Loss of Drosophila pseudouridine synthase triggers apoptosis-induced proliferation and promotes cell-nonautonomous EMT.

Many developing tissues display regenerative capability that allows them to compensate cell loss and preserve tissue homeostasis. Because of their remarkable regenerative capability, Drosophila wing discs are extensively used for the study of regenerative phenomena. We thus used the developing wing to investigate the role played in tissue homeostasis by the evolutionarily conserved eukaryotic H/ACA small nucleolar ribonucleoprotein pseudouridine synthase. Here we show that localized depletion of this enzyme can act as an endogenous stimulus capable of triggering apoptosis-induced proliferation, and that context-dependent effects are elicited in different sub-populations of the silenced cells. In fact, some cells undergo apoptosis, whereas those surrounding the apoptotic foci, although identically depleted, overproliferate. This overproliferation correlates with ectopic induction of the Wg and JAK-STAT (Janus kinase-signal transducer and activator of transcription) mitogenic pathways. Expression of a p35 transgene, which blocks the complete execution of the death program and generates the so-called 'undead cells', amplifies the proliferative response. Pseudouridine synthase depletion also causes loss of apicobasal polarity, disruption of adherens cell junctions and ectopic induction of JNK (c-Jun N-terminal kinase) and Mmp1 (matrix metalloproteinase-1) activity, leading to a significant epithelial reorganization. Unexpectedly, cell-nonautonomous effects, such as epithelial mesenchymal transition in the contiguous unsilenced squamous epithelium, are also promoted. Collectively, these data point out that cell-cell communication and long-range signaling can take a relevant role in the response to pseudouridine synthase decline. Considering that all the affected pathways are highly conserved throughout evolution, it is plausible that the response to pseudouridine synthase depletion has been widely preserved. On this account, our results can add new light on the still unexplained tumor predisposition that characterizes X-linked dyskeratosis, the human disease caused by reduced pseudouridine synthase activity.

Drosophila alpha-1,4-glycosyltransferase (alpha-4GT1) inhibits reaper-mediated apoptosis in the eye.

In a genetic screen, alpha-4GT1 has been identified as a potential enhancer of Hairless-mediated cell death in the eye of Drosophila. alpha-4GT1 encodes an alpha-1,4-glycosyltransferase, known to catalyze the fifth step in a series of ceramide glycosylation events. As reported for other enzymes involved in the glycosylation of ceramide, alpha-4GT1 is strongly expressed during oogenesis and is deposited maternally in the egg. Moreover, the protein is enriched at cell membranes. Unexpectedly, overexpression of alpha-4GT1 does not enhance Hairless-mediated cell death; instead, Hairless enhancement is caused by an allele of Scutoid present on the alpha-4GT1 chromosome. Interestingly, the downregulation of alpha-4GT1 during eye development amplifies cell death induction by the pro-apoptotic gene reaper. Accordingly, overexpression of alpha-4GT1 represses reaper-induced cell death. Thus, alpha-4GT1 appears to be an inhibitor of apoptosis, as has previously been observed for other ceramide glycosylating enzymes, suggesting that it likewise contributes to ceramide anchoring in the membrane.

Quantitative real-time PCR detection of oral Enterococcus faecalis in humans.

