• Source: PIEZO1

PIEZO1 is a mechanosensitive ion channel protein that in humans is encoded by the gene PIEZO1. PIEZO1 and its close homolog PIEZO2 were cloned in 2010, using an siRNA-based screen for mechanosensitive ion channels.




Structure and function


PIEZO1 (this gene) and PIEZO2 share 47% identity with each other and they have no similarity to any other protein and contain no known protein domains. They are predicted to have 24-36 transmembrane domains, depending on the prediction algorithm used. In the original publication the authors were careful not to call the piezo proteins ion channels, but a more recent study by the same lab convincingly demonstrated that indeed PIEZO1 is the pore-forming subunit of a mechanosensitive channel. This new " PIEZO" family is catalogued as InterPro: IPR027272 and TCDB 1.A.75. PIEZO1 homologues are found in C. elegans and Drosophila, which, like other invertebrates, have a single PIEZO protein.
It is known (PDB: 6B3R​) that PIEZO1 channel is a three-bladed propeller-like structure. A lever-like mechanogating mechanism is assumed.




Tissue distribution


PIEZO1 is expressed in the lungs, bladder and skin, where mechanosensation has important biological roles. Unlike PIEZO2 which is highly expressed in sensory dorsal root ganglia, PIEZO1 is not expressed in sensory neurons. Consequently PIEZO1 plays a significant role in multiple neurobiological processes including axon regeneration, neural stem cells differentiation and neurological diseases progression.
PIEZO1 is also expressed in immune cells, including lymphocytes and myeloid cells, and has been shown to have a role in the function of fundamental immune processes, like antigen presentation and phagocytosis.
Levels of PIEZO1 mRNA have been shown to be increased by mechanical stimulation, such as vibration at 1,000 Hz in monocytes.




Clinical significance


PIEZO1 is also found in red blood cells, and gain of function mutations in the channels are associated with hereditary xerocytosis or stomatocytosis. PIEZO1 channels are pivotal integrators in vascular biology.
An allele of PIEZO1, E756del, results in a gain-of-function mutation, resulting in dehydrated RBCs and conveying resistance to Plasmodium. This allele has been demonstrated in vitro to prevent cerebral malaria infection.
PIEZO1 has been implicated in extrusion of epidermal cells when a layer becomes too confluent to preserve normal skin homeostasis. This acts to prevent excess proliferation of skin tissue, and has been implicated in cancer biology as a contributing factor to metastases by assisting living cells in escaping from a monolayer.
Expression of murine PIEZO1 in mouse innate immune cells is essential for their function, a role mediated by sensing mechanical cues. Deficiency in PIEZO1 in mice lead to increased susceptibility of myeloid cells to infection by Pseudomonas aeruginosa.
Lymphatic malformation 6 syndrome is caused by mutations in PIEZO1 and was characterized in 2015.
PIEZO1 has been proposed as a therapeutic target for Alzheimer's disease. The build-up of amyloid-β plaques stiffen the brain's structure. Microglial maintenance cells, which express PIEZO1, detect this stiffness via PIEZO1-enabled mechanosensation and in response surround, compact, and phagocytosize the plaques. Removal of the gene which codes for PIEZO1 in microglia decreases plaque clearance and hastens cognitive decline in rats.




Ligands


Agonists
Jedi1/2
Yoda1 (small molecule agonist)
Antagonists

Streptomycin
Ruthenium Red
GsMTx4
Dooku1




References

Kata Kunci Pencarian:

• Ardem Patapoutian
• PIEZO1
• Ardem Patapoutian
• Piezo
• Human blood group systems
• Epithelium
• Lymphatic malformation 6 syndrome
• Er blood group system
• Hereditary stomatocytosis
• Yoda1
• Serotonin