Involvement of CD44v6 in InlB-dependent Listeria invasion.

Listeria monocytogenes, a Gram-positive bacterium, is the causative agent for the disease called listeriosis. This pathogen utilizes host cell surface proteins such as E-cadherin or c-Met in order to invade eukaryotic cells. The invasion via c-Met depends on the bacterial protein InlB that activates c-Met phosphorylation and internalization mimicking in many regards HGF, the authentic c-Met ligand. In this paper, we demonstrate that the activation of c-Met induced by InlB is dependent on CD44v6, a member of the CD44 family of transmembrane glycoproteins. Inhibiting CD44v6 by means of a blocking peptide, a CD44v6 antibody or CD44v6-specific siRNA prevents the activation of c-Met induced by InlB. Subsequently, signalling, scattering and the entry of InlB-coated beads into host cells are also impaired by CD44v6 blocking reagents. For the entry process, ezrin, a protein that links the CD44v6 cytoplasmic domain to the cytoskeleton, is required as well. Most importantly, this collaboration between c-Met and CD44v6 contributes to the invasion of L. monocytogenes into target cells as demonstrated by a drastic decrease in bacterial invasion in the presence of blocking agents such as the CD44v6 peptide or antibody.

RNA: guiding gene silencing.

In diverse organisms, small RNAs derived from cleavage of double-stranded RNA can trigger epigenetic gene silencing in the cytoplasm and at the genome level. Small RNAs can guide posttranscriptional degradation of complementary messenger RNAs and, in plants, transcriptional gene silencing by methylation of homologous DNA sequences. RNA silencing is a potent means to counteract foreign sequences and could play an important role in plant and animal development.

Localization of Agrobacterium rhizogenes T-DNA in plant chromosomes by in situ hybridization.

We have used in situ hybridization to determine the sites of insertion of Agrobacterium rhizogenes Ri T-DNA in the chromosomes of Crepis capillaris (2n = 6) transformed roots. Four transformed root lines were obtained by infecting Crepis stem segments with A. rhizogenes. Southern hybridization analysis indicated that each root line was the result of one or more independent T-DNA insertion events. In two root lines, one copy of T-DNA was present; the other two root lines each contained two copies of T-DNA. To localize these T-DNA inserts on Crepis chromosomes, metaphase spreads were perpared from each root line, and hybridized in situ to a biotinlabeled T-DNA probe. The results indicated that T-DNA was present in a different chromosomal location in each root line, and that each chromosome had been a target for T-DNA insertion at least once. In the root lines containing two T-DNA inserts, two patterns of integration were observed: in one case the T-DNAs were present on separate chromosomes; in the other case the two T-DNAs were close together (but not tandemly arranged) on a single chromosome. A comparison of these results and those obtained previously for a fifth Crepis-transformed root line demostrated that Ri T-DNA does not insert preferentially into a particlar chromosomal location.

RNA-based silencing strategies in plants.

In plants, double-stranded RNA can silence genes by triggering degradation of homologous RNA in the cytoplasm and by directing methylation of homologous nuclear DNA sequences. Analyses of Arabidopsis mutants and plant viral suppressors of silencing are unraveling RNA-silencing mechanisms, which require common proteins in diverse organisms, and are assessing the role of methylation in transcriptional and posttranscriptional gene silencing.

Resistance of RNA-mediated TGS to HC-Pro, a viral suppressor of PTGS, suggests alternative pathways for dsRNA processing.

In plants, double-stranded (ds) RNA that is degraded to small (sm) RNAs that are approximately 23 nucleotides in length can trigger the degradation of homologous RNAs in the cytoplasm (posttranscriptional gene silencing or PTGS) and de novo methylation of homologous DNA in the nucleus [1]. PTGS is similar to quelling in fungi [2] and RNAi in animals [3]. RNA-directed DNA methylation (RdDM) can lead to transcriptional gene silencing (TGS) and the methylation of homologous target promoters if dsRNAs containing promoter sequences are involved [4]. HC-Pro is a plant viral suppressor of PTGS that acts by preventing the accumulation of smRNAs [5, 6] that provide the specificity determinant for homologous RNA degradation [7-10]. Here, we show that HC-Pro does not suppress TGS induced by promoter dsRNA. Moreover, the amount of promoter smRNAs is elevated 5-fold in the presence of HC-Pro, and target promoter methylation is slightly increased without a concomitant rise in the level of promoter dsRNA. The promoter dsRNA, which is not polyadenylated, failed to trigger substantial degradation of polyadenylated, single-stranded promoter RNA. The differential effects of HC-Pro on smRNA accumulation associated with dsRNA-mediated TGS and at least some cases of PTGS suggest that dsRNA processing can occur by alternative pathways, and they support the idea that RdDM is triggered by smRNAs.

