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.     

DNA polymorphisms in north Sardinian newborns and their linkage with abnormal γ globin gene arrangements and with βo-thalassemia

Fetal hemoglobin analysis and globin gene mapping have identified one type of beta(0)-thalassemia and four different gamma globin gene arrangements among newborn babies from the northern part of Sardinia. The beta(0)-thalassemia with a nonsense mutation at codon 39 was found on two chromosomes, each with a distinct pattern of polymorphic restriction sites; one had the A gamma T (A gamma 75 Ile----Thr) mutation, while the second did not. Four closely related haplotypes were identified for chromosomes with the A gamma T mutation. The gamma-thalassemia heterozygosity with the -GA gamma- hybrid gene fell into two categories. One apparently originated through crossing-over between mismatched chromosomes characterized by the most common haplotype, while the other had polymorphisms resembling those of a less frequently occurring chromosome. Chromosomes with the -G gamma-AG gamma-A gamma- triplication had polymorphic sites to be expected for this condition, being complimentary to the -GA gamma- thalassemias. Of the two additional gamma globin gene variations the -G gamma- G gamma- arrangement was associated with the chromosome with the most commonly occurring haplotype, while the chromosome with the -A gamma-A gamma- arrangement had a haplotype characteristic for that with the A gamma T mutation, which identified an -A gamma-A gamma T- arrangement. The incidental discovery of a silent beta-chain mutant, Hb Hamilton, with the Val----Ile substitution at position beta 11, in five newborns was also reported.     

Analysis of the 5′ flanking sequence of the Gγ globin gene by denaturing gradient gel electrophoresis confirms the heterogeneity of the Bantu βs haplotype

Summary The GCTT polymorphism recently described at positions — 1106 and — 1105 in the 5 flanking region of the G globin gene for the Bantu ^S haplotype was analysed by denaturing gradient gel electrophoresis. We studied 108 ^S chromosome and 122 ^A chromosomes. The TT sequence was found as follows: in all of 80 chromosomes bearing the Bantu ^S haplotype with the 6-bp deletion -400 nt from the G gene in 3 out of 5 Bantu ^S chromosomes without the deletion, in 1 out of 122 ^A chromosomes from different ethnic origins but in none of 23 ^S chromosomes bearing the Senegal, Benin or Cameroon haplotypes. These results confirm the heterogeneity of the Bantu ^S haplotype and allow a tentative evolutionary sequence for the different alleles at this locus to be presented.     

Beta-globin gene haplotypes and alpha-thalassemia analysis in Babinga pygmies from Congo-Brazzaville

We analyzed beta-globin gene cluster haplotypes and deletional alpha+-thalassemia (-alpha3.7kb) in 54 Babinga pygmy subjects from Congo-Brazzaville. The beta(S)-globin gene frequency was 0.065 and that of the deletional alpha-globin gene (-alpha3.7kb) was 0.29. Eighty-five percent of the beta(S) chromosomes and 13% of the beta(A) chromosomes were associated with the Bantu haplotype, 10% of beta(A) chromosomes with the Senegal haplotype, and the remaining beta chromosomes with atypical haplotypes. None of the chromosomes were of the Benin haplotype. These results are clearly of anthropological and evolutionary interest. They also support earlier observations that alpha+-thalassemia is prevalent at a high frequency in African populations.     

Common 5' beta-globin RFLP haplotypes harbour a surprising level of ancestral sequence mosaicism

Blocks of linkage disequilibrium (LD) in the human genome represent segments of ancestral chromosomes. To investigate the relationship between LD and genealogy, we analysed diversity associated with restriction fragment length polymorphism (RFLP) haplotypes of the 5' beta-globin gene complex. Genealogical analyses were based on sequence alleles that spanned a 12.2-kb interval, covering 3.1 kb around the psibeta gene and 6.2 kb of the delta-globin gene and its 5' flanking sequence known as the R/T region. Diversity was sampled from a Kenyan Luo population where recent malarial selection has contributed to substantial LD. A single common sequence allele spanning the 12.2-kb interval exclusively identified the ancestral chromosome bearing the "Bantu" beta(s) (sickle-cell) RFLP haplotype. Other common 5' RFLP haplotypes comprised interspersed segments from multiple ancestral chromosomes. Nucleotide diversity was similar between psibeta and R/T-delta-globin but was non-uniformly distributed within the R/T-delta-globin region. High diversity associated with the 5' R/T identified two ancestral lineages that probably date back more than 2 million years. Within this genealogy, variation has been introduced into the 3' R/T by gene conversion from other ancestral chromosomes. Diversity in delta-globin was found to lead through parts of the main genealogy but to coalesce in a more recent ancestor. The well-known recombination hotspot is clearly restricted to the region 3' of delta-globin. Our analyses show that, whereas one common haplotype in a block of high LD represents a long segment from a single ancestral chromosome, others are mosaics of short segments from multiple ancestors related in genealogies of unsuspected complexity.     

Two novel arrangements of the human fetal globin genes: G gamma-G gamma and A gamma-A gamma.