OBJECTIVE: Enterococcus faecalis is consistently associated with recurrent root canal infections. Only low concentrations of E. faecalis in the human mouth have been demonstrated by culture techniques. Quantitative detection strategies more sensitive than culturing, such as quantitative PCR (qPCR), could provide more illuminating data. DESIGN: Thirty outpatients attending the University of Michigan Graduate Endodontic Clinic for endodontic treatment provided oral rinse samples that were analysed for E. faecalis using qPCR and microbiological culturing. A SYBR Green I qPCR protocol was developed for the quantifiable detection of E. faecalis and total bacteria in oral rinse samples using primers designed to target the 16S rRNA gene. Annealing temperature and primer, magnesium ion, and dimethyl sulfoxide concentrations were investigated for optimisation of the protocol; a minimum sensitivity limit of 23 rRNA copies (an estimated six E. faecalis cells) was established for E. faecalis in pure culture, and 104 rRNA copies (an estimated 26 E. faecalis cells) in mixed culture. RESULTS: In qPCR assays, based on extrapolation from estimated rRNA gene copy numbers, E. faecalis comprised 0.0006-0.0047% of a total bacteria load that ranged from 5.92 x 10(5) to 5.69 x 10(7) cells/ml of oral rinse. E. faecalis was detected in five (17%) samples in concentrations from 114 to 490 cells/ml. In parallel culture assays E. faecalis were detected in only two samples (7%) of the five identified by qPCR and in concentrations 30 and 240 CFU/ml. CONCLUSIONS: qPCR reported a higher incidence of E. faecalis in oral rinse samples than culture techniques and afforded greater sensitivity.

Influence of irrigant needle depth in removing bioluminescent bacteria inoculated into instrumented root canals using real-time imaging in vitro.

AIM: To test the hypothesis that the mechanical efficacy of irrigation in reducing bacteria in the root canal is dependent on depth of placement of the irrigation needle. METHODOLOGY: The root canals of 30 permanent cuspids were instrumented to apical size 60 using a crown-down technique. A suspension of the bioluminescent reporter strain Pseudomonas fluorescens 5RL was inoculated into each canal of sterilized teeth. Emission of bioluminescence (photons s(-1)) from each tooth was quantified on four sequential occasions using luminometry and bioluminescence imaging: (i) background, (ii) after inoculation, (iii) after irrigating the inoculated teeth with 3 mL of a nonantimicrobial irrigant delivered either 1 mm (group 1, n = 15) or 5 mm (group 2, n = 15) from working length (WL) using a 28G safety-ended irrigating needle, (iv) after an additional 3 mL irrigation (total 6 mL). Intragroup and intergroup comparisons were made using Wilcoxon matched pairs and Mann-Whitney tests, respectively. RESULTS: In group 1, there was a mean log10 decrease in bacteria of 0.68 +/- 0.26 after 3 mL of irrigant compared with 1.19 +/- 0.48 after 6 mL (P < 0.001); in group 2 the mean log10 decrease was 0.58 +/- 0.28 after 3 mL of irrigant compared with 0.69 +/- 0.35 after 6 mL (P < 0.02) (Wilcoxon matched pairs). Using 3 mL of irrigant, needle depth did not have a significant effect on reduction of intracanal bacteria (P = 0.407), but the effect became significant when 6 mL of irrigant was used (P < 0.002) (Mann-Whitney tests). CONCLUSIONS: The mechanical efficacy of 6 mL of irrigant in reducing intracanal bacteria was significantly greater when delivered 1 mm compared with 5 mm from WL.

Mutations in rugose promote cell type-specific apoptosis in the Drosophila eye.

RUGOSE (RG): encodes an A kinase anchor protein and was isolated as a genetic interactor of the Notch and epidermal growth factor receptor (EGFR) pathways during eye development in Drosophila. rg mutants display a small, rough eye phenotype primarily caused by the loss of cone cells. Here we show that the basis of this phenotype is cell type-specific apoptosis rather than transformation and hence can be rescued by reduction of proapoptotic signals. Moreover, a nearly complete rescue is observed by an increased Notch signal suggesting an antiapoptotic function of Notch in this developmental context. Cone cell loss in rg mutants is accompanied by enhanced Jun N-terminal kinase activity and, concomitantly, by a reduction of EGFR signalling activity. Together, these findings support the idea that rg plays an important role in the integration of different signals required for the exact regulation of cone cell development and survival.

Virulence, phenotype and genotype characteristics of endodontic Enterococcus spp.

