As Sr isotope compositions in seawater are globally homogeneous, these proxies are useful in checking marine Sr budget change in direct link to global calcium cycle. ⁸⁷Sr/⁸⁶Sr valueis mainlydriven by two input fluxes to seawater; riverine flux connected with weathering of time-integrated radiogenic old continent and hydrothermal input flux derived from less radiogenic mantle. δ⁸⁸Sr in seawaterreflects marine calcium carbonate input/output flux. The marine Sr budget changed dramatically, in particular, during the Guadalupian (Middle Pemian), with the lowest value of seawater ⁸⁷Sr/⁸⁶Sr in the Phanerozoic, i.e., “the Capitanian minimum”. This likely reflected a major global environmental change associated with the end-Guadalupian mass extinction. Likewise, theδ⁸⁸Sr started to decrease in the Early Permian, and reached the Phanerozoic lowest value at the end of Capitanian (late Guadalupian). We measured δ⁸⁸Sr values of the Middle-Upper Permian marine carbonates with detailed biostratigraphy by TRITONTIMS, with correction of isotope fractionation during mass spectrometry with ⁸⁷Sr-⁸⁴Sr double spike. Analyzed samples were from various localities in the world, e.g., the Akasaka paleo-atoll limestone (Japan), and shelf carbonates in S. China. These results confirmed that both in stable δ⁸⁸Sr and radiogenic ⁸⁷Sr/⁸⁶Sr ratios, low values remained throughout the Guadalupian, whereas they increased in the Wuchiapingian. The extremely low δ⁸⁸Sr value in seawater may reflect the increased dissolution of carbonates and/or reduced carbonate burial, i.e., enhanced carbonate weathering or suppression of reef building on shelf settings according to the coeval global sea-level drop.