Molecular analysis of the most prevalent mutations of the FANCA and FANCC genes in Brazilian patients with Fanconi anaemia

Rodriguez, David Enrique Aguilar; Lima, Carmen Silvia Passos; Lourenço, Gustavo Jacob; Figueiredo, Maria Estela; Carneiro, Jorge David Aivazoglu; Tone, Luiz Gonzaga; Llerena Jr., Juan Clinton; Toscano, Raquel Alves; Brandalise, Silvia; Pinto Júnior, Walter; Costa, Fernando Ferreira; Bertuzzo, Carmen Sílvia

doi:10.1590/S1415-47572005000200004

Abstract

Fanconi anaemia (FA) is a recessive autosomal disease determined by mutations in genes of at least eleven complementation groups, with distinct distributions in different populations. As far as we know, there are no reports regarding the molecular characterisation of the disease in unselected FA patients in Brazil. OBECTIVE: This study aimed to investigate the most prevalent mutations of FANCA and FANCC genes in Brazilian patients with FA. METHODS: Genomic DNA obtained from 22 racially and ethnically diverse unrelated FA patients (mean age ± SD: 14.0 ± 7.8 years; 10 male, 12 female; 14 white, 8 black) was analysed by polymerase chain reaction and restriction site assays for identification of FANCA (delta3788-3790) and FANCC (delta322G, IVS4+4A -> T, W22X, L496R, R548X, Q13X, R185X, and L554P) gene mutations. RESULTS: Mutations in FANCA and FANCC genes were identified in 6 (27.3%) and 14 (63.6%) out of 22 patients, respectively. The disease could not be attributed to the tested mutations in the two remaining patients enrolled in the study (9.1%). The registry of the two most prevalent gene abnormalities (delta3788-3790 and IVS4 + 4 -> T) revealed that they were present in 18.2% and 15.9% of the FA alleles, respectively. Additional FANCC gene mutations were found in the study, with the following prevalence: delta322G (11.4%), W22X (9.1%), Q13X (2.3%), L554P (2.3%), and R548X (2.3%) of total FA alleles. CONCLUSION: These results suggest that mutations of FANCA and FANCC genes are the most prevalent mutations among FA patients in Brazil.

Fanconi anaemia; DEB test; molecular diagnosis; FANCA; FANCC

HUMAN AND MEDICAL GENETICS

RESEARCH ARTICLE

Molecular analysis of the most prevalent mutations of the FANCA and FANCC genes in Brazilian patients with Fanconi anaemia

David Enrique Aguilar Rodriguez^I; Carmen Silvia Passos Lima^I; Gustavo Jacob Lourenço^I; Maria Estela Figueiredo^II; Jorge David Aivazoglu Carneiro^III; Luiz Gonzaga Tone^IV; Juan Clinton Llerena Jr.^V; Raquel Alves Toscano^VI; Silvia Brandalise^VII; Walter Pinto Júnior^I; Fernando Ferreira Costa^I; Carmen Sílvia Bertuzzo^I

^IUniversidade Estadual de Campinas, Campinas, SP, Brazil

^IIUniversidade Federal de São Paulo, São Paulo, SP, Brazil

^IIIUniversidade de São Paulo, São Paulo, SP, Brazil

^IVUniversidade de São Paulo, Campus de Ribeirão Preto, São Paulo, SP, Brazil

^VFundação Oswaldo Cruz, Rio de Janeiro, RJ, Brazil

^VIUniversidade de Brasília, Brasília, DF, Brazil

^VIICentro Boldrini, Campinas, SP, Brazil

^{Correspondence} Correspondence to Carmen Sílvia Bertuzzo Universidade Estadual de Campinas, Departamento de Genética Rua Tessália Vieira de Camargo 126 13081-970 Barão Geraldo, Campinas, São Paulo, Brazil E-mail: bertuzzo@fcm.unicamp.br

ABSTRACT

Fanconi anaemia (FA) is a recessive autosomal disease determined by mutations in genes of at least eleven complementation groups, with distinct distributions in different populations. As far as we know, there are no reports regarding the molecular characterisation of the disease in unselected FA patients in Brazil.

OBECTIVE: This study aimed to investigate the most prevalent mutations of FANCA and FANCC genes in Brazilian patients with FA.

