Correction to: Common findings of blaCTX-M-55-encoding 104-139 kbp plasmids harbored by extended-spectrum ß-lactamase-producing Escherichia coli in pork meat, wholesale market workers, and patients with urinary tract infection in Vietnam.

The original version of this article unfortunately contained a mistake. The legends of Tables 2 and 3, Fig. 1 are incorrect. The corrected legends are given below.

Common findings of bla CTX-M-55-encoding 104-139 kbp plasmids harbored by extended-spectrum ß-lactamase-producing Escherichia coli in pork meat, wholesale market workers, and patients with urinary tract infection in Vietnam.

Extended-spectrum, ß-lactamase-producing Escherichia coli (ESBL-E) harboring the bla CTX-M-55-encoding plasmid (ESBL-E55) has been reported to be associated with urinary tract infection (UTI). The aims of this study were to clarify the prevalence of ESBL-E55 in pork meats and workers from the same wholesale market, as well as patients with UTI from a nearby hospital in Vietnam; we also investigated the plasmids encoding bla CTX-M-55. Sequencing analysis showed that 66.6% of the ESBL-E isolated from pork meats contained bla CTX-M-55, whereas the gene was present in 25.0% of workers and 12.5% of patients with UTI. Plasmid analysis showed that several sizes of plasmid encoded bla CTX-M-55 in ESBL-E55 isolated from pork meats, whereas ESBL-E55 isolated from workers and patients with UTI contained only 104-139 kbp of bla CTX-M-55-encoding plasmids. This indicates that the 104-139 kbp sizes of bla CTX-M-55-encoding plasmids were commonly disseminated in pork meats, wholesale market workers, and patients with UTI.

Modulation of ethanol effect on hepatocyte proliferation by polyamines.

An occurrence and a magnitude of alcoholic liver diseases depend on the balance between ethanol-induced injury and liver regeneration. Like ethanol, polyamines including putrescine, spermidine, and spermine modulate cell proliferation. Thus, the purpose of this study was to evaluate the relationship between effect of ethanol on hepatocyte (HC) proliferation and polyamine metabolism using the HepaRG cell model. Results showed that ethanol effect in proliferating HepaRG cells was associated with a decrease in intracellular polyamine levels and ornithine decarboxylase (ODC) activity. Ethanol also induced disorders in expression of genes coding for polyamine-metabolizing enzymes. The α-difluoromethyl ornithine, an irreversible inhibitor of ODC, amplified ethanol toxicity on cell viability, protein level, and DNA synthesis through accentuation of polyamine depletion in proliferating HepaRG cells. Conversely, putrescine reversed ethanol effect on cell proliferation parameters. In conclusion, this study suggested that ethanol effect on HC proliferation was closely related to polyamine metabolism and that manipulation of this metabolism by putrescine could protect against the anti-proliferative activity of ethanol.

Impaired circulating myeloid DCs from myeloma patients.

BACKGROUND: In clinical trials, cancer patients have received immunotherapy based on DCs generated from leukapheresed blood. It would therefore be an advantage to be able to measure blood levels and estimate the phenotype of DC before leukapheresis, to estimate the yield required for preparation of vaccines, or ex vivo stimulation of T cells for adoptive immunotherapy. METHODS: Recently, circulating lineage negative (Lin-) myeloid DC cells and their precursors have been identified by flow cytometry. We apply this strategy to the screening of blood samples from patients with multiple myeloma, in an attempt to characterize and quantitate the subset. By a direct flow cytometry approach, the blood levels of circulating lineage (CD3, CD19, CD14) negative, CD33++, HLA-DR+ cells were estimated before and following ex vivo cell differentiation, and phenotyped by MAbs with specificity against HLA-DR, HLA-ABC, CD1a, CD11c, CD33, CD40, CD49d, CD49e, CD54, CD80, CD83, and CD86. RESULTS: This study demonstrated that multiple myeloma patients have a 50% reduced blood level of Lin-, CD33++, HLA-DR+ myeloid DC, but a DC-precursor level within normal range. Furthermore, GM-CSF and IL-4 ex vivo stimulated DCs demonstrated an impaired up-regulation of the co-stimulatory molecule CD80 and the adhesion molecule CD54. DISCUSSION: These results may have clinical implications as a predictor for yield and functionality of the harvested DCs to be used in vaccination of myeloma patients.