BACKGROUND/AIMS: Enterococci have been implicated in persistent root canal infections but their role in the infection process remains unclear. This study investigated the virulence, phenotype and genotype of 33 endodontic enterococcal isolates. METHODS: Phenotypic tests were conducted for antibiotic resistance, clumping response to pheromone, and production of gelatinase, hemolysin and bacteriocin. Genotype analysis involved polymerase chain reaction amplification of virulence determinants encoding aggregation substances asa and asa373, cytolysin activator cylA, gelatinase gelE, gelatinase-negative phenotype ef1841/fsrC, adherence factors esp and ace, and endocarditis antigen efaA. Physical DNA characterization involved pulsed-field gel electrophoresis of genomic DNA, and plasmid analysis. RESULTS: Potential virulence traits expressed included production of gelatinase by Enterococcus faecalis (n=23), and response to pheromones in E. faecalis culture filtrate (n=16). Fourteen strains produced bacteriocin. Five strains were resistant to tetracycline and one to gentamicin, whereas all were susceptible to ampicillin, benzylpenicillin, chloramphenicol, erythromycin, fusidic acid, kanamycin, rifampin, streptomycin and vancomycin. Polymerase chain reaction products encoding efaA, ace, and asa were detected in all isolates; esp was detected in 20 isolates, cylA in six isolates, but asa373 was never detected. The gelatinase gene (gelE) was detected in all isolates of E. faecalis (n=31) but not in Enterococcus faecium (n=2); a 23.9 kb deletion sequence corresponding to the gelatinase-negative phenotype was detected in six of the eight E. faecalis isolates that did not produce gelatinase. Pulsed-field gel electrophoresis and plasmid analyses revealed genetic polymorphism with clonal types evident. Plasmid DNA was detected in 25 strains, with up to four plasmids per strain and a similar (5.1 kb) plasmid occurring in 16 isolates. CONCLUSIONS: Phenotypic and genotypic evidence of potential virulence factors were identified in endodontic Enterococcus spp., specifically production of gelatinase and response to pheromones.

Scalloped and strawberry notch are target genes of Notch signaling in the context of wing margin formation in Drosophila.

The Notch pathway regulates the differentiation of many cell types throughout development of higher metazoa. Different cellular responses are elicited through specific activation of distinct Notch target genes. In the Drosophila wing, for example, the cut gene is activated by Notch signaling along the dorso-ventral boundary but, as we show here, not in other cell types. We identify additional regulatory components, scalloped and strawberry notch, that are targets of the Notch pathway specifically within the wing anlagen. As suggested by physical interactions, these proteins could be co-factors of the cut trans-regulator Vestigial. Additional regulatory input comes from the Wingless pathway. Our data support a model, whereby context specific involvement of distinct co-regulators modulates Notch target gene activation.

Screening for ribosomal-based false positives following prokaryotic mRNA differential display.

Differential display (DD) and the closely related RNA arbitrarily primed PCR (RAP-PCR) have become the molecular tools of choice for identifying and isolating differentially expressed genes in both eukaryotic and prokaryotic systems. However, one of the current drawbacks of both techniques is the high number of false positives generated. In prokaryotic applications, the many false positive typically generated by DD are subsequently identified as rRNAs because of their greater abundance compared to mRNAs. To circumvent this problem, full-length 16S and 23S rDNA probes, derived from Pseudomonas putida G7 and Pseudomonas aeruginosa FRD1, respectively, were used as a prescreening approach to discriminate between those bands, which appear to be differentially expressed mRNAs, but in fact are rRNAs, following prokaryotic mRNA DD.

Dynamic expression of Drosophila TRAF1 during embryogenesis and larval development.

