The work is to investigate the bystander effect and related signaling factor induced by targeted irradiation on tumor cells. Human glioblastoma T98G cells were irradiated with a precise number of helium microbeam ions, which targeted to either nuclear or cytoplasm. Chromosome damage and intracellular NO level were assayed. Influence of a NO free radical scavenger on these radiation responses was measured. Using DEANO, the cellular effect of NO was also studied. It was found that even only one cell with a population was targeted with one particle through either nuclear or cytoplasm, additional cellular damage was induced in other 10s cells through a signaling amplification pathway and related bystander response. Although cell damage induced directly by nuclear irradiation was greater than that induced by cytoplasmic irradiation, bystander responses induced by these two kinds of irradiation were similar. When a fraction of cells were individually irradiated by helium ions, the yield of micronuclei was obviously higher than that assuming no bystander effect. However, these targeted irradiation induced bystander response were inhibited by c-PTIO, a scavenger of nitric oxide (NO) free radical. Detected with a NO molecular probe DAF-AM, it was observed that when only 1% of cells were irradiated either through nuclear or cytoplasm, the percentage of NO-positive cells increased by about 30% so that the NO-related fluorescence intensity increased by 15%. Moreover, micronuclei were induced indeed in T98G cells treated with a NO donor. These indicate that NO is a bystander signaling factor for both nuclear irradiation and cytoplasmic irradiation.