Haptoglobin gene subtypes in three Brazilian population groups of different ethnicities

Miranda-Vilela, Ana L.; Akimoto, Arthur K.; Alves, Penha C.Z.; Hiragi, Cássia O.; Penalva, Guilherme C.; Oliveira, Silviene F.; Grisolia, Cesar K.; Klautau-Guimarães, Maria N.

doi:10.1590/S1415-47572009005000051

Abstract

Haptoglobin is a plasma hemoglobin-binding protein that limits iron loss during normal erythrocyte turnover and hemolysis, thereby preventing oxidative damage mediated by iron excess in the circulation. Haptoglobin polymorphism in humans, characterized by the Hp*1 and Hp*2 alleles, results in distinct phenotypes known as Hp1-1, Hp2-1 and Hp2-2, whose frequencies vary according to the ethnic origin of the population. The Hp*1 allele has two subtypes, Hp*1F and Hp*1S, that also vary in their frequencies among populations worldwide. In this work, we examined the distribution frequencies of haptoglobin subtypes in three Brazilian population groups of different ethnicities. The haptoglobin genotypes of Kayabi Amerindians (n = 56), Kalunga Afro-descendants (n = 70) and an urban population (n = 132) were determined by allele-specific PCR. The Hp*1F allele frequency was highest in Kalunga (29.3%) and lowest in Kayabi (2.6%). The Hp*1F/Hp*1S allele frequency ratios were 0.6, 1.0 and 0.26 for the Kayabi, Kalunga and urban populations, respectively. This variation was attributable largely to the Hp*1F allele. However, despite the large variation in Hp*1F frequencies, results of FST (0.0291) indicated slight genetic differentiation among subpopulations of the general Brazilian population studied here. This is the first Brazilian report of variations in the Hp *1F and Hp*1S frequencies among non-Amerindian Brazilians.

Brazilian ethnicities; haptoglobin; polymorphism; subtypes

HUMAN AND MEDICAL GENETICS

RESEARCH ARTICLE

Haptoglobin gene subtypes in three Brazilian population groups of different ethnicities

Ana L. Miranda-Vilela; Arthur K. Akimoto; Penha C.Z. Alves; Cássia O. Hiragi; Guilherme C. Penalva; Silviene F. Oliveira; Cesar K. Grisolia; Maria N. Klautau-Guimarães

Departamento de Genética e Morfologia, Instituto de Ciências Biológicas, Universidade de Brasília, Brasília, DF, Brazil

^{Sendo correspondence to} Send correspondence to: Ana Luisa Miranda-Vilela Laboratório de Genética, Departamento de Genética e Morfologia, Instituto de Ciências Biológicas, Universidade de Brasília 70910-900 Brasília, DF, Brazil E-mail: mirandavilela@unb.br

ABSTRACT

Haptoglobin is a plasma hemoglobin-binding protein that limits iron loss during normal erythrocyte turnover and hemolysis, thereby preventing oxidative damage mediated by iron excess in the circulation. Haptoglobin polymorphism in humans, characterized by the Hp^*1 and Hp^*2 alleles, results in distinct phenotypes known as Hp1-1, Hp2-1 and Hp2-2, whose frequencies vary according to the ethnic origin of the population. The Hp^*1 allele has two subtypes, Hp^*1F and Hp^*1S, that also vary in their frequencies among populations worldwide. In this work, we examined the distribution frequencies of haptoglobin subtypes in three Brazilian population groups of different ethnicities. The haptoglobin genotypes of Kayabi Amerindians (n = 56), Kalunga Afro-descendants (n = 70) and an urban population (n = 132) were determined by allele-specific PCR. The Hp^*1F allele frequency was highest in Kalunga (29.3%) and lowest in Kayabi (2.6%). The Hp^*1F/Hp^*1S allele frequency ratios were 0.6, 1.0 and 0.26 for the Kayabi, Kalunga and urban populations, respectively. This variation was attributable largely to the Hp^*1F allele. However, despite the large variation in Hp^*1F frequencies, results of FST (0.0291) indicated slight genetic differentiation among subpopulations of the general Brazilian population studied here. This is the first Brazilian report of variations in the Hp ^*1F and Hp^*1S frequencies among non-Amerindian Brazilians.

Key words: Brazilian ethnicities, haptoglobin, polymorphism, subtypes.

Introduction

Molecular variation in human haptoglobin (Hp) was described by Smithies (1955), who identified three major phenotypes, Hp1-1, Hp2-1, and Hp2-2, by starch gel electrophoresis. These phenotypes are controlled by two autosomal codominant alleles, Hp^*1 and Hp^*2 (Smithies and Walker, 1956). Two subtypes of the Hp^*1 allele, Hp^*1S and Hp^*1F, were subsequently identified in urea-containing starch gels (Smithies et al., 1962). Despite populational differences in the distribution of haptoglobin phenotypes, these alleles have been found in every human population examined so far. The Hp^*1 allele frequency is lower in South-East Asia and higher in South America (Langlois and Delanghe, 1996). There is also a significant difference in the frequency distribution of Hp^*1F and Hp^*1S alleles among populations worldwide (Carter and Worwood, 2007). An extreme case of populational variation was reported for the Hp^*1F allele in which a geographical cline of this allele increased in the same direction as the Hp^*1 allele, whereas the Hp^*1S frequency showed no variation (Delanghe et al., 2000).

