AUTHOR AND EDITOR INFORMATION

Section 1 of 10  

• Authors and Editors
• Introduction
• Clinical
• Differentials
• Workup
• Treatment
• Medication
• Follow-up
• Miscellaneous
• References

INTRODUCTION

Section 2 of 10  

• Authors and Editors
• Introduction
• Clinical
• Differentials
• Workup
• Treatment
• Medication
• Follow-up
• Miscellaneous
• References

Background

Clotting factor II, or prothrombin, is a vitamin K–dependent proenzyme that functions in the blood coagulation cascade. Factor II deficiency is a rare, inherited or acquired bleeding disorder. In 1947, Quick and colleagues were the first to describe a deficiency of factor II; in 1969, Shapiro and colleagues were the first to report a structural prothrombin abnormality.

Inherited factor II deficiency is an autosomal recessive disorder that can manifest as hypoprothrombinemia; a decrease in the overall synthesis of prothrombin; or dysprothrombinemia, the synthesis of dysfunctional prothrombin (Baudo, 1972; Girolami, 1998). Homozygous individuals are generally asymptomatic and have functional prothrombin levels of 2-25%. However, symptomatic individuals may experience easy bruising, epistaxis, soft tissue hemorrhage, excessive postoperative bleeding, and/or menorrhagia.

In true hypoprothrombinemia, immunologic assays correlate well with functional assays in that both reveal low prothrombin values. Heterozygous patients are generally asymptomatic and have prothrombin levels of 50% or greater on both immunologic and functional assay.

In dysprothrombinemia, only the functional assay for prothrombin returns significantly reduced values, while the immunologic assay reveals normal values. Acquired factor II deficiency can be caused by severe liver disease, vitamin K deficiency, anticoagulant drugs (eg, warfarin), or the presence of an antibody directed against the protein (Bajaj, 1985).

The gene encoding prothrombin is primarily expressed in the liver (Royle, 1987) and is located on chromosome 11 in the region of the centromere (Degen, 1992). It is composed of 14 exons and contains 24 kilobases of DNA (Degen, 1992). The gene encodes a signal region, a propeptide region, a glutamic acid domain, 2 kringle regions, and a catalytic domain (Degen, 1992). The enzyme gamma-glutamyl carboxylase, in the presence of vitamin K, converts the N-terminal glutamic acid residues to gamma-carboxyglutamic acid residues. These gamma-carboxyglutamic acid residues are necessary for the binding of prothrombin to phospholipids on platelet membranes.

Since measurable prothrombin is present in all individuals with hypoprothrombinemia or dysprothrombinemia, authorities believe that complete absence of prothrombin is incompatible with postnatal life. Studies of transgenic mice with a complete deficiency of prothrombin reveal embryonic lethality and neonatal death (Sun, 1998; Sun, 2002).

Aside from the prothrombin deficiencies, another disorder of prothrombin is the prothrombin 20210a mutation. First reported in 1996 as a familial cause of venous thromboembolism, the prothrombin 20210a mutation results in increased levels of plasma prothrombin and a concurrent increased risk for the development of thrombosis (Poort, 1996). While the exact mechanism of this disorder has not been elucidated, the prothrombin 20210a mutation involves the substitution of an adenine for a guanine at position 20210 within the 3' untranslated region of the prothrombin gene (Pollak, 2002). This mutation alters the polyadenylation site of the gene and results in increased mRNA synthesis with a subsequent increase in protein expression (Ceelie, 2004).

Prothrombin 20210a has an estimated prevalence of 2% in whites (Rosendaal, 1998; Atasay, 2003). The mutation is more prevalent in those of southern European descent than in those of northern European descent and is rarely seen in Asians or Africans (Rosendaal, 1998). A recent study of patients in Turkey revealed the presence of the prothrombin 20210a mutation in 0.7% of subjects (Irdem, 2005). Individuals carrying the mutation have a 2- to 3-fold increased risk for developing thrombosis (Poort, 1996; Margaglione, 1998). One case-control study found evidence of an increased risk of developing an ischemic cerebrovascular event in men aged younger than 60 years with the prothrombin 20210a mutation (Lalouschek, 2005). A study of cancer patients in the Netherlands found that the presence of the prothrombin 20210a mutation in these patients may increase the risk of venous thrombosis to a level greater than that attributable to the malignancy alone (Blom, 2005). The mutation can be identified with DNA analysisand should be considered in any patient experiencing a thrombotic event without other risk factors. Treatment with oral anticoagulants is useful in preventing recurrence in patients with the mutation who have already experienced a thrombotic event.

Additionally, women who are known to carry the mutation may want to avoid oral contraceptives because of the additional risk of thrombosis.

