v-jun oncogene prevents terminal differentiation and suppresses muscle-specific gene expression in ASV-17-infected muscle cells

Infection of replicating quail myoblasts with avian sarcoma virus 17 (ASV-17) results in the inhibition of terminal differentiation into multinucleated myotubes and in the acquisition of anchorage-independent proliferation. Expression of v-jun, the ASV-17 oncogene, concomitantly leads to the accumulation of the gag-jun polyprotein P65 in the nucleus and to the lack of expression of typical differentiation-specific genes such as myosin heavy chain (MHC) and alpha-actinin. Surprisingly, expression of desmin, the muscle-specific subunit of intermediate filaments, is conserved in ASV-17-transformed myoblasts. Analysis of clonal strains of transformed myoblasts suggests that (i) suppression of morphological and biochemical differentiation depends on the absence of muscle-specific gene transcripts; (ii) inhibition of muscle differentiation by v-jun does not depend on the transcriptional silencing of MyoD, a muscle-specific regulatory gene; (iii) expression of desmin is compatible with proliferation of ASV-17-transformed cells and is independent of v-jun and MyoD levels of expression. The present data suggest that nuclear localization of v-jun prevents terminal differentiation in myoblasts and selectively down-regulates muscle-specific genes in terminally differentiated myotubes. In this respect, the behaviour of v-jun is quite different from that of v-myc, thus suggesting that these two oncogenes, although both encoding nuclear proteins, may have different mechanisms of action

Virulence plasmids of enteroinvasive Escherichia coli and Shigella flexneri integrate into a specific site on the host chromosome: integration greatly reduces expression of plasmid-carried virulence genes.

The ability of enteroinvasive Escherichia coli and Shigella flexneri to cause disease depends on the presence of a large virulence plasmid (pINV). In this report we show that pHN280, the pINV of the O135:K-:H- enteroivasive strain E. coli HN280, and pWR100, the pINV of S. flexneri serotype 5 strain M90T, are able to integrate into a specific site on the host chromosome. pINV-integrated HN280 and M90T strains required methionine (Met-) to grow in minimal medium, were noninvasive, did not produce contact-mediated hemolysin, and had lost the ability to bind Congo red (Crb-) at 37 degrees C. Immunoblots of whole bacterial extracts from pHN280-integrated HN280 derivatives revealed that integration severely reduced the expression of ipa and virG (icsA) plasmid genes. Met- HN280 and M90T derivative strains spontaneously generated Met+ revertants that either contained excised forms of pINV or had lost pINV. Restriction analysis of excised pINVs showed that they either were virtually identical to parental pINVs (precise excision) or had suffered some deletion (imprecise excision). Precisely excised pINVs expressed the full pattern of virulence, whereas imprecisely excised pINVs were always Crb- and noninvasive. The revertion to Met+ was shown to be recA dependent, indicating that homologous plasmid and chromosomal DNA sequences are involved in the integration-excision process. The maintainance of pINV through integration and downregulation of its virulence genes may represent an advantageous mechanism for enteroinvasive bacteria, particularly when they are outside host cells and/or have to face adverse environmental conditions

Organization of aerobactin, hemolysin, and antibacterial resistance genes in lactose-negative Escherichia coli strains of serotype O4 isolated from children with diarrhea.

