Pancreatic elastase

Pancreatic elastase
Identifiers
EC number 3.4.21.36
CAS number 848900-32-3
Databases
IntEnz IntEnz view
BRENDA BRENDA entry
ExPASy NiceZyme view
KEGG KEGG entry
MetaCyc metabolic pathway
PRIAM profile
PDB structures RCSB PDB PDBe PDBsum
Gene Ontology AmiGO / EGO
Pancreatic elastase II
Identifiers
EC number 3.4.21.71
CAS number 75603-19-9
Databases
IntEnz IntEnz view
BRENDA BRENDA entry
ExPASy NiceZyme view
KEGG KEGG entry
MetaCyc metabolic pathway
PRIAM profile
PDB structures RCSB PDB PDBe PDBsum
Gene Ontology AmiGO / EGO
Pancreatic endopeptidase E
Identifiers
EC number 3.4.21.70
CAS number 68073-27-8
Databases
IntEnz IntEnz view
BRENDA BRENDA entry
ExPASy NiceZyme view
KEGG KEGG entry
MetaCyc metabolic pathway
PRIAM profile
PDB structures RCSB PDB PDBe PDBsum

Pancreatic elastase is a form of elastase that is produced in the acinar cells of the pancreas, initially produced as an inactive zymogen and later activated in the duodenum by trypsin. Elastases form a subfamily of serine proteases, characterized by a distinctive structure consisting of two beta barrel domains converging at the active site that hydrolyze amides and esters amongst many proteins in addition to elastin, a type of connective tissue that holds organs together. Pancreatic elastase 1 is a serine endopeptidase, a specific type of protease that has the amino acid serine at its active site. Although the recommended name is pancreatic elastase, it can also be referred to as elastase-1, pancreatopeptidase, PE, or serine elastase.

The first isozyme, pancreatic elastase 1, was initially thought to be expressed in the pancreas. However it was later discovered that it was the only chymotrypsin-like elastase that was not expressed in the pancreas. In fact, pancreatic elastase is expressed in basal layers of epidermis (at protein level). Hence pancreatic elastase 1 has been renamed elastase 1 (ELA1) or chymotrypsin-like elastase family, member 1 (CELA1).[1] For a period of time, it was thought that that ELA1 / CELA1 was not transcribed into a protein.[2] However it was later discovered that it was expressed in skin keratinocytes.[3]

Clinical literature that describes human elastase 1 activity in the pancreas or fecal material is actually referring to chymotrypsin-like elastase family, member 3B (CELA3B).[1]

Structure

Pancreatic elastase is a compact globular protein with a hydrophobic core. This enzyme is formed by three subunits. Each subunit binds one calcium ion (cofactor). There are three important metal-binding sites in amino acids 77, 82, 87.[4] The catalytic triad , located in the active site is formed by three hydrogen-bonded amino acid residues (H71, D119, S214), and plays an essential role in the cleaving ability of all proteases. It is composed of a single peptide chain of 240 amino acids and contains 4 disulfide bridges. It has a high degree of sequence identity with pancreatic elastases that correspond to other species, such as the rat's, with whom it shares 86% of its sequence.[5] Its enzymatic activity is a result of the specific three-dimensional conformation which its single polypeptide chain adopts, and therefore, activity is lost by denaturation and/or conformational changes.

Inhibitors

Elafin, the skin-derived elastase inhibitor, has been shown to be a potent and specific inhibitor of both the porcine homolog of ELA1 and human leukocyte elastase in vitro. Elafin is expressed by epidermal keratinocytes under hyperproliferative conditions such as psoriasis and wound healing. It has also been reported to be present in many other adult epithelia that are exposed to environmental stimuli: tongue, plate, lingual tonsils, gingiva, pharynx, epiglottis, vocal fold, esophagus, uterine cervix, vagina, and hair follicles. In all these tissues, the presence of inflammatory cells is physiologic and elafin expression is believed to protect against leukocyte proteases, thereby helping to maintain epithelial integrity.

Elafin on the contrary has never been found in the basal layer in any type of epithelial tissue. Indeed elafin is virtually absent in normal human epidermis. The other known elastase inhibitor, SLP1, however, has been reported to be expressed in the basal keratinocytes suggesting that this may be the major elastase inhibitor in normal epidermis.

