MEFV is a gene expressed specifically in myeloid cells and whose mutations underlie an autosomal recessive auto-inflammatory disease, called familial Mediterranean fever (FMF), characterized by recurrent episodes of serosal inflammation. This gene, which encodes a protein with unclear physiological functions, has been shown to be up-regulated by the pro-inflammatory cytokine tumor necrosis factor alpha (TNFalpha). However, the mechanism of this regulation is unknown, and the MEFV promoter is still to be characterized. Here, we show that 243 bp of the 5'-flanking region of the human MEFV gene are sufficient to direct high level expression of MEFV in TNFalpha-treated cells. The TNFalpha-induced expression of MEFV is dependent on both NFkappaB p65 and C/EBPbeta that bind to evolutionarily conserved sites located, in the human promoter, at positions -163 and -55, respectively. As shown by a series of transcription and gel shift assays performed with wild-type and mutated promoter sequences, these two transcription factors act differently on the TNFalpha-dependent transcription of MEFV: C/EBPbeta is the key regulatory factor required to confer cell responsiveness to TNFalpha, whereas NFkappaB p65 increases this response by means of a synergistic interaction with C/EBPbeta that is dependent on the integrity of the identified -55 C/EBP binding site. Given the phenotype of patients with FMF, this C/EBP-NFkappaB interaction may represent a key step in the control of an inflammatory response that is abnormally high in this disease. These data, which shed novel light on the pathophysiology of FMF, represent an unusual example of cross-talk between C/EBP and NFkappaB pathways in TNFalpha signaling.