Beta-globin gene haplotypes in the Saudi sickle cell anaemia patients

The beta S-globin gene haplotypes were investigated using restriction endonucleases Hinc II and Hind III in 22 sickle cell anaemia patients from the eastern province, 67 sickle cell anaemia patients from the south-western province and 4 sickle cell anaemia patients from north-western province. The beta S was found to be mainly linked to the haplotype + + - + + in the eastern province (50% homozygous and 45.45% heterozygous), and - - - - + haplotypes in the south-western (44.77% homozygous and 43.28% heterozygous) and north-western (100% homozygous) provinces. A comparison of the haematological values and clinical manifestations in patients with the two major haplotypes revealed significant differences, with the disease presenting more severely in the south-western compared to the eastern population. The level of Hb F was not significantly different in the two groups and no association could be demonstrated between the beta-globin gene haplotype and Hb F level. These results have led us to suggest that the haplotype + + - + + is in some way linked to a benign sickle cell anemia, though the exact mechanism leading to a benign disease is not clear.     

Haplotypes in tribal Indians bearing the sickle gene: evidence for the unicentric origin of the beta S mutation and the unicentric origin of the tribal populations of India

To determine the origin of sickle cell anemia (SS) in India, we analyzed haplotypes of the beta gene cluster in beta S-carrying individuals belonging to tribal populations living in the Nilgiris region of southern India and complemented the available data on tribes of east-central India. We found that in the Nilgiris tribes chromosomes bearing the beta S gene are linked in 91% of the cases to the "Asian" (Arab-Indian) haplotype (although 25% of the haplotypes had the epsilon polymorphic site negative, making the 5' portion of the haplotype identical with the African Senegal haplotype). These XmnI (+) chromosomes were associated with high G gamma expression (67.2 +/- 5.9%) and a high percentage of Hb F (15.5 +/- 7.9%; range, 6-25.3%). We have similar findings for tribal groups from west-central India (Gujarat). In east-central India we have confirmed the data of others, finding the same haplotype linked to beta S in tribes living in the east (Orissa, Andhra Pradesh). We conclude that the beta S gene in presently isolated and disperse tribal populations in India is associated with one predominant typical haplotype, suggesting a unicentric origin of the mutation in India. In addition, this finding implies a unicentric origin of the tribal populations themselves: The gene must have arisen and spread before tribal dispersion. Furthermore, we find extremely high frequencies of the (-alpha) haplotype in the Nilgiris (0.89) and in Gujarat (0.95). The beta S gene linkage to a high Hb F-expressing haplotype and the high incidence of alpha-thalassemia predict a mild phenotypical expression of sickle cell anemia in India.     

Some atypical and rare sickle cell gene haplotypes in populations of Andhra Pradesh, India.

We have investigated the clinical, hematological, and molecular genetic characteristics of sickle cell anemia patients from 6 populations of Andhra Pradesh, South India. Of 72 sickle cell chromosomes (HBB*S) 60 belong to characteristic Arab-Indian haplotypes, 6 to variant Arab-Indian haplotypes, 1 to a Bantu haplotype, 2 to a Cameroon haplotype, and 3 to rare haplotypes. This is the first report of a Bantu haplotype in an Indian population. Some information on haplotype characteristics of normal chromosomes (HBB*A) is also presented. The average hemoglobin level was 7.3 g% and mean fetal hemoglobin (HbF) level was 12.6%. The higher HbF levels corroborate earlier observations in sickle cell homozygotes from India. Clinical investigations have revealed splenomegaly and painful crises as the most common features in these patients.     

Importation route of the sickle cell trait into Portugal: contribution of molecular epidemiology.

To elucidate the origin and spread of the sickle cell trait into the Portuguese population, we examined nine polymorphic DNA markers within the beta globin gene cluster defining the haplotype. The population sample included 64 sickle-cell-gene-bearing individuals from defined Portuguese-speaking white, black, and Asian Indian populations. The nature and geographic distribution of the different beta S haplotypes in Portugal suggest that the sickle cell trait has been imported twice: between the eighth and the thirteenth centuries from the Mediterranean basin (in association with the Benin haplotype) and after the fifteenth century from black Africa over an Atlantic route (Senegal and Bantu haplotypes).     

