Nondefective murine leukemia viruses (MuLV) can induce a large spectrum of pathologic responses in mice, with a predominance of hematopoietic tumors. They do not carry an oncogene, and tumorigenic transformation is usually achieved by retroviral integration at the vicinity of a cellular proto-oncogene. Although MuLVs can infect many tissues and cell types, each virus will induce a specific type of tumor: T or B lymphomas, erythroleukemia, myeloid leukemia, etc. Many studies have shown that the primary determinant for this disease specificity and for tumorigenicity itself is the viral long terminal repeat (LTR) (11, 19–21, 25, 34, 35, 42, 58, 76). Moreover, a very good correlation has been demonstrated between transcriptional tissue specificity and disease specificity: viral gene expression is higher in the cell type that is the target for oncogenic transformation (6, 12, 32, 64). The U3 region of the LTR contains the promoter and the transcriptional regulatory elements. Since retroviruses use the cellular machinery for gene expression (transcription, translation), they are also likely to use the cellular regulatory functions, including transcription factors. Indeed, dissection of retroviral promoter-enhancer regions has led to the identification of binding sites for many cellular transcription factors, some of which seem to be crucial for tissue and disease specificity and tumorigenicity (11, 32, 46, 59, 60, 75). One striking example is the core binding factor: first identified as a factor binding to the core motif present in simian virus 40, polyomavirus, and MuLV enhancers (72), this transcription factor is now involved in the regulation of a growing number of genes specifically expressed in lymphoid or myeloid lineages (28, 49, 55, 63, 71, 78, 79). The core motif was shown to play a key role in disease specificity for several MuLV (11, 59). Other cellular factors playing a role in viral gene regulation are ETS family members (62), CAAT/enhancer binding proteins, AP1, NF1, helix-loop-helix (HLH) proteins binding to E-boxes, Oct proteins, and hormone receptors (14, 38, 47). Thus, analysis of retroviral regulatory regions can lead to new insights into the control of gene expression in eucaryotes. We have undertaken an analysis of the factors binding to the U3 region of two murine retroviruses that induce myeloid leukemia: Cas-Br-E and Graffi leukemia virus. Cas-Br-E induces a wide variety of hematopoietic tumors in NFS/N mice; however, injection in NIH Swiss mice causes mainly a non-T, non-B leukemia composed of blasts lacking any myeloid or lymphoid markers (13, 54). Genetic analyses have shown that the determinants for leukemogenicity are dispersed in different regions of the genome, including the LTRs (36). We have shown that the virus preferentially targets two potential oncogenes, fli-1 and evi-1, in 70 and 18% of the tumors, respectively (5–7). We have recently molecularly cloned the Graffi MuLV and shown that the molecular clones induced the same pathologic responses in BALB/c and NFS mice as the parental mixture did, i.e., a granulocytic leukemia, composed of myeloblasts and neutrophils with characteristic donut-like nuclei (54, 56). Two molecular clones, GV1.2 and GV1.4, have been characterized and shown to cause the same disease. They were highly similar, except for the presence of a perfect 60-bp duplication in the U3 region of the GV1.2 clone, which displays a shorter latency period. This correlation between the latency period and the number of enhancer repeats strongly suggest a role for the U3 region in the leukemogenic potential and disease specificity. Two of the regions found protected by DNase I footprinting analyses contain potential binding sites for GATA factors (1a). GATA factors are a family of DNA binding proteins that recognize the motif (A/T)GATA(A/G) (24, 44, 51). They possess a zinc finger of the form Cys-X2-Cys-X17-Cys-X2-Cys (24, 65). The founding member, GATA-1, was identified as a positive regulator of globin gene transcription (23) and has since been involved in the regulation of all known erythroid specific genes (50, 74). At least six GATA family members have been identified: GATA-1, GATA-2, and GATA-3 are involved in the regulation of hematopoiesis-specific genes (reviewed in reference 50) and are required for normal hematopoietic development in mice (51, 66, 74). Given this crucial role of GATA family members in hematopoietic gene regulation, one would not be surprised if they were involved in the transcription regulation of leukemia viruses. Here, we identify in the Cas-Br-E and Graffi U3 regions two GATA elements and show that GATA-1, GATA-2, and GATA-3 can bind to these elements. We also demonstrate that those three family members can indeed transactivate Cas-Br-E and Graffi LTR-driven expression.