The Hp phenotypes determine the serum levels of Hp-glycoprotein but differ in their number of protein components, electrophoretic mobility, plasma concentration of Hp, and antioxidant and antiinflammatory activities, often with divergent clinical consequences (Langlois and Delanghe, 1996; Yano et al., 1998; Wassel, 2000; Koch et al., 2003; Sadrzadeh and Bozorgmehr, 2004; Tseng et al., 2004; Carter and Worwood, 2007). Many clinical studies have demonstrated a link between Hp polymorphism and a broad range of pathological conditions, and such associations probably reflect functional differences among the phenotypes (Langlois and Delanghe, 1996; Wassel, 2000; Sadrzadeh and Bozorgmehr, 2004; Levy, 2006; Zvi and Levy, 2006). In contrast, other studies have reported no such associations, despite the wide range of Hp^*1 and Hp^*2 gene frequencies throughout the world (Carter and Worwood, 2007). These apparently divergent findings can only be understood through additional characterization of the distribution of Hp subtype polymorphisms.

The Brazilian population is very mixed, primarily as a result of five centuries of interethnic crosses among Europeans, Africans and Amerindians. This three-hybrid genetic admixture has been demonstrated by genetic and historical studies (Callegari-Jacques and Salzano, 1999; Alves-Silva et al., 2000; Carvalho-Silva et al., 2001; Mendes-Junior and Simões, 2001; Callegari-Jacques et al., 2003; Barcelos et al., 2006a,b; Suarez-Kurtz et al., 2007; Godinho et al., 2008). Haptoglobin is one of the genetic markers used to describe the genetic constitution of populations. However, there are few data on the haptoglobin gene subtypes in the general Brazilian population, although several reports on Hp subtypes (phenotypes) and types have been published, mostly for indigenous populations (reviewed by Salzano and Callegari-Jacques, 1988; Simões et al., 1989; Salzano et al., 1991, 1997a,b, 1998; Santos et al., 1998; Beiguelman et al., 2003; Calderoni et al., 2006; Zaccariotto et al., 2006). The aim of this work was to examine the frequencies of the Hp gene subtypes in three Brazilian population groups of different ethnic origins (Kayabi Amerindians, Kalunga Afro-descendents and inhabitants of the Federal District).

Subjects and Methods

Populations

1) The Kayabi are a Tupi-Guarani Amerindian tribe (Rodrigues, 1994) with a population of about 1,000 found mainly in the Xingu Indigenous National Park (Mato Grosso state). The Kayabi village sampled consisted of 110 individuals living on the margins of the Teles Pires River (11° 37' 0" S and 55° 40' 60' W) (Dórea et al., 2005; Klautau-Guimarães et al., 2005a,b). More details about this tribe can be found in Dórea et al. (2005). The sample (n = 56) used here was collected in 2000 and consisted of 29 males and 27 females, with a median age of 24.5 years and no first-degree (parent-offspring) relationship.

2) The Kalunga are an Afro-derived Brazilian group with an estimated population of 5,300. This group lives in midwestern Brazil, in a rural area of northeastern Goiás State (15° 30' S to 16° 03' S ; 47° 25' W to 48° 12' W) (Oliveira et al., 2002). Historically and numerically, the Kalunga are one of the most important Brazilian Afro-derived populations known as quilombos. The Kalunga are organized into several subregions with different degrees of isolation. The sample (n = 70) used here was collected in 2001 and 2002 and consisted of 29 males and 41 females from the Vão das Almas and Vão de Muleque subregions, with a median age of 42.9 years and a relationship coefficient of up to 1/16.

3) The Federal District (15° 30' S to 16° 03' S and 47° 25' W to 48° 12' W) was founded in 1960 and in 2007 had an urban population of 2,455,903 (2007 IBGE census). Most of the Federal District population initially consisted of migrants from other regions of Brazil (Queiroz 2006), and currently almost half of the Districts inhabitants are migrants (www.distritofederal.df.gov.br). The sample used here (n = 132) was collected in 2002 and consisted of 54 males and 78 females and with a median age of 21.1 years. Based on the subjects self-declared skin color, 68.5% were racially mixed, 24.7% were white, 1.7% was black and 5.1% did not declare their color.

In each of the communities sampled, the aims of this study were explained and the voluntary nature of the donation of biological material was emphasized. Informed consent was obtained in all cases and oral informed consent was obtained in the Kayabi village.

Haptoglobin (Hp) genotyping

About 5 mL of peripheral blood was collected by venipuncture using Vacutainer tubes with EDTA as anticoagulant, and then cooled as quickly as possible. DNA was isolated from the buffy-coat layer by using a purification kit GFX (GE Healthcare, Buckinghamshire, England) and the samples were stored below 20 °C until analysis.

