A variety of polypeptide toxins are isolated from spider venom, and hanatoxin 1 (HaTx1) from a Chilean tarantula is one of the most extensively investigated peptides. HaTx1 might act as a voltage-gating modifiers to bind ion channels and has been used to characterize the blocking properties of the voltage-gated potassium channel Kv2.1 through electrophysiological and mutational studies. Recent studies have shown that HaTx1 may first interact with the cell membrane rather than directly bind onto voltage-sensing domain of Kv2.1. Thus, in this study the interactions between HaTx1 and bio-membranes were investigated with biophysical methods as an excellent experimental platform and high intensity synchrotron radiation source to explore the structural changes of bio-membranes at atomic level. Furthermore, we depicted the detailed mechanism between HaTx1 and bio-membranes. Two parts of experiments were designed to investigate the interactions between HaTx1 and monolayers at air/water interface and between HaTx1 and lipid bilayers. The Langmuir-Blodgett film was used to study the adsorption and the insertion into monolayers of HaTx1 and its effect on different compositions of lipids. The results indicated that HaTx1 first adsorbed to monolayers and caused the area expansion of membranes, which varied with different compositions of lipids (POPC；POPC：DOPG = 3：1；POPC：DOPG = 2：1), when inserting into monolayers. This implied that the headgroup of phospholipids plays a crucial role in the adsorption and insertion of HaTx1. In addition, Lamellar X-ray diffraction was used to measure the membrane thickness of phospholipid bilayers interacting with HaTx1. The results showed that the membrane thickness decreased as the molar ratio of peptide-to-lipid (P/L) increased in all three compositions of lipids (POPC；POPC：DOPG = 3：1；POPC：DOPG = 2：1); as the P/L increased, HaTx1 caused the thinning effect on the thickness of lipid bilayer in different extent. HaTx1 has been shown to be a amphipathic peptide and demonstrated the membrane-thinning effect. As other extensively investigated amphipathic molecules (e.g., melittin and curcumin), HaTx1 caused bilayer deformation. Such deformation of cell membrane might affect the function of membrane proteins, thus it is considerable that HaTx1 could affect the function of voltage-gated potassium channels by modifying the properties of phospholipid bilayers. In the future with the breakthrough of experimental techniques, we aim to reveal the interplay between three components, HaTx1, lipid membranes, and voltage-gated potassium channels, and to elucidate the detailed mechanism of voltage-gated potassium channels.