Murine cultured microglial cells were immortalized after infection with a v-raf/v-myc recombinant retrovirus. This immortalized cell line (BV-2) shares properties with body macrophages with respect to the antigen profile, their phagocytic capacity and antimicrobial activity. BV-2 cells are not constitutively able to kill tumor cells in vitro, but acquire antitumor activity following an increase in [Ca++]i. BV-2 cells, like microglial cells, are however, distinct from peripheral macrophages by their expression of inwardly rectifying K+ channels in concert with a lack in outwardly rectifying K+ channels and the formation of spineous processes. The BV-2 cell line thus represents a suitable model for in vitro studies of activated microglial cells.
Myeloid precursors can be grown in vitro in the presence of specific growth factors; however, their expansion is limited by a competing process of terminal differentiation. Proto-oncogenes seem to be involved in cellular proliferation and/or differentiation and may also play a role in the myelopoietic process. Murine myeloid precursors which are grown in vitro with growth factors respond with augmented self-renewal upon infection with recombinant retroviruses carrying the v-myc or v-src oncogenes, suggesting a synergism or complementation between some viral oncogenes (v-onc) and certain growth factors. We now show that the combination of two v-onc genes (raf and myc) induces the selective proliferation of monocytic cells from fresh murine bone marrow (BM) in the absence of a specific growth factor supplement. Depending on the culture conditions these cells can either differentiate and cease to proliferate or grow continuously, thus mimicking the alternative pathways that can be followed by committed BM stem cells in vivo.
The fungal component of the intestinal microbiota of eight healthy subjects was studied over 12 months using metagenome survey and culture-based approaches.
Aspergillus
,
Candida
,
Debaryomyces
,
Malassezia
,
Penicillium
,
Pichia
, and
Saccharomyces
were the most recurrent and/or dominant fungal genera, according to metagenomic analysis. The biodiversity of fungal communities was lower and characterized by greater unevenness, when compared to bacterial microbiome. The dissimilarities both among subjects and over the time within the same subject suggested that most of the fungi passed through the gastro-intestinal tract (GIT) without becoming stable colonizers. Certain genera, such as
Aspergillus
and
Penicillium
, were isolated in a minority of cases, although they recurred abundantly and frequently in the metagenomics survey, likely being environmental or food-borne fungi that do not inhabit the GIT.
Candida
genus was recurrently detected.
Candida albicans
isolates dominated among the cultivable mycobiota and longitudinally persisted, likely as commensals inhabiting the intestine or regularly reaching it from
Candida
-colonized districts, such as the oral cavity. Other putative colonizers belonged to
Candida zeylanoides
,
Geotrichum candidum
, and
Rhodotorula mucilaginosa
, with persisting biotypes being identified. Phenotyping of fungal isolates indicated that
C. albicans
adhered to human epithelial cells more efficiently and produced greater amounts of biofilm
in vitro
than non-
albicans Candida
(NAC) and non-
Candida
fungi (NCF). The
C. albicans
isolates also induced the highest release of HBD-2 by human epithelial cells, further differing from NAC and NCF. Nine representative isolates were administered to mice to evaluate the ability to colonize the intestine. Only two out of three
C. albicans
strains persisted in stools of animals 2 weeks after the end of the oral administration, whereas NAC and NCF did not. These results confirm the allochthonous nature of most the intestinal fungi, while
C. albicans
appears to be commonly involved in stable colonization. A combination of specific genetic features in the microbe and in the host likely allow colonization from fungi normally present solely as passengers. It remains to be established if other species identified as potential colonizers, in addition to
Candida
, are true inhabitants of the GIT or rather reach the intestine spreading from other body districts.
The J2 recombinant retrovirus expressing v-myc/v-raf (also known as MYC/RAF1) immortalized macrophages from the bone marrow of lipopolysaccharide-responsive mouse strains, producing the ANA-1 cell line from C57BL/6 mice and the INF-3A cell line from C3H/HeN mice. In contrast, J2 recombinant retrovirus infection of the fetal liver from C57BL/6-Ly-5a mice immortalized a cell line (GGD) that did not exhibit the characteristics of mature macrophages. The GGD cell line was classified as leukocytic on the basis of its expression of the Ly-6B.2, Fc gamma R, and Ly-5.2 antigens. Our results indicate that the J2 recombinant retrovirus selectively immortalizes macrophages from the bone marrow of C57BL/6 and C3H/HeN mice but immortalizes cells without definitive macrophage characteristics from murine fetal liver under the same culture conditions.
Hyaluronic acid (HA) has several clinical applications (aesthetic surgery, dermatology, orthopaedics and ophtalmology). Following recent evidence, suggesting antimicrobial and antiviral properties for HA, we investigated its effects on 15 ATCC strains, representative of clinically relevant bacterial and fungal species. The in vitro system employed allowed to assess optical density of broth cultures as a measure of microbial load in a time-dependent manner. The results showed that different microbial species and, sometimes, different strains belonging to the same species, are differently affected by HA. In particular, staphylococci, enterococci, Streptococcus mutans, two Escherichia coli strains, Pseudomonas aeruginosa, Candida glabrata and C. parapsilosis displayed a HA dose-dependent growth inhibition; no HA effects were detected in E. coli ATCC 13768 and C. albicans; S. sanguinis was favoured by the highest HA dose. Therefore, the influence of HA on bacteria and fungi warrants further studies aimed at better establishing its relevance in clinical applications.
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