Position effects and epigenetic silencing of plant transgenes.

Nuclear processes that silence plant transgenes are being revealed by analyses of natural triggers of epigenetic modifications, particularly cytosine methylation, and by comparisons of the genomic environments of differentially expressed transgene loci. It is increasingly apparent that plant genomes can sense and respond to the presence of foreign DNA in certain sequence contexts and at multiple dispersed sites. Determining the basis of this sensitivity and how nuclear defense systems are activated poses major challenges for the future.

Host defenses to transposable elements and the evolution of genomic imprinting.

Genomic imprinting is the differential expression of maternally and paternally inherited alleles of specific genes. Several organismic level hypotheses have been offered to explain the evolution of genomic imprinting. We argue that evolutionary explanations of the origin of imprinting that focus exclusively on the organismic level are incomplete. We propose that the complex molecular mechanisms that underlie genomic imprinting originally evolved as an adaptive response to the mutagenic potential of transposable elements (TEs). We also present a model of how these mechanisms may have been co-opted by natural selection to evolve molecular features characteristic of genomic imprinting.

A test for transvection in plants: DNA pairing may lead to trans-activation or silencing of complex heteroalleles in tobacco.

To study whether DNA pairing that influences gene expression can take place in somatic plant cells, a system designed to mimic transvection was established in transgenic tobacco. Pairing was evaluated by testing whether an enhancerless GUS gene on one allele could be activated in trans by an enhancer on the second allele. The required heteroalleles were obtained at four genomic locations using Cre-lox-mediated recombination. In one transgenic line, elevated GUS activity was observed with the heteroallelic combination, suggesting that trans-activation occurred. Conversely, when the unaltered allele was homozygous, GUS activity dropped to hemizygous levels in a silencing phenomenon resembling dosage compensation. Double-stranded GUS RNAs or small GUS RNAs indicative of RNA-based silencing mechanisms were not detected in plants displaying reduced GUS activity. These results suggested that a transgene locus capable of pairing, as revealed by trans-activation, could also become silenced in an RNA-independent manner, thus linking DNA pairing and gene silencing. The transgene locus was complex and comprised an inverted repeat, which possibly potentiated allelic interactions. The locus was unable to trans-activate transgenes at ectopic sites, further implicating allelic pairing in the transvection effects.

Killing tumour cells by alkylphosphocholines: evidence for involvement of CD95.

Many lipids act as cellular messengers and lead to a variety of different cellular responses. Out of the group of these compounds the ceramides are able to induce apoptosis, and some synthetic lipids can mimic this effect. Apoptosis is an important mechanism whereby chemotherapeutics exhibit their anti-oncogenic activity. Although, some lipid analogues were used in clinical trials, they exert severe side effects and their mechanism of action is widely unknown. We present here a new class of synthetic alkylphosphocholines (APC) that induce programmed cell death in leukaemia cells. The signs of apoptosis arise after 1 h of incubation with these compounds as shown by phosphatidylserine externalisation followed by caspase activation and DNA fragmentation. We demonstrate that the molecular target of these lipids is upstream of caspases and Bcl-2. Experiments with FADD dominant negative cells reveal that induction of apoptosis occurs on the level of CD95 and that these compounds can now be optimised for their capacity to activate the apoptosis-inducing receptor CD95.

A large conductance ion channel in the nuclear envelope of a higher plant cell.

To detect and characterize ion channel activity in the nuclear envelope of a higher plant cell, we performed patch clamp experiments on nuclei isolated from coconut endosperm cells and on giant liposomes containing nuclear envelope fragments prepared from the same cells. An ion channel exhibiting a number of conductance substates, with a maximum of ca. 1,000 pS, was observed. Above an applied potential of +/- 100 mV, the behavior of the channel was similar in isolated nuclei and liposomes, indicating that both patch clamp modes were detecting the same channel. That such a channel has now been identified in members of both the animal and plant kingdoms reinforces the notion that the nuclear pores are not always open to ions.

Detection of a large cation-selective channel in nuclear envelopes of avian erythrocytes.

