In an ongoing survey of the bioactive potential of microorganisms associated with marine invertebrates, the culture media of a sponge-associated bacterial strain of Pseudomonas aeruginosa was found to contain metabolites which inhibit the growth of several Gram-positive microorganisms. A series of diketopiperazines (1-6) including a new natural product (6) and two known phenazine alkaloid antibiotics (7 and 8) were isolated from the culture broth of this bacterium.
A method is describedforproducing sizable quantities of synchronously dividing, minimally disturbed mammalian cells. Cultures were grown immobilized on surfaces such that cell division within the population resulted in the continuous release of synchronous newborn cells. As judged by the quality and duration of synchronous growth, cell size distributions, and DNA compositions, newborn mouse L1210 cells grew with a very high level of synchrony without overt evidence of growth disturbances. The technology should be applicable to a variety of hematopoietic cells, as evidenced by similar results with human MOLT-4 and U937 cell lines.
Growth characteristics of synchronous human MOLT-4, human U-937 and mouse L1210 cultures produced with a new minimally-disturbing technology were compared to each other and to synchronous Escherichia coli B/r. Based on measurements of cell concentrations during synchronous growth, synchrony persisted in similar fashion for all cells. Cell size and DNA distributions in the mammalian cultures also progressed synchronously and reproducibly for multiple cell cycles. The results demonstrate that unambiguous multi-cycle synchrony, critical for verifying the absence of significant growth imbalances induced by the synchronization procedure, is feasible with these cell lines, and possibly others.
The cyclins are tightly regulated elements governing eukaryotic cell cycle progression by means of sequential activation-inactivation of cyclin-dependent kinases. In one manifestation of this regulation, the mRNA levels of several cyclin genes oscillate during the cycle in mammalian cells. Such cycle-dependent fluctuations in transcript levels could result from changes not only in rates of transcription, but also in mRNA stability. Here we used a new, minimally-disturbing method for producing multi-cycle synchronous growth of human MOLT-4 cells, in combination with quantitative real-time RT-PCR, to compare cell cycle-dependent transcript levels and half-lives of cyclin A2, B1, D3, E and PCNA mRNAs. While all mRNA levels except cyclin D3 varied in the cycle, there were no apparent variations in message half-lives. This differs from several previous reports of dramatic fluctuations in the stabilities of cyclin mRNAs, and infers that fluctuations in cyclin mRNA transcript levels during the MOLT-4 cell cycle are not due to variations in half-lives. The discrepancy in mRNA stability determinations could be due to differences in cell types or synchronization methods, but our findings may be representative of mRNA processing in the cycle of cells in unstressed steady-state growth.
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