Residues of TRPM8 at the Lipid-Water-Interface have Coevolved with Cholesterol Interaction and are Relevant for Diverse Health Disorders.

TRPM8 is a non-selective cation channel that is expressed in several tissues and cells and also has a unique property to be activated by low-temperature. In this work, we have analyzed the conservation of amino acids that are present in the lipid-water-interface (LWI) region of TRPM8, the region which experiences a microenvironment near the membrane surface. We demonstrate that the amino acids present in the LWI region are more conserved than the transmembrane or even full-length TRPM8, suggesting strong selection pressure in these residues. TRPM8 also has several conserved cholesterol-binding motifs where cholesterol can bind in different modes and energies. We suggest that mutations and/or physiological conditions can potentially alter these TRPM8-cholesterol complexes and can lead to physiological disorders or even apparently irreversible diseases such as cancer and neurodegeneration.

Ratio of Hydrophobic-Hydrophilic and Positive-Negative Residues at Lipid-Water-Interface Influences Surface Expression and Channel Gating of TRPV1.

During evolution, TRPV1 has lost, retained or selected certain residues at Lipid-Water-Interface (LWI) and formed specific patterns there. The ratio of "hydrophobic-hydrophilic" and "positive-negative-charged" residues at the inner LWI remains conserved throughout vertebrate evolution and plays important role in regulating TRPV1 trafficking and localization. Arg575 is an important residue as Arg575Asp mutant has reduced surface expression, co-localization with lipid raft markers, cell area and increased cell lethality. This lethality is most likely due to the disruption of the ratio between positive-negative charges caused by the mutation. Such lethality can be rescued by either using TRPV1-specfic inhibitor 5'-IRTX or by restoring the positive-negative charge ratio at that position, i.e. by introducing Asp576Arg mutation in Arg575Asp backbone. We propose that Arg575Asp mutation confers TRPV1 in a "constitutive-open-like" condition. These findings have broader implication in understanding the molecular evolution of thermo-sensitive ion channels and the micro-environments involved in processes that goes erratic in different diseases. The segment of TRPV1 that is present at the inner lipid-water-interface (LWI) has a specific pattern of amino acid combinations. The overall ratio of +ve charge /-ve charge and the ratio of hydrophobicity/hydrophilicity remain constant throughout the vertebrate evolution (ca 450 million years). This specific pattern is not observed in the outer LWI region of TRPV1.

Cytochrome C interacts with the pathogenic mutational hotspot region of TRPV4 and forms complexes that differ in mutation and metal ion-sensitive manner.

The importance of TRPV4 in physiology and disease has been reported by several groups. Recently we have reported that TRPV4 localizes in the mitochondria in different cellular systems, regulates mitochondrial metabolism and electron transport chain functions. Here, we show that TRPV4 colocalizes with Cytochrome C (Cyt C), both in resting as well as in activated conditions. Amino acid region 592-630 of TRPV4 (termed as Fr592-630) that also covers TM4-Loop-TM5 region (which is also a hotspot of several pathogenic mutations) interacts with Cyt C, in a Ca2+-sensitive manner. This interaction is also variable and sensitive to other divalent and trivalent cations (i.e., Cu2+, Mn2+, Ni2+, Zn2+, Fe3+). Key residues of TRPV4 involved in these interactions remain conserved throughout the vertebrate evolution. Accordingly, this interaction is variable in the case of different pathogenic mutations (R616Q, F617L, L618P, V620I). Our data suggest that the TRPV4-Cyt C complex differs due to different mutations and is sensitive to the presence of different metal ions. We propose that TRPV4-Cyt C complex formation is important for physiological functions and relevant for TRPV4-induced channelopathies.