). The dicistroviruses encode a positive-strand 8- to 10-kb single-stranded RNA genome, which contains two main open reading frames, ORF1 and ORF2, encoding the nonstructural and structural proteins, respectively, separated by an IGR (see Fig. ​Fig.1A).1A). The 5′ end of the CrPV RNA is linked to the viral protein VpG and the 3′ end contains a poly(A) tail (16). Radiolabeling of intracellular RNA in infected cells reveals no subgenomic RNA species smaller than the full-length genomic RNA, and this has been supported by Northern blot analysis (16, 81). Translation of ORF2 is directed by the IGR IRES, whereas ORF1 expression is mediated by an IRES within the 5′ untranslated region (5′UTR) (35, 67, 81, 82). Remarkably, the IGR IRES element can directly recruit the ribosome independently of eIFs or the initiator Met-tRNA_i (29, 30, 54, 80). Furthermore, the IRES occupies the P-site of the ribosome to initiate translation from the ribosomal A-site encoding non-AUG codon (35, 81). Extensive biochemical and structural analyses from several groups have revealed that the IGR IRES mimics a tRNA that occupies the mRNA cleft of the ribosome and sets the ribosome into an elongation state (9, 29, 30, 34, 51, 55, 58, 68, 72, 83). Using reporter constructs, it has also been demonstrated that CrPV IGR IRES-mediated translation is active under a number of cellular conditions when the activity of the ternary complex eIF2-Met-tRNA_i-GTP is compromised (17, 63, 78, 80). Because IGR IRES-mediated translation does not require initiation factors, the IRES can direct translation under a number of cellular conditions when the activity of multiple eIFs is compromised (12). Although the majority of studies have focused on the IGR IRES of CrPV, PSIV, and TSV, it is predicted that the IGRs within this viral family all function similarly based on the predicted conserved RNA structures (28, 36, 49). In contrast, only the 5′UTR IRES mechanism of RhPV has been studied in detail (77). Despite the wealth of studies on the mechanics of these IRES, the mechanisms that lead to translational shutoff during dicistrovirus infection and the interaction of dicistrovirus with the host machinery to allow virus production have been relatively unexplored.Open in a separate windowFIG. 1.Kinetics of host protein synthesis and viral protein expression in CrPV-infected Drosophila S2 cells. (A) Genomic arrangement of the CrPV RNA. The viral open reading frames, ORF1 and ORF2, that encode nonstructural (NS) and structural (S) proteins, respectively, are shown, which are separated by the intergenic internal ribosome entry site (IGR IRES). Translation of ORF1 and ORF2 is directed by the 5′UTR IRES and the IGR IRES, respectively. The first amino acid of ORF2 directed by the IGR IRES is encoded by a GCU alanine codon. (B) Autoradiography of protein lysates resolved on a SDS-12% PAGE gel. The protein lysates were collected from S2 cells that were untreated (U), mock infected (M), CrPV infected (5 FFU/cell), or thapsigargin treated (Tg; 0.4 μM) for the indicated times (h p.i.) and metabolically labeled with [³⁵S]methionine for 30 min at each time point. The migration of proteins with known molecular masses is shown on the left. The expression of detectable nonstructural (NS) and structural (S) proteins is denoted. (C) Quantitation of host protein synthesis during CrPV infection. To calculate the host translation at each time point, the amount of radioactivity of the bands between 55 and 70 kDa in panel A was quantitated by using ImageQuant, and the percent translation was calculated at each time point of virus infection or thapsigargin treatment compared to the mock infection. Shown are averages (± the standard deviation) from at least three independent experiments. (D) Immunoblots of viral ORF1 and ORF2 during CrPV infection at various times postinfection (h p.i.). Antibodies were raised against peptides within ORF1 and ORF2. The expression of ORF1 and ORF2 was quantitated by a LI-COR Odyssey system, plotted against time of infection, and normalized to the amount of ORF1 or ORF2 expression at 6 h p.i. (100%). As a comparison, viral RNA synthesis as detected by Northern blot analysis (see Fig. ​Fig.2B)2B) is plotted on the same graph.Previous studies have shown that the CrPV and the related DCV can infect a wide range of insect hosts, including the Drosophila melanogaster S2 cell line (60, 69). In the present study, we have explored how CrPV infection leads to host translational shutoff in S2 cells. Two steps of translational initiation are targeted during CrPV infection. First, the interaction of deIF4G with deIF4E is disrupted early in infection and remains dissociated during the course of infection. Second, deIF2α is phosphorylated at a time that lags after the initial host translational shutoff during infection. Premature phosphorylation of deIF2α early in infection inhibited translation directed by the 5′UTR IRES, but IGR IRES-mediated translation remained relatively resistant. These results support the model that multiple mechanisms, including impairment of deIF4F complex formation and induction of deIF2α phosphorylation, contribute to the host translational shutoff during CrPV infection. The inhibition of host translation and the release of ribosomes from host mRNAs ensures that translation mediated by the 5′UTR and IGR IRES is optimal to produce sufficient viral nonstructural and structural proteins for proper CrPV maturation and assembly.     

