In Amnio MRI of Mouse Embryos

Mouse embryo imaging is conventionally carried out on ex vivo embryos excised from the amniotic sac, omitting vital structures and abnormalities external to the body. Here, we present an in amnio MR imaging methodology in which the mouse embryo is retained in the amniotic sac and demonstrate how important embryonic structures can be visualised in 3D with high spatial resolution (100 µm/px). To illustrate the utility of in amnio imaging, we subsequently apply the technique to examine abnormal mouse embryos with abdominal wall defects. Mouse embryos at E17.5 were imaged and compared, including three normal phenotype embryos, an abnormal embryo with a clear exomphalos defect, and one with a suspected gastroschisis phenotype. Embryos were excised from the mother ensuring the amnion remained intact and stereo microscopy was performed. Embryos were next embedded in agarose for 3D, high resolution MRI on a 9.4T scanner. Identification of the abnormal embryo phenotypes was not possible using stereo microscopy or conventional ex vivo MRI. Using in amnio MRI, we determined that the abnormal embryos had an exomphalos phenotype with varying severities. In amnio MRI is ideally suited to investigate the complex relationship between embryo and amnion, together with screening for other abnormalities located outside of the mouse embryo, providing a valuable complement to histology and existing imaging methods available to the phenotyping community.     

Virulence for chickens of Clostridium perfringens isolated from poultry and other sources

Clostridium perfringens type A is the most common cause of poultry necrotic enteritis (NE). Of the four “major” toxins, type A strains produce only alpha toxin (CPA), which has long been considered a major factor in pathogenesis of NE. We investigated the virulence for poultry of type A strains from a variety of enteric sources. Newly-hatched Cornish × Rock chicks were fed a low protein diet for one week, a high protein diet for a second week, and then challenged with log-phase cultures of C. perfringens, mixed 3:4 (v/v) with high protein feed. Strain JGS4143 [genotype A, beta2 positive (cpb2^pos), from a field case of NE] produced gross lesions compatible with NE in >85% of challenged birds. However, strains JGS1714 (enterotoxigenic genotype A, cpb2^pos, human food poisoning), JGS1936 (genotype A, cpb2^neg, bovine neonatal enteritis), JGS4142 (genotype A, cpb2^pos, bovine jejunal hemorrhage syndrome), JGS1473 (genotype A, cpb2^pos, chicken normal flora), JGS1070 (genotype C, cpb2^pos, porcine hemorrhagic enteritis), JGS1882 (genotype A, cpb2^pos, porcine neonatal enteritis), JGS1120 (ATCC 13124, genotype A, cpb2^neg, gas gangrene), JGS4151 (strain 13, genotype A, cpb2^pos, canine), and JGS4303 (SM101, enterotoxigenic genotype A, cpb2^neg, human food poisoning) failed to produce disease. In vivo passage failed to increase virulence of the non-NE strains. NE strains must have specific poultry-associated virulence attributes, such as the recently identified NetB and other factors, which allow for the development of disease.     

Non-channel functions of connexins in cell growth and cell death

Cellular communication mediated by gap junction channels and hemichannels, both composed of connexin proteins, constitutes two acknowledged regulatory platforms in the accomplishment of tissue homeostasis. In recent years, an abundance of reports has been published indicating functions for connexin proteins in the control of the cellular life cycle that occur independently of their channel activities. This has yet been most exemplified in the context of cell growth and cell death, and is therefore as such addressed in the current paper. Specific attention is hereby paid to the molecular mechanisms that underpin the cellular non-channel roles of connexin proteins, namely the alteration of the expression of tissue homeostasis determinants and the physical interaction with cell growth and cell death regulators. This article is part of a Special Issue entitled: The Communicating junctions, composition, structure and characteristics.     

Caldinitratiruptor microaerophilus, gen. nov., sp. nov. isolated from a French hot spring (Chaudes-Aigues, Massif Central): a novel cultivated facultative microaerophilic anaerobic thermophile pertaining to the Symbiobacterium branch within the Firmicutes