Pathophysiology

In the blood coagulation cascade, prothrombin is cleaved by factor Xa to form thrombin, an active serine protease (Narayanan, 1999). This proteolytic reaction occurs on the phospholipid surfaces of platelets and requires calcium. Thrombin is responsible for inducing platelet aggregation and activating several other mediators in the coagulation cascade. It converts fibrinogen to fibrin, which then polymerizes to form a clot around platelet aggregates. Thrombin also converts factor XIII to factor XIIIa, an enzyme that cross-links and stabilizes fibrin polymers. The prothrombotic effects of thrombin are ultimately suppressed by the binding of thrombin to thrombomodulin on endothelial cell surfaces to form a complex that activates protein C. Protein C then degrades factors Va and VIIIa to inhibit the coagulation cascade.

Thrombin also has cytokine and growth-factor functions, inducing mitosis and chemotaxis in cell lines, including smooth muscle, fibroblasts, endothelial cells, and mononuclear phagocytes (Zhou, 1998). Decreased levels or a dysfunctional structure of factor II can lead to absent or defective clot formation and dysfunctional platelet aggregation.

Several specific missense mutations of the prothrombin gene have been documented (Akhavan, 2000; Sun, 1999; Wang, 2004; Jayandharan, 2005). These single amino acid substitutions can cause hypoprothrombinemia and/or dysprothrombinemia. A family in San Antonio, Tex, was found to have normal antigenic levels of prothrombin but half the normal levels of prothrombin activity (Sun, 1999). A single guanine-to-adenine mutation was found, which resulted in the substitution of His for Arg at residue 320. The arginine 320–to–isoleucine 321 bond is 1 of 2 sites in prothrombin cleaved by factor Xa to form thrombin. Substitution of histidine for arginine at this site resulted in the blockage of factor Xa cleavage, forming a dysfunctional molecule and resulting in dysprothrombinemia.

Two members of a family from Venezuela were found to have undetectable antigen levels and prothrombin activity levels at 4% of normal (Sun, 2001). A mutation was identified that had resulted in the substitution of cystine for tyrosine at residue 44. Substitution of a cystine at residue 44, located in the aromatic stack region of the protein, would result in an abnormal folding of the protein and could be the cause for the observed lack of secretion of prothrombin. Other mutations, affecting various regions of the gene, have also been described.

Acquired factor II deficiency has several possible etiologies. Because prothrombin is synthesized almost exclusively in the liver, severe liver disease can have a dramatic impact on prothrombin levels. Vitamin K deficiency can also result in decreased prothrombin levels. Vitamin K is produced in the gut by enteric flora, and levels can be affected by intestinal malabsorption, bile duct obstruction, or antibiotic administration (Bhat, 2003). Vitamin K deficiency can be iatrogenically induced by the administration of propylthiouracil or vitamin K antagonists such as warfarin. Vitamin K deficiency can also be seen in neonates. Finally, acquired factor II deficiency can sometimes be observed in patients with lupus anticoagulant (Baudo, 1990). These patients can develop specific prothrombin autoantibodies that form a complex with prothrombin and cause excessive clearance of prothrombin from the body (Cote, 1997; Vivaldi, 1997).

Frequency

United States

Both congenital and acquired factor II deficiencies are rare.

International

Only 30 cases of congenital factor II deficiency have been documented worldwide (Degen, 1995).

Mortality/Morbidity

Congenital factor II deficiency is a lifelong bleeding disorder. Death can result because of massive hemorrhage from relatively minor accidents or trauma. Hemorrhage can also occur as a result of surgery if precautions are not taken. Intracranial bleeding is another serious sequela of this disorder. Rarely, hemarthroses can occur (Baudo, 1972).

Race

This disorder has no known racial or ethnic predilection.

Sex

Males and females are affected equally.

Age

Patients with severe congenital factor II deficiency present early in life, whereas those with less severe forms can present at any age. Acquired forms can be observed in all age groups.

CLINICAL

Section 3 of 10  

• Authors and Editors
• Introduction
• Clinical
• Differentials
• Workup
• Treatment
• Medication
• Follow-up
• Miscellaneous
• References

History

Patients with a factor II deficiency may report a family history of bleeding disorders. They may also report a history of the following symptoms:

• Umbilical cord stump bleeding at birth
• Prolonged bleeding following circumcision
• Postpartum hemorrhage
• Easy bruising
• Bleeding gums
• Epistaxis
• Menorrhagia
• Prolonged postsurgical bleeding
• Melena
• Hematuria
• Hemarthroses
• Soft tissue hemorrhages
• Intracranial bleeding

Physical

• The physical examination of a patient with factor II deficiency may reveal petechiae and/or ecchymoses, which commonly develop in areas of minor trauma. Ambulatory patients may have petechiae or ecchymoses in the ankle area, while bedridden patients may have them on the back. Petechiae may develop following blood pressure measurements in the area beneath the cuff. Additionally, patients may ooze from venipuncture sites. Patients with active hemorrhage may also be seen in emergency departments.
• In the case of acquired factor II deficiency, physical examination may reveal signs of underlying liver disease or gastrointestinal malabsorption.

Causes

• Inherited factor II deficiency is an autosomal recessive disorder.
• The most common causes of acquired factor II deficiency include severe liver disease, vitamin K deficiency, or vitamin K antagonist administration (eg, warfarin).