TNF-receptor associated factors (TRAFs) comprise a family of adaptor proteins that act as downstream signal transducers of the TNF receptor superfamily and the Toll/interleukin-1 receptor family. The mammalian TRAFs 2, 5 and 6 are known to activate JNK- and NF-kappaB signaling pathways, whereas the function of the other three mammalian family members, TRAF 1, 3 and 4 is less well characterized. Vertebrate TRAFs have a very similar structure with the exception of TRAF1: aside the characteristic C-terminal TRAF domain, they share a N-terminal RING finger followed by five or, in the case of TRAF4, seven regularly spaced zinc fingers. Two TRAF homologues are present in the genome of Drosophila melanogaster, DTRAF1 and DTRAF2 (also known as DTRAF6) and both have been implicated in the Toll-receptor pathways leading to the activation of NF-kappa B and JNK. DTRAF1 is most closely related to mammalian TRAF4 which is predominantly expressed during nervous system development and in ephitelial progenitor cells. In order to gain insight into possible roles of DTRAF1 during development, we have performed a detailed transcriptional analysis of the gene at various embryonic and larval stages.

Neural hyperplasia induced by RNA interference with m4/malpha gene activity.

The E(spl) complex (E(spl)-C) contains three different classes of genes that are downstream of Notch signaling. The bHLH genes mediate the Notch signal by repressing proneural gene activity, for example during the singularization of mechanosensory organ precursor cells (SOPs). Genes of the second class, the E(spl) m4/malpha family, antagonize this process if overexpressed. Here we show that this is based on dominant-negative effects since RNA interference gives neurogenic phenotypes indistinguishable from E(spl)-C mutations. Furthermore, a third member of the m4/malpha gene family, named bbu/tom, behaves differently with respect to RNA expression patterns, its regulation by Notch signaling and loss of function phenotypes.

Su(H)-independent activity of hairless during mechano-sensory organ formation in Drosophila.

Formation of mechano-sensory organs in Drosophila involves the selection of neural precursor cells (SOPs) mediated by the classical Notch pathway in the process of lateral inhibition. Here we show that the subsequent cell type specifications rely on distinct subsets of Notch signaling components. Whereas E(spl) bHLH genes implement SOP selection, they are not required for later decisions. Most remarkably, the Notch signal transducer Su(H) is essential to determine outer but not inner cell fates. In contrast, the Notch antagonist Hairless, thought to act upon Su(H), influences strongly the entire cell lineage demonstrating that it functions through targets other than Su(H) within the inner lineage. Thereby, Hairless and numb may have partly redundant activities. This suggests that Notch-dependent binary cell fate specifications involve different sets of mediators depending on the cell type considered.

Subcellular localization of Hairless protein shows a major focus of activity within the nucleus.

Hairless, a major antagonist of the Notch signaling-pathway in Drosophila (Bang and Posakony, 1992; Maier et al., 1992), associates with Suppressor of Hairless [Su(H)], thereby inhibiting trans-activation of Notch target genes (Brou et al., 1994). These molecular interactions could occur either at the step of signal transduction in the cytoplasm or during implementation of the signal within the nucleus. We examined the subcellular distribution of Hairless, showing that it is a low abundant, ubiquitous protein that is cytosolic as well as nuclear. High levels of Hairless cause nuclear retention of Su(H), loss of Hairless reduces the amount of Su(H) in the nucleus.

Enhancer of split [E(spl)(D)] is a gro-independent, hypermorphic mutation in Drosophila.