The origin of sickle cell alleles in Israel

Summary Molecular genetic studies were undertaken to determine the source of chromosomes carrying the sickle cell allele in Israeli patients. Analysis of restriction fragment length polymorphism (RFLP) patterns (haplotypes) along the -globin gene cluster was performed on 31 sickle chromosomes obtained from 10 unrelated families living in Israel. One is a Caucasian Jewish family, recently found to be carrying the sickle allele, and the other 9 are Arab families of various communities. The Jewish family, previously noted not to carry African red blood cell markers, was discovered to have the most common African haplotype of the -globin gene cluster, Benin. Similarly, 8 of the Arab families were also found to carry the Benin haplotype, whereas the ninth has the CAR (Central African Republic or Bantu) haplotype. The results suggest that sickle alleles in Israel originated in Africa, probably in two different regions, and migrated north into Arab and Jewish populations.     

Implications of the genetic epidemiology of globin haplotypes linked to the sickle cell gene in southern Iran

To determine the origin of sickle cell mutation in different ethnic groups living in southern Iran, we studied the haplotype background of the betaS and betaA genes in subjects from the provinces of Fars, Khuzestan, Bushehr, Hormozgan, and Kerman and from the islands of Khark and Qeshm. beta-globin gene cluster haplotypes were determined using the PCR-RFLP technique. Detection of -alpha 3.7 deletion and beta-thalassemia mutations were defined by PCR and reverse dot blot techniques, respectively. The framework of the beta-globin gene was determined using denaturing gradient gel electrophoresis. We found that the betaS mutation in southern Iran is associated with multiple mutational events. Most of the patients were from two ethnic groups: Farsi speakers (presumably Persian in origin) from Fars province and patients of Arab origin from Khuzestan province. In both ethnic groups the Arab-Indian haplotype was the most prevalent. The frequencies of the Arab-Indian and African haplotypes in sickle cell anemia patients from the provinces of Fars and Khuzestan were similar. Among betaA chromosomes the Bantu A2 haplotype was the most prevalent. The decrease in alpha-globin production in SS patients and AS individuals appeared to be related to the reduction in mean cell volume and mean cell hemoglobin. The Arab-Indian haplotype gene flow into this region of Iran can be traced to the Sassanian Empire. It is likely that the influx of betaS genes linked to the Benin and Bantu haplotypes, of African origin, must have occurred during the Arab slave trade.     

Glutathione reductase deficiency in association with sickle cell and thalassaemia genes in Saudi populations

Glutathione reductase (GR) deficiency is reported to occur with a variable frequency in some populations of the world. In this study, the populations of two regions of Saudi Arabia which have a high frequency of sickle cell, thalassaemia and glucose-6-phosphate dehydrogenase (G-6-PD) deficiency, were screened for GR deficiency. Studies were also carried out to investigate the frequency of GR deficiency with other genetic blood disorders. The frequencies of complete GR deficiency were 0.0065 and 0.006, while those of partial deficiency were 0.146 and 0.074 in Al-Hafouf and Khaiber, respectively. GR deficiency was encountered in combination with the sickle gene, the G-6-PD deficiency gene and the thalassaemia gene in both regions. Individuals with GR deficiency showed slightly reduced haematological parameters. In thalassaemic/GR-deficient subjects, mean cell volume and mean cell haemoglobin were low, while in sickle cell anaemia patients with GR deficiency the haematological parameters were higher than in sickle cell anaemia patients without GR deficiency.     

Molecular evolution and genetics of the Saitohin gene and tau haplotype in Alzheimer's disease and argyrophilic grain disease

A single nucleotide polymorphism that results in an amino acid change (Q7R) has been identified in the Saitohin (STH) gene and was initially found to be over-represented in the homozygous state in subjects with late-onset Alzheimer's disease (AD). More extensive studies provide limited support for the association with AD, but confirm an association of the Q allele with progressive supranuclear palsy and argyrophilic grain disease. A homologous sequence was found in the appropriate location of the rat and mouse tau genes, but there was no open reading frame allowing STH expression in these species, suggesting relatively recent evolution of this gene. In some non-human primates, the STH gene was identified, and this was found to differ from the human gene at two of 128 amino acids. All primates in which the STH gene was identified were homozygous for the R allele of STH, suggesting this is the ancestral allele. This observation was surprising, in that the Q allele is more common in human populations, and raises the possibility that natural selection has operated to favor individuals carrying this allele. The STH polymorphism is part of the tau gene haplotype, of which two major variants exist in human populations, the Q being part of the H1 haplotype and the R part of the H2 haplotype. More detailed studies confirm the H2 haplotype to be the ancestral tau gene. This situation is reminiscent of the evolution of the apolipoprotein (ApoE) gene, another locus that is potentially important for the risk of development of AD.     

