Dimethylsilane polyamines: cytostatic compounds with potentials as anticancer drugs. II. Uptake and potential cytotoxic mechanisms.

Dimethylsilane tetramines are structural analogues of spermine with a (CH3)2 Si-group incorporated into the central carbon chain. They have potential as anticancer drugs. Their cytotoxic effect was considered to rely mainly on their polyamine antagonist property. In order to obtain new ideas about cellular mechanisms, which are potential targets of the dimethylsilane polyamines, the effects of these compounds on some basic cell functions, such as protein and DNA synthesis, and calmodulin antagonism were studied. In addition, their mode of accumulation in cells was investigated. It became evident that the intracellular accumulation of dimethylsilane polyamines is almost exclusively achieved via the polyamine transport system. However, the exchange of a part of the intracellular natural polyamines against dimethylsilane polyamines has only a small effect on polyamine uptake. Binding to the endoplasmic reticulum and inhibition of protein synthesis are presumably important for the cytotoxic action of bis(11-amino-4,8-diazaundecyl)dimethylsilane, a hexamine, but seem of no importance for the tetramines. Calmodulin antagonism, however, is likely to contribute to their cytotoxic effect.

Bis(7-amino-4-azaheptyl)dimethylsilane: a new tetramine with polyamine-like features. Effects on cell growth.

Bis(7-amino-4-azaheptyl)dimethylsilane is a new type of aliphatic polycation with structural features resembling those of spermine. The elongation to a seven-membered carbon chain in which the central CH2-group was substituted by (CH3)2Si renders the molecule more lipophilic than spermine. Cells accumulate the compound via the polyamine transport system. Due to suppression of ornithine decarboxylase, de novo putrescine biosynthesis is impaired, and intracellular putrescine and spermidine concentrations are depleted. Depletion of intracellular spermidine together with binding to functionally important polyamine binding sites are considered the main features of the compound which cause cytostatic, and at high concentrations, cytotoxic effects.

Dimethylsilane polyamines: cytostatic compounds with potentials as anticancer drugs.

Several dimethylsilane tetramines [homologs of spermine with an Si(CH3)2 group in the central carbon chain], a carbon analog of the dimethylsilane tetramines [containing C(CH3)2 instead of Si(CH3)2] and a dimethylsilane hexamine were studied with regard to their cytotoxic activity and their ability to interact with double-stranded DNA. All polyamine analogs exerted cytostatic effects to several cell lines at micromolar concentrations. Their ability to condense DNA was comparable to and their ability to displace ethidium bromide from binding to DNA was superior to that of spermine. Their cytostatic effect was not correlated with the depletion of cellular spermidine concentrations. It is suggested that the new polyamine analogs act mainly by displacing spermidine from binding sites which are essential for the promotion of cell growth.

Bis(7-amino-4-azaheptyl)dimethlysilane and bis(7-ethylamino-4-azaheptyl)dimethylsilane: inhibition of tumor cell growth in vitro and in vivo.

Bis(7-amino-4-azaheptyl)dimethylsilane (AzhepSi) and its bis(ethyl) derivative [bis(7-ethylamino-4-azaheptyl)dimethylsilane] (EtAzhepSi) are the first examples of a new type of aliphatic tetramine with a dimethylsilane group incorporated into the central carbon chain. AzhepSi shares certain properties with the natural polyamines, but in contrast with spermidine and spermine it inhibits the growth of L1210 leukemia cells in culture at micromolar concentrations. The bis(ethyl) derivative of AzhepSi was made, in analogy to bis(ethyl) spermine, a polyamine derivative, which gained much attention during the last decade as a potential anticancer drug. Chinese hamster ovary (CHO) cells accumulate the dimethylsilyl tetramines considerably more and are more sensitive to these drugs than are CHO-MG cells, a polyamine uptake-deficient mutant. This and related observations demonstrate that AzhepSi and EtAzhepSi are preferentially taken up by a polyamine transport system. Both tetramines inhibit the growth of a variety of tumor cells at micromolar concentrations. AzhepSi turned out to be either equipotent or more potent, but in no case less potent than EtAzhepSi. When given alone at daily doses of 25 micromol/kg, the compounds did not prolong the survival time of L1210 leukemia mice. However, in combination with 2-(difluoromethyl)ornithine and neomycin, AzhepSi had a significant effect on the life span of the animals. The growth rate of 3LL Lewis lung carcinoma was reduced by both compounds at daily doses of 25 micromol/kg. The observations presented in this work suggest that the dimethylsilyl tetramines are antiproliferative agents in vitro and in vivo. Due to enhanced general toxicity, the introduction of N-ethyl substituents was of no advantage in the case of these polyamine analogues.