Literature DB >> 26709270

Genetic Confirmation of Congenital Factor V Deficiency in Korean Patients.

Chang-Hun Park1, Kiyoung Yoo2, Ki-O Lee3, Sun-Hee Kim1, Ki-Woong Sung4, Hee-Jin Kim5.   

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Year:  2016        PMID: 26709270      PMCID: PMC4713856          DOI: 10.3343/alm.2016.36.2.182

Source DB:  PubMed          Journal:  Ann Lab Med        ISSN: 2234-3806            Impact factor:   3.464


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Dear Editor, Deficiencies of coagulation factors such as fibrinogen and factors II, V, V + VIII, VII, X, XI, and XIII are called rare bleeding disorders (RBDs). Congenital factor V (FV) deficiency is caused by mutations in F5, which is located on chromosome 1q24, and accounts for about 8% of all RBDs. FV is important for modulating thrombin production. Organization of FV is highly homologous to that of factor VIII. Clinical manifestations of FV deficiency (FVD) are diverse, ranging from life threatening to asymptomatic, even among patients with severe deficiency. FVD is suspected by prolonged prothrombin time (PT) and activated partial thromboplastin time (aPTT) that are corrected on mixing tests and is diagnosed by a significantly decreased FV activity. We described genetically confirmed FVD cases in two unrelated Korean families and reviewed previous cases of FVD in Korea. Proband 1 was a 14-yr-old girl with a history of hematuria and menorrhagia. She had prolonged PT/aPTT and decreased FV activity of 41% (Table 1). Her asymptomatic mother had prolonged PT/aPTT and FV activity of 44%. Her father yielded normal results for coagulation tests. Proband 2 was a 51-yr-old woman with easy bruisability. She had prolonged PT/aPTT and FV activity of 3%. Her daughter had normal PT/aPTT and FV activity of 39%. The daughter reported pain in the left hip, which was suspected to be caused by a hematoma according to ultrasound examination. Both probands yielded normal results for other coagulation factors. Genomic DNA was extracted from the peripheral blood of probands and family members after obtaining their written informed consent. Direct sequencing of F5 identified causative mutations in both probands. Proband 1 was heterozygous for missense mutation c.286G>C (p.Asp96His; Fig. 1). Proband 2 was compound heterozygous for in-frame deletion c.6027_6032delGAACAG (p.Asn2010_Ser2011del) and missense mutation c.6604C>T (p.Arg2202Cys; Fig. 1). A review of the literature and databases showed that the above three F5 mutations had been reported previously [1234]. The mother of proband 1 was heterozygous for Asp96His, and the daughter of proband 2 was heterozygous for Asn2010_Ser2011del (Table 1).
Table 1

Clinical features and laboratory findings of patients with congenital factor V deficiency in Korea

CaseRelationshipAge/SexBleeding episodesBleeding severityPT (sec) (N/I)aPTT (sec) (N/I)FV activity (%)MutationsReference
1Proband14/FHematuria, menorrhagiaGrade II15.4 (I)48.1 (I)41p.(Asp96His)Present study
 1-1Mother40/FAsymptomatic14.1 (N)37.9 (N)44p.(Asp96His)Present study
2Proband51/FEasy bruisabilityGrade II40.9 (I)106.0 (I)3p.[(Asn2010_Ser2011del)];[(Arg2202Cys)]Present study
 2-1Daughter21/FSuspected hematomaGrade III12.6 (N)35.0 (N)39p.(Asn2010_Ser2011del)Present study
3Proband9/MHemarthrosisGrade III36.0 (I)110.0 (I)6Not tested1987 [7]
4Proband25/MProlonged bleeding after tooth extractionGrade I35.7 (I)111.7 (I)4p.[(Arg1161*)];[(Asn2010_Ser2011del)]2009 [3]
 4-1Twin brother25/MProlonged bleeding after tooth extractionGrade I33.1 (I)103.2 (I)5p.[(Arg1161*)];[(Asn2010_Ser2011del)]2009 [3]
 4-2Sister 1?/FAsymptomatic14.9 (N)42.5 (N)45p.(Arg1161*)2009 [3]
 4-3Sister 2?/FAsymptomatic15.1 (I)46.6 (I)50p.(Asn2010_Ser2011del)2009 [3]

Abbreviations: PT, prothrombin time; aPTT, activated partial thromboplastin time; N, within normal range; I, increased time than reference range; FV, factor V.

Fig. 1

(A) Molecular analyses of F5 in two unrelated Koreans patients with congenital FV deficiency. Proband 1 and her mother were heterozygous for c.286G>C (p.Asp96His) (upper panel). Proband 2 was compound heterozygous for c.6027_6032del GAACAG (p.Asn2010_Ser2011del) and c.6604C>T (p.Arg2202Cys), and her daughter was heterozygous for c.6027_6032 delGAACAG (p.Asn2010_Ser2011del) (lower panel). The arrows indicate the mutations.(B) Comparative genomic analyses by using the CLUSTAL W algorithm showed that the Arg2202 residue, which corresponds to the Arg2326 residue of factor VIII, is highly conserved across mammalian species (indicated by an arrow).