Hp genotypes were determined by allele-specific PCR (polymerase chain reaction) as described by Yano et al. (1998). The identification of alleles Hp^*1F, Hp^*1S and Hp^*2 was based on three independent PCR reaction product analyses. PCR products were separated by electrophoresis in 6% polyacrylamide gels under non-denaturing conditions and then detected by staining with silver nitrate.

Data management and statistical analysis

Allelic and genotypic frequencies were estimated by gene counting and the goodness of fit of the genotype distribution to the Hardy-Weinberg equilibrium was assessed by the chi-square (χ²) test. Values of p > 0.05 indicated Hardy-Weinberg equilibrium. Haptoglobin genetic diversity was assessed by comparing the observed and expected heterozygosities and the F-statistics. Probability (p) values for heterozygote excess were generated by the Genepopweb statistical program version 3.4 (http://genepop.curtin.edu.au/). Comparisons between the different ethnic groups (heterogeneity test) were based on contingency tables analyzed by χ² tests.

Results

Table 1 summarizes the distribution of the Hp allele frequencies in the populations studied. The Hp^*1 allele frequency varied from 58.6% in the Afro-descendant Kalunga population to 43.7% in the indigenous Kayabi population. Based on the F-statistics (Table 1), the Brazilian population showed low genetic differentiation among subpopulations (F_ST) for Hp polymorphism, despite the large variation in Hp ^*1F frequencies.

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Table 2 shows the Hp genotype frequencies in the Kayabi, Kalunga and Federal District populations and the results of the Hardy-Weinberg equilibrium test. The genotypic distributions indicated Hardy-Weinberg equilibrium, except for the Kayabi population, in which there was a heterozygote excess (F_IS = -0.5876), as shown in Table 1. Heterogeneity tests for all pairwise comparisons among the three populations revealed significant differences (Table 2).

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Discussion

In this study, there were significant differences in Hp allele frequencies among the three Brazilian populations of different ethnicities. The Hp^*1 allele frequency was higher in the Kalunga (Afrodescendents) and lower in the Kayabi (Amerindian), in which the Hp*2 allele was most frequent. These results agreed with literature (reviewed by Carter and Worwood 2007), since they showed geographical differences in the Hp^*1 and Hp^*2 frequencies, depending on the ethnic origin of the group. We also observed significant differences in the distribution of the Hp^*1F and Hp^*1S alleles. The results for the Kalunga, Kayabi and Federal District agree, respectively, with the Hp^*1 allele frequencies described for Brazilian Afro-descendants (55%) (Tondo et al., 1963), Içana River Indians (43%) (Simões et al., 1989) and an urban group from São Paulo (46.5%) (Wobeto et al., 2007). The Hp^*1 allele frequency in the Kalunga (58%) was also similar to that described for the African continent (0.56) and North America (0.55), but higher than in Asia (0.27) (Carter and Worwood, 2007), probably because of the contribution of Afro-descendants that formed the quilombo. For the Kayabi, the frequency of the Hp^*1 allele (44%) was similar to that reported for three South American Amerindian populations, viz., the Makiritare (42%), Kubenkokre (49%) (Arends et al., 1970; Santos et al., 1998) and the French Guiana population of Kaliña (44.5%) (Mazières et al., 2007), but was lower than for other Brazilian Amerindians (Salzano et al., 1974, 1991, 1997a,b, 1998; Oliveira et al., 1998).

The Hp^*1 allele frequency (49.6%) of the Federal District urban population was similar to that reported for other Brazilian urban populations from São Paulo state (46%) (Wobeto et al., 2007) and Euro-descendants from Porto Alegre (41.4%) (Tondo et al., 1963). The distribution of the Hp alleles in the Federal District population probably reflects the history of the creation of Brasília, the new Brazilian capital, in the late 1950s. Unlike most Brazilian cities, Brasília and the accompanying Federal District were completely new projects in which settlement of the Federal Capital was driven by government benefits. The construction of Brasília (1956-1960) was the main attraction for migrants, who came from northern, southeastern and southern Brazil (Queiroz, 2006). As a result, the population of Brasília and the Federal District was formed by a wide-ranging mixture of migrants from all regions of Brazil (Queiroz, 2006) that reflected five centuries of interethnic crosses among people of European, African and Amerindian descent (Alves-Silva et al., 2000; Carvalho-Silva et al., 2001; Mendes-Junior and Simões, 2001; Vargas et al., 2006; Suarez-Kurtz et al., 2007; Godinho et al., 2008). This very diverse origin of the Federal District population has made it the most representative sample-group of the Brazilian population.

