Factor V Deficiency via the F5 Gene

  • Summary and Pricing
  • Clinical Features and Genetics
  • Citations
  • Methods
  • Ordering/Specimens
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NGS Sequencing

Test Code Test Copy GenesIndividual Gene PriceCPT Code Copy CPT Codes
3183 F5$850.00 81479 Add to Order
Pricing Comment

Our most cost-effective testing approach is NextGen sequencing with Sanger sequencing supplemented as needed to ensure sufficient coverage and to confirm NextGen calls that are pathogenic, likely pathogenic or of uncertain significance. If, however, full gene Sanger sequencing only is desired (for purposes of insurance billing or STAT turnaround time for example), please see link below for Test Code, pricing, and turnaround time information.

For Sanger Sequencing click here.
Targeted Testing

For ordering targeted known variants, please proceed to our Targeted Variants landing page.

Turnaround Time

The great majority of tests are completed within 20 days.

Clinical Sensitivity

About 95% of mutations in the F5 gene are detected through sequencing. If combined Factor V and VIII deficiency is ruled out, clinical sensitivity is predicted to be high as mutations in the F5 gene are the only known cause of congenital Factor V deficiency.

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Deletion/Duplication Testing via aCGH

Test Code Test Copy GenesIndividual Gene PriceCPT Code Copy CPT Codes
600 F5$990.00 81479 Add to Order
Pricing Comment

# of Genes Ordered

Total Price









Over 100

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Targeted Testing

For ordering targeted known variants, please proceed to our Targeted Variants landing page.

Turnaround Time

The great majority of tests are completed within 20 days.

Clinical Features

Factor V deficiency (also known as Owren Disease and parahemophilia) is an inherited bleeding disorder with a broad spectrum of symptoms. Mucosal bleeding is the most common manifestation with menorrhagia, muscle hematoma, and hemarthroses present in smaller subsets of patients (Thalji et al 2013). Unlike hemophilia A and B, bleeding severity is not directly correlated to factor serum levels. Patients may be treated with antifibrinolytics or receive fresh frozen plasma infusions to mitigate symptoms (Shakhnovich et al. 2013). About a third of patients are asymptomatic until incursion of trauma or surgery. Factor V deficiency may also be acquired in rare cases with auto-inhibitory antibodies directed against FV protein (Lippi et al. 2011). Patients with other pathological conditions such as liver disease have been shown to have reduced FV levels (Thalji et al. 2013). Genetic testing is helpful in the differential diagnosis of congenital and acquired Factor V deficiency states.


Factor V deficiency is a rare autosomal recessive or compound heterozygous disease characterized by mutations in the F5 gene that affect males and females. To date, more than 200 different mutations have been documented as causative for the disease (Thalji et al. 2013). Missense mutations represent nearly 50% of causative alleles and are clustered to the A and C domains of the F5 gene and often affect secretion of FV protein (Montefusco et al. 2003; Chapla et al. 2011). Nonsense and splice site mutations leading to premature termination account for nearly 40% of Factor V deficiency (Delev et al. 2008; Cutler et al. 2010). Combined Factor V and VIII deficiency is phenotypically similar, but is due to causative mutations in the MCFD2 and LMAN1 genes (Peyvandi et al 2013). FV protein is part of the common coagulation pathway. Its activated form is an essential cofactor in the prothrombinase complex which is required to convert prothrombin to thrombin to promote clot formation.

Testing Strategy

For this Next Generation (NextGen) test, the full coding regions plus ~10 bp of non-coding DNA flanking each exon are sequenced for the gene listed below. Sequencing is accomplished by capturing specific regions with an optimized solution-based hybridization kit, followed by massively parallel sequencing of the captured DNA fragments. Additional Sanger sequencing is performed for any regions not captured or with insufficient number of sequence reads. All pathogenic, likely pathogenic, or variants of uncertain significance are confirmed by Sanger sequencing.

Indications for Test

This test is for individuals with symptoms and assays of hemostasis (prolonged PT and PPT) that suggest Factor V Deficiency. Ideal candidates have FV-specific PT assays indicating Factor V deficiency. Genetic testing is especially helpful in differential diagnosis of prolonged bleeding disorders.


