Dysfibrinogenemia

Fibrinogen is a glycoprotein made and secreted into the blood primarily by liver hepatocyte cells. Endothelium cells also make what appears to be small amounts of fibrinogen but this fibrinogen has not been fully characterized; blood platelets and their precursors, bone marrow megakaryocytes, although once thought to make fibrinogen, are now known to take up and store but not make the glycoprotein. The final secreted, hepatocyte-derived glycoprotein is made of two trimers each of which is composed of three polypeptide chains, Aα (also termed α) encoded by the FGA gene, Bβ (also termed β) encoded by the FGB gene, and γ encoded by the FGG gene. All three genes are located on the long (i.e. "p") arm of human chromosome 4 (at positions 4q31.3, 4q31.3, and 4q32.1, respectively) and may contain mutations that are the cause of congenital dysfibrinogenemia. The heximer is assembled as a protein in the endoplasmic reticulum of hepatocytes and then transferred to the Golgi where Polysaccharides (i.e. complex sugars) and sialic acid are added by respective glycosylation and sialylation enzyme pathways thereby converting the heximer to a functional fibrinogen glycoprotein. The final circulating glycoprotein (notated as (AαBβγ)2, (αβγ)2, Aα2Bβ2γ2, or α2β2γ2) is arranged as a long flexible rod with nodules at both ends termed D domains and central nodule termed the E domain. The normal process of blood clot formation involves the coordinated operation of two separate pathways that feed into a final common pathway: 1) primary hemostasis, i.e. the adhesion, activation, and aggregation of circulating blood platelets at sites of vascular injury and 2) secondary hemostasis, i.e. cleavage of the Aα and Bβ chains of fibrinogen by thrombin to form individual fibrin strands plus the respective fibrinopeptides A and B formed from this cleavage. In the final common pathway fibrin is cross-linked by activated clotting factor XIII (termed factor XIIIa) to form mature gel-like fibrin clots. Subsequent fibrinolysis pathways act to limit clot formation and dissolve clots no longer needed. Fibrinogen and its Aα fibrin chain have several functions in this process: • Blood clotting: fibrinogen concentration is the rate-limiting factor in blood clot formation and along with blood platelets is critical to this formation (see Coagulation). • Platelet aggregation: fibrinogen promotes platelet aggregation by cross-linking platelet Glycoprotein IIb/IIIa receptors and thereby promotes blood clot formation through the primary hemostasis pathway. • Blood clot lysis: The Aα fibrin chain formed from fibrinogen binds tissue plasminogen activator, an agent that breaks down blood clots to participate thereby in promoting fibrinolysis. Based on these fibrinogen functions, a fibrinogen mutation may act either to inhibit or promote blood clot formation and/or lysis to thereby produce in individuals a diathesis to develop pathological bleeding, thrombosis, or both conditions. == Congenital dysfibrinogenemia ==

Presentation Many cases of congenital dysfibrinogenemia are asymptomatic. Since manifestations of the disorder generally occur in early adulthood or middle-age, younger individuals with a gene mutation causing it may not have had time to develop symptoms while previously asymptomatic individuals of advanced age with such a mutation are unlikely to develop symptoms. Bleeding episodes in most cases of this disorder are mild and commonly involve easy bruising and menorrhagia. Less common manifestations of bleeding may be severe or even life-threatening; these include excessive bleeding after tooth extraction, surgery, vaginal birth, and miscarriage. Rarely, these individuals may suffer hemarthrosis or cerebral hemorrhage. In one study of 37 individuals >50 years old afflicted with this disorder, 19% had a history of thrombosis. Thrombotic complications occur in both arteries and veins and include transient ischemic attack, ischemic stroke, myocardial infarction, retinal artery thrombosis, peripheral artery thrombosis, and deep vein thrombosis. In one series of 33 individuals with a history of thrombosis due to congenital dysfibrinogenemia, five developed chronic pulmonary hypertension due to ongoing pulmonary embolism probably stemming form deep vein thrombosis. About 26% of individuals with the disorder suffer both bleeding and thrombosis complications. Diagnosis The diagnosis of congenital dysfibrinogenmia is made by clinical laboratory studies that find normal levels of plasma fibrinogen but significant excess in the amount of immunologically detected compared to functionally detected (i.e. able to be clotted) fibrinogen. The ratio of functionally-detected to immunologically detected fibrinogen masses in these cases is 1 gram/liter. Tranexamic acid or fibrinogen concentrates are recommended for prophylactic treatment prior to minor surgery while fibrinogen concentrates are recommended prior to major surgery with fibrinogen concentrates usage seeking to maintain fibrinogen activity levels at >1 gram/liter. Women undergoing vaginal or Cesarean child birth should be treated at a hemophilia center with fibrinogen concentrates to maintain fibrinogen activity levels at 1.5 gram/liter. The latter individuals require careful observation for bleeding during their post-partum periods. Individuals experiencing episodic thrombosis as a result of congenital dysfibrinogenemia should also be treated at a center specialized in treating hemophilia using antithrombotic agents. They should be instructed on antithrombotic behavioral methods fur use in high risk situations such as long car rides and air flights. Venous thrombosis should be treated with low molecular weight heparin for a period that depends on personal and family history of thrombosis events. Prophylactic treatment prior to minor surgery should avoid fibrinogen supplementation and use prophylactic anticoagulation measures; prior to major surgery, fibrinogen supplementation should be used only if serious bleeding occurs; otherwise, prophylactic anticoagulation measures are recommended. == Hereditary fibrinogen Aα-Chain amyloidosis ==