The present study provides the first report of variations in the Hp^*1F and Hp^*1S frequencies in non-Amerindian Brazilians. The frequency of the Hp^*1F allele was highest in the Afro-descendant Kalunga (29.3%) and lowest in the indigenous population of Kayabi (2.6%). This finding agrees with reports in which a higher Hp^*1 frequency has been linked to a higher Hp^*1F frequency (Delanghe et al., 2000; Carter and Worwood, 2007). In addition, the Hp frequency distribution in the populations studied was not homogenous (p < 0.0001 in the heterogeneity test) and probably reflected selection or recent ethnic admixture. The Hp^*1F/Hp^*1S allele frequency ratios among these populations were 0.06 for the Kayabi, 1.0 for the Kalunga and 0.26 for the Federal District. This variation was attributable essentially to the Hp^*1F allele since variation in the Hp^*1S allele frequency was very low among these populations (no marked geographical differences). Similar variation in the Hp^*1 allele has been reported for Central American populations (Delanghe et al., 2000), although the ratios were different from those seen here.

The Kayabi population had Hp genotype frequencies that were not in Hardy-Weinberg equilibrium, with an excess of heterozygotes (F_IS = -0.5876). Factors that could account for this finding include the following: (i) the Kayabi live in an area that has experienced intense migration as a result of gold prospecting, and they have consequently become somewhat mixed (Klautau-Guimarães et al., 2005b), (ii) the Hp phenotypes are associated with several disorders such as diabetes and cardiovascular and infectious diseases (Langlois and Delanghe, 1996; Sadrzadeh and Bozorgmehr, 2004; Carter and Worwood, 2007) that may have subjected the population to some form of natural selection and (iii) the Kayabi population consumes freshwater fish contaminated by monomethyl mercury, and is also exposed to endemic infectious diseases such as malaria, for which they lack basic medical services (Dórea et al., 2005, Klautau-Guimarães et al., 2005a); the latter two hypotheses suggest selection in favor of heterozygotes.

Since F_IT and F_IS represent the correlations between the two uniting gametes that produce individuals in the total population and subpopulations, respectively (Nei 1977), and since our results for these parameters were negative in both cases, this implies an excess of heterozygotes in both situations. However, these results were affected by the Kayabi population. In addition, given that F_ST is the correlation between two gametes drawn at random from each subpopulation and measures the degree of genetic differentiation of subpopulations (Nei 1977), our results (F_ST = 0.0291) showed that there was a slight genetic differentiation among subpopulations of the general Brazilian population studied.

In conclusion, we have provided the first description of the distribution frequencies of the Hp subtypes Hp^*1F and Hp^*1S in three Brazilian populations of different ethnic origins. For haptoglobin polymorphism, despite the large variation in Hp^*1F frequencies, results of F_ST (0.0291) indicated slight genetic differentiation among subpopulations of the general Brazilian population studied. This polymorphism has proven to be an interesting biomarker for understanding human migrations around the world and for identifying associations with diseases. Additional studies are required to map the distribution of these Hp subtypes in other ethnicities, and to gain a better understanding of the biological significance of this marker for anthropogenic studies.

Acknowledgments

This study was supported by the University of Brasília and the Brazilian National Council for Technological and Scientific Development (CNPq).

Internet Resources

Received: October 22, 2008; Accepted: January 17, 2009.

