A new insight into the treatment of factor V deficiency.

Inherited factor V deficiency is an extremely rare bleeding disorder with no proper treatment currently available and can result in fatal bleeding episodes for the most severe cases. It is characterized by mutations on the F5 gene and provokes reduced levels and activity of factor V (FV) , a critical protein involved in the coagulation process. One of the most promising biotechnologies in the medical field to tackle similar genetic disorders is the use of messenger RNA, being studied for the management of several conditions. Messenger RNA can be encapsulated into lipid nanoparticles, another promising non-viral delivery system. This present article will detail the possible therapeutic effects of a composition of FV mRNA encapsulated in LNPs, by hypothesizing its details, evaluating the possible treatment and suggesting a possible experimental study that may provide further data about this treatment.

High Mutational Heterogeneity, and New Mutations in the Human Coagulation Factor V Gene. Future Perspectives for Factor V Deficiency Using Recombinant and Advanced Therapies

Factor V is an essential clotting factor that plays a key role in the blood coagulation cascade on account of its procoagulant and anticoagulant activity. Eighty percent of circulating factor V is produced in the liver and the remaining 20% originates in the α-granules of platelets. In humans, the factor V gene is about 80 kb in size; it is located on chromosome 1q24.2, and its cDNA is 6914 bp in length. Furthermore, nearly 190 mutations have been reported in the gene. Factor V deficiency is an autosomal recessive coagulation disorder associated with mutations in the factor V gene. This hereditary coagulation disorder is clinically characterized by a heterogeneous spectrum of hemorrhagic manifestations ranging from mucosal or soft-tissue bleeds to potentially fatal hemorrhages. Current treatment of this condition consists in the administration of fresh frozen plasma and platelet concentrates. This article describes the cases of two patients with severe factor V deficiency, and of their parents. A high level of mutational heterogeneity of factor V gene was identified, nonsense mutations, frameshift mutations, missense changes, synonymous sequence variants and intronic changes. These findings prompted the identification of a new mutation in the human factor V gene, designated as Jaén-1, which is capable of altering the procoagulant function of factor V. In addition, an update is provided on the prospects for the treatment of factor V deficiency on the basis of yet-to-be-developed recombinant products or advanced gene and cell therapies that could potentially correct this hereditary disorder.

Significance of the p.Phe218Ser and p.Gly304Glu F5 Variants in Hereditary Factor V Deficiency

Hereditary factor V (FV) deficiency is a rare autosomal recessive bleeding disorder caused by <i>F5</i> gene mutations. The objective of this study was to investigate the p.Phe218Ser and p.Gly304Glu variants found in 2 families with hereditary FV deficiency. The FV activity (FV:C) and FV antigen (FV:Ag) were measured by clotting and ELISA, respectively. The <i>F5</i> gene and sequence conservation were analyzed by direct sequencing and ClustalX-2.1-win, respectively. One proband carried a homozygous p.Phe218Ser (c.653T&#x3e;C) mutation, with FV:C and FV:Ag decreased to 11 and 14%, respectively. The other proband carried a heterozygous p.Gly304Glu (c.911G&#x3e;A) mutation, with FV:C and FV:Ag reduced to 55 and 62%, respectively. Phe218 and Gly304 were highly conserved in the homologous gene in 9 other species. We hypothesized that the p.Phe218Ser and p.Gly304Glu variants are deleterious and responsible for the reduction in FV:C and FV:Ag.