We have studied the effect of local environment on the electrical properties of gate confined quasi-one-dimensional channels at low temperature. By lithographic technique, six isolated nearby metal gates were fabricated on high mobility GaAs/AlGaAs heterostructure. The channel width and nearby potential profiles can be varied by individually biasing these metal gates. The temperature of the sample is also easily controlled. This work focused on the response of the electrical properties of the channel to local environmental factors. The observation of quantized conductance secures the quality of each narrow channel. The source-drain spectroscopy demonstrates subband structure and zero bias anomaly notably. Both source-drain spectroscopy and zero bias anomaly are sensitive to temperature, impurities and the shape of narrow channels. The zero bias anomaly peak decreases with increasing temperature. For a channel of a fixed width, a very small conductance peak appears upon varying nearby gates’ voltage ascribing to additional scattering points which arise from accumulated charges of impurities. In the other split gate configuration, we find that electrons would be backscattered due to misaligning subband bottoms of two adjacent quasi-one dimensional channels. The backscattered electrons would interfere with the original current leading to the conductance oscillations by continuously changing the energy levels of the adjacent narrow channel.