METHODS: Genomic DNA obtained from 22 racially and ethnically diverse unrelated FA patients (mean age ± SD: 14.0 ± 7.8 years; 10 male, 12 female; 14 white, 8 black) was analysed by polymerase chain reaction and restriction site assays for identification of FANCA (D3788-3790) and FANCC (D322G, IVS4+4A ® T, W22X, L496R, R548X, Q13X, R185X, and L554P) gene mutations.

RESULTS: Mutations in FANCA and FANCC genes were identified in 6 (27.3%) and 14 (63.6%) out of 22 patients, respectively. The disease could not be attributed to the tested mutations in the two remaining patients enrolled in the study (9.1%). The registry of the two most prevalent gene abnormalities (D3788-3790 and IVS4 + 4 ® T) revealed that they were present in 18.2% and 15.9% of the FA alleles, respectively. Additional FANCC gene mutations were found in the study, with the following prevalence: D322G (11.4%), W22X (9.1%), Q13X (2.3%), L554P (2.3%), and R548X (2.3%) of total FA alleles.

CONCLUSION: These results suggest that mutations of FANCA and FANCC genes are the most prevalent mutations among FA patients in Brazil.

Key words: Fanconi anaemia, DEB test, molecular diagnosis, FANCA, FANCC.

Introduction

Fanconi anaemia (FA) is an autosomal recessive disease characterised by a very high frequency of bone marrow failure and many other manifestations, including but not restricted to severe birth defects and marked predisposition to malignancies, especially acute myeloid leukaemia and, to a lesser extent, solid tumours (Young and Alter, 1994; Alter and Young, 1998; Alter, 2003).

FA cells exhibit spontaneous chromosomal instability and hypersensitivity to DNA cross-linking agents such as diepoxybutane (DEB) and mitomycin C (Auerbach and Wolman, 1976) and the resulting increase in chromosome breakage provides the basis for a diagnostic test (Auerbach, 1993).

Complementation analysis by cell fusion and correction of cross-linker hypersensitivity has delineated at least eleven complementation groups (A, B, C, D1, D2, E, F, G, L, I, J) (Joenje and Patel, 2001; Meetei et al., 2003) and seven genes have been cloned (FANCA, C, D2, E, F, G and L) (Strathdee et al., 1992; Whitney et al., 1993; Lo Tem Foe et al., 1996; De Winter et al., 1998; De Winter et al., 2000; Timmers et al., 2001; Meetei et al., 2003). Four FA-D1 patients were shown to possess biallelic mutations in the breast cancer susceptibility gene BRCA2 (Levitus et al., 2003). FANCA and FANCC mutations are the most prevalent, accounting for approximately 65% and 5-15% of FA patients (Tischkowitz and Hodgson, 2003).

The prevalence of distinct FA gene mutations is variable in different populations (Tischkowitz and Hodgson, 2003). FANCA mutations are more common in Afrikaners (Tipping et al., 2001) and FANC in Ashkenazi Jews and Japanese (Yamashita et al., 1996; Gillio et al., 1997; Futaki et al., 2000; Tamary et al., 2003).

The relationship between the complementation group and mutation type and the clinical outcome of the patients with disease is controversial. Patients with FANCA and FANCG mutations appear to constitute a high risk group according to some authors (Faivre et al., 2000). In contrast, The International Fanconi Anaemia Register revealed a significantly earlier onset of bone marrow failure and poorer survival rates for complementation group C compared with groups A and G. Moreover, there was no significant difference in the time for haematologic or nonhaematologic neoplasm development between FA groups of patients (Kutler et al., 2003).

The ethnic origin of the Brazilian population is highly heterogeneous, consisting of indigenous Amerindians and immigrants from Europe, Africa, and Asia (Alves-Silva et al., 2000; Carvalho-Silva et al., 2001).

The D3788-3790 and IVS8-2A > G gene mutations were found in a group of Brazilian FA patients seen at a single bone marrow transplantation service, and were described as the most common FANCA and FANCG Brazilian mutations by the International Fanconi Anemia Registry (IFAR) (Levran et al., 1997; Auerbach et al., 2003). As far as we know, there are no reports regarding the molecular analysis of FA in unselected populations of our country. Therefore, this was the aim of the study presented herein.

