Alpha-1 antitrypsin explained

Alpha-1 antitrypsin or α1-antitrypsin (A1AT, α1AT, A1A, or AAT) is a protein belonging to the serpin superfamily. It is encoded in humans by the SERPINA1 gene. A protease inhibitor, it is also known as alpha1–proteinase inhibitor (A1PI) or alpha1-antiproteinase (A1AP) because it inhibits various proteases (not just trypsin).[1] In older biomedical literature it was sometimes called serum trypsin inhibitor (STI, dated terminology), because its capability as a trypsin inhibitor was a salient feature of its early study. As a type of enzyme inhibitor, it protects tissues from enzymes of inflammatory cells, especially neutrophil elastase, and has a reference range in blood of 0.9–2.3 g/L (in the US the reference range is expressed as mg/dL or micromoles), but the concentration can rise manyfold upon acute inflammation.[2]

When the blood contains inadequate amounts of A1AT or functionally defective A1AT (such as in alpha-1 antitrypsin deficiency), neutrophil elastase is excessively free to break down elastin, degrading the elasticity of the lungs, which results in respiratory complications, such as chronic obstructive pulmonary disease, in adults. Normally, A1AT leaves its site of origin, the liver, and joins the systemic circulation; defective A1AT can fail to do so, building up in the liver, which results in cirrhosis in either adults or children.

In addition to binding to neutrophil elastase released by inflammatory cells, A1AT also binds to elastase localized on the cell surface in which case elastase does not act as an enzyme, but instead acts to signal cells to undergo locomotion.[3] Besides liver cells, A1PI is produced in bone marrow, by lymphocytic and monocytic cells in lymphoid tissue, and by the Paneth cells of the gut.[4]

Inactivation of A1AT by enzymes other than elastase due to inflammation/infection causes the migration of T cells to halt precisely at the site where the pathologic insult exists. This suggests a role for α1PI not only in locomotion of lymphocytes through tissue, but as a consequence of infection, a primary role as a sentinel in immune vigilance.[5]

A1AT is both an endogenous protease inhibitor and an exogenous one used as medication. The pharmaceutical form is purified from human donor blood and is sold under the nonproprietary name alpha1–proteinase inhibitor (human) and under various trade names (including Aralast NP, Glassia, Prolastin, Prolastin-C, and Zemaira). Recombinant versions are also available but are currently used in medical research more than as medication.

Function

A1AT is a 52-kDa serpin and, in medicine, it is considered the most prominent serpin; the terms α1-antitrypsin and protease inhibitor (Pi) are often used interchangeably.

Most serpins inactivate enzymes by binding to them covalently. These enzymes are released locally in relatively low concentrations where they are immediately cleared by proteins such as A1AT. In the acute phase reaction, a further elevation is required to "limit" the damage caused by activated neutrophil granulocytes and their enzyme elastase, which breaks down the connective tissue fiber elastin.

Besides limiting elastase activity to limit tissue degradation, A1PI also acts to induce locomotion of lymphocytes through tissue including immature T cells through the thymus where immature T cells mature to become immunocompetent T cells that are released into tissue to elevate immune responsiveness.[6]

Like all serine protease inhibitors, A1AT has a characteristic secondary structure of beta sheets and alpha helices. Mutations in these areas can lead to non-functional proteins that can polymerise and accumulate in the liver (infantile hepatic cirrhosis).

Role in disease

See main article: Alpha-1 antitrypsin deficiency. Disorders of this protein include alpha-1 antitrypsin deficiency, an autosomal co-dominant hereditary disorder in which a deficiency of alpha-1 antitrypsin leads to a chronic uninhibited tissue breakdown. This causes the degradation especially of lung tissue and eventually leads to characteristic manifestations of pulmonary emphysema.[7] Evidence has shown[8] that cigarette smoke can result in oxidation of methionine 358 of α1-antitrypsin (382 in the pre-processed form containing the 24 amino acid signal peptide), a residue essential for binding elastase; this is thought to be one of the primary mechanisms by which cigarette smoking (or second-hand smoke) can lead to emphysema. Because A1AT is expressed in the liver, certain mutations in the gene encoding the protein can cause misfolding and impaired secretion, which can lead to liver cirrhosis.