Official Gene Symbol OMIM ID
F5 612309
Inheritance Abbreviation
Autosomal Dominant AD
Autosomal Recessive AR
X-Linked XL
Mitochondrial MT


Name Inheritance OMIM ID
Factor V Deficiency 227400


Genetic Counselors
  • Chapla, A, G R Jayandharan, E Sumitha, G Sankari Devi, P Shenbagapriya, S C Nair, A Viswabandya, B George, V Mathews, and A Srivastava. Molecular Basis of Hereditary Factor V Deficiency in India: Identification of Four Novel Mutations and Their Genotype-Phenotype Correlation. Thrombosis and Haemostasis 105, no. 6 (June 2011): 1120-1123. PubMed ID: 21647534
  • Cutler, J A, R Patel, S Rangarajan, R C Tait, and M J Mitchell. Molecular Characterization of 11 Novel Mutations in Patients with Heterozygous and Homozygous FV Deficiency. Haemophilia: The Official Journal of the World Federation of Hemophilia 16, no. 6 (November 2010): 937-942. PubMed ID: 20546033
  • Delev, D, A Pavlova, S Heinz, E Seifried, and J Oldenburg. Factor 5 Mutation Profile in German Patients with Homozygous and Heterozygous Factor V Deficiency. Haemophilia: The Official Journal of the World Federation of Hemophilia 15, no. 5 (September 2009): 1143-1153. PubMed ID: 19486170
  • Lippi, Giuseppe, Emmanuel J Favaloro, Martina Montagnana, Franco Manzato, Gian C Guidi, and Massimo Franchini. Inherited and Acquired Factor V Deficiency. Blood Coagulation & Fibrinolysis: An International Journal in Haemostasis and Thrombosis 22, no. 3 (April 2011): 160-166. PubMed ID: 21245750
  • Montefusco, Maria Claudia, Stefano Duga, Rosanna Asselta, Massimo Malcovati, Flora Peyvandi, Elena Santagostino, Pier Mannuccio Mannucci, and Maria Luisa Tenchini. Clinical and Molecular Characterization of 6 Patients Affected by Severe Deficiency of Coagulation Factor V: Broadening of the Mutational Spectrum of Factor V Gene and in Vitro Analysis of the Newly Identified Missense Mutations. Blood 102, no. 9 (November 1, 2003): 3210-3216. PubMed ID: 12816860
  • Peyvandi, Flora, Tom Kunicki, and David Lillicrap. Genetic Sequence Analysis of Inherited Bleeding Diseases. Blood 122, no. 20 (November 14, 2013): 3423-3431. PubMed ID: 24124085
  • Shakhnovich, V, J Daniel, B Wicklund, G Kearns, and K Neville. “Use of Pharmacokinetic Modelling to Individualize FFP Dosing in Factor V Deficiency. Haemophilia: The Official Journal of the World Federation of Hemophilia 19, no. 2 (March 2013): 251-255. PubMed ID: 23173558
  • Thalji, Nabil, and Rodney M Camire. Parahemophilia: New Insights into Factor v Deficiency. Seminars in Thrombosis and Hemostasis 39, no. 6 (September 2013): 607-612. PubMed ID: 23893775
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NextGen Sequencing using PG-Select Capture Probes

Test Procedure

We use a combination of Next Generation Sequencing (NGS) and Sanger sequencing technologies to cover the full coding regions of the listed genes plus ~20 bases of non-coding DNA flanking each exon.  As required, genomic DNA is extracted from the patient specimen.  For NGS, patient DNA corresponding to these regions is captured using an optimized set of DNA hybridization probes.  Captured DNA is sequenced using Illumina’s Reversible Dye Terminator (RDT) platform (Illumina, San Diego, CA, USA).  Regions with insufficient coverage by NGS are covered by Sanger sequencing.  All pathogenic, likely pathogenic, or variants of uncertain significance are confirmed by Sanger sequencing.