Material and Methods

Eligibility requirements

All unrelated patients with confirmed FA, attended at the Medical Genetic and the Haematology services of UNICAMP and Haemotherapy Centres of several Brazilian Universities, were considered as fully eligible for the present study. The diagnosis of the disease was based on clinical and laboratory data, including haematological analysis, bone marrow aspiration and biopsy, and was confirmed by DEB test. The study protocol was approved by the local Research Ethics Committee.

DEB test

The DEB test was performed at the Cytogenetics Laboratory of the Haematology and Haemotherapy Centre of the State University of Campinas, according to conventional methods (Rosendorff and Bernstein, 1988; Auerbach et al., 1989).

Molecular Analysis of FANCA and FANCC genes

Genomic DNA was obtained from peripheral blood of patients enrolled in the study using the salt/chloroform method (Müllenbach et al., 1989). FANCA and FANCC mutations were analysed by polymerase chain reaction (PCR) followed by restriction site assays.

FANCA and FANCC exonic sequences of interest were amplified by PCR using primers described by Levran et al. (1997) and Gibson et al. (1996). PCR was carried out in 25 mL reactions with 250 ng of genomic DNA, 10 ng/mL of each primer, 0.5 mM of each dNTP, and 1.5 units of Taq polymerase in a buffer containing 6.7 mM MgCl₂. After initial denaturation at 94 °C for 5 min, samples were amplified for 30 denaturation cycles at 94 °C for 1 min, annealing at 51-60 °C, and extension at 72 °C for 1 min, followed by a final 5 min extension at 72 °C.

PCR products were then digested with 5-10 units of the appropriate restriction enzyme for a minimum of 2 h at 37 °C (50C for Bcl I), according to previously described techniques (Gibson et al., 1996; Levran et al., 1997) and analysed on horizontal 7% polyacrylamide gel.

The investigated gene mutations, restriction enzymes, and sizes of the normal and mutant gene fragments obtained from PCR and restriction site assays performed in the study are presented in Table 1.

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Results

The clinical and laboratory features of 22 FA patients enrolled in the study are presented in Table 2. Their mean age ± SD was 14.0 ± 7.8 years (range: 2-33 years); 10 patients were male and 12 female, 14 were white and 8 black. Sixteen patients presented congenital abnormalities such as microphthalmia (8 cases), microcephaly (4 cases), abnormalities of the thumbs (5 cases), café-au-lait spots (4 cases), hyperpigmentation (4 cases), short stature (2 cases), genital abnormalities (1 case), and renal aplasia (1 case). Short stature was the only physical abnormality identified in FANCA patients. Variable degrees of peripheral cytopenia and positive DEB test were found in all patients enrolled in the study. Cases 1, 2, 16 and 22 are children of consanguineous parents (18%).

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FA was attributed to D3788-3790 mutation of the FANCA gene in 6 out of 22 (27.3%) patients. The gene abnormality was present in 18.2% of FA alleles. Mutations of the FANCC gene were found in 14 out of 22 (63.6%) patients, with the following prevalence: 15.9% for IVS4+4A ® T, 11.4% for DG322, 9.1% for W22X, 2.3% for Q13X, 2.3% for L554P, and 2.3% for R548X on FA alleles. The analysed mutations were not found in 2 out of 22 (9.1%) patients enrolled in the study. Figure 1 shows the analysis for IVS4+4A ® T mutation.

Two pre-symptomatic patients with FA were identified in our familial studies (Cases 1 and 2).

Discussion

We have screened the D3788-3790 mutation of the FANCA and eight mutations (IVS4+4 A ® T, DG322, W22X, Q13X, L554P, R548X, L496R, and R185X) of the FANCC genes in an unselected group of Brazilian patients with confirmed FA diagnosis.

The median age of the studied group, 14 years old, was higher than those obtained in previous reports, which was 7 years old (McMullin et al., 1991; Auerbach and Allen, 1994; Butturini et al., 1994), and may be attributed to the difficulties in achieving a reference service for FA diagnosis in the country. The congenital abnormalities were more frequent and severe in FA determined by FANCC gene mutations, particularly in cases with IVS4+4 A ® T mutations, in accordance with previous reports (Faivre et al., 2000).

Interestingly, the disease was found in 8 (36.4%) patients of African origin in our group, in disagreement with the reports of Rosendorff et al. (1987) and MacDougall et al. (1990), in which the disease was rare in this race.