Associate Editor: Francisco Mauro Salzano

Alves-Silva J, Santos MS, Guimarães PEM, Ferreira ACS, Bandelt HJ, Pena SDJ and Prado VF (2000) The ancestry of Brazilian mtDNA lineages. Am J Hum Genet 67:444-461.
Arends T, Weitkamp LR, Gallango ML, Neel JV and Schultz J (1970) Gene frequencies and microdifferentiation among the Makiritare Indians. II. Seven serum protein systems. Am J Hum Genet 22:526-532.
Barcelos RSS, Ribeiro GGBL, Silva-Júnior WA, Abe-Sandes K, Marinho-Netto F, Gigonzac MAD, Klautau-Guimaraes MN and Oliveira SF (2006a) Male contribution in the constitution of the Brazilian Centro-Oeste population estimated by Y-chromosome binary markers. In: International Society of Forensic Genetics (eds) Progress in Forensic Genetics, v. 11. 11th edition. Elsevier Science, Amsterdam, pp 228-230.
Barcelos RSS, Silva-Júnior WA, Abe-Sandes K, Godinho NMO and Oliveira SF (2006b) Contribución parental en la constitución de poblaciones del Brasil Central estimada por el cromosoma Y y marcadores del mtADN. In: Sociedade Espanhola de Antropologia Física (ed) Diversidade Biológica e Saúde Humana. 1a edición. Quaderna Editorial, Múrcia, pp 55-60.
Beiguelman B, Alves FP, Moura MM, Engracia V, Nunes ACS, Heckmann MIO, Ferreira RGM, Pereira da Silva LH, Camargo EP and Krieger H (2003) The association of genetic markers and malaria infection in the Brazilian Western Amazonian region. Mem Inst Oswaldo Cruz 98:455-460.
Calderoni DR, Andrade TD and Grotto HZW (2006) Haptoglobin phenotype appears to affect the pathogenesis of American trypanosomiasis. Ann Trop Med Parasitol 100:213-221.
Callegari-Jacques SM and Salzano FM (1999) Brazilian Indian/non-Indian interactions and their effects. Ciênc Cult 51:166-174.
Callegari-Jacques SM, Grattapaglia D, Salzano FM, Salamoni SP, Crossetti SG, Ferreira ME and Hutz MH (2003) Historical genetics: Spatiotemporal analysis of the formation of the Brazilian population. Am J Hum Biol 15:824-834.
Carter K and Worwood M (2007) Haptoglobin: A review of the major allele frequencies worldwide and their association with diseases. Int J Lab Hem 29:92-110.
Carvalho-Silva DR, Santos FR, Rocha J and Pena SDJ (2001) The phylogeography of Brazilian Y-chromosome lineages. Am J Hum Genet 68:281-286.
Delanghe J, Langlois M, Esquivel CA and Haene H (2000) Haptoglobin 1F allele frequency is high among indigenous populations in the State of Durango, Mexico. Hum Hered 50:263-265.
Dórea JG, Souza JR, Rodrigues P, Ferrari I and Barbosa AC (2005) Hair mercury (signature of fish consumption) and cardiovascular risk in Munduruku and Kayabi Indians of Amazonia. Environ Res 97:209-219.
Godinho NMO, Gontijo CC, Diniz MECG, Falcão-Alencar G, Dalton GC, Amorim CEG, Barcelos RSS, Klautau-Guimarães MN and Oliveira SF (2008) Regional patterns of genetic admixture in South America. FSI Genet 1:329-330.
Klautau-Guimarães MN, D'Ascenção R, Caldart FA, Grisolia CK, Souza JR, Barbosa AC, Cordeiro CMT and Ferrari I (2005a) Analysis of genetic susceptibility to mercury contamination evaluated through molecular biomarkers in at-risk Amazon Amerindian populations. Genet Mol Biol 28:827-832.
Klautau-Guimarães MN, Hiragi CO, D'Ascenção RF, Oliveira SF, Grisolia CK, Hatagima AH and Ferrari I (2005b) Distribution of glutathione S-transferase GSTM1 and GSTT1 null phenotypes in Brazilian Amerindians. Genet Mol Biol 28:32-35.
Koch W, Latz W, Eichinger M, Gschwendner C, Teige B, Schömig A and Kastrati A (2003) Haptoglobin gene subtyping restriction enzyme analysis. Clin Chem 49:1937-1940.
Langlois MR and Delanghe JR (1996) Biological and clinical significance of haptoglobin polymorphism in humans. Clin Chem 42:1589-1600.
Levy AP (2006) Application of pharmacogenomics in the prevention of diabetic cardiovascular disease: Mechanistic basis and clinical evidence for utilization of the haptoglobin genotype in determining benefit from antioxidant therapy. Pharmacol Ther 112:501-512.
Mazières S, Sevin A, Bonnet F, Crubézy E, Salzano F and Larrouy G (2007) Genetic studies in French Guiana populations: Synthesis. Am J Phys Anthropol 132:292-300.
Mendes-Junior CT and Simões AL (2001) Alu insertions and ethnic composition in a Brazilian population sample. Int J Hum Genet 1:249-254.
Nei M (1977) F-statistics and analysis of gene diversity in subdivided populations. Ann Hum Genet 41:225-233.
Oliveira SF, Lopes DEBL, Santos SEB and Guerreiro JF (1998) The Awá-Guajá Indians of the Brazilian Amazon: Demographic data, serum protein markers and blood groups. Hum Hered 48:163-168.
Oliveira SF, Pedrosa MAF, Souza SMB, Mingronineto R, Sandes KA, Ferrari I, Barbosa AAL, Auricchio MTBM and Klautau-Guimarães MN (2002) Heterogeneous distribution on HbS and HbC alleles in Afro-derived Brazilian populations. Int J Hum Genet 2:153-160.
Rodrigues AD (1994) Línguas Brasileiras: Para o Conhecimento das Línguas Indígenas. Loyola, São Paulo, 136 pp.
Sadrzadeh SMH and Bozorgmehr J (2004) Haptoglobin phenotypes in health and disorders. Am J Pathol 121:S97-S104.
Salzano FM and Callegari-Jacques SM (1988) South American Indians: A Case Study in Evolution. Clarendon Press, Oxford, 259 pp.
Salzano F, Woodall JP, Black FL, Weitkamp LR and Franco MHLP (1974). Blood groups, serum proteins and hemoglobins of Brazilian Tiriyo Indians. Hum Biol 46:81-87.
Salzano FM, Black FL, Callegari-Jacques SM, Santos SEB, Weimer TA, Mestriner MA, Kubo RR, Pandey JP and Hutz MH (1991) Blood genetic systems in four Amazonian Tribes. Am J Phys Anthropol 85:51-60.
Salzano F, Callegari-Jacques SM, Weimer TA, Franco MHLP, Hutz MH and Petzl-Erler ML (1997a) Electrophoretic protein polymorphisms in Kaingang and Guarani Indians of southern Brazil. Am J Hum Biol 9:505-512.
Salzano F, Franco MHLP, Weimer TA, Callegari-Jacques SM, Mestriner MA, Hutz MH, Flowers NM, Santos RV and Coimbra Jr CEA (1997b) The Brazilian Xavante Indians revisited: New protein genetic studies. Am J Phys Anthropol 104:23-34.
Salzano FM, Weimer TA, Franco MHLP, Callegari-Jacques SM, Mestriner MA, Hutz MH, Santos RV and Coimbra Jr CEA (1998) Protein genetic studies among the Tupi-Mondé Indians of the Brazilian Amazonia. Am J Hum Biol 10:711-722.
Santos SEB, Ribeiro-dos-Santos AKC, Guerreiro JF, Santos EJM, Weimer TA, Callegari-Jacques SM, Mestriner MA, Franco MHLP, Hutz MH and Salzano FM (1998) New protein genetic studies in six Amazonian Indian populations. Ann Hum Biol 25:505-522.
Simões AL, Kömpf J, Ritter H, Luckenbach C, Zischler H and Salzano FM (1989) Electrophoretic and isoelectric focusing studies in Brazilian Indians: Data on four systems. Hum Biol 61:427-438.
Smithies O (1955) Zone electrophoresis in starch gels: Group variations in the serum proteins of normal adults. Biochem J 61:629-641.
Smithies O and Walker NF (1956) Notation for a serum-protein group and the genes controlling their inheritance. Nature 178:694-695.
Smithies O, Connell GE and Dixon GH (1962) Inheritance of haptoglobin subtypes. Am J Hum Genet 14:14-21.
Suarez-Kurtz G, Vargens DD, Struchiner CJ, Bastos-Rodrigues L and Pena SDJ (2007) Self-reported skin color, genomic ancestry and the distribution of GST polymorphisms. Pharmacogenet Genom 17:765-771.
Tondo CV, Mundt C and Salzano FM (1963) Haptoglobin types in Brazilian negroes. Ann Hum Genet 26:325-331.
Tseng CF, Lin CC, Huang HY, Liu HC and Mao SJT (2004) Antioxidant role of human haptoglobin. Proteomics 4:2221-2228.
Vargas AE, Marrero AR, Salzano FM, Bortolini MC and Chies JAB (2006) Frequency of CCR5D32 in Brazilian populations. Braz J Med Biol Res 39:321-325.
Wassel J (2000) Haptoglobin: Function and polymorphism. Clin Lab 46:547-552.
Wobeto VPA, Rosim ET, Melo MB, Calliari LEP and Sonati MF (2007) Haptoglobin polymorphism and diabetic retinopathy in Brazilian patients. Diabetes Res Clin Pract 77:385-388.
Yano A, Yamamoto Y, Miyaishi S and Ishizu H (1998) Haptoglobin genotyping by allele-specific polymerase chain reaction amplification. Acta Med 52:173-181.
Zaccariotto TR, Rosim ET, Melo D, Garcia PMD, Munhoz RR, Aoki FH and Sonati MF (2006) Haptoglobin polymorphism in a HIV-1 seropositive Brazilian population. J Clin Pathol 59:550-553.
Zvi B and Levy AP (2006) Haptoglobin phenotypes, which one is better and when? Clin Lab 52:29-35.
Queiroz EP (2006) A migração intrametropolitana no Distrito Federal e Entorno: O conseqüente fluxo pendular e o uso dos equipamentos urbanos de saúde e educação. http://www.abep.nepo.unicamp.br/encontro2006/docspdf/ABEP2006_724.pdf (january 12, 2009).

