Biology:Proton coupled amino acid transporter

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Proton-coupled amino acid transporters belong to the SLC26A5 family; they are protein receptors whose main function is the transmembrane movement of amino acids and their derivatives. This family of receptors is most commonly found within the luminal surface of the small intestine as well as in some lysosomes. The solute carrier family (SLC) of genes includes roughly 400 membrane proteins that are characterized by 66 families in total. The SLC36 family of genes maps to chromosome 11. The diversity of these receptors is vast, with the ability to transport both charged and uncharged amino acids along with their derivatives. In research and practice, SLC36A1/2 are both targets for drug-based delivery systems for a wide range of disorders.

Structure

The human protein acid transporter (hPAT1) is 5585 base pairs long and codes for a protein 476 amino acids long. The transporter has nine transmembrane regions where the amino terminus faces the cytoplasm. The rat protein acid transporter (rPAT1) has been widely studied and an 85% amino acid sequence match was found between hPAT1 and rPAT1. The hPAT1 gene is located on chromosome 5q31-33 and has 11 exons that are coding regions. Its translation site begins in exon 2 and exon 11 contains the termination site.[1]

Proton-coupled amino acid transporters 1 and 2

The molecular weight of Proton-coupled amino acid transporter 1 is 53.28 kDA; the molecular weight of Proton-coupled amino acid transporter 2 is 53.22 kDA. PAT1 has been found in lysosomes in brain neurons but also in the apical membrane of intestinal epithelial cells where it is associated with the brush border. Proton-coupled amino acid transporter 1 has a higher affinity for proline than it does for glycine and alanine Proton-coupled amino acid transporter 2 is found subcellularly in the kidneys, lungs, spinal cord, and brain and likely has a role in myelinating neurons.[2] It has an overall higher affinity for glycine, alanine, and proline than PAT1 but is more specific for what can inhibit it.[3][4]

Biochemistry

Unlike most amino acid transporters in the exchange of Na+ with amino acid symporters, proton-coupled amino acid transporters function as H+ with amino acid symporters. They are located within the luminal surface of the small intestine and within lysosomes, so their action functions in absorption in the intestine and in the efflux pathway after intralysosomal digestion. Unlike typical mammalian amino acid transporters which function in exchanging Na+/amino acid symporters, these- transporters function in exchanging H+/amino acid symporters. The activity of transporters, such as Proton-coupled amino acid transporter 1 and Proton-coupled amino acid transporter 2 can be measured at the apical membrane of the human epithelial layer of cells which are loaded with pH sensitive dyes. The change in membrane potential can be measured by the absorption of pH sensitive dyes and the associated influx of H+ ions. The proteins involved in these transporters are consider anion exchangers

Function

The function of proton-coupled amino acid transporters is the transmembrane movement of amino acids and their derivatives for absorption by the luminal surface of the small intestine or digestion by intralysosomal proteins. In Drosophila models, the expression of SLC family genes that code for proton-coupled amino acid transporters is directly linked to the nutrient-dependent growth. In humans, similar expression patterns are observed and their function correlates to their location anatomically. Being located within the lamina of the small intestine allows for functional absorption of transported amino acids and derivatives. The majority of nutrient absorption takes place within this region of the intestines, and makes sense that these transporters are located throughout this tissue.

Non-functional proton coupled amino acid transporter

In hereditary disease iminoglycinuria, there is a defect in the human proton-coupled amino acid transporter 1 and 2 genes which results in a defect in the absorption of proline and glycine. Iminoglycinuria is an autosomal recessive disorder of the renal tubular. Lack of glycine and proline absorption leads to excess urinary excretions containing amino acids. If the transporters are not working properly, a drug that they usually help gain entry in to the cell might not be absorbed[3] Their function can also be inhibited by tryptophan derivatives and allow for exploration into the function of hPAT1 and hPAT2. Additionally, mutations that lead to structural changes in amino acid binding sites play a role in their functional transport.[5]

