T. Robson et al., INCREASED DNA-REPAIR CAPACITY AND THE MODULATION OF 2 PROTEINS IN ANDMETALLOTHIONEIN OVEREXPRESSING CHINESE-HAMSTER CELL-LINE, MUTATION RESEARCH, 314(2), 1994, pp. 143-157
Elevated intracellular levels of metallothionein have been associated
with resistance to the cytotoxic effects of some alkylating agents. In
order to study the mechanisms responsible for this resistance, we use
d a pair of CHO cell lines consisting of normal K1-2 cells and their d
erivative K1-2MT, which overexpresses the human metallothionein II-A g
ene (Lohrer et al., 1989). K1-2MT cells were found to be resistant to
cadmium chloride and the alkylating agents N-methyl-N'-nitro-N-nitroso
guanidine (MNNG), but resistance did not extend to the alkylating agen
t, 1,3-bis(2-chloroethyl)-1-nitrosourea, nor to adriamycin, an inhibit
or of DNA synthesis. The DNA damage caused by MNNG, was only marginall
y less in resistant cells compared with the parental cell line, thus e
xcluding drug scavenging as a possible mechanism for resistance. Also,
glutathione S-transferases (GSTs) were present at equal levels in bot
h cell lines (acidic and basic type GST) or slightly reduced in drug r
esistant K1-2MT cells (neutral type GST), thereby ruling out metabolic
inactivation of the alkylating agents. However, the drug resistant ph
enotype was accompanied by a more efficient block of DNA synthesis aft
er MNNG treatment and by a 3-h delay in the G2 phase of the cell cycle
. Using two-dimensional gel electrophoresis of total protein extracts,
we identified a 24-kDa protein (MIP1), which is only present in the r
esistant K1-2MT cells, and a 23.5-kDa protein (MIP2) which is 2-3 time
s over-synthesized in K1-2MT cells. MNNG treatment reduced the level o
f both proteins MIP1 and MIP2. These results suggest that the proteins
MIP1 and possibly MIP2 may be responsible for the alkylating agent re
sistant phenotype and are probably modulated by the human metallothion
ein II-A protein.