Send correspondence to:

Ana Luisa Miranda-Vilela

Laboratório de Genética, Departamento de Genética e Morfologia, Instituto de Ciências Biológicas, Universidade de Brasília

70910-900 Brasília, DF, Brazil

E-mail:

mirandavilela@unb.br

Publication Dates

Publication in this collection
26 June 2009
Date of issue
2009

History

Accepted
17 Jan 2009
Received
22 Oct 2008

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

[1] Alves-Silva J, Santos MS, Guimarães PEM, Ferreira ACS, Bandelt HJ, Pena SDJ and Prado VF (2000) The ancestry of Brazilian mtDNA lineages. Am J Hum Genet 67:444-461.

[2] Arends T, Weitkamp LR, Gallango ML, Neel JV and Schultz J (1970) Gene frequencies and microdifferentiation among the Makiritare Indians. II. Seven serum protein systems. Am J Hum Genet 22:526-532.

[3] Barcelos RSS, Ribeiro GGBL, Silva-Júnior WA, Abe-Sandes K, Marinho-Netto F, Gigonzac MAD, Klautau-Guimaraes MN and Oliveira SF (2006a) Male contribution in the constitution of the Brazilian Centro-Oeste population estimated by Y-chromosome binary markers. In: International Society of Forensic Genetics (eds) Progress in Forensic Genetics, v. 11. 11th edition. Elsevier Science, Amsterdam, pp 228-230.

