M. Hagemann et al., DNA, RNA, AND PROTEIN-SYNTHESIS IN THE CYANOBACTERIUM SYNECHOCYSTIS SP PCC-6803 ADAPTED TO DIFFERENT SALT CONCENTRATIONS, Current microbiology, 28(4), 1994, pp. 201-207
A salt shock of 684 mM NaCl reduced RNA and DNA synthesis to about 30%
of the control level in Synechocystis. DNA synthesis recovered to the
initial level within 4 h, while for recovery of RNA synthesis about 8
h were necessary. In cells completely adapted to different salt conce
ntrations (from 171 to 1026 mM NaCl), a continuous decrease in the RNA
content with increasing salt concentrations up to 684 mM NaCl was fou
nd, whereas the lowest DNA content was measured around 342 mM NaCl, i.
e., the salinity at which maximal growth occurred. With the uracil and
thymidine incorporation technique, maxima in DNA and RNA synthesis we
re detected in control cells. Comparing these rates with nucleic acid
synthesis rates calculated from the contents of DNA and RNA and the gr
owth rates indicated that adaptation to 1026 mM NaCl seemed to lead to
an increased RNA turnover in Synechocystis. Analysis of protein synth
esis with S-35-methionine labeling showed alterations in salt-adapated
cells of Synechocystis. At least three proteins (20.5, 25.8, and 35.8
kDa) were synthesized with highest rates at salinities leading to max
imal growth, the synthesis of nine proteins (12.5, 16.9, 19.2, 22.2, 2
4.7, 28.5, 30.5, 50.3, and 63.5 kDa) increased and that of several oth
er proteins decreased with increasing salinity; but only three protein
s (12.5, 22.2, and 30.5 kDa) accumulated under these conditions. The a
daptation of Synechocystis to enhanced salt concentrations led also to
increased contents of glucosylglycerol, glycogen, and significant amo
unts of K+ as well as Na+ ions.