In previous study, gibberellic acid[GA]-and IR-induced gene1 (VrGIR1) was isolated by differential display from mungbean (Vigina radiate) seedlings irradiated with 3~5 µm IR light. Its homolog in Arabidopsis, GASA4 (gibberellic acid-stimulated transcripts in Arabidopsis) was also induced by GA and IR. My thesis aims to investigate the functions of GASA4 in the crosstalk between GA and IR signaling pathways. Jasmonates (JA) and GA are important plant hormones that mainly mediate defense and growth, respectively. However, direct crosstalk between these two hormone pathways remains largely unknown. GASA4 has been shown to participate in GA signaling, and FAR-RED INSENSITIVE 219 (FIN219)/JAR1 was previously shown to play vital roles in far-red (FR) light and JA signaling pathway. Previous study indicated that GASA4 was down-regulated by FIN219. It is interesting to understand the relationship between FIN219 and GASA4 in the integration of both GA and JA signaling. Here, we analyze the regulation between FIN219 and GASA4 in both GA and JA treatments. The results revealed that gasa4 and fin219 mutant showed an insensitive phenotype to JA treatment, but more sensitive to GA treatment. The gene expression studies indicated that FIN219 positively regulated JA responsive genes, but GASA4 negatively regulated them. GASA4 was also found to regulate a GA responsive gene, SPINDLY (SPY), which can alter DELLA protein activity. Moreover, GASA4 negatively regulated DELLA RGA-LIKE3 (RGL3) expression, one of negative regulator of GA signaling that has been shown to participate in JA signaling, whereas FIN219 positively regulates RGL3 expression. Taken together, our data indicate that FIN219 and GASA4 participate in GA and JA signaling via regulating RGL3 expression. In addition to the regulation of GA and JA signaling, GASA4 was also involved in IR signaling pathway. The IR-induced PSAK and NPQ4 genes were acting in this pathway and regulated by GASA4. CO2 can absorb IR wavelength at about 4.3 µm. IR might affect photosynthetic efficiency by improving CO2 fixation. Our studies revealed that IR promotes the expression of PEP carboxylase gene and delays senescence in leaf discs of maize and Arabidopsis. Taken together, our data indicate that GASA4 functions as a crosstalk between light, including IR, and multiple hormones such as GA and JA, and may serve as a good candidate for future applications in improving crop yields.