Eom S , Lee S , Lee J , Pyeon M , Yeom HD , Song JH , Choi EJ , Lee M , Lee JH , Chang JY .

	Graphical Abstract
	Fig. 1. Confirmation of interaction between LPGA and hPKD2L1. (A) The chemical structure of LPGA. (B) Confirmation of proton concentration-dependent activity of hPKD2L1. (C) By applying proton and LPGA to non-injected oocyte, it was confirmed that no activity was shown in non-injected oocytes. (D) In oocytes injected with hPKD2L1 and expressed, activity by proton and LPGA is shown. The scaling bar and each applied pH are displayed at the top side of the current in the figures. All experiments were performed at room temperature, and the holding potential of the protocol used in the experiments was -80 mV. (n = 6-8, obtained from four different oocytes)
	Fig. 2. Confirmation of LPGA's activation manner on hPKD2L1. (A) Confirm whether this activity has concentration-dependent by applying various concentrations of LPGA to hPKD2L1. (B) The sigmoidal graph is shown by normalizing the current shown in 2A, the current of 10 mM LPGA was specified as 100%, and pitted using the Hill equation. (C) The current activity of LPGA applied to hPKD2L1 is shown in a vertical bar chart. Each 'n' number is represented by a black rhombus shape and the applied concentration was indicated at the top of the bar. (D) A ramp protocol was performed to confirm the voltage-dependent manner, and the voltage was applied from -100 mV to +60 mV. Each applied concentration is shown in the figure. All experiments were performed at room temperature, and the holding potential of the protocol used in the experiments was -80 mV. (n = 6-8, obtained from four different oocytes)
	Fig. 3. Molecular docking modeling of LPGAs to hPKD2L1. (A) Side views of the docked LPGAs in complex with hPKD2L1. (B) Top views of the docking model. (C) An enlarged view of the red dotted line in Fig. 3A. (D) An enlarged view of the red dotted line in Fig. 3B.
	Fig. 4. The binding pocket and docking results of LPGAs and hPKD2L1. (A) The binding pocket in the hPKD2L1 region of the extracellular domain membrane pocket side. (B) Two-dimensional schematic presentation of the predicted binding mode of LPGAs in the ligand-binding pocket. The ligands and important residues are shown. (C, D) Computational simulated binding interaction of ligand and residues in wild-type and mutants. The replaced mutants showed changes in interaction activities at varying degrees. (C) Interaction between naringin and wild-type hPKD2L1. (D) Interaction between LPGAs and mutant-type hPKD2L1.
	Fig. 5. Confirmation of inward current change through a changing promising binding residue of LPGA in hPKD2L1 mutant-type. (A) Result of applying ND96 (pH4.0) and LPGA to R229A mutant-type by concentration. The scaling bar and each applied pH are displayed at the top side of the current in the figures. (B) Results of normalization of inward current by Fig. 5A that LPGA and comparison with wild-type inward current. This sigmoid graph was pitted by the Hill equation. (C) The inward current of wild-type and mutant-type hPKD2L1 was numerically quantified and expressed as a vertical error-bar chart. Each 'n' number is represented by a black rhombus shape. The p-value is < 0.001 *** and < 0. 0.01 **. (D) Current of wild-type and mutant-type according to voltage fluctuation from -100 mV to +60 mV through ramp protocol. All experiments were performed at room temperature, and the holding potential of the protocol used in the experiments was - 80 mV. (n = 6-8, obtained from four different oocytes)

Adler, A novel family of mammalian taste receptors. 2000, Pubmed

Adler, A novel family of mammalian taste receptors. 2000, Pubmed
Breslin, Mammalian taste perception. 2008, Pubmed
Chandrashekar, The receptors and cells for mammalian taste. 2006, Pubmed
Chandrashekar, T2Rs function as bitter taste receptors. 2000, Pubmed
Chandrashekar, The cells and peripheral representation of sodium taste in mice. 2010, Pubmed
Chandrashekar, The taste of carbonation. 2009, Pubmed
Chang, A proton current drives action potentials in genetically identified sour taste cells. 2010, Pubmed
Diepeveen, Molecular insights into human taste perception and umami tastants: A review. 2022, Pubmed
Drewnowski, Sweetness and food preference. 2012, Pubmed
Glendinning, Is the bitter rejection response always adaptive? 1994, Pubmed
Guan, Two-electrode voltage clamp. 2013, Pubmed , Xenbase
Huang, The cells and logic for mammalian sour taste detection. 2006, Pubmed
Kwak, Cancer Preventive Potential of Kimchi Lactic Acid Bacteria (Weissella cibaria, Lactobacillus plantarum). 2014, Pubmed
Mucchetti, Production of pyroglutamic acid by thermophilic lactic acid bacteria in hard-cooked mini-cheeses. 2002, Pubmed
Mueller, The receptors and coding logic for bitter taste. 2005, Pubmed
Nelson, Mammalian sweet taste receptors. 2001, Pubmed
Park, Health benefits of kimchi (Korean fermented vegetables) as a probiotic food. 2014, Pubmed
Park, Effect of antioxidant activity in kimchi during a short-term and over-ripening fermentation period. 2011, Pubmed
Su, Cryo-EM structure of the polycystic kidney disease-like channel PKD2L1. 2018, Pubmed
Wang, High humidity aggravates the severity of arthritis in collagen-induced arthritis mice by upregulating xylitol and L-pyroglutamic acid. 2021, Pubmed
Woo, Bioactive Compounds in Kimchi Improve the Cognitive and Memory Functions Impaired by Amyloid Beta. 2018, Pubmed
Zhang, Coding of sweet, bitter, and umami tastes: different receptor cells sharing similar signaling pathways. 2003, Pubmed
Zhang, Novel Umami Ingredients: Umami Peptides and Their Taste. 2017, Pubmed
Zhao, The receptors for mammalian sweet and umami taste. 2003, Pubmed