At present, more than 100 mutations have been identified in F5 (Human Gene Mutation Database professional version, release 2015.1; last access, April 13, 2015), of which 50% are missense mutations [5]. Most missense mutations in F5 are clustered in A and C2 domains. Asp96His and Arg2202Cys in the present study are located in A1 and C2 domains, respectively. Asp96His (Asp68His in the mature protein) was previously described in four unrelated Chinese patients with FVD and was caused by the disruption of salt bridge and subsequent interference in protein expression [12]. Arg2202Cys was reported in a Chinese patient [2]. Arg2202 residue of FV was highly conserved across mammalian species (Fig. 1B). Although Arg2202Cys was predicted to be mutational, it was not detected in 100 control chromosomes of Korean descent. Asn2010_Ser2011 are located in a loop on the surface of C1 domain and are in close contact with another loop of A3 domain, and Asn2010_Ser2011del was reported in a Korean patient [3]. Asn2010_Ser2011del destabilizes C1-A3 interaction, thus affecting the folding, stability, and secretion of FV [3]. Thus, detection of these F5 mutations in Asian patients suggests shared genetic backgrounds among Asian ethnicities [1234]. The 2013 Annual Report of Korea Hemophilia Foundation indicated that RBDs, including FVD (0.2%), represented about 4% of all bleeding disorders in Korea [6]. Except the previous cases reported by Song et al., [3] a literature review revealed that previous Korean case of FVD lacked genetic information (Table 1) [7]. The European Network of Rare Bleeding Disorders recently established categories of bleeding severity, ranging from asymptomatic to grades I, II, and III [8]. The association between clinical severity and coagulation factor activities has been variably reported in RBDs, with a poor association for FVD [9]. A recent study explained this poor association by highlighting the important role of FV in platelet compartments [10]. In this study, proband 1 showed grade II, while her mother was asymptomatic, despite showing similar FV activity from the same mutation (intrafamilial variability). Proband 2 showed grade II, with 3% FV activity from biallelic mutations, while her daughter was suspected of having grade III, with 39% FV activity from a monoallelic mutation. In contrast, a family member of a previously reported patient who had the same genotype as the daughter of the proband 2 was asymptomatic. This underscores the importance of careful analysis of genotype-phenotype correlations in patients with FVD.
  9 in total

Review 1.  Rare bleeding disorders - bleeding assessment tools, laboratory aspects and phenotype and therapy of FXI deficiency.

Authors:  P James; O Salomon; D Mikovic; F Peyvandi
Journal:  Haemophilia       Date:  2014-05       Impact factor: 4.287

2.  Asp68His mutation in the A1 domain of human factor V causes impaired secretion and ineffective translocation.

Authors:  H C Liu; M C Shen; H L Eng; C H Wang; T M Lin
Journal:  Haemophilia       Date:  2014-06-03       Impact factor: 4.287

3.  [Analysis of phenotype and genotype in four Chinese pedigrees with inherited coagulation factor V deficiency.].

Authors:  Dan-Dan Huang; Xue-Feng Wang; Hua-Yun Chen; Guan-Qun Xu; Li-Wei Zhang; Jin Dai; Ye-Ling Lu; Qiu-Lan Ding; Xiao-Dong Xi; Hong-Li Wang
Journal:  Zhonghua Xue Ye Xue Za Zhi       Date:  2010-03

4.  Coagulation factor activity and clinical bleeding severity in rare bleeding disorders: results from the European Network of Rare Bleeding Disorders.

Authors:  F Peyvandi; R Palla; M Menegatti; S M Siboni; S Halimeh; B Faeser; H Pergantou; H Platokouki; P Giangrande; K Peerlinck; T Celkan; N Ozdemir; C Bidlingmaier; J Ingerslev; M Giansily-Blaizot; J F Schved; R Gilmore; A Gadisseur; M Benedik-Dolničar; L Kitanovski; D Mikovic; K M Musallam; F R Rosendaal
Journal:  J Thromb Haemost       Date:  2012-04       Impact factor: 5.824

5.  [Gene analysis of five inherited factor V deficiency cases].

Authors:  Li-Juan Cao; Zhao-Yue Wang; Yan-Hua Su; Hai-Yan Yang; Xiao-Juan Zhao; Wei Zhang; Zi-Qiang Yu; Xia Bai; Chang-Geng Ruan
Journal:  Zhonghua Xue Ye Xue Za Zhi       Date:  2008-03

6.  A novel in-frame deletion in the factor V C1 domain associated with severe coagulation factor V deficiency in a Korean family.

Authors:  Jaewoo Song; Ilaria Guella; Ki-Yung Kwon; Hyunsoo Cho; Rojin Park; Rosanna Asselta; Jong Rak Choi
Journal:  Blood Coagul Fibrinolysis       Date:  2009-03       Impact factor: 1.276

7.  Residual platelet factor V ensures thrombin generation in patients with severe congenital factor V deficiency and mild bleeding symptoms.

Authors:  Connie Duckers; Paolo Simioni; Luca Spiezia; Claudia Radu; Paolo Dabrilli; Sabrina Gavasso; Jan Rosing; Elisabetta Castoldi
Journal:  Blood       Date:  2009-10-27       Impact factor: 22.113

Review 8.  Parahemophilia: new insights into factor v deficiency.

Authors:  Nabil Thalji; Rodney M Camire
Journal:  Semin Thromb Hemost       Date:  2013-07-26       Impact factor: 4.180

9.  A case of congenital factor V deficiency.

Authors:  J W Song; M R Um; H S Ahn; C Y Hong
Journal:  J Korean Med Sci       Date:  1987-09       Impact factor: 2.153
  9 in total
  1 in total

1.  Congenital factor V deficiency from compound heterozygous mutations with a novel variant c.2426del (p.Pro809Hisfs*2) in the F5 gene: A case report.

Authors:  Chang-Hun Park; Min-Seung Park; Ki-O Lee; Sun-Hee Kim; Young Shil Park; Hee-Jin Kim
Journal:  Medicine (Baltimore)       Date:  2020-01       Impact factor: 1.889
  1 in total

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