Alpha 1-antitrypsin deficiency pathophysiology

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: Mazia Fatima, MBBS [2]Cafer Zorkun, M.D., Ph.D. [3]

Overview

Pathophysiology

Genetics

  • Alpha1-antitrypsin deficiency (AATD) is inherited in an autosomally-codominant pattern caused by mutations in the SERPINA1 gene.
  • Normal blood levels of alpha-1 antitrypsin are 1.5-3.5 gm/l.
  • The alpha-1 AT gene is located on the long arm of chromosome 14 (gene locus:14q32.1). The SERPINA1 gene has six introns, seven axons and 12.2kb in length. There have been 120 different alleles for alpha-1 AT variants that have been described, but only 10-15 are associated with severe alpha-1 deficiency.
  • Each allele has been given a letter code based upon electrophoretic mobility that varies according to protein charge from amino acid alterations on gel electrophoresis that is used to identify the PI phenotype.
  • SERPINA1 gene mutation alters the configuration of the alpha1-antitrypsin molecule and prevents its release from hepatocytes. By far, the most common severe deficient variant is the Z allele, which is produced by substitution of a lysine for glutamate at position 342 of the molecule. This accounts for 95% of the clinically recognized cases of severe alpha-1 AT deficiency. The 75 alleles can basically be divided into four groups:
  • Normal – M alleles (normal phenotype is MM), found in 90% of the U.S. population, patients have normal lung function.
  • Deficient – Z allele (carried by 2-3% of the U.S. Caucasian population), have plasma levels of alpha-1 AT that is < 35% of normal.
  • Null – No detectable alpha-1 AT. Least common and most severe form of the disease.
  • Dysfunctional – Patients have a normal alpha-1 AT level, but the enzyme does not function properly.

In individuals with PiSS, PiMZ and PiSZ phenotypes, blood levels of A1AT are reduced to between 40 and 60 % of normal levels. This is sufficient to protect the lungs from the effects of elastase in people who do not smoke. However, in individuals with the PiZZ phenotype, A1AT levels are less than 15 % of normal, and patients are likely to develop emphysema at a young age; 50 % of these patients will develop liver cirrhosis, because the A1AT is not secreted properly and instead accumulates in the liver. A liver biopsy in such cases will reveal Periodic acid-Shiff (PAS)-positive, diastase-negative granules.


Differences in speed of migration of different protein variants on gel electrophoresis have been used to identify the PI phenotype, and these differences in migration relate to variations in protein charge resulting from amino acid alterations (Fig. 1).43 The M allele results in a protein with a medium rate of migration; the Z form of the protein has the slowest rate of migration. Some individuals inherit null alleles that result in protein levels that are not detectable. Individuals with a Z pattern on serum isoelectric focusing are referred to as phenotype PIZ (encompassing both PIZZ and PIZnull genotype variants). The S variant occurs at a frequency of 0.02–0.03 and is associated with mild reductions in serum AAT levels. The Z variant is associated with a severe reduction in serum AAT levels. The most common alleles are the M variants with allele frequencies of greater than 0.95 and normal AAT levels

Molecular Biology

  • Crystal structure of alpha1-antitrypsin enzyme is composed of three β sheets (A, B, C) and an exposed mobile reactive loop with a peptide sequence as a pseudosubstrate for the target proteinase enzyme. This loop consists of amino acids within this loop are the PI–PI′ residues, methionine serine, as these are binding sites for neutrophil elastase.
  • The Alpha-1 antitrypsin deficiency molecule is an acute phase glycoprotein.
  • Alpha-1 AT is the protease inhibitor in highest concentration in human plasma.Its functions include inhibition of trypsin and neutrophil elastase. Alpha-1 antitrypsin is a part of serpin class of serine protease inhibitors characterized by their unique ability to undergo a conformational change. Other members of the serpin class of protease inhibitors include antithrombin, C1-inhibitor, and the many inhibitors of plasminogen. An advantage of this molecular mobility is that it enables the inhibitor to trap its target protease form a complex that can remain stable for hours. A potential disadvantage, however, is that it makes the serpins more than usually vulnerable to dysfunctional mutations.

Associated Conditions

α1-antitrypsin deficiency has been associated with a number of diseases:

Gross Pathology

Microscopic Pathology

References


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