Activation of the AT(2) receptor of angiotensin II induces neurite outgrowth and cell migration in microexplant cultures of the cerebellum.

Microexplant cultures from three-day-old rats were used to investigate whether angiotensin II (Ang II), through its AT(1) and AT(2) receptors, could be involved in the morphological differentiation of cerebellar cells. Specific activation of the AT(2) receptor during 4-day treatment induced two major morphological changes. The first was characterized by increased elongation of neurites. The second change was cell migration from the edge of the microexplant toward the periphery. Western blot analyses and indirect immunofluorescence studies revealed an increase in the expression of neuron-specific betaIII-tubulin, as well as an increase in expression of the microtubule-associated proteins tau and MAP2. These effects were demonstrated by co-incubation of Ang II with 1 microM DUP 753 (AT(1) receptor antagonist) or with 10 nM CGP 42112 (AT(2) receptor agonist) but abolished when Ang II was co-incubated with 1 microM PD 123319 (AT(2) receptor antagonist), indicating that differentiation occurs through AT(2) receptor activation and that the AT(1) receptor inhibits the AT(2) effect. Taken together, these results demonstrate that Ang II is involved in cerebellum development for both neurite outgrowth and cell migration, two important processes in the organization of the various layers of the cerebellum.

Hemoglobin switching in Rana/Xenopus erythroid heterokaryons: factors mediating the metamorphic hemoglobin switch are conserved.

Hemoglobin switching, which occurs in all classes of vertebrates as well as in certain invertebrates, is due to developmental regulation of different globin genes which are typically arranged in clustered families. By fusing erythroid cells of different developmental programs, trans-acting factors that regulate this switch in gene expression have been detected [Ramseyer et al. (1989): Dev Biol 133:262-271]. Adult erythroid cells of one anuran species, Xenopus laevis, were fused with tadpole erythroid cells of another frog, Rana catesbeiana, creating developmental erythroid heterokaryons that synthesize adult Rana globin mRNA and hemoglobins. The results show that factors from adult Xenopus erythroid cells are capable of inducing adult Rana globin gene expression in the Rana tadpole erythroid cell nucleus. We have used the cross-induction of adult Rana hemoglobin synthesis in these adult Xenopus/Rana tadpole erythroid heterokaryons to address two practical questions, answers to which may be helpful in isolating developmental stage-specific globin gene regulatory proteins: 1) Are erythroblasts which are actively expressing globin mRNAs and hemoglobins richer in specific globin-inducing activities than other stages of erythroid cellular differentiation? 2) Do mature, circulating erythrocytes still have the activities necessary to mediate the cross-induction of Hb synthesis? The results reported here show that the answers to both questions are affirmative and show that quiescent, fully differentiated adult erythroid cells are still capable of expressing the trans-activator(s). These findings show that factors which mediate the metamorphic hemoglobin switch are conserved between these two genera of frogs.

Hemoglobin switching across vertebrate classes: exchange of developmental signals by cell fusion.

Our aim is to obtain evidence for trans-acting factors that regulate developmental hemoglobin (Hb) switching. Our approach is to fuse erythroid cells that have different developmental programs, allowing the trans-acting factors from the adult cell to have access to the nucleus of the fetal or embryonic cell and vice-versa. After cell fusion, the heteropolykaryons are cultured for six hours, and globin gene expression is assayed at two levels: (1) at the level of mRNAs on dot blots hybridized with globin-specific cDNA probes, and (2) at the level of fully-formed Hb tetramers separated by native polyacrylamide gel electrophoresis (PAGE). Since the donor erythroid cells are from different species, it is easy to determine which globin gene products are from which nucleus. And since there is no nuclear fusion for at least twelve hours, the Hb switching that occurs is due to regulation in trans. Our results show that developmental Hb switching occurs in mouse-frog erythroid cell polykaryons. When DMSO-induced murine erythroleukemia (MEL) cells (which express only adult mouse Hbs) are fused with Rana tadpole RBCs (which express only embryonic and fetal-like Hbs), the resultant heteropolykaryons express adult frog globin mRNA and adult frog Hbs. We conclude that there are developmental stage-specific trans-acting factors for Hb switching, that trans-acting factors from adult mouse erythroid cells can induce expression of adult frog globin genes in a tadpole RBC nucleus, and that Hb switching mechanisms are conserved across vertebrate classes.