The dairy yeast Kluyveromyces marxianus is a promising cell factory for producing bioethanol and heterologous proteins, as well as a robust synthetic biology platform host, due to its safe status and beneficial traits, including fast growth and thermotolerance. However, the lack of high-efficiency transformation methods hampers the fundamental research and industrial application of this yeast. Protoplast transformation is one of the most commonly used fungal transformation methods, but it yet remains unexplored in K. marxianus. Here, we established the protoplast transformation method of K. marxianus for the first time. A series of parameters on the transformation efficiency were optimized: cells were collected in the late-log phase and treated with zymolyase for protoplasting; the transformation was performed at 0 °C with carrier DNA, CaCl2 , and PEG; after transformation, protoplasts were recovered in a solid regeneration medium containing 3-4% agar and 0.8 m sorbitol. By using the optimized method, plasmids of 10, 24, and 58 kb were successfully transformed into K. marxianus. The highest efficiency reached 1.8 × 104 transformants per μg DNA, which is 18-fold higher than the lithium acetate method. This protoplast transformation method will promote the genetic engineering of K. marxianus that requires high-efficiency transformation or the introduction of large DNA fragments.