DIFFERENTIALS

Section 4 of 10  

• Authors and Editors
• Introduction
• Clinical
• Differentials
• Workup
• Treatment
• Medication
• Follow-up
• Miscellaneous
• References

Other Problems to be Considered

Pseudoxanthoma elasticum
von Willebrand disease
Schwartzman phenomenon
Ehlers-Danlos syndrome
Waterhouse-Friderichsen syndrome
Henoch-Schönlein purpura
Corticosteroid administration
Aspirin administration
Actinic purpura
Gardner-Diamond syndrome (autoerythrocyte sensitization syndrome)

WORKUP

Section 5 of 10  

• Authors and Editors
• Introduction
• Clinical
• Differentials
• Workup
• Treatment
• Medication
• Follow-up
• Miscellaneous
• References

Lab Studies

• Prothrombin time (PT) is prolonged in patients with factor II deficiency.
• Activated partial thromboplastin time (aPTT) is prolonged in patients with factor II deficiency.
• Bleeding time is within reference ranges in patients with factor II deficiency.
• Functional and antigenic factor II levels
• • Functional and antigenic levels are decreased in hypoprothrombinemia.
  • In dysprothrombinemia, functional levels are decreased; antigenic levels are within reference ranges to slightly decreased.
• Assays for other clotting factors
• • In isolated factor II deficiency, assays of other clotting factors should reveal normal levels.
  • In factor II deficiency due to liver disease, vitamin K deficiency, or vitamin K antagonist use, assays of other clotting factors reveal a decrease in the level of all vitamin K–dependent factors (ie, factor II, factor VII, factor IX, factor X, protein C).

TREATMENT

Section 6 of 10  

• Authors and Editors
• Introduction
• Clinical
• Differentials
• Workup
• Treatment
• Medication
• Follow-up
• Miscellaneous
• References

Medical Care

Treatment of factor II deficiency should be individualized and aimed at restoring circulating factor II to levels sufficient for hemostasis. Levels greater than 30% of normal are usually adequate. Additionally, in patients with acquired factor II deficiency, the underlying cause should be found and treated.

• Infusion of fresh frozen plasma (FFP) is usually sufficient to treat most cases of bleeding. A loading dose of 15-20 mL/kg IV is administered, followed by a maintenance dose of 3-6 mL/kg IV q12-24h.
• Plasma exchange transfusion may be used to increase factor II levels before surgery.
• Prothrombin complex concentrates (PCC) have also been used to increase factor II levels (Lechler, 1999). PCC contains factors II, VII, IX, and X, along with protein C. PCC should be used judiciously because of the risk of thromboembolic complications.
• Vitamin K administration may be useful in patients with acquired factor II deficiency.

Consultations

• Hematologists
• Genetic counselors (in patients with congenital factor II deficiency)

Diet

No dietary restrictions are necessary. Patients should be advised to decrease consumption of alcohol to reduce the risk of alcohol-induced liver disease.

Activity

Activity should be regulated based on the severity of the deficiency and the presence or absence of symptoms. Because of the risk of hemorrhage following traumatic injury, activities with high levels of physical contact are not recommended.

MEDICATION

Section 7 of 10  

• Authors and Editors
• Introduction
• Clinical
• Differentials
• Workup
• Treatment
• Medication
• Follow-up
• Miscellaneous
• References

The goals of pharmacotherapy are to reduce morbidity and to prevent complications.

Drug Category: Blood products

Are indicated for the correction of abnormal hemostatic parameters.

Drug Category: Vitamins, fat-soluble

Agents in this class may play essential role in the function of clotting factors.

FOLLOW-UP

Section 8 of 10  

• Authors and Editors
• Introduction
• Clinical
• Differentials
• Workup
• Treatment
• Medication
• Follow-up
• Miscellaneous
• References

Prognosis

• The prognosis of a patient with factor II deficiency depends on the etiology and severity of his or her disease. While acquired factor II deficiency may be eliminated if the underlying cause is treated, the congenital form of the disease is lifelong. Although specific levels of factor II and severity of symptoms are poorly correlated, patients with very low levels of functional factor II have a greater tendency to hemorrhage and thus face a greater risk of life-threatening complications.

Patient Education

• For excellent patient education resources, visit eMedicine's Blood and Lymphatic System Center.

MISCELLANEOUS

Section 9 of 10  

• Authors and Editors
• Introduction
• Clinical
• Differentials
• Workup
• Treatment
• Medication
• Follow-up
• Miscellaneous
• References

Medical/Legal Pitfalls

• Misdiagnosis of the type of factor disorder
• Failure to diagnose the presence of factor inhibitors
• Failure to recognize an underlying disease process

REFERENCES

Section 10 of 10

• Authors and Editors
• Introduction
• Clinical
• Differentials
• Workup
• Treatment
• Medication
• Follow-up
• Miscellaneous
• References

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Article Last Updated: Feb 15, 2006