A novel facultative microaerophilic nitrate-reducing bacterium designated CA62N^T was isolated from a thermal spring in France. Cells were non-motile rods (2–3 × 0.2 μm) and showed low cytoplasmic density when observed under a phase-contrast microscope. Strain CA62N^T grew at temperatures between 50 and 75°C (optimum 65°C) and at a pH between 6.3 and 7.9 (optimum 7.0). NaCl was not required for growth but was tolerated up to 10 gl⁻¹. Sulfate, thiosulfate, elemental sulfur, sulfite, and nitrite were not used as electron acceptors. Nitrate was reduced to nitrite. Strain CA62N^T used lactate, pyruvate, glucose, mannose, fructose, and casamino acids and some amino acids as electron donors only in the presence of nitrate as electron acceptor. None of these substrates was fermented. The main end-products of glucose oxidation were acetate, CO₂, and traces of H₂. The G + C content of the genomic DNA was 70.3 mol% (HPLC techniques). Phylogenetic analysis of the small-subunit (SSU) ribosomal RNA (rRNA) gene sequence indicated that strain CA62N^T was affiliated to the Symbiobacterium branch within the Firmicutes and had Symbiobacterium thermophilum and “S. toebii” as its closest phylogenetic relatives. On the basis of phylogenetical and physiological characteristics, strain CA62N^T is proposed to be the type strain for the novel species in the novel genus, Caldinitratiruptor microaerophilus gen. nov., sp. nov. (DSM 22660, JCM 16183).     

Ultrastructure of Human labial salivary glands

Summary Human labial salivary glands, obtained by biopsy from 32 subjects, were studied by light and electron microscopy. Intranuclear inclusions, unrelated to nucleoli, were present in many of the acinar nuclei in glands from 16 of the 32 donors. More than one inclusion was sometimes observed within a single nucleus. They measured about 1 in diameter, and were stainable in a variety of ways. They were eosinophilic, some were stained by Nile blue sulphate, some were PAS-positive, and all were Feulgen-negative. They were bounded by a single membrane, which never exhibited continuity with the nuclear envelope, and they showed considerable morphological variation. The more complex inclusions consisted of alternating shells of light and dark material with tiny dense granules embedded in the latter. The intranuclear inclusions, which apparently were non-viral in origin, were in some way related to the secretory cycle of the mucous cells, since they were found only in immature cells, and never in cells in which secretory products were abundant.This work was supported in part by grants from the Henry Spenadel Trust and the Max C. Fleischmann Foundation of Nevada, by grant CA-08748 from the National Cancer Institute, by grant 5 SO1 FR 05335-07 from the National Institutes of Health, by a grant from the National Cystic Fibrosis Research Foundation, and by an Institutional Grant to the School of Dental and Oral Surgery, Columbia University, from the National Institutes of Health.The authors are indebted to Dr.Louis Mandel for performing the biopsies used in this study. The expert technical assistance of Mrs.Mona Seggio is acknowledged.     

Increased effect of the ApoE gene on survival at advanced age in healthy and long‐lived Danes: two nationwide cohort studies

Studies of Nordic twins suggest an increased genetic influence on mortality with age. Contrary to this, the heterogeneity hypothesis predicts that the mortality of individuals carrying a ‘frail’ or ‘risky’ genotype in a population will approach that of noncarriers with age because of selection pressure. The ApoE ε4 allele is associated with an increased mortality risk, and its effect has been suggested to decrease with age. Here, we investigated the effect of ApoE ε4 allele on survival in a sample of the healthiest and long‐lived Danes. The study population comprised Danes born in 1905 and a replicate sample of the 1895 cohort. For the 1905 cohort, a total of 350 carriers and 1256 noncarriers of the ApoE ε4 allele were followed from 1998 until death or end of follow‐up. Cox regression models were used for the analysis. Of the 1606 persons with known ApoE ε4 status in 1998, 1546 had died at the end of the 10‐year follow‐up. Carriers of the ApoE ε4 allele had an increased mortality compared to noncarriers, and the influence of ApoE status on mortality increased in the age interval 92–103. For the covariates sex and independency status, the difference in relative risk of death between groups decreased with advancing age. Our findings of increasing influence of ApoE ε4 allele on mortality with age do not support previous findings of decreased influence ApoE ε4 allele on mortality with age, and alternative models such as the multifactorial threshold models should be considered for understanding the genetic effects on mortality at advanced age.     

A new righteye flounder, Poecilopsetta multiradiata (Teleostei: Pleuronectiformes: Poecilopsettidae), from New Zealand and New Caledonia (South-West Pacific)

A new righteye flounder, Poecilopsetta multiradiata, is described from eight specimens (two males and six females) collected from deep waters (336–408 m) around New Zealand and New Caledonia (South-West Pacific). This new species is distinguished from its 14 congeners by the following combination of characters: high numbers of dorsal (70–73) and anal (58–62) fin rays, ca. 85–99 lateral-line scales, 31–32 caudal vertebrae, and a relatively shallow body depth of 36.9–41.9% SL.     