Conditional Hitchhiking of Mitochondrial DNA: Frequency Shifts of Drosophila Melanogaster Mtdna Variants Depend on Nuclear Genetic Background

Tests were performed of the selective neutrality of mitochondrial DNA (mtDNA) variants from geographic populations of Drosophila melanogaster in Argentina (ARG) and Central Africa (CAF). The two populations were completely reproductively compatible. The two distinct mtDNA haplotypes from the two populations were competed in replicate experimental populations on three nuclear genetic backgrounds: homozygous ARG, homozygous CAF, or hybrid ARG/CAF. Mitochondrial haplotype frequencies did not change significantly on either of the two homozygous nuclear backgrounds, and there was no change after experimental perturbation of haplotype frequencies. On the hybrid background, the ARG haplotype frequency increased significantly for the first two generations in all replicate populations but then did not change in subsequent generations. After perturbation, the ARG haplotype frequency increased in only one of four replicates. There is no evidence for selective differences among mtDNA variants in homozygous nuclear contexts or for nuclear-mitochondrial coadaptation. While some ``fitness' difference among mtDNA variants is required to account for the observed frequency shifts, it appears that in these hybrid populations, mtDNA is hitchhiking on fitness variation among hybrid segregating nuclear genes. These results have implications for the use of mtDNA in the study of hybrid zones and gene flow.     

A genetic study of the Konda Kapu tribe of coastal Andhra Pradesh, South India

Phenotype and gene frequencies of two blood group and four red cell enzyme systems were examined in a Konda Kapu tribal sample of Coastal Andhra Pradesh, South India. The gene frequencies for these systems in Konda Kapus indicate the middle range values for Andhra Pradesh tribal populations, excepting the ADA and Rh(D) systems, where extreme range values are found. Further, gene flow is indicated between the Konda Kapus under study and Plain Kapus, a neighbouring caste population by calculation of Fi estimates.     

Detecting and Characterizing Genomic Signatures of Positive Selection in Global Populations

Natural selection is a significant force that shapes the architecture of the human genome and introduces diversity across global populations. The question of whether advantageous mutations have arisen in the human genome as a result of single or multiple mutation events remains unanswered except for the fact that there exist a handful of genes such as those that confer lactase persistence, affect skin pigmentation, or cause sickle cell anemia. We have developed a long-range-haplotype method for identifying genomic signatures of positive selection to complement existing methods, such as the integrated haplotype score (iHS) or cross-population extended haplotype homozygosity (XP-EHH), for locating signals across the entire allele frequency spectrum. Our method also locates the founder haplotypes that carry the advantageous variants and infers their corresponding population frequencies. This presents an opportunity to systematically interrogate the whole human genome whether a selection signal shared across different populations is the consequence of a single mutation process followed subsequently by gene flow between populations or of convergent evolution due to the occurrence of multiple independent mutation events either at the same variant or within the same gene. The application of our method to data from 14 populations across the world revealed that positive-selection events tend to cluster in populations of the same ancestry. Comparing the founder haplotypes for events that are present across different populations revealed that convergent evolution is a rare occurrence and that the majority of shared signals stem from the same evolutionary event.     

Sickle beta 0 thalassemia in Eastern Saudi Arabia

The sickle cell (beta s) gene occurs at a high frequency in the oasis populations of Eastern Saudi Arabia. However, as compared with the disorder in Africans, sickle cell anemia runs an unusually benign clinical course in this populations; this has been attributed in part to the relatively high levels of fetal hemoglobin (Hb F) which characterize Saudi Arabians with this condition [1, 2]. As yet, there is no satisfactory explanation for this remarkable phenomenon. To learn more about the expression of the beta s gene in Eastern Saudi Arabia, we examined its interaction with beta 0 thalassemia. We found that remarkably high levels of Hb F in this population are not restricted to individuals with sickle cell anemia but also occur in compound heterozygotes for the beta s and beta 0 thalassemia (beta 0 thal) genes. Additionally, this study has characterized sickle cell-beta 0 thalassemia (S-beta 0 thal) in Eastern Saudi Arabia for the first time.     