Biosynthesis

The DNA sequence of these transporters is transcribed in the nucleus of the cell by RNA polymerase and undergoes splicing and capping before it travels to the cytoplasm. In the cytoplasm, translation begins via a sequence in exon 2 of the mRNA. Subsequently, protein folding and packaging insert the transporter into the membrane. The protein has a signal recognition particle that is recognized as it leaves the ribosome. N-glycosylation at various sites on hPAT1 is necessary for its transport function. Three of its extracellular residues are glycosylated and determine transport efficacy.[6]

Clinical significance

PAT1 mRNA is expressed in the GI tract between the stomach and descending colon, but is generally absent in the esophagus, caecum, and rectum. This allows for different treatments that affect the affinity of the carrier protein for its substrates, giving the potential to treat various amino-acid related diseases. HPAT1 and HPAT2 are important in the absorption of certain drugs, especially pharmaceutically active amino acids derivatives.[3] They have also been targeted with medications used as anticonvulsants, for prostate cancer, and for bladder cancer.[7] HPAT1 and 2 are integral to the central nervous system because they transport GABA and its analogues which can induce and inhibitory and excitatory effect in the brain.[1]

References

  1. 1.0 1.1 Chen, Zhong; Fei, You‐Jun; Anderson, Catriona M. H.; Wake, Katherine A.; Miyauchi, Seiji; Huang, Wei; Thwaites, David T.; Ganapathy, Vadivel (January 2003). "Structure, function and immunolocalization of a proton‐coupled amino acid transporter (hPAT1) in the human intestinal cell line Caco‐2". The Journal of Physiology 546 (2): 349–361. doi:10.1113/jphysiol.2002.026500. PMID 12527723. 
  2. Boll, Michael; Daniel, Hannelore; Gasnier, Bruno (1 February 2004). "The SLC36 family: proton-coupled transporters for the absorption of selected amino acids from extracellular and intracellular proteolysis". Pflügers Archiv: European Journal of Physiology 447 (5): 776–779. doi:10.1007/s00424-003-1073-4. PMID 12748860. 
  3. 3.0 3.1 3.2 Pillai, Samyuktha Muralidharan; Meredith, David (28 January 2011). "SLC36A4 (hPAT4) Is a High Affinity Amino Acid Transporter When Expressed in Xenopus laevis Oocytes". The Journal of Biological Chemistry 286 (4): 2455–2460. doi:10.1074/jbc.M110.172403. PMID 21097500. 
  4. Anderson, Catriona M.H.; Grenade, Danielle S.; Boll, Michael; Foltz, Martin; Wake, Katherine A.; Kennedy, David J.; Munck, Lars K.; Miyauchi, Seiji et al. (November 2004). "H+/amino acid transporter 1 (PAT1) is the imino acid carrier: An intestinal nutrient/drug transporter in human and rat". Gastroenterology 127 (5): 1410–1422. doi:10.1053/j.gastro.2004.08.017. PMID 15521011. 
  5. Edwards, Noel; Anderson, Catriona M.H.; Gatfield, Kelly M.; Jevons, Mark P.; Ganapathy, Vadivel; Thwaites, David T. (January 2011). "Amino acid derivatives are substrates or non-transported inhibitors of the amino acid transporter PAT2 (slc36a2)". Biochimica et Biophysica Acta (BBA) - Biomembranes 1808 (1): 260–270. doi:10.1016/j.bbamem.2010.07.032. PMID 20691150. 
  6. Dorn, Madlen; Jaehme, Michael; Weiwad, Matthias; Markwardt, Fritz; Rudolph, Rainer; Brandsch, Matthias; Bosse-Doenecke, Eva (19 May 2009). "The role of N -glycosylation in transport function and surface targeting of the human solute carrier PAT1". FEBS Letters 583 (10): 1631–1636. doi:10.1016/j.febslet.2009.04.037. PMID 19409386. 
  7. Frølund, S; Holm, R; Brodin, B; Nielsen, CU (October 2010). "The proton-coupled amino acid transporter, SLC36A1 (hPAT1), transports Gly-Gly, Gly-Sar and other Gly-Gly mimetics". British Journal of Pharmacology 161 (3): 589–600. doi:10.1111/j.1476-5381.2010.00888.x. PMID 20880398. 



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