Epidemiologically related, non-lactose-fermenting (NLF) Escherichia coli strains of serotype O4 have been isolated at a high frequency from children with diarrhea in Somalia (M. Nicoletti, F. Superti, C. Conti, A. Calconi, and C. Zagaglia, J. Clin. Microbiol. 26:524-529, 1988). In order to define the virulence potential of these strains, we characterized the replication properties of their high-molecular-weight plasmids and studied the genetic locations and organization of the aerobactin (aer) and hemolysin (hly) determinants encoded by 23 NLF O4 E. coli strains. Southern blot hybridizations, mobilization assays of nonconjugative plasmids, and incompatibility-exclusion experiments conducted with a conjugative incompatibility group FI (IncFI) plasmid showed that (i) 20 out of the 23 strains examined harbor a 160- to 180-kb IncFI plasmid that shares homology with the basic replicons RepFIA, RepFIB, and (except for the plasmid of one strain) RepFIC, and 22 strains also contain a 40- to 140-kb IncFII plasmid sharing homology with the RepFIIA replicon; (ii) the IncFI plasmid is nonconjugative and carries antibiotic resistance genes; (iii) the aer system is located on the IncFI plasmids and/or the chromosomes in the three strains not harboring IncFI, and it is found in an inverted orientation; (iv) the hly determinants are located on the chromosome, and their genetic organization is well conserved and closely resembles that of the reference hemolytic plasmid pHly152; and (v) Hly- mutants obtained by transposon insertion mutagenesis are not cytotoxic to HeLa cell monolayers, indicating that hemolysin is responsible for the high cytotoxic activity we have previously reported for these strains. The structural organization of the plasmid-encoded aer operon, together with the finding that those plasmids also carry antibiotic resistance genes, indicates that the IncFI plasmid of the NLF O4 E. coli strains studied more closely resembles aer-encoding virulence IncFI Salmonella R plasmids than E. coli ColV plasmids. The data presented here cannot rule out whether the strains examined are potentially intestinal or extraintestinal pathogens. Nevertheless, the genetic organization of the virulence genes, together with the epidemiological behavior and the wide spectrum of antibiotic resistance of the NLF O4 E. coli strains, indicates that these strains are structured as typical E. coli pathogenic isolates of human origin

ORGANIZATION OF AEROBACTIN, HEMOLYSIN, AND ANTIBACTERIAL RESISTANCE GENES IN LACTOSE-NEGATIVE ESCHERICHIA-COLI STRAINS OF SEROTYPE O4 ISOLATED FROM CHILDREN WITH DIARRHEA

Epidemiologically related, non-lactose-fermenting (NLF) Escherichia coli strains of serotype O4 have been isolated at a high frequency from children with diarrhea in Somalia (M. Nicoletti, F. Superti, C. Conti, A. Calconi, and C. Zagaglia, J. Clin. Microbiol. 26:524-529, 1988). In order to define the virulence potential of these strains, we characterized the replication properties of their high-molecular-weight plasmids and studied the genetic locations and organization of the aerobactin (aer) and hemolysin (hly) determinants encoded by 23 NLF O4 E. coli strains. Southern blot hybridizations, mobilization assays of nonconjugative plasmids, and incompatibility-exclusion experiments conducted with a conjugative incompatibility group FI (IncFI) plasmid showed that (i) 20 out of the 23 strains examined harbor a 160- to 180-kb IncFI plasmid that shares homology with the basic replicons RepFIA, RepFIB, and (except for the plasmid of one strain) RepFIC, and 22 strains also contain a 40- to 140-kb IncFII plasmid sharing homology with the RepFIIA replicon; (ii) the IncFI plasmid is nonconjugative and carries antibiotic resistance genes; (iii) the aer system is located on the IncFI plasmids and/or the chromosomes in the three strains not harboring IncFI, and it is found in an inverted orientation; (iv) the hly determinants are located on the chromosome, and their genetic organization is well conserved and closely resembles that of the reference hemolytic plasmid pHly152; and (v) Hly- mutants obtained by transposon insertion mutagenesis are not cytotoxic to HeLa cell monolayers, indicating that hemolysin is responsible for the high cytotoxic activity we have previously reported for these strains. The structural organization of the plasmid-encoded aer operon, together with the finding that those plasmids also carry antibiotic resistance genes, indicates that the IncFI plasmid of the NLF O4 E. coli strains studied more closely resembles aer-encoding virulence IncFI Salmonella R plasmids than E. coli ColV plasmids. The data presented here cannot rule out whether the strains examined are potentially intestinal or extraintestinal pathogens. Nevertheless, the genetic organization of the virulence genes, together with the epidemiological behavior and the wide spectrum of antibiotic resistance of the NLF O4 E. coli strains, indicates that these strains are structured as typical E. coli pathogenic isolates of human origin