[4] Barcelos RSS, Silva-Júnior WA, Abe-Sandes K, Godinho NMO and Oliveira SF (2006b) Contribución parental en la constitución de poblaciones del Brasil Central estimada por el cromosoma Y y marcadores del mtADN. In: Sociedade Espanhola de Antropologia Física (ed) Diversidade Biológica e Saúde Humana. 1a edición. Quaderna Editorial, Múrcia, pp 55-60.

[5] Beiguelman B, Alves FP, Moura MM, Engracia V, Nunes ACS, Heckmann MIO, Ferreira RGM, Pereira da Silva LH, Camargo EP and Krieger H (2003) The association of genetic markers and malaria infection in the Brazilian Western Amazonian region. Mem Inst Oswaldo Cruz 98:455-460.

[6] Calderoni DR, Andrade TD and Grotto HZW (2006) Haptoglobin phenotype appears to affect the pathogenesis of American trypanosomiasis. Ann Trop Med Parasitol 100:213-221.

[7] Callegari-Jacques SM and Salzano FM (1999) Brazilian Indian/non-Indian interactions and their effects. Ciênc Cult 51:166-174.

[8] Callegari-Jacques SM, Grattapaglia D, Salzano FM, Salamoni SP, Crossetti SG, Ferreira ME and Hutz MH (2003) Historical genetics: Spatiotemporal analysis of the formation of the Brazilian population. Am J Hum Biol 15:824-834.

[9] Carter K and Worwood M (2007) Haptoglobin: A review of the major allele frequencies worldwide and their association with diseases. Int J Lab Hem 29:92-110.

[10] Carvalho-Silva DR, Santos FR, Rocha J and Pena SDJ (2001) The phylogeography of Brazilian Y-chromosome lineages. Am J Hum Genet 68:281-286.

[11] Delanghe J, Langlois M, Esquivel CA and Haene H (2000) Haptoglobin 1F allele frequency is high among indigenous populations in the State of Durango, Mexico. Hum Hered 50:263-265.

[12] Dórea JG, Souza JR, Rodrigues P, Ferrari I and Barbosa AC (2005) Hair mercury (signature of fish consumption) and cardiovascular risk in Munduruku and Kayabi Indians of Amazonia. Environ Res 97:209-219.

[13] Godinho NMO, Gontijo CC, Diniz MECG, Falcão-Alencar G, Dalton GC, Amorim CEG, Barcelos RSS, Klautau-Guimarães MN and Oliveira SF (2008) Regional patterns of genetic admixture in South America. FSI Genet 1:329-330.

[14] Klautau-Guimarães MN, D'Ascenção R, Caldart FA, Grisolia CK, Souza JR, Barbosa AC, Cordeiro CMT and Ferrari I (2005a) Analysis of genetic susceptibility to mercury contamination evaluated through molecular biomarkers in at-risk Amazon Amerindian populations. Genet Mol Biol 28:827-832.

[15] Klautau-Guimarães MN, Hiragi CO, D'Ascenção RF, Oliveira SF, Grisolia CK, Hatagima AH and Ferrari I (2005b) Distribution of glutathione S-transferase GSTM1 and GSTT1 null phenotypes in Brazilian Amerindians. Genet Mol Biol 28:32-35.

[16] Koch W, Latz W, Eichinger M, Gschwendner C, Teige B, Schömig A and Kastrati A (2003) Haptoglobin gene subtyping restriction enzyme analysis. Clin Chem 49:1937-1940.

[17] Langlois MR and Delanghe JR (1996) Biological and clinical significance of haptoglobin polymorphism in humans. Clin Chem 42:1589-1600.

[18] Levy AP (2006) Application of pharmacogenomics in the prevention of diabetic cardiovascular disease: Mechanistic basis and clinical evidence for utilization of the haptoglobin genotype in determining benefit from antioxidant therapy. Pharmacol Ther 112:501-512.

[19] Mazières S, Sevin A, Bonnet F, Crubézy E, Salzano F and Larrouy G (2007) Genetic studies in French Guiana populations: Synthesis. Am J Phys Anthropol 132:292-300.

[20] Mendes-Junior CT and Simões AL (2001) Alu insertions and ethnic composition in a Brazilian population sample. Int J Hum Genet 1:249-254.

[21] Nei M (1977) F-statistics and analysis of gene diversity in subdivided populations. Ann Hum Genet 41:225-233.

[22] Oliveira SF, Lopes DEBL, Santos SEB and Guerreiro JF (1998) The Awá-Guajá Indians of the Brazilian Amazon: Demographic data, serum protein markers and blood groups. Hum Hered 48:163-168.

[23] Oliveira SF, Pedrosa MAF, Souza SMB, Mingronineto R, Sandes KA, Ferrari I, Barbosa AAL, Auricchio MTBM and Klautau-Guimarães MN (2002) Heterogeneous distribution on HbS and HbC alleles in Afro-derived Brazilian populations. Int J Hum Genet 2:153-160.

