The sulfur isotope record as preserved in sedimentary sulfate and sulfide minerals reflects the progressive oxidation of Earth's surface environment. The latest Proterozoic to early Paleozoic marine sulfur isotope record is distinguished by unusually high δ 34 S values in marine sulfates and sulfides. Geological considerations and sulfur-isotopic data indicate that the 34S-enrichment of the marine sulfate reservoir was the result of a rapid increase in the net fractionation between sedimentary sulfate and pyrite (Δ 34S) without a compensatory decline in the fractional burial rate of pyrite ( f pyr). A simple one-box model, in which Δ 34S is linked non-linearly to marine [SO 4], is used to explore the response in sedimentary sulfur isotope records ( δ 34S sulf and δ 34S pyr) to an increasing marine sulfate reservoir. The model results, when compared with a compilation of existing δ 34S sulf and δ 34S pyr data, suggest that the marine sulfate reservoir grew rapidly to roughly Phanerozoic levels in the middle Ediacaran Period, before the Gaskiers glaciation and prior to the onset of the Shuram–Wonoka negative δ 13C anomaly. It is further hypothesized that pO 2 levels rose prior to the onset of this extreme perturbation to the global carbon cycle, permitting the oxidation of a previously euxinic deep ocean and appearance of the first Ediacaran fauna by ca. 575 Ma, despite the enormous demand on oxidants implied by this large magnitude and long duration carbon isotope anomaly.