Corn is one of the most important crops in the world since it is a staple food of many people and animals. Southern corn leaf blight (SCLB) is caused by the air-borne fungal pathogen Cochliobolus heterostrophus. Infected lesions expand and merge rapidly, cauing corn leaves shrivel and ultimately end up with low yield. Foliar spray with fungicide Maneb is a usual measure of disease control. Previous field trials had shown Bacillus cereus C1L application in corn rhizosphere suppressed SCLB disease severity. This research attempts to demonstrate possible defense mechanisms involved in C1L-induced systemic resistance to SCLB by gene expression analysis and microscopical examination. Gene expressions of cytosolic ascorbate peroxidase (cAPX) and phenylalanine ammonia lyase (PAL) increased earlier and to higher level in the C1L- and dimethyl disulfide (DMDS)-treated corn leaves after pathogen inoculation as compared with the control. In addition, through histochemical staining, lower H2O2, more phenolic compounds, and increased callose deposition were observed in the C1L- and DMDS-treated corn leave than the control after inoculation with C. heterostrophus. In addition, since lesion sizes were significantly reduced by application of ethylene biosynthesis inhibitor Retain® and the ethylene-inducible EIN2 gene were down regulated in the leaves by C1L treatment, it appears that strain C1L can prevent the disease by suppressing ethylene pathway. On the other hand, increased expression of glutathione transferase genes and activities in C. heterostrophus-inoculated leaves were observed in microarray analysis and GST activity assay, suggesting that strain C1L could build disease resistance capacity through enhancing detoxification in maize.