An extremely rare form of Pi, termed PiPittsburgh, functions as an antithrombin (a related serpin), due to a mutation (Met358Arg). One person with this mutation has been reported to have died of a bleeding diathesis.[9]

A liver biopsy will show abundant PAS-positive globules within periportal hepatocytes.

Patients with rheumatoid arthritis (RA) have been found to make autoantibodies toward the carbamylated form of A1AT in the synovial fluid. This suggests that A1AT may play an anti-inflammatory or tissue-protecting role outside the lungs. These antibodies are associated with a more severe disease course, can be observed years before disease onset, and may predict the development of RA in arthralgia patients. Consequently, carbamylated A1AT is currently being developed as an antigenic biomarker for RA.[10]

Nomenclature

The protein was initially named "antitrypsin" because of its ability to bind and irreversibly inactivate the enzyme trypsin in vitro covalently. Trypsin, a type of peptidase, is a digestive enzyme active in the duodenum and elsewhere.

The term alpha-1 refers to the protein's behavior on protein electrophoresis. On electrophoresis, the protein component of the blood is separated by electric current. There are several clusters, the first being albumin, the second being the alpha, the third beta and the fourth gamma (immunoglobulins). The non-albumin proteins are referred to as globulins.

The alpha region can be further divided into two sub-regions, termed "1" and "2". Alpha-1 antitrypsin is the main protein of the alpha-globulin 1 region.

Another name used is alpha-1 proteinase inhibitor1-PI).

Genetics

The gene is located on the long arm of chromosome 14 (14q32.1).

Over 100 different variants of α1-antitrypsin have been described in various populations. North-Western Europeans are most at risk for carrying one of the most common mutant forms of A1AT, the Z mutation (Glu342Lys on M1A, rs28929474).[11]

Biochemical properties

A1AT is a single-chain glycoprotein consisting of 394 amino acids in the mature form and exhibits many glycoforms. The three N-linked glycosylations sites are mainly equipped with so-called diantennary N-glycans. However, one particular site shows a considerable amount of heterogeneity since tri- and even tetraantennary N-glycans can be attached to the Asparagine 107 (UniProtKB amino acid nomenclature). These glycans carry different amounts of negatively charged sialic acids; this causes the heterogeneity observed on normal A1AT when analysed by isoelectric focusing. Also, the fucosylated triantennary N-glycans were shown to have the fucose as part of a so-called Sialyl Lewis x epitope,[12] which could confer this protein particular protein-cell recognition properties. The single cysteine residue of A1AT in position 256 (UniProtKB nomenclature) is found to be covalently linked to a free single cysteine by a disulfide bridge.[12]

Analysis

The level of A1AT in serum is most often determined by adding an antibody that binds to A1AT, then using turbidimetry to measure how much A1AT is present. Other detection methods include the use of enzyme-linked-immuno-sorbent-assays and radial immunodiffusion.

Different analytical methods are used to determine A1AT phenotype. As protein electrophoresis is imprecise, the A1AT phenotype is analysed by isoelectric focusing (IEF) in the pH range 4.5-5.5, where the protein migrates in a gel according to its isoelectric point or charge in a pH gradient.

Normal A1AT is termed M, as it migrates toward the center of such an IEF gel. Other variants are less functional and are termed A-L and N-Z, dependent on whether they run proximal or distal to the M band. The presence of deviant bands on IEF can signify the presence of alpha-1 antitrypsin deficiency. Since the number of identified mutations has exceeded the number of letters in the alphabet, subscripts have been added to most recent discoveries in this area, as in the Pittsburgh mutation described above.

As every person has two copies of the A1AT gene, a heterozygote with two different copies of the gene may have two different bands showing on electrofocusing, although heterozygote with one null mutant that abolishes expression of the gene will only show one band.

In blood test results, the IEF results are notated as in PiMM, where Pi stands for protease inhibitor and "MM" is the banding pattern of that patient.

Alpha-1 antitrypsin levels in the blood depend on the genotype. Some mutant forms fail to fold properly and are, thus, targeted for destruction in the proteasome, whereas others have a tendency to polymerise, being retained in the endoplasmic reticulum. The serum levels of some of the common genotypes are:

Other rarer forms have been described; in all, there are over 80 variants.