Alpha 1-antitrypsin and alpha-2-macroglobulin are human serum protease inhibitors that completely inhibit the general proteolytic activity of pancreatic elastase 1 and 2. It has been observed that a protease must be active in order to bind to these two inhibitors. Studies proved that the activity of elastase 2 was enhanced in 25-250 mM NaCl. The activity of elastase 2 in NaCl approached approximately twice the activity without NaCl. Elastase 1 is slightly inhibited above 150 mM NaCl[6]

Clinical significance

Mutations of the CELA1 gene were suspected to be associated with diffuse nonepidermolytic palmoplantar keratoderma (diffuse NEPPK).[3] However the suspected sequence variant was fully functional and did not strongly associate with the disease. More recently, a specific mutation in the KRT6C gene has been linked to some cases of diffuse NEPPK.[7]

A possible polymorphism of the CELA1 gene coding this protein was found. On a secondary structure level, this polymorphism manifests itself in an excision of a short sequence of CELA1. The disappeared sequence carries the key amino acid residues Val-227 and Thr-239, which contribute to the substrate specificity of elastase I (highlighted in Figure 3), as well as five of the eight amino acids involved in the primary contact of the elafin(inhibitor)/elastase complex formation. These observations imply that the sequence variant might modify the substrate specificity of the enzyme and abolish the inhibitor binding capability. Though there were no obvious pathogenic epidermal abnormalities associated with the truncated ELA1 variant, it is possible that carriers of the polymorphism may be at greater risk of developing the common skin diseases such as psoriasis and eczema (genetic and histologic studies will be required to investigate the role of ELA1 in these common epidermal disorders.).[3]

Biosynthesis

Pancreatic elastase is formed by activation of proelastase from mammalian pancreas by trypsin. After processing to proelastase, it is stored in the zymogen granules and then activated to elastase in the duodenum by the tryptic cleavage of a peptide bond in the inactive form of the precursor molecule.[8] This process results in the removal of an activation peptide from the N-terminal, that enables the enzyme to adopt its native conformation.

Isozymes

Humans have five chymotrypsin-like elastase genes which encode the structurally similar proteins:

Family Gene symbol Protein name EC number
Approved Previous Approved Previous
chymotrypsin-
like
CELA1 ELA1 chymotrypsin-like elastase family, member 1 elastase 1, pancreatic EC 3.4.21.36
CELA2A ELA2A chymotrypsin-like elastase family, member 2A elastase 2A, pancreatic EC 3.4.21.71
CELA2B ELA2B chymotrypsin-like elastase family, member 2B elastase 2B, pancreatic EC 3.4.21.71
CELA3A ELA3A chymotrypsin-like elastase family, member 3A elastase 3A, pancreatic EC 3.4.21.70
CELA3B ELA3B chymotrypsin-like elastase family, member 3B elastase 3B, pancreatic EC 3.4.21.70

Post-translational modifications

Glycosylation at Asn79 and Asn233.[9]

Gene

The gene that codes for pancreatic elastase 1 is CELA1 (synonym: ELA1) Pancreatic elastase 1 is encoded by a single genetic locus on chromosome 12. Studies of human pancreatic elastase 1 have shown that this serine protease maps to the chromosomal region 12q13[10] and it is close to a locus for an autosomal dominant skin disease, Diffuse nonepidermolytic palmoplantar keratoderma.[3]

Reactions

Reaction catalysed by pancreatic elastase 1. This image represents the hydrolysis of the succinyl-Ala-Ala-Ala-p-nitroanalide. The addition of one water molecule provokes the hydrolysis of the molecule and the release of p-nitroaniline.

