A strain of Pseudomonas putida isolated from activated sewage grew aerobically on the xenoestrogen precursor, nonylphenol polyethoxylate (NPEO_x, where x is the number of ethoxylate units) as sole carbon source. Comparative growth yields on NPEO_av6, NPEO_av9, and NPEO_av20 (mixtures with average ethoxylate numbers as indicated) were consistent with utilization of all but two ethoxylate units, and the final accumulating metabolite was identified by gas chromatography-mass spectroscopy as nonylphenol diethoxylate (NPEO₂). There was no growth on nonylphenol or polyethylene glycols, and there was no evidence for production of carboxylic acid analogs of NPEO_x. Biodegradation kinetics measured by high-pressure liquid chromatography (HPLC) for each component in NPEO_x mixtures showed that biodegradation proceeded via successive exoscission of the ethoxylate chain and not by direct scission between the second and third ethoxylate residues. The NPEO_x-degrading activity was inducible by substrate, and cell extracts of NPEO_av9-induced cells were also active on the pure alcohol ethoxylate, dodecyl octaethoxylate (AEO₈), producing sequentially, under either aerobic or anaerobic conditions, AEO₇, AEO₆, AEO₅, etc., thus demonstrating that the pathway involved removal of single ethoxylate units. HPLC analysis of 2,4-dinitrophenylhydrazone derivatives revealed acetaldehyde (ethanal) as the sole aldehydic product from either NPEO_av9 or AEO₈ under either aerobic or anaerobic conditions. We propose a mechanism for biotransformation which involves an oxygen-independent hydroxyl shift from the terminal to the penultimate carbon of the terminal ethoxylate unit of NPEO_x and dissociation of the resulting hemiacetal to release acetaldehyde and the next-lower homolog, NPEO_x1, which then undergoes further cycles of the same reaction until x = 2.