Medical uses

Verifiedrevid:477318673
Tradename:Aralast, Zemaira, Glassia, others[13]
Dailymedid:Alpha 1 proteinase inhibitor
Routes Of Administration:Intravenous
Atc Prefix:B02
Atc Suffix:AB02
Legal Au:S4
Legal Au Comment:[14] [15] [16]
Legal Ca:Rx-only
Legal Ca Comment:/Schedule D[17] [18]
Legal Uk:POM
Legal Uk Comment:[19]
Legal Us:Rx-only
Legal Eu:Rx-only
Legal Status:Rx-only
Cas Number:9041-92-3
Drugbank:DB00058
Chemspiderid:none
Unii:F43I396OIS
Chembl:4297879
Pdb Ligand:KB2
Iupac Name:Alpha-1-proteinase inhibitor
C:2001
H:3130
N:514
O:601
S:10

Alpha-1 antitrypsin concentrates are prepared from the blood plasma of blood donors. The US Food and Drug Administration (FDA) has approved the use of four alpha-1 antitrypsin products derived from a human plasma: Prolastin, Zemaira, Glassia, and Aralast.[20] [21] [22] [23] [24] [25] These products for intravenous augmentation A1AT therapy can cost up to $100,000 per year per patient.[26] They are administered intravenously at a dose of 60 mg/kg once a week; higher doses do not provide additional benefit although they can be used in anticipation of an interruption of weekly administration, such as for a vacation.[27]

Alpha1-proteinase inhibitor (Respreeza) was approved for medical use in the European Union in August 2015.[28] It is indicated for maintenance treatment, to slow the progression of emphysema in adults with documented severe alpha1-proteinase inhibitor deficiency (e.g., genotypes PiZZ, PiZ (null), Pi (null, null), PiSZ). People are to be under optimal pharmacologic and non-pharmacologic treatment and show evidence of progressive lung disease (e.g. lower forced expiratory volume per second (FEV1) predicted, impaired walking capacity or increased number of exacerbations) as evaluated by a healthcare professional experienced in the treatment of alpha1-proteinase inhibitor deficiency.

The most common side effects include dizziness, headache, dyspnoea (shortness of breath) and nausea. Allergic reactions have been observed during treatment, some of which were severe.

Aerosolized-augmented A1AT therapy is under study. This involves inhaling purified human A1AT into the lungs and trapping the A1AT into the lower respiratory tract. However, inhaled A1AT may not reach the elastin fibers in the lung where elastase injury occurs. Further study is currently underway.[29] Recombinant alpha-1 antitrypsin is not yet available for use as a medication but is under development.[30]

History

Axelsson and Laurell first investigated the possibility of allelic variants of A1AT leading to disease in 1965.[31]