Mutations in the FANCC and FANCA genes accounted for approximately two-thirds and one-third of our cases. The disease was not determined by the tested mutations in only 9.1% of analysed cases. Therefore, FANCC gene mutations were the most prevalent in our group of patients (14 patients), in disagreement with previous reports that show to a higher prevalence of FANCA mutations in the majority of populations (Tischkowitz and Hodgson, 2003).

Levran et al. (1997) and Auerbach et al. (2003) described the D3788-3790 and IVS8-2A > G as the most common Brazilian mutations of FANCA and FANCC genes. As far as we know, both studies included Brazilian patients from a single bone marrow transplantation service, and may have included predominantly patients with the most severe disease forms. In our sample there were both patients with slight and severe haematological manifestations. As we did not select patients for study, it is possible that mutations of the FANCC gene represent a particular characteristic of the Brazilian population.

The most prevalent mutation of FANCA gene in our group was D3788-3790, in accordance with the report by Levran et al. (1997). The second most common mutation was the IVS4+4 A ® T of the FANCC gene (Yamashita et al., 1996; Gillio et al., 1997; Tamary et al., 2003).

In addition, the molecular analysis performed in our study was also important for early diagnosis of the disease, identification of pre-symptomatic and unaffected siblings with FA, as well as genetic counselling for the family.

Another fact that draws our attention is the high number of compound heterozygotes among FA patients. Since FA is considered a rare disease, a high rate of consanguineous parents and a larger number of homozygotes was expected, but not found in study. Our data suggest that FA may not be as rare as thought and taking into account its variable expressivity, many cases may be undiagnosed.

In conclusion, these results present preliminary evidence that FANCA and FANCC gene mutations are the most prevalent mutations among Brazilian FA patients. However, a large study concerning the molecular analysis of the Brazilian FA patients from different areas of the country should be carried out to clarify this issue.

Acknowledgments

This project was supported by Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP).

Received: April 5, 2004; Accepted: November 11, 2004.

Associate Editor: Mayana Zatz

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Correspondence to

Carmen Sílvia Bertuzzo

Universidade Estadual de Campinas, Departamento de Genética

Rua Tessália Vieira de Camargo 126

13081-970 Barão Geraldo, Campinas, São Paulo, Brazil

E-mail:

bertuzzo@fcm.unicamp.br

Publication Dates

Publication in this collection
11 July 2005
Date of issue
2005

History

Received
05 Apr 2004
Accepted
11 Nov 2004

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Alter BP and Young NS (1998) Inherited bone marrow failure syndromes. In: Nathan DG, Ginsburg D and Orkin SH (eds) Hematology of Infancy and Childhood. Philadelphia, WB Saunders, pp 280-365.

[2] Alter BP (2003) Cancer in Fanconi anemia. Cancer 101:425-440.

[3] Alves-Silva J, Silva-Santos M, Guimarães PE, Ferreira AC, Bandelt HJ, Pena SD and Prado VF (2000) The ancestry of Brazilian mtDNA lineages. Am J Hum Genet 67:444-461.

[4] Auerbach AD and Wolman SR (1976) Susceptibility of Fanconi's anaemia fibroblasts to chromosome damage by carcinogens. Nature 261:494-496.

[5] Auerbach AD, Rogatko A and Schroeder-Kurth TM (1989) International Fanconi Anemia registry: Relation of clinical symptoms to diepoxybutane sensitivity. Blood 73:391-396.

[6] Auerbach AD (1993) Fanconi anemia diagnosis and the diepoxybutane (DEB test). Exp Hematol 21:731-733.

[7] Auerbach AD and Allen RG (1994) Leukemia and preleukemia in Fanconi anemia patients. A review of the literature and report of the International Fanconi Anemia Registry study. Blood 51:1-12.

[8] Auerbach AD, Greenbaum J, Pujara K, Batish SD, Bitencourt MA, Kokemohr I, Schneider H, Lobitzc S, Pasquini R, Giampietro PF, Hanenberg H and Levran O (2003) Spectrum of sequence variation in the FANCG gene: An International Fanconi Anemia Registry (IFAR) study. Human Mutat 21:158-168.