Control of Cell Survival and Proliferation by Mammalian Eukaryotic Initiation Factor 4B

Translation initiation plays an important role in cell growth, proliferation, and survival. The translation initiation factor eIF4B (eukaryotic initiation factor 4B) stimulates the RNA helicase activity of eIF4A in unwinding secondary structures in the 5′ untranslated region (5′UTR) of the mRNA in vitro. Here, we studied the effects of eIF4B depletion in cells using RNA interference (RNAi). In agreement with the role of eIF4B in translation initiation, its depletion resulted in inhibition of this step. Selective reduction of translation was observed for mRNAs harboring strong to moderate secondary structures in their 5′UTRs. These mRNAs encode proteins, which function in cell proliferation (Cdc25C, c-myc, and ODC [ornithine decarboxylase]) and survival (Bcl-2 and XIAP [X-linked inhibitor of apoptosis]). Furthermore, eIF4B silencing led to decreased proliferation rates, promoted caspase-dependent apoptosis, and further sensitized cells to camptothecin-induced cell death. These results demonstrate that eIF4B is required for cell proliferation and survival by regulating the translation of proliferative and prosurvival mRNAs.Targeting the translation initiation pathway is emerging as a potential therapy for inhibiting cancer cell growth (35, 38). Ribosome recruitment to the 5′ ends of eukaryotic mRNAs proceeds via translation initiation mechanisms that are dependent either on the 5′ cap structure (m⁷GpppN, where N is any nucleotide) or an internal ribosome entry site (IRES). The majority of translation initiation events in eukaryotes are mediated through cap-dependent translation whereby the 40S ribosomal subunit is recruited to the vicinity of the mRNA 5′ cap structure by the eukaryotic initiation factor 4F (eIF4F) complex. eIF4F is comprised of eIF4E (the cap-binding subunit), eIF4A (an RNA helicase), and eIF4G (a large scaffolding protein for eIF4E, eIF4A, and other initiation factors). Once assembled at the 5′ cap, the 40S ribosomal subunit in association with several initiation factors scans the 5′ untranslated region (5′UTR) of the mRNA until it encounters a start codon in a favorable context, followed by polypeptide synthesis (37).Early in vitro studies have shown that the initiation factor eIF4B acts to potentiate ribosome recruitment to the mRNA (3, 45). eIF4B stimulates translation of both capped and uncapped mRNAs in vitro (1, 36). This function is exerted through stimulation of the helicase activity of eIF4A (43), possibly through direct interactions with eIF4A (44) or with mRNA, the ribosome-associated eIF3, and 18S rRNA (28, 29, 44). Thus, eIF4B is thought to form auxiliary bridges between the mRNA and the 40S ribosomal subunit. Toeprinting studies using mammalian eIF4B underscored its importance in the assembly of the 48S initiation complex, especially on mRNAs harboring secondary structures in the 5′UTRs (11).In vivo studies of eIF4B are limited. Ectopic expression of eIF4B in cultured Drosophila melanogaster cells and in developing eye imaginal discs stimulated cell proliferation (16). Enhanced cell proliferation is most likely mediated by increased translation of a subset of mRNAs, since knockdown of Drosophila eIF4B by RNA interference (RNAi) caused a modest reduction in global translation but compromised the survival of insect cells grown under low serum conditions (16). Studies of eIF4B in mammalian cells yielded contradictory results. Transient overexpression of eIF4B stimulated translation initiation in a phosphorylation-dependent manner in some cells (18, 49) while inhibiting translation in others (30, 31, 41). These differences might be attributed to disparate levels of eIF4B overexpression.To address the physiological role of eIF4B in mRNA translation in the cell, RNAi knockdown of eIF4B was used here. We demonstrate that eIF4B is required for optimal translation. Importantly, the translation of mRNAs bearing structured 5′UTRs, such as the cell cycle regulators Cdc25C, c-myc, and ODC (ornithine decarboxylase), and the antiapoptotic factors Bcl-2 and XIAP (X-linked inhibitor of apoptosis), was reduced as a result of eIF4B silencing by RNAi. Furthermore, eIF4B silencing promoted caspase-dependent apoptosis. Thus, we show that mammalian eIF4B is required for cell proliferation and survival, whereby it acts by regulating the translation of a functionally related subset of mRNAs.