Presentation Individuals with hereditary fibrinogen Aα-chain amyloidosis present with evidence ranging from asymptomatic proteinuria to progressive renal impairment and end-stage kidney disease. They do not evidence pathological bleeding or thrombosis and their amyloidosis is non-systemic in that it is restricted to the kidney. In a report on 474 patients with renal amyloidosis, hereditary fibrinogen Aα chain disease represented only 1.3% of all cases whereas aberrant immunoglobulin-induced renal amyloidosis (e.g. AL amyloidosis) represented 86% of the cases). The disorder is due to autosomal dominant inheritance of Aα chain mutations the most common of which is hemoglobin Indianapolis, a heterozygous missense (c.1718G>T: Arg554Leu) mutation. Other missense mutations causing this disorder are unnamed; they include 1634A>T: Glu526Val; c.1670C>A: Thr538lys; c.1676A.T:Glu540Val; and c1712C>A:Pro552His. A deletion mutation causing a frameshift viz., c.1622delT: Thr525Leu, is also a cause of the disorder. The fibrinogen bearing these mutant Aα-chains is secreted into the circulation and gradually accumulates in, and causes significant injury to, the kidney. The mutant fibrinogen does not appear to accumulate in, or injure, extra-renal tissues. Diagnosis The diagnosis of this disorder depends on demonstrating: 1) a dysfunctional plasma fibrinogen, i.e. significantly less functionally-detected compared to immunologically-detected fibrinogen; b) presence of signs and/or symptoms of kidney disease; and c) histological evidence of often massive obliteration of renal glomeruli by amyloid as detected by Congo red staining. There also should be no evidence for systemic amyloidosis. Specialized centers use immunological and genetic studies to define the nature of the renal amyloid deposits, the presence of FGA gene mutations, and the occurrence of these mutations in family members. The disorder exhibits a highly variable penetrance among family members. Hereditary fibrinogen Aα-Chain amyloidosis shows variable penetrance among family members, a distinctive histological appearance, proteinuria, progressive renal impairment, and markedly better survival rates than other forms of systemic renal amyloidosis. Treatment Treatment of hereditary fibrinogen Aα-Chain amyloidosis has relied on chronic maintenance hemodialysis and, where possible, kidney transplantation. While recurrence of amyloidosis in the transplanted kidney occurs and is to be expected, transplant survival rates for this form of amyloidosis are significantly better than those for transplants in other forms of systemic renal amyloidosis. Relatively healthy individuals with hereditary fibrinogen Aα-Chain-related renal amyloidosis may be considered for kidney and liver bi-transplantation with the expectation that survival of the transplanted kidney will be prolonged by replacing the fibrinogen Aα-Chain-producing liver with a non-diseased donor liver. == Acquired dysfibrinogenemia ==

Presentation Acquired dysfibrinogenemia commonly present with signs, symptoms, and/or prior diagnoses of the underlying causative disease or drug intake in an individual with an otherwise unexplained bleeding tendency or episode. Bleeding appears to be more prominent in acquired compared to congenital dysfibrinogenemia; pathological thrombosis, while potentially occurring in these individuals as a complication of their underlying disease, is an uncommon feature of the acquired disorder. The following Table gives some abnormalities, causes, and apparent pathophysiology along with some comments on examples of acquired dysfibrinogenemia. ==References==