Chemically-defined media were developed for rapamycin production by Streptomyces hygroscopicus. Thirty-five carbon sources were tested for their effect on production. Eight failed to support growth and seven appeared to repress or inhibit rapamycin formation. The best combination of two carbon sources were 2% fructose and 0.5% mannose. Acetate and propionate, which are known to contribute most of the carbon atoms of the lactone ring, were unsatisfactory for growth and/or rapamycin production.
Six non-amino acid nitrogen compounds were examined as nitrogen source for growth of Streptomyces hygroscopicus and biosynthesis of rapamycin. Of the nitrogen sources studied, ammonium sulfate was the best with respect to formation of rapamycin, and supported cell growth comparable to the organic nitrogen sources used in the control chemically defined medium, i.e., aspartate, arginine plus histidine. In the new chemically defined medium, which is buffered with 200 mM 2-(N-morpholino)ethanesulfonic acid to prevent decline of pH during fermentation, an ammonium sulfate concentration of 40 mM was optimal for biosynthesis of rapamycin. Rapamycin production increased by more than 30% on both volumetric and specific bases as compared to the previous medium containing the three amino acids as nitrogen source.
During the preimplantation development of mouse embryos between the 4-cell to 8-cell stage and the morula stage, when the first irreversible segregation of cell fates proceeds into the pluripotent inner cell mass (progenitor cells to form the fetus) and the trophectoderm (to form the placenta) of blastocysts, pluripotency-maintaining and differentiation-inducing genes are expressed to coordinately regulate cell fates. Three structurally related cDNAs (Crxos1, Crxos1 sv2, and Crxos1 tv3) that exhibited concomitant elevated expression during this critical period were identified by subtractive cDNA cloning. CRXOS1 contains two homeodomains, while CRXOS1 sv2 and CRXOS1 tv3 each contain one of the homeodomains included in CRXOS1. Crxos1, Crxos1 sv2, and Crxos1 tv3 were expressed differentially during in vitro embryonic stem (ES) cell differentiation. Even under differentiation-inducing conditions, forced expression of Crxos1 sv2 inhibited the differentiation of ES cells. In contrast, under conditions that promote self-renewal of ES cells, forced expression of Crxos1 induced differentiation. Forced expression of Crxos1 resulted in induction of Gata4 but in repression of T, probably indicating that Crxos1 promotes the differentiation of ES cells into primitive endoderm, while inhibiting differentiation into mesoderm. On the other hand, no apparent effects of forced expression of Crxos1 tv3 were observed. Taken together, it was concluded that these transcripts encoding homeoproteins are capable of regulating the maintenance and/or differentiation of mouse ES cells and likely regulate that of preimplantation embryos.
The antifungal agent rapamycin is highly effective in inhibiting growth of yeast and mold strains. This study demonstrates that in liquid medium, rapamycin is more active than its derivatives (prolylrapamycin, 32-desmethylrapamycin, 32-desmethoxyrapamycin) against Candida albicans, Saccharomyces cerevisiae, and Fusarium oxysporum. All the rapamycins were more active than amphotericin B. Although four other molds were not inhibited in liquid medium, they were very sensitive to rapamycin and its derivatives when tested on agar. The latter assay showed that rapamycin is the most active and 32-desmethylrapamycin is more active than prolylrapamycin and 32-desmethoxyrapamycin. The conclusion of this study is that rapamycin is the most active antifungal agent of the compounds examined. The unexpected finding of high activity of rapamycin and its derivatives against filamentous fungi when assayed by the agar diffusion assay suggests that rapamycin or a derivative may hold promise for chemotherapy against pathogenic molds as well as yeasts.
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