See also

Further reading

External links

Notes and References

  1. Gettins PG . Serpin structure, mechanism, and function . Chemical Reviews . 102 . 12 . 4751–804 . December 2002 . 12475206 . 10.1021/cr010170 .
  2. Book: A. . Mackiewicz . I. . Kushner . H. . Baumann . Acute phase response: an overview . Acute phase proteins: molecular biology, biochemistry, and clinical applications . CRC Press . 1993 . 1-000-14197-7 . 3–19 . 1164833220.
  3. Guttman O, Baranovski BM, Schuster R, Kaner Z, Freixo-Lima GS, Bahar N, Mizrahi MI, Brami I, Ochayon DE, Lewis EC . Acute-phase protein α1-anti-trypsin: diverting injurious innate and adaptive immune responses from non-authentic threats . Clinical & Experimental Immunology . 179 . 2 . 161–172 . February 2015 . 25351931 . 4298394 . 10.1111/cei.12476 .
  4. Winkler IG, Hendy J, Coughlin P, Horvath A, Lévesque JP . Serine protease inhibitors serpina1 and serpina3 are down-regulated in bone marrow during hematopoietic progenitor mobilization . The Journal of Experimental Medicine . 201 . 7 . 1077–88 . April 2005 . 15795238 . 2213124 . 10.1084/jem.20042299 .
  5. Richler R, Forssmann W, Henschler R . Current developments in mobilization of hematopoietic stem and progenitor cells and their interaction with nicehes in bone marrow . Transfus Med Hemother . 44 . 3 . 151–164 . June 2017 . 28626366 . 5473067 . 10.1159/000477262 .
  6. Lapidot T, Petit I . Current understanding of stem cell mobilization: the roles of chemokines, proteolytic enzymes, adhesion molecules, cytokines, and stromal cells . Exp Hematol . 30 . 9 . 973–981 . September 2012 . 12225788 . 10.1016/s0301-472x(02)00883-4 . free .
  7. DeMeo DL, Silverman EK . Alpha1-antitrypsin deficiency. 2: genetic aspects of alpha(1)-antitrypsin deficiency: phenotypes and genetic modifiers of emphysema risk . Thorax . 59 . 3 . 259–64 . March 2004 . 14985567 . 1746953 . 10.1136/thx.2003.006502 .
  8. Taggart C, Cervantes-Laurean D, Kim G, McElvaney NG, Wehr N, Moss J, Levine RL . Oxidation of either methionine 351 or methionine 358 in alpha 1-antitrypsin causes loss of anti-neutrophil elastase activity . The Journal of Biological Chemistry . 275 . 35 . 27258–65 . September 2000 . 10867014 . 10.1074/jbc.M004850200 . free .
  9. Owen MC, Brennan SO, Lewis JH, Carrell RW . Mutation of antitrypsin to antithrombin. alpha 1-antitrypsin Pittsburgh (358 Met leads to Arg), a fatal bleeding disorder . The New England Journal of Medicine . 309 . 12 . 694–8 . September 1983 . 6604220 . 10.1056/NEJM198309223091203 .
  10. Verheul MK, Yee A, Seaman A, Janssen GM, van Veelen PA, Drijfhout JW, Toes RE, Mahler M, Trouw LA . Identification of carbamylated alpha 1 anti-trypsin (A1AT) as an antigenic target of anti-CarP antibodies in patients with rheumatoid arthritis . Journal of Autoimmunity . 80 . 77–84 . June 2017 . 28291659 . 10.1016/j.jaut.2017.02.008 .
  11. Web site: NM_001127701.1(SERPINA1):c.1096G>A (p.Glu366Lys) . Interpretation: Pathogenic risk factor . ClinVar Genomic variation as it relates to human health . U.S. National Library of Medicine, National Insittues of Health . 13 October 2022 . 13 October 2022 . https://web.archive.org/web/20221013133622/https://www.ncbi.nlm.nih.gov/clinvar/variation/17967/?new_evidence=true . live .
  12. Kolarich D, Weber A, Turecek PL, Schwarz HP, Altmann F . Comprehensive glyco-proteomic analysis of human alpha1-antitrypsin and its charge isoforms . Proteomics . 6 . 11 . 3369–80 . June 2006 . 16622833 . 10.1002/pmic.200500751 . 25498702 .
  13. Web site: Alpha-1-Proteinase Inhibitor, Human . Drugs.com . 4 May 2020 . 11 May 2020 . 3 October 2020 . https://web.archive.org/web/20201003035210/https://www.drugs.com/international/alpha-1-proteinase-inhibitor-human.html . live .
  14. Web site: Prescription medicines: registration of new chemical entities in Australia, 2017 . Therapeutic Goods Administration (TGA) . 21 June 2022 . 9 April 2023 . 10 April 2023 . https://web.archive.org/web/20230410060848/https://www.tga.gov.au/resources/publication/publications/prescription-medicines-registration-new-chemical-entities-australia-2017 . live .