For Sanger sequencing, Polymerase Chain Reaction (PCR) is used to amplify targeted regions.  After purification of the PCR products, cycle sequencing is carried out using the ABI Big Dye Terminator v.3.0 kit.  PCR products are resolved by electrophoresis on an ABI 3730xl capillary sequencer.  In nearly all cases, cycle sequencing is performed separately in both the forward and reverse directions.

Patient DNA sequence is aligned to the genomic reference sequence for the indicated gene region(s). All differences from the reference sequences (sequence variants) are assigned to one of five interpretation categories, listed below, per ACMG Guidelines (Richards et al. 2015).

(1) Pathogenic Variants
(2) Likely Pathogenic Variants
(3) Variants of Uncertain Significance
(4) Likely Benign Variants
(5) Benign, Common Variants

Human Genome Variation Society (HGVS) recommendations are used to describe sequence variants (  Rare variants and undocumented variants are nearly always classified as likely benign if there is no indication that they alter protein sequence or disrupt splicing.

Analytical Validity

As of March 2016, 6.36 Mb of sequence (83 genes, 1557 exons) generated in our lab was compared between Sanger and NextGen methodologies. We detected no differences between the two methods. The comparison involved 6400 total sequence variants (differences from the reference sequences). Of these, 6144 were nucleotide substitutions and 256 were insertions or deletions. About 65% of the variants were heterozygous and 35% homozygous. The insertions and deletions ranged in length from 1 to over 100 nucleotides.

In silico validation of insertions and deletions in 20 replicates of 5 genes was also performed. The validation included insertions and deletions of lengths between 1 and 100 nucleotides. Insertions tested in silico: 2200 between 1 and 5 nucleotides, 625 between 6 and 10 nucleotides, 29 between 11 and 20 nucleotides, 25 between 21 and 49 nucleotides, and 23 at or greater than 50 nucleotides, with the largest at 98 nucleotides. All insertions were detected. Deletions tested in silico: 1813 between 1 and 5 nucleotides, 97 between 6 and 10 nucleotides, 32 between 11 and 20 nucleotides, 20 between 21 and 49 nucleotides, and 39 at or greater than 50 nucleotides, with the largest at 96 nucleotides. All deletions less than 50 nucleotides in length were detected, 13 greater than 50 nucleotides in length were missed. Our standard NextGen sequence variant calling algorithms are generally not capable of detecting insertions (duplications) or heterozygous deletions greater than 100 nucleotides. Large homozygous deletions appear to be detectable.   

Analytical Limitations

Interpretation of the test results is limited by the information that is currently available.  Better interpretation should be possible in the future as more data and knowledge about human genetics and this specific disorder are accumulated.

When Sanger sequencing does not reveal any difference from the reference sequence, or when a sequence variant is homozygous, we cannot be certain that we were able to detect both patient alleles.  Occasionally, a patient may carry an allele which does not amplify, due to a large deletion or insertion.   In these cases, the report will contain no information about the second allele.  Our Sanger and NGS Sequencing tests are generally not capable of detecting Copy Number Variants (CNVs).

We sequence all coding exons for each given transcript, plus ~20 bp of flanking non-coding DNA for each exon.  Test reports contain no information about other portions of the gene, such as regulatory domains, deep intronic regions or any currently uncharacterized alternative exons.

In most cases, we are unable to determine the phase of sequence variants.  In particular, when we find two likely causative mutations for recessive disorders, we cannot be certain that the mutations are on different alleles.

Our ability to detect minor sequence variants due to somatic mosaicism is limited.  Sequence variants that are present in less than 50% of the patient’s nucleated cells may not be detected.

Runs of mononucleotide repeats (eg (A)n or (T)n) with n >8 in the reference sequence are generally not analyzed because of strand slippage during PCR.

Unless otherwise indicated, DNA sequence data is obtained from a specific cell-type (usually leukocytes from whole blood).   Test reports contain no information about the DNA sequence in other cell-types.

We cannot be certain that the reference sequences are correct.

Rare, low probability interpretations of sequencing results, such as for example the occurrence of de novo mutations in recessive disorders, are generally not included in the reports.

We have confidence in our ability to track a specimen once it has been received by PreventionGenetics.  However, we take no responsibility for any specimen labeling errors that occur before the sample arrives at PreventionGenetics.