[9] Butturini A, Gale RP, Verlander PC, Adler-Brecher B, Gillio AP and Auerbach AD (1994) Hematologic abnormalities in Fanconi anemia: An International Fanconi Anemia Registry study. Blood 84:1650-1655.

[10] Carvalho-Silva DR, Santos FR, Rocha J and Pena SD (2001) The phylogeography of Brazilian Y-chromosome lineages. Am J Hum Genet 68:281-6.

[11] De Winter JP, Waisfisz Q, Rooimans MA, van Berkel CG, Bosnoyan-Collins L, Alon N, Carreau M, Bender O, Demuth I, Schindler D, Pronk JC, Arwert F, Hoehn H, Digweed M, Buchwald M and Joenje H (1998) The Fanconi anaemia group G gene FANCG is identical with XRCC9. Nat Genet 20:281-283.

[12] De Winter JP, Leveille F, Van Berkel CG, Rooimans MA, van Der Weel L, Steltenpool J, Demuth I, Morgan NV, Alon N, Bosnoyan-Collins L, Lightfoot J, Leegwater PA, Waisfisz Q, Komatsu K, Arwert F, Pronk JC, Mathew CG, Digweed M, Buchwald M and Joenje H (2000) Isolation of a cDNA representing the Fanconi anemia complementation group E gene. Am J Hum Genet 67:1306-1308.

[13] De Winter JP, Rooimans MA, Van Der Weel L, van Berkel CG, Alon N, Bosnoyan-Collins L, de Groot J, Zhi Y, Waisfisz Q, Pronk JC, Arwert F, Mathew CG, Scheper RJ, Hoatlin ME, Buchwald M and Joenje H (2000) The Fanconi anaemia gene FANCF encodes a novel protein with homology to ROM. Nat Genet 24:15-16.

[14] Faivre L, Guardiola P, Lewis C, Dokal I, Ebell W, Zatterale A, Altay C, Poole J, Stones D, Kwee ML, van Weel-Sipman M, Havenga C, Morgan N, de Winter J, Digweed M, Savoia A, Pronk J, de Ravel T, Jansen S, Joenje H, Gluckman E and Mathew CG (2000) Association of complementation group and mutation type with clinical outcome in Fanconi anemia. Blood 96:4064-4070.

[15] Futaki M, Yamashita T, Yagasaki H, Toda T, Yabe M, Kato S, Asano S and Nakahata T (2000) The IVS4 + 4 A to T mutation of the Fanconi anemia gene FANCC is not associated with severe phenotype in Japanese patients. Blood 95:1493-1498.

[16] Gibson RA, Morgan NV, Goldstein LH, Pearson IC, Kesterton IP, Foot NJ, Jansen S, Havenga C, Pearson T, de Ravel TJ, Cohn RJ, Marques IM, Dokal I, Roberts I, Marsh J, Ball S, Milner RD, Llerena JC Jr, Samochatova E, Mohan SP, Vasudevan P, Birjandi F, Hajianpour A, Murer-Orlando M and Mathew CG (1996) Novel mutations and polymorphisms in the Fanconi anemia group C gene. Hum Mutat 8:140-148.

[17] Gillio AP, Verlander PC, Batish SD, Giampietro PF and Auerbach AD (1997) Phenotypic consequences of mutations in the Fanconi anemia FAC gene: an International Fanconi Anemia Registry study. Blood 90:105-110.

[18] Joenje H and Patel KJ (2001) The emerging genetic and molecular basis of Fanconi anaemia. Nat Rev Genet 2:446-457.

[19] Kutler DI, Singh B, Satagopan J, Batish AD, Berwich M, Giampietro PF, Hanenberg H and Auerbach AD (2003) A 20-year perspective on the International Fanconi Registry (IFAR). Blood 101: 1249-1256.

[20] Levitus M, Rooiman MA, Steltenpool J, Cool NFC, Oostra AB, Mathew CG, Hoatlin ME, Waisfisz Q, Arwert F, de Winter JP and Joenje H (2003) Heterogeneity in Fanconi anemia: evidence for two new genetic subtypes. Blood 20 (online).

[21] Levran O, Erlich T, Magdalena N, Gregory JJ, Batish SD, Verlander PC and Auerbach AD (1997) Sequence variation in the Fanconi anaemia gene FAA. Proc Natl Acad Sci USA 94:13051-13056.

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