Experimental generation of SNP haplotype signatures in patients with sickle cell anaemia

Background

Sickle cell anemia is caused by a single type of mutation, a homozygous A→T substitution in the ß globin gene. Clinical severity is diverse, partially due to additional, disease-modifying genetic factors. We are studying one such modifier locus, HMIP (HBS1L-MYB intergenic polymorphism, chromosome 6q23.3). Working with a genetically admixed patient population, we have encountered the necessity to generate haplotype signatures of genetic markers to label genomic fragments with distinct genealogical origin at this locus. With the goal to generate haplotype signatures from patients experimentally, we have investigated the suitability of an existing nanofluidic assay platform to perform phase alignment with single-nucleotide polymorphism alleles.

Methodology/Principal Findings

Patient DNA samples were loaded onto Fluidigm Digital Arrays and individual DNA molecules were assayed with allele-specific probes for SNP markers. Here we present data showing the utility of the nanofluidic approach, yielding haplotype data identical to those obtained with a family-based method. We then determined haplotype composition in a group of patients with sickle cell disease, including in those where a mathematical inference approach gave ambiguous or misleading results. Experimental phasing of genotypes across 3.8 kb for rs9399137, rs9402685, and rs11759553 created unequivocal haplotype signatures for each of the patients. In 68 patients, we found 8 copies of a haplotype signature (‘C-C-T’), which is known to be prevalent in Europeans but to be absent in West African populations. We have confirmed the identity of our phased allele pairs by single-molecule sequencing and have demonstrated, in principle, that three-allele phasing (using three colors) is a potential extension to this method.

Conclusions/Significance

Phased haplotypes yield more information than the individual marker genotypes. Procedures such as the one described here would therefore benefit genetic mapping and functional studies as well as diagnostic procedures where the identity or parental origin of short genetic fragments is of importance.     

A Definitive Haplotype Map as Determined by Genotyping Duplicated Haploid Genomes Finds a Predominant Haplotype Preference at Copy-Number Variation Events

The majority of complete hydatidiform moles (CHMs) harbor duplicated haploid genomes that originate from sperm. This makes CHMs more advantageous than conventional diploid cells for determining haplotypes of SNPs and copy-number variations (CNVs), because all of the genetic variants in a CHM genome are homozygous. Here we report SNP and CNV haplotype structures determined by analysis of 100 CHMs from Japanese subjects via high-density DNA arrays. The obtained haplotype map should be useful as a reference for the haplotype structure of Asian populations. We resolved common CNV regions (merged CNV segments across the examined samples) into CNV events (clusters of CNV segments) on the basis of mutual overlap and found that the haplotype backgrounds of different CNV events within the same CNV region were predominantly similar, perhaps because of inherent structural instability.     

Chronic inflammatory state in sickle cell anemia patients is associated with HBB*S haplotype

The chronic inflammatory state in sickle cell anemia (SCA) is associated with several factors such as the following: endothelial damage; increased production of reactive oxygen species; hemolysis; increased expression of adhesion molecules by leukocytes, erythrocytes, and platelets; and increased production of proinflammatory cytokines. Genetic characteristics affecting the clinical severity of SCA include variations in the hemoglobin F (HbF) level, coexistence of alpha-thalassemia, and the haplotype associated with the HbS gene. The different haplotypes of SCA are Bantu, Benin, Senegal, Cameroon, and Arab-Indian. These haplotypes are associated with ethnic groups and also based on the geographical origin. Studies have shown that the Bantu haplotype is associated with higher incidence of clinical complications than the other haplotypes and is therefore considered to have the worst prognosis. This study aimed to evaluate the profile of the proinflammatory cytokines interleukin-6, tumor necrosis factor-α, and interleukin-17 in patients with SCA and also to assess the haplotypes associated with beta globin cluster S (HBB^*S). We analyzed a total of 62 patients who had SCA and had been treated with hydroxyurea; they had received a dose ranging between 15 and 25 (20.0 ± 0.6) mg/kg/day for 6–60 (18 ± 3.4) months; their data were compared with those for 30 normal individuals. The presence of HbS was detected and the haplotypes of the beta S gene cluster were analyzed by polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP). Our study demonstrated that SCA patients have increased inflammatory profile when compared to the healthy individuals. Further, analysis of the association between the haplotypes and inflammatory profile showed that the levels of IL-6 and TNF-α were greater in subjects with the Bantu/Bantu haplotype than in subjects with the Benin/Benin haplotype. The Bantu/Benin haplotype individuals had lower levels of cytokines than those with the Bantu/Bantu haplotype and greater levels than those of subjects with the Benin/Benin haplotype. For IL-17, a slight trend toward decreased levels was observed in the subjects with the Benin/Benin haplotype, when compared to those with the Bantu/Bantu and Bantu/Benin haplotypes; however, this difference was not statistically significant. Our results show that genetic polymorphisms in sickle cell anemia are associated with the inflammatory profile.     