[24] Rodrigues AD (1994) Línguas Brasileiras: Para o Conhecimento das Línguas Indígenas. Loyola, São Paulo, 136 pp.

[25] Sadrzadeh SMH and Bozorgmehr J (2004) Haptoglobin phenotypes in health and disorders. Am J Pathol 121:S97-S104.

[26] Salzano FM and Callegari-Jacques SM (1988) South American Indians: A Case Study in Evolution. Clarendon Press, Oxford, 259 pp.

[27] Salzano F, Woodall JP, Black FL, Weitkamp LR and Franco MHLP (1974). Blood groups, serum proteins and hemoglobins of Brazilian Tiriyo Indians. Hum Biol 46:81-87.

[28] Salzano FM, Black FL, Callegari-Jacques SM, Santos SEB, Weimer TA, Mestriner MA, Kubo RR, Pandey JP and Hutz MH (1991) Blood genetic systems in four Amazonian Tribes. Am J Phys Anthropol 85:51-60.

[29] Salzano F, Callegari-Jacques SM, Weimer TA, Franco MHLP, Hutz MH and Petzl-Erler ML (1997a) Electrophoretic protein polymorphisms in Kaingang and Guarani Indians of southern Brazil. Am J Hum Biol 9:505-512.

[30] Salzano F, Franco MHLP, Weimer TA, Callegari-Jacques SM, Mestriner MA, Hutz MH, Flowers NM, Santos RV and Coimbra Jr CEA (1997b) The Brazilian Xavante Indians revisited: New protein genetic studies. Am J Phys Anthropol 104:23-34.

[31] Salzano FM, Weimer TA, Franco MHLP, Callegari-Jacques SM, Mestriner MA, Hutz MH, Santos RV and Coimbra Jr CEA (1998) Protein genetic studies among the Tupi-Mondé Indians of the Brazilian Amazonia. Am J Hum Biol 10:711-722.

[32] Santos SEB, Ribeiro-dos-Santos AKC, Guerreiro JF, Santos EJM, Weimer TA, Callegari-Jacques SM, Mestriner MA, Franco MHLP, Hutz MH and Salzano FM (1998) New protein genetic studies in six Amazonian Indian populations. Ann Hum Biol 25:505-522.

[33] Simões AL, Kömpf J, Ritter H, Luckenbach C, Zischler H and Salzano FM (1989) Electrophoretic and isoelectric focusing studies in Brazilian Indians: Data on four systems. Hum Biol 61:427-438.

[34] Smithies O (1955) Zone electrophoresis in starch gels: Group variations in the serum proteins of normal adults. Biochem J 61:629-641.

[35] Smithies O and Walker NF (1956) Notation for a serum-protein group and the genes controlling their inheritance. Nature 178:694-695.

[36] Smithies O, Connell GE and Dixon GH (1962) Inheritance of haptoglobin subtypes. Am J Hum Genet 14:14-21.

[37] Suarez-Kurtz G, Vargens DD, Struchiner CJ, Bastos-Rodrigues L and Pena SDJ (2007) Self-reported skin color, genomic ancestry and the distribution of GST polymorphisms. Pharmacogenet Genom 17:765-771.

[38] Tondo CV, Mundt C and Salzano FM (1963) Haptoglobin types in Brazilian negroes. Ann Hum Genet 26:325-331.

[39] Tseng CF, Lin CC, Huang HY, Liu HC and Mao SJT (2004) Antioxidant role of human haptoglobin. Proteomics 4:2221-2228.

[40] Vargas AE, Marrero AR, Salzano FM, Bortolini MC and Chies JAB (2006) Frequency of CCR5D32 in Brazilian populations. Braz J Med Biol Res 39:321-325.

[41] Wassel J (2000) Haptoglobin: Function and polymorphism. Clin Lab 46:547-552.

[42] Wobeto VPA, Rosim ET, Melo MB, Calliari LEP and Sonati MF (2007) Haptoglobin polymorphism and diabetic retinopathy in Brazilian patients. Diabetes Res Clin Pract 77:385-388.

[43] Yano A, Yamamoto Y, Miyaishi S and Ishizu H (1998) Haptoglobin genotyping by allele-specific polymerase chain reaction amplification. Acta Med 52:173-181.

[44] Zaccariotto TR, Rosim ET, Melo D, Garcia PMD, Munhoz RR, Aoki FH and Sonati MF (2006) Haptoglobin polymorphism in a HIV-1 seropositive Brazilian population. J Clin Pathol 59:550-553.

[45] Zvi B and Levy AP (2006) Haptoglobin phenotypes, which one is better and when? Clin Lab 52:29-35.

[46] Queiroz EP (2006) A migração intrametropolitana no Distrito Federal e Entorno: O conseqüente fluxo pendular e o uso dos equipamentos urbanos de saúde e educação. http://www.abep.nepo.unicamp.br/encontro2006/docspdf/ABEP2006_724.pdf (january 12, 2009).

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