Deletion/Duplication Testing via Array Comparative Genomic Hybridization

Test Procedure

Equal amounts of genomic DNA from the patient and a gender matched reference sample are amplified and labeled with Cy3 and Cy5 dyes, respectively. To prevent any sample cross contamination, a unique sample tracking control is added into each patient sample. Each labeled patient product is then purified, quantified, and combined with the same amount of reference product. The combined sample is loaded onto the designed array and hybridized for at least 22-42 hours at 65°C. Arrays are then washed and scanned immediately with 2.5 µM resolution. Only data for the gene(s) of interest for each patient are extracted and analyzed.

Analytical Validity

PreventionGenetics' high density gene-centric custom designed aCGH enables the detection of relatively small deletions and duplications within a single exon of a given gene or deletions and duplications encompassing the entire gene. PreventionGenetics has established and verified this test's accuracy and precision.

Analytical Limitations

Our dense probe coverage may allow detection of deletions/duplications down to 100 bp; however due to limitations and probe spacing this cannot be guaranteed across all exons of all genes. Therefore, some copy number changes smaller than 100-300 bp within a targeted large exon may not be detected by our array.

This array may not detect deletions and duplications present at low levels of mosaicism or those present in genes that have pseudogene copies or repeats elsewhere in the genome.

aCGH will not detect balanced translocations, inversions, or point mutations that may be responsible for the clinical phenotype.

Breakpoints, if occurring outside the targeted gene, may be hard to define.

The sensitivity of this assay may be reduced when DNA is extracted by an outside laboratory.

Order Kits

Ordering Options

myPrevent - Online Ordering
  • The test can be added to your online orders in the Summary and Pricing section.
  • Once the test has been added log in to myPrevent to fill out an online requisition form.
  • A completed requisition form must accompany all specimens.
  • Billing information along with specimen and shipping instructions are within the requisition form.
  • All testing must be ordered by a qualified healthcare provider.


(Delivery accepted Monday - Saturday)

  • Collect 3 ml -5 ml (5 ml preferred) of whole blood in EDTA (purple top tube) or ACD (yellow top tube). For Test #500-DNA Banking only, collect 10 ml -20 ml of whole blood.
  • For small babies, we require a minimum of 1 ml of blood.
  • Only one blood tube is required for multiple tests.
  • Ship blood tubes at room temperature in an insulated container. Do not freeze blood.
  • During hot weather, include a frozen ice pack in the shipping container. Place a paper towel or other thin material between the ice pack and the blood tube.
  • In cold weather, include an unfrozen ice pack in the shipping container as insulation.
  • At room temperature, blood specimen is stable for up to 48 hours.
  • If refrigerated, blood specimen is stable for up to one week.
  • Label the tube with the patient name, date of birth and/or ID number.


(Delivery accepted Monday - Saturday)

  • Send in screw cap tube at least 5 µg -10 µg of purified DNA at a concentration of at least 20 µg/ml for NGS and Sanger tests and at least 5 µg of purified DNA at a concentration of at least 100 µg/ml for gene-centric aCGH, MLPA, and CMA tests, minimum 2 µg for limited specimens.
  • For requests requiring more than one test, send an additional 5 µg DNA per test ordered when possible.
  • DNA may be shipped at room temperature.
  • Label the tube with the composition of the solute, DNA concentration as well as the patient’s name, date of birth, and/or ID number.
  • We only accept genomic DNA for testing. We do NOT accept products of whole genome amplification reactions or other amplification reactions.


(Delivery preferred Monday - Thursday)

  • PreventionGenetics should be notified in advance of arrival of a cell culture.
  • Culture and send at least two T25 flasks of confluent cells.
  • Some panels may require additional flasks (dependent on size of genes, amount of Sanger sequencing required, etc.). Multiple test requests may also require additional flasks. Please contact us for details.
  • Send specimens in insulated, shatterproof container overnight.
  • Cell cultures may be shipped at room temperature or refrigerated.
  • Label the flasks with the patient name, date of birth, and/or ID number.
  • We strongly recommend maintaining a local back-up culture. We do not culture cells.
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