Translation initiation factor modifications and the regulation of protein synthesis in apoptotic cells

The rate of protein synthesis is rapidly down-regulated in mammalian cells following the induction of apoptosis. Inhibition occurs at the level of polypeptide chain initiation and is accompanied by the phosphorylation of the alpha subunit of initiation factor eIF2 and the caspase-dependent cleavage of initiation factors eIF4G, eIF4B, eIF2alpha and the p35 subunit of eIF3. Proteolytic cleavage of these proteins yields characteristic products which may exert regulatory effects on the translational machinery. Inhibition of caspase activity protects protein synthesis from long-term inhibition in cells treated with some, but not all, inducers of apoptosis. This review describes the initiation factor modifications and the possible signalling pathways by which translation may be regulated during apoptosis. We discuss the significance of the initiation factor cleavages and other changes for protein synthesis, and the implications of these events for our understanding of the cellular changes associated with apoptosis.     

Warthin''s tumour: unusual vs. common morphological findings in fine needle aspiration biopsies

Fine needle aspiration biopsies (FNA) of 47 Warthin's tumours confirmed by histology were re-evaluated for cytomorphological findings. The majority of aspirates (37/47) contained a typical background with proteinaceous substance and cell debris, along with cellular elements represented by oncocytic, lymphoid, and mast cells with degranulated cytoplasm. Uncommon cellular findings were true squamous cells (1/47), atypical cells with vacuoles (1/47), osteoclastic giant cells (1/47), epithelioid cells (1/47), mast cells with preserved granules in cytoplasm (3/47), and siderophages (4/47). Uncommon findings in the background were corpora amylacea-like structures and homogeneous bright red droplets. Squamous cells and atypical cells with vacuoles caused diagnostic difficulties in distinguishing a Warthin's tumour from a squamous cell or mucoepidermoid carcinoma. However, other unusual cellular and background findings were not worrying; therefore, they are merely regarded as a curiosity in the cytomorphological appearance of the tumour.     

Effects of carbon dioxide exposure on early brain development in rats

The developing brain is vulnerable to environmental factors. We investigated the effects of air that contained 0.05, 0.1 and 0.3% CO₂ on the hippocampus, prefrontal cortex (PFC) and amygdala. We focused on the circuitry involved in the neurobiology of anxiety, spatial learning, memory, and on insulin-like growth factor-1 (IGF-1), which is known to play a role in early brain development in rats. Spatial learning and memory were impaired by exposure to 0.3% CO₂ air, while exposure to 0.1 and 0.3% CO₂ air elevated blood corticosterone levels, intensified anxiety behavior, increased superoxide dismutase (SOD) enzyme activity and MDA levels in hippocampus and PFC; glutathione peroxidase (GPx) enzyme activity decreased in the PFC with no associated change in the hippocampus. IGF-1 levels were decreased in the blood, PFC and hippocampus by exposure to both 0.1 and 0.3% CO₂. In addition, apoptosis was increased, while cell numbers were decreased in the CA1 regions of hippocampus and PFC after 0.3% CO₂ air exposure in adolescent rats. A positive correlation was found between the blood IGF-1 level and apoptosis in the PFC. We found that chronic exposure to 0.3% CO₂ air decreased IGF-1 levels in the serum, hippocampus and PFC, and increased oxidative stress. These findings were associated with increased anxiety behavior, and impaired memory and learning.     

Selection of objective function in genome scale flux balance analysis for process feed development in antibiotic production

Using flux variability analysis of a genome scale metabolic network of Streptomyces coelicolor, a series of reactions were identified, from disparate pathways that could be combined into an actinorhodin-generating mini-network. Candidate process feed nutrients that might be expected to influence this network were used in process simulations and in silico predictions compared to experimental findings. Ranking potential process feeds by flux balance analysis optimisation, using either growth or antibiotic production as objective function, did not correlate with experimental actinorhodin yields in fed processes. However, the effect of the feeds on glucose assimilation rate (using glucose uptake as objective function) ranked them in the same order as in vivo antibiotic production efficiency, consistent with results of a robustness analysis of the effect of glucose assimilation on actinorhodin production.