DNA haplotypes and frameworks associated with the beta-globin gene in the Kachari population of Assam (India)

DNA haplotypes and frameworks associated with the beta-globin gene were determined in a Tibeto-Burman group, the Kachari, from Upper Assam, India, using restriction analysis at eight restriction sites. Of the total of 59 subjects, 26 were homozygous for HBB*A and 33 homozygous for HBB*E. Complete haplotype determination in 33 subjects revealed a conspicuous difference in haplotype distribution between HBB*A- and HBB*E-bearing chromosomes. The Southeast Asian HBB*E-associated haplotype -+- +- (27-2 in the present terminology) predominated on HBB*E chromosomes. The previously established beta-globin-associated frameworks 1, 2 and 3 were evenly distributed among the HBB*A chromosomes, whereas all HBB*E chromosomes had framework 2. These findings favor a common origin of the HBB*E gene in Southeast Asia and Assam.     

A novel sickle cell mutation of yet another origin in Africa: the Cameroon type

Summary The sickle cell mutation (^s) arose as at least three independent events in Africa and once in Asia, being termed the Senegal, Benin, Bantu and Indian types respectively. An investigation in Cameroon was carried out to determine whether the atypical sickle genes observed in the neighboring countries are the result of recombination or the presence of a sickle cell mutation of a different genetic origin. It was conducted on 40 homozygous SS patients followed at the Blood Transfusion Center in the capital city of Yaoundé. On 80 ^s chromosomes, 13 exhibited a novel polymorphic pattern that was observed three times in the homozygous state. This chromosome contains an ^AT gene. The restriction fragment length polymorphism haplotype is different from all the other ^s chromosomes in both the 5 and 3 regions, but has previously been reported in sporadic cases. The (AT)8(T)5 sequence in the — 500 region of the gene is specific and different from that of the Senegal, Benin, Bantu or Indian ^s genes. All the carriers of this specific chromosome belong to the Eton ethnic group and originate from the Sanaga river valley. This observation strongly argues for yet another independent origin of the sickle cell mutation in Africa, here referred to as the Cameroon type. The Benin haplotype and a Benin/ Bantu recombinant haplotype have been observed in the other studied populations: Ewondo, Bamiléké, Bassa, Yambassa and Boulou.     

A beta-thalassemia lesion abolishes the same Mst II site as the sickle mutation.

Digestion of DNA from a patient with homozygous beta zero thalassemia from Calabria, Italy with the restriction endonuclease Mst II produced a pattern similar to the one obtained with sickle cell trait DNA in that the Mst II site at the beta 6 position on one chromosome was abolished. We cloned the DNA from this beta-thalassemia chromosome and performed sequence analysis. The deletion of a single nucleotide (A) at the GAG codon of the beta 6 position results in a frame shift and early beta-globin chain termination. This mutation occurs on a chromosome with a haplotype similar to two other Mediterranean beta-thalassemia lesions. The Mst II enzyme is useful for prenatal diagnosis of beta thalassemia in this population.     

Deletions in the SMN gene in infantile and adult spinal muscular atrophy patients from the same family

Recently, a gene determining spinal muscular atrophy (SMA), termed survival motor neuron (SMN) gene, has been isolated from the 5g13 region. This gene has been found to be deleted in most patients with childhood-onset SMA. We have studied the SMN gene in a clinically heterogeneous family, including one patient affected by infantile chronic SMA and three subjects with mild adult-onset muscle weakness. Deletions in the SMN gene were detected in all of these patients, indicating that the childhood and adult SMAs are genetically homogeneous in this family. Genotyping of the family members established that the three mildly affected individuals were homozygous for the same haplotype from the SMA region, whereas the more severely affected patient was heterozygous with one different haplotype.