Metal-organic framework play an important role in developing novel detection techniques. Herein, an ultrathin two-dimensional (2D) metal-organic framework nanosheet (Cu-TCPP) assembled microflower was successfully synthesized and applied for ultrasensitive detection. The high detection performance of Cu-TCPP microflower was attributed to high-capacity aptamer adsorption and specific desorption resulting from numerous approachable active sites, and its ultrathin nanosheets microflower-like structure. Moreover, the Cu-TCPP microflower had overcame the disadvantages of 2D MOF nanosheets which tended to agglomerate. Moreover, it exhibited excellent fluorescence quenching performance as a donor for fluorescence resonance energy transfer. Acetamiprid, a new chloronicotinic neurotoxic insecticide was used as the model analyte. The ultrasensitive sensor was developed by combining the Cu-TCPP microflower with deoxyribonuclease Ⅰ signal enhanced fluorescence. When acetamiprid was present, the fluorescent labeled aptamer probe was selectively bound to acetamiprid and desorbed from the Cu-TCPP microflower, resulting in fluorescence recovery. Subsequently, DNase Ⅰ was used to cleave the DNA strands of the aptamer probe, and acetamiprid was released to participate in a new cycle. The detection limit of the assay was as low as 5.56 pg/mL with a linear range 50.00 pg/mL∼5.00 μg/mL, and it was a universal platform to detect other analytes. Display omitted •The Cu-TCPP microflower was synthetized with superior active sites and FRET performance.•The Cu-TCPP microflower and DNase I assisted amplification was combined for ultrasensitive aptasensor.•The aptasensor for sensitive and selective detection of acetamiprid with LOD 5.56 pg/mL and linear range 50 ∼ 5,000,000 pg/mL.