The hydrolysis that elastases bring about occur in several steps, starting with the formation of a complex between elastase and its substrate, with the carbonyl carbon positioned near the nucleophilic serine, followed by a nucleophillic attack that forms an acyl-enzyme intermediate ( a pair of electrons from the double bond of the carbonyl oxygen moves to the oxygen) while the first product is released. The intermediate is then hydrolyzed in a deacylation step, regenerating the active enzyme and resulting in the release of the second product ( the electron-deficient carbonyl carbon re-forms the double bond with the oxygen and the C-terminus of the peptide is released. It preferentially cleaves peptide bonds at the carbonyl end of amino acid residues with small hydrophobic side chains such as glycine, valine, leucine, isoleucine and alanine. The wide specificity of elastases for non-aromatic uncharged side chains can explain its ability to break down native elastin.[11]

Use in diagnostic tests

Human pancreatic elastase 1 (E1) remains undegraded during intestinal transit. Therefore its concentration in feces reflects exocrine pancreatic function. During an inflammation of the pancreas, E1 is released into the bloodstream. Thus the quantification of pancreatic elastase 1 in serum allows diagnosis or exclusion of acute pancreatitis.[12]

Main indications:

Method of detection:

Reference concentration to interpret Pancreatic Elastase results: For adults and children after the first month of life

References

  1. 1 2 EntrezGene 1990
  2. Rose SD, MacDonald RJ (June 1997). "Evolutionary silencing of the human elastase I gene (ELA1)". Hum. Mol. Genet. 6 (6): 897–903. doi:10.1093/hmg/6.6.897. PMID 9175736.
  3. 1 2 3 4 Talas U, Dunlop J, Khalaf S, Leigh IM, Kelsell DP (January 2000). "Human elastase 1: evidence for expression in the skin and the identification of a frequent frameshift polymorphism". J. Invest. Dermatol. 114 (1): 165–70. doi:10.1046/j.1523-1747.2000.00825.x. PMID 10620133.
  4. Q9UNI1
  5. "Elastase". Worthington Enzyme Manual.
  6. Largman C, Brodrick JW, Geokas MC (1976). "Purification and characterization of two human pancreatic elastases". Biochemistry 15 (11): 2491–500. doi:10.1021/bi00656a036. PMID 819031.
  7. Akasaka E, Nakano H, Nakano A, Toyomaki Y, Takiyoshi N, Rokunohe D, Nishikawa Y, Korekawa A, Matsuzaki Y, Mitsuhashi Y, Sawamura D (2011). "Diffuse and focal palmoplantar keratoderma can be caused by a keratin 6c mutation". Br. J. Dermatol. 165 (6): 1290–2. doi:10.1111/j.1365-2133.2011.10552.x. PMID 21801157.
  8. Gertler A, Birk Y (1970). "Isolation and characterization of porcine proelastase". Eur. J. Biochem. 12 (1): 170–6. doi:10.1111/j.1432-1033.1970.tb00835.x. PMID 5461547.
  9. "CELA1 Gene". GeneCards.
  10. Davies RL, Yoon SJ, Weissenbach J, Ward D, Krauter K, Kucherlapati R (October 1995). "Physical mapping of the human ELA1 gene between D12S361 and D12S347 on chromosome 12q13". Genomics 29 (3): 766–8. doi:10.1006/geno.1995.9939. PMID 8575772.
  11. Shotton DM (1970). "Elastase". Methods in Enzymology 19: 113–140. doi:10.1016/0076-6879(70)19009-4.
  12. Stein J, Schoonbroodt D, Jung M, Lembcke B, Caspary WF (1996). "Mesure de l'élastase fécale par immunoréactivité: une nouvelle approche indirecte de la fonction pancréatique" [Measurement of fecal elastase 1 by immunoreactivity: A new indirect test of the pancreatic function]. Gastroentérologie Clinique et Biologique (in French) 20 (5): 424–9. PMID 8761139.
  13. Gonzales AC, Vieira SM, Maurer RL, Silva FA, Silveira TR (2011). "Use of monoclonal faecal elastase-1 concentration for pancreatic status assessment in cystic fibrosis patients". J Pediatr (Rio J) 87 (2): 157–62. doi:10.2223/JPED.2075. PMID 21503378.
  14. Löser C, Möllgaard A, Fölsch UR (October 1996). "Faecal elastase 1: a novel, highly sensitive, and specific tubeless pancreatic function test". Gut 39 (4): 580–6. doi:10.1136/gut.39.4.580. PMC 1383273. PMID 8944569.

External links

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