1. Departments of Molecular Biology and Physics, Princeton University , Princeton, New Jersey 08544, USA

Correspondence to: Michael B. Elowitz Correspondence and requests for materials should be addressed to M.B.E. (e-mail: Email: melowitz@princeton.edu).

Networks of interacting biomolecules carry out many essential functions in living cells¹, but the 'design principles' underlying the functioning of such intracellular networks remain poorly understood, despite intensive efforts including quantitative analysis of relatively simple systems². Here we present a complementary approach to this problem: the design and construction of a synthetic network to implement a particular function. We used three transcriptional repressor systems that are not part of any natural biological clock^{3, 4, 5} to build an oscillating network, termed the repressilator, in Escherichia coli. The network periodically induces the synthesis of green fluorescent protein as a readout of its state in individual cells. The resulting oscillations, with typical periods of hours, are slower than the cell-division cycle, so the state of the oscillator has to be transmitted from generation to generation. This artificial clock displays noisy behaviour, possibly because of stochastic fluctuations of its components. Such 'rational network design' may lead both to the engineering of new cellular behaviours and to an improved understanding of naturally occurring networks.