Enhancer of split [E(spl)] refers to a gene complex in Drosophila melanogaster, which contains a number of target genes of the Notch signaling pathway. The complex was originally identified by a dominant mutation E(spl)(D) that displays allele-specific interactions with a recessive mutation in the Notch locus called split (N(spl)). The spl phenotype is characterized by smaller eyes with irregularly spaced ommatidia, and it is strongly enhanced by E(spl)(D). This enhancement is correlated with a truncation of one of the E(spl) bHLH genes, m8, causing an increased stability of the mutant transcripts and an altered C-terminus in the mutant M8* protein. Concurrently, an insertion of a middle repetitive element in the adjacent groucho (gro) gene was observed. In this work, three different E(spl)(D) revertants (BE22, BE25, BX37), which have lost the ability to enhance N(spl) completely, were analyzed at the molecular level. In each case, the structure of the mutant M8* protein was affected, suggesting a specific involvement of the aberrant protein in the enhancement of the spl phenotype. This hypothesis is supported by the finding that a perfect phenocopy of spl enhancement can be achieved with hybrid constructs, where the altered C-terminus of M8* was fused to other E(spl) bHLH proteins. Thus, the ability to interact with N(spl) is not restricted to M8* but instead can be induced by an appropriate mutation in other E(spl) bHLH genes within the context of N(spl). In a N(spl) background, E(spl)(D) behaves like a hyperactive M8 mutation. However, the mutant M8* protein has lost the ability of binding to the corepressor Gro, which is an essential feature for normal E(spl) activity. Yet, other protein interactions, notably those with other bHLH proteins of either E(spl) or proneural family, are still observed. These findings suggest that the structural changes associated with the E(spl)(D) mutant protein are the primary cause for the phenotypic interactions with the recessive Notch mutation N(spl).

Overexpression of the m4 and malpha genes of the E(spl)-complex antagonizes notch mediated lateral inhibition.

Intercellular signalling mediated by Notch proteins is crucial to many cell fate decisions in metazoans. Its profound effects on cell fate and proliferation require that a complex set of responses involving positive and negative signal transducers be orchestrated around each instance of signalling. In Drosophila the basic-helix-loop-helix (bHLH) repressor encoding genes of the E(spl) locus are induced by Notch signalling and mediate some of its effects, such as suppression of neural fate. Here we report on a novel family of Notch responsive genes, whose products appear to act as antagonists of the Notch signal in the process of adult sensory organ precursor singularization. They, too, reside in the E(spl) locus and comprise transcription units E(spl) m4 and E(spl) malpha. Overexpression of these genes causes downregulation of E(spl) bHLH expression accompanied by cell autonomous overcommitment of sensory organ precursors and tufting of bristles. Interestingly, negative regulation of the Notch pathway by overexpression of E(spl) m4 and malpha is specific to the process of sensory organ precursor singularization and does not impinge on other instances of Notch signalling.

Notchspl is deficient for inductive processes in the eye, and E(spl)D enhances split by interfering with proneural activity.

Eye development in Drosophila involves the Notch signaling pathway at several consecutive steps. At first, Notch signaling is required for stable expression of the proneural gene atonal (ato), thereby maintaining neural potential of the cells. Second, in a process of lateral inhibition, Notch signaling is necessary to confine neural commitment to individual photoreceptor founder cells. Later on, the successive addition of cells to maturing ommatidia is under Notch control. In contrast to previous assumptions, the recessive Notch allele split (Nspl) involves specifically loss of the early proneural Notch activity in the eye, which is in agreement with bristle defects as well. As a result, fewer cells gain neural potential and fewer ommatidia are founded. Enhancement of this phenotype by the dominant mutation Enhancer of split [E(spl)D] happens within the remaining proneural cells, in which Ato expression is abolished. In line with genetic data, this process occurs primarily at the protein level due to altered protein-protein interactions between the aberrant E(spl)D and proneural proteins. Nspl is the first Notch mutation known to specifically affect Notch inductive processes during eye development.

Induction of the tod operon by trichloroethylene in Pseudomonas putida TVA8.

Bioluminescence, mRNA levels, and toluene degradation rates in Pseudomonas putida TVA8 were measured as a function of various concentrations of toluene and trichloroethylene (TCE). TVA8 showed an increasing bioluminescence response to increasing TCE and toluene concentrations. Compared to uninduced TVA8 cultures, todC1 mRNA levels increased 11-fold for TCE-treated cultures and 13-fold for toluene-treated cultures. Compared to uninduced P. putida F1 cultures, todC1 mRNA levels increased 4.4-fold for TCE-induced cultures and 4.9-fold for toluene-induced cultures. Initial toluene degradation rates were linearly correlated with specific bioluminescence in TVA8 cultures.