Protein C - Synthesis, Structure and Activation

Synthesis, Structure and Activation

Human protein C is a vitamin K-dependent glycoprotein structurally similar to other vitamin K-dependent proteins affecting blood clotting, such as prothrombin, Factor VII, Factor IX and Factor X. Protein C synthesis occurs in the liver and begins with a single-chain precursor molecule: a 32 amino acid N-terminus signal peptide preceding a propeptide. Protein C is formed when a dipeptide of Lys198 and Arg199 is removed; this causes the transformation into a heterodimer with N-linked carbohydrates on each chain. The protein has one light chain (21 kDa) and one heavy chain (41 kDa) connected by a disulfide bond between Cys183 and Cys319.

Inactive protein C comprises 419 amino acids in multiple domains: one Gla domain (residues 43–88); a helical aromatic segment (89–96); two epidermal growth factor (EGF)-like domains (97–132 and 136–176); an activation peptide (200–211); and a trypsin-like serine protease domain (212–450). The light chain contains the Gla- and EGF-like domains and the aromatic segment. The heavy chain contains the protease domain and the activation petide. It is in this form that 85–90% of protein C circulates in the plasma as a zymogen, waiting to be activated. The remaining protein C zymogen comprises slightly modified forms of the protein. Activation of the enzyme occurs when a thrombin molecule cleaves away the activation peptide from the N-terminus of the heavy chain. The active site contains a catalytic triad typical of serine proteases (His253, Asp299 and Ser402).

The activation of protein C is strongly promoted by thrombomodulin and endothelial protein C receptor (EPCR), the latter of which is found primarily on endothelial cells (cells on the inside of blood vessels). The presence of thrombomodulin accelerates activation by several orders of magnitude, and EPCR speeds up activation by a factor of 20. If either of these two proteins is absent in murine specimens, the mouse dies from excessive blood-clotting while still in an embryonic state. On the endothelium, APC performs a major role in regulating blood clotting, inflammation, and cell death (apoptosis). Because of the accelerating effect of thrombomodulin on the activation of protein C, the protein may be said to be activated not by thrombin but the thrombin-thrombomodulin (or even thrombin-thrombomodulin-EPCR) complex. Once in active form, APC may or may not remain bound to EPCR, to which it has approximately the same affinity as the protein zymogen.

The Gla domain is particularly useful for binding to negatively charged phospholipids for anticoagulation and to EPCR for cytoprotection. One particular exosite augments protein C's ability to inactive Factor V_a efficiently. Another is necessary for interacting with thrombomodulin.

The biologic instructions for synthesising protein C in humans are encoded in the gene officially named "protein C (inactivator of coagulation factors Va and VIIIa)". The gene's symbol approved by the HUGO Gene Nomenclature Committee is "PROC" from "protein C". It is located on the second chromosome (2q13-q14) and comprises nine exons. The nucleotide sequence that codes for human protein C is approximately 11,000 bases long.

Protein C in zymogen form is present in normal adult human blood plasma at concentrations between 65–135 IU/dL. Activated protein C is found at levels approximately 2000 times lower than this. Mild protein C deficiency corresponds to plasma levels above 20 IU/dL, but below the normal range. Moderately severe deficiencies describe blood concentrations between 1 and 20 IU/dL; severe deficiencies yield levels of protein C that are below 1 IU/dL or are undetectable. Protein C levels in a healthy term infant average 40 IU/dL. The concentration of protein C increases until six months, when the mean level is 60 IU/dL; the level stays low through childhood until it reaches adult levels after adolescence. The half-life of activated protein C is around 15 minutes.