  15. Web site: Prescription medicines: registration of new chemical entities in Australia, 2016 . Therapeutic Goods Administration (TGA) . 21 June 2022 . 10 April 2023 . 10 April 2023 . https://web.archive.org/web/20230410065503/https://www.tga.gov.au/prescription-medicines-registration-new-chemical-entities-australia-2016 . live .
  16. Web site: Prescription medicines and biologicals: TGA annual summary 2017 . Therapeutic Goods Administration (TGA) . 21 June 2022 . 31 March 2024.
  17. Web site: Health product highlights 2021: Annexes of products approved in 2021 . . 3 August 2022 . 25 March 2024.
  18. Web site: Regulatory Decision Summary for Pronextica Liquid . Drug and Health Products Portal . 14 November 2023 . 1 April 2024.
  19. Web site: Respreeza - Summary of Product Characteristics (SmPC) . (emc) . 10 October 2018 . 11 May 2020 . 3 October 2020 . https://web.archive.org/web/20201003014150/https://www.medicines.org.uk/emc/product/7026/smpc . live .
  20. Web site: Aralast NP . U.S. Food and Drug Administration (FDA) . 22 July 2017 . 11 May 2020 . 10 August 2020 . https://web.archive.org/web/20200810223748/https://www.fda.gov/vaccines-blood-biologics/approved-blood-products/aralast-np . live .
  21. Web site: Aralast . U.S. Food and Drug Administration (FDA) . 22 July 2017 . 11 May 2020 . 4 August 2020 . https://web.archive.org/web/20200804001929/https://www.fda.gov/vaccines-blood-biologics/approved-blood-products/aralast . live .
  22. Web site: Glassia . U.S. Food and Drug Administration (FDA) . 22 July 2017 . 11 May 2020 . 1 April 2020 . https://web.archive.org/web/20200401234108/https://www.fda.gov/vaccines-blood-biologics/approved-blood-products/glassia . live .
  23. Web site: Prolastin . U.S. Food and Drug Administration (FDA) . 5 March 2018 . 11 May 2020 . 28 September 2020 . https://web.archive.org/web/20200928040339/https://www.fda.gov/vaccines-blood-biologics/approved-blood-products/prolastin . live .
  24. Web site: Prolastin-C . U.S. Food and Drug Administration (FDA) . 21 September 2017 . 11 May 2020 . 3 October 2020 . https://web.archive.org/web/20201003030712/https://www.fda.gov/vaccines-blood-biologics/approved-blood-products/prolastin-c . live .
  25. Web site: Zemaira . U.S. Food and Drug Administration (FDA) . 22 July 2017 . 11 May 2020 . 1 April 2020 . https://web.archive.org/web/20200401234137/https://www.fda.gov/vaccines-blood-biologics/approved-blood-products/zemaira . live .
  26. Alkins SA, O'Malley P . Should health-care systems pay for replacement therapy in patients with alpha(1)-antitrypsin deficiency? A critical review and cost-effectiveness analysis . Chest . 117 . 3 . 875–80 . March 2000 . 10713018 . 10.1378/chest.117.3.875 .
  27. Brantly ML, Lascano JE, Shahmohammadi A . Intravenous Alpha-1 Antitrypsin Therapy for Alpha-1 Antitrypsin Deficiency: The Current State of the Evidence . Chronic Obstructive Pulmonary Diseases . 6 . 1 . 100–114 . November 2018 . 30775428 . 6373587 . 10.15326/jcopdf.6.1.2017.0185 .
  28. Web site: Respreeza EPAR . European Medicines Agency (EMA) . 17 September 2018 . 11 May 2020 . 3 October 2020 . https://web.archive.org/web/20201003022345/https://www.ema.europa.eu/en/medicines/human/EPAR/respreeza . live .
  29. Usmani OS . Feasibility of Aerosolized Alpha-1 Antitrypsin as a Therapeutic Option . Chronic Obstr Pulm Dis . 7 . 3 . 272–9 . July 2020 . 32726075 . 7857706 . 10.15326/jcopdf.7.3.2019.0179 .
  30. Bianchera A, Alomari E, Michielon A, Bazzoli G, Ronda N, Pighini G, Zanotti I, Giorgio C, Mozzarelli A, Bettini R, Bruno S . Recombinant Alpha-1 Antitrypsin as Dry Powder for Pulmonary Administration: A Formulative Proof of Concept . Pharmaceutics . 14 . 12 . December 2022 . 2754 . 36559248 . 9784676 . 10.3390/pharmaceutics14122754 . free .
  31. Axelsson U, Laurell CB . Hereditary variants of serum alpha-1-antitrypsin . American Journal of Human Genetics . 17 . 6 . 466–72 . November 1965 . 4158556 . 1932630 .