To determine whether the nuclear envelope of eukaryotic cells has the capability to regulate ion fluxes, we have used the patch-clamp technique to detect ion channels in this membrane system. Since possible sites for ion channels in the nuclear envelope include not only the nuclear pores, but also both the inner and outer nuclear membranes, we have patched giant liposomes composed of phosphatidylcholine and nuclear envelope fragments isolated from mature avian erythrocytes. A large, cation-selective channel with a maximum conductance of approximately 800 pS in symmetrical 100 mM KCl was detected. This channel is a possible candidate for a nuclear pore.

Gene silencing in plants: relevance for genome evolution and the acquisition of genomic methylation patterns.

Transgenes often become silenced in plants because of repressive influences exerted by flanking plant DNA and/or because of interactions among multiple copies of closely linked transgenes. Repeated transgenes on different chromosomes can also interact in a way that leads to silencing and methylation, suggesting a previously unrecognized ability of unlinked homologous sequences to cross-talk in complex genomes. Non-Mendelian inheritance is a frequent consequence of these interactions because the silenced genes do not fully reactivate or lose methylation after segregating in progeny. Several examples of gene silencing in plants appear to reflect the action of genome defence system that methylates and inactivates foreign or invasive sequences such as transgenes and transposable elements. Because certain types of transposable elements are embedded in regulatory regions of plant genes and have become greatly amplified in plant genomes, they could contribute substantially to normal gene expression and to the generation of genomic methylation patterns. Polyploidy, which has been a major force in plant and vertebrate evolution, might encourage proliferation of transposable elements because genes in polyploids are duplicated and hence less susceptible to the consequences of insertional mutagenesis. Accordingly, the appearance of genome-wide methylation has often coincided with episodes of polyploidization.

The antiproliferative alkylphospholipid S-1-O-phosphocholine-2-N-acetyl-octadecane induces apoptosis in leukemia cell lines.

Lipids are involved in a multitude of important cellular functions. They act as signaling molecules and can even provoke apoptosis. In this context we investigated the efficacy of synthetic alkylphosphocholines (APCs) as potential anti-cancer membrane-affecting drugs. Leading to novel therapeutic strategies for cancer treatment, the new agents interact with the cell membrane and do not affect the DNA. The data presented here show a cell death-inducing capacity for 1-O-phosphocholine-2[S]-O-acetyl-octadecane and 1-O-phosphocholin-2[S]-N-acetyl-octadecane in Jurkat T cells as well as in BJAB cells. The activation of caspases is generally required for the induction of apoptosis as shown by experiments with specific caspase inhibitors. The results point on the one hand to the formation of a functional DISC after APC-treatment as indicated by the clustering of receptor molecules and on the other hand to the dependency on the instrinsic apoptotic machinery and the downstream of mitochondria-activated apoptosome.

[Daytime sedation measured after intake of nitrazepam and lorazepam, respectively, as hypnotics for 10 days]. / Dagsedation målt efter indtagelse af henholdsvis nitrazepam og lorazepam som hypnotikum gennem ti døgn.

A prospective double-blind cross-over investigation was undertaken among 46 geriatric patients (62-92 years) in which either 5 mg nitrazepam or 1 mg lorazepam were administered as hypnotics for two periods of ten days. No significant differences were observed in the quality of sleep but the objective psychomotor tests and the patients' subjective experience of hang-overs showed that there were significant differences in the frequencies of side effects in favour of lorazepam. It is concluded that daytime sedation after repetitive administration of a benzodiazepine preparation depends upon the half-life and that side effects are revealed better by psychomotor tests than by intellectual, cognitive tests and that lorazepam should be given preference to nitrazepam as a hypnotic for elderly patients.

Use of forward genetic screens to identify genes required for RNA-directed DNA methylation in Arabidopsis thaliana.

RNA-directed DNA methylation is a small RNA-mediated epigenetic modification that contributes to transcriptional silencing of transposons and repetitive sequences in plants. We have conducted several forward genetic screens to identify factors required for RNA-directed DNA methylation and transcriptional gene silencing in Arabidopsis thaliana. Here, we review the findings from these screens and report on two new mutants, dms12 and dms13, that are defective in Pol V-specific subunits NRPE5 and NRPE9b. Cumulative results from genetic screens performed in our laboratory and those of other investigators have revealed that RNA-directed DNA methylation requires a complex transcriptional machinery comprising a number of plant-specific factors, many of which were functionally uncharacterized before being implicated in this pathway. Future challenges include unraveling the detailed mechanism and full range of functions of RNA-directed DNA methylation.