Cell Reproduction and Morphological Changes in Mycoplasma capricolum

The cell reproduction of Mycoplasma capricolum was studied. The velocity of DNA replication fork progression was about 6 kb/min, which is 10 times slower than that of Escherichia coli. The time required for one round of DNA replication accorded with the doubling time. The origin/terminus ratio was 2.0. M. capricolum cell morphology was classified into two types, rod and branched. In the ordinary-growth phase, the rod cells accounted for about 90% of the total population, with branched cells comprising the remaining 10%. The proportion of branched cells increased to 90% following inhibition of DNA replication by nucleoside starvation. An increase in the proportion of branched cells was induced by transfer of a temperature-sensitive mutant deficient in DNA replication to the restrictive temperature. The rod cells had a regular structure, a fixed cell length, and constrictions in the center. The DNA contents of individual rod cells were distributed with a standard deviation of 0.40 of average. The branched cells had irregular structures and a wide distribution of DNA contents. Counting of viable cells revealed that the cells ceased division upon cell type conversion; however, branched cells maintained a reproductive capacity. A model for the reproduction process is proposed.Mycoplasmas are parasitic bacteria that have extremely low G+C contents and small genomes (9). Their morphology is irregular because of the lack of a peptidoglycan layer.In Escherichia coli, initiation of chromosomal DNA replication occurs once during the cell’s replicative cycle, and the nucleoids partition before cell division (13). The chromosomal replication of E. coli initiates in a small region and proceeds in both directions. It is mainly controlled by the timing and frequency of initiation, while the velocity of replication is constant.In mycoplasmas, chromosome replication also starts at a fixed site, followed by bidirectional progression (19–21, 25, 40). As in many eubacteria (36), the dnaA gene is expressed and plays important roles in the initiation of replication (35). These observations suggest that the outline of chromosome replication of mycoplasmas is similar to that of E. coli. However, the process of mycoplasma cell reproduction has not been clarified. Moreover, the cell division cycle of E. coli cannot be simply applied to mycoplasmas because of their irregular cell morphology (4). A model has been suggested for the cell cycle of Mycoplasma mycoides (6, 30, 31), which is closely related to Mycoplasma capricolum (39). According to this model, an elementary rounded body grows into a filamentous form and then new elementary rounded bodies are developed within this filament and released, but this model has not been adequately substantiated.In this study, we analyzed the process of DNA replication, cell morphology, and viability under various conditions of M. capricolum and proposed a model of cellular reproduction for this bacterium.