We describe two novel arrangements of the human fetal globin gene region: one chromosome with two linked A gamma genes (A gamma-A gamma) and two chromosomes with two linked G gamma genes (G gamma-G gamma). The gamma genes of these three chromosomes were cloned and the unusual 5' A gamma gene and one of the unusual 3' G gamma genes were partially sequenced. Both of these unusual genes differ from the genes normally found at their respective locations by a nucleotide substitution at the site of the single coding region difference between normal G gamma and A gamma genes. In both cases, the substitution is identical to the nucleotide found at that position in the normal neighboring gene. The unusual 3' G gamma gene also differs from normal A gamma genes at two other nucleotide positions, but both differences appear to be "private" or exclusive to this particular gene. These unusual fetal globin gene arrangements could have arisen from point mutations or from gene conversions of limited extent, the boundaries of which have been determined for all three chromosomes.     

Bantu beta s cluster haplotype predominates among Brazilian blacks.

We describe the combination of polymorphic restriction-enzyme sites in the beta globin gene cluster (haplotypes) for 74 chromosomes from Brazilian Blacks bearing the sickle hemoglobin gene (beta s). The three most common African beta s haplotypes account for 67 chromosomes: 49/74 (66.2%) were identified as Central African Republic (CAR or Bantu) type, 17 (23.0%) as Benin, and one as Senegal; seven chromosomes (9.5%) had minor atypical haplotypes. This distribution is different from that observed in the United States or Jamaica, where the Benin haplotype predominates, and results from different patterns of slave trades to North and South Americas. Since the beta s gene cluster polymorphisms modulate the severity of sickle cell anemia, this heterogeneity may explain differences of the clinical behavior of the disease in the United States and South America, and should also be considered in relation to other features and diseases.     

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.     

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.     

Abnormal arrangements in the alpha- and gamma-globin gene clusters in a relatively large group of Japanese newborns.

Data were obtained on blood samples from a relatively large group (264) of healthy Japanese newborns, collected at hospitals in Tokyo, Kurashiki, and Ube. The studies included an evaluation of anomalies in alpha-globin gene and gamma-globin gene arrangements using gene mapping and gamma-chain composition analyses. The results confirmed the rarity of alpha-thalassemia among Japanese; only a few babies had alpha-thalassemia-2 trait (the -3.7-kilobase [kb] deletion), while others had alpha-globin gene triplications (both the alpha alpha alpha anti-3.7 and the alpha alpha alpha anti-4.2 types). Among the gamma-globin gene anomalies that were observed, a few babies had the -A gamma-A gamma- globin gene arrangement or the -G gamma A gamma- type of deletion. The gamma-chain triplication (-G gamma-A gamma G gamma-A gamma-) occurred in 10 out of 256 newborns, and its frequency exceeded that of its corresponding -G gamma A gamma- deletion by a factor of 5. The restriction endonuclease XmnI was a useful tool, in addition to the enzymes Bg1II and BclI, to evaluate and confirm the gamma-globin gene deletion and triplication. The A gamma T variant, which is the product of a mutant A gamma-globin gene, occurred at a frequency of 0.156. The chromosome carrying this mutant A gamma gene had a characteristic haplotype that was originally seen in black and Mediterranean patients with Hemoglobin (Hb) S or with beta-thalassemia.     

Refined mapping of the CSNU3 gene to a 1.8-Mb region on chromosome 19q13.1 using historical recombinants in Libyan Jewish cystinuria patients.

Cystinuria is a genetic disease manifested by the development of kidney stones. In some patients, the disease is caused by mutations in the SLC3A1 gene located on chromosome 2p. In others, the disease is caused by a gene that maps to chromosome 19q, but has not yet been cloned. Cystinuria is very common among Jews of Libyan ancestry living in Israel. Previously we have shown that the disease-causing gene in Libyan Jews maps to an 8-cM interval on chromosome 19q between the markers D19S409 and D19S208. Several markers from chromosome 19q showed strong linkage disequilibrium, and a specific haplotype was found in more than half of the carrier chromosomes. In this study we have analyzed Libyan Jewish cystinuria families with eight markers from within the interval containing the gene. Seven of these markers showed significant linkage disequilibrium. A common haplotype was found in 16 of the 17 carrier chromosomes. Analysis of historical recombinants placed the gene in a 1.8-Mb interval between the markers D19S430 and D19S874. Two segments of the historical carrier chromosome used to calculate the mutation's age revealed that the disease-causing mutation was introduced into this population 7-16 generations ago.     

Nucleotide variations in the 3'' A gamma enhancer region are linked to beta-gene cluster haplotypes and are unrelated to fetal hemoglobin expression.

Molecular cloning and sequence analysis of a nondeletion form of Sicilian beta o hereditary persistence of fetal hemoglobinemia (HPFH) (mutation in IVS2 nt1 position) homozygous for haplotype III revealed the presence of four sequence variations: C----T at -158 5' to G gamma, T----C at +2285, C----A at +2476, and A----G at +2676, all 3' to A gamma. The latter three variations in the putative A gamma enhancer are identical to those observed in the case of Seattle HPFH. However, a severe beta o-thalassemia case from Algeria (mutation in IVS1 nt1 position), also homozygous for haplotype III, revealed the same nucleotide variation, albeit an inefficient HbF production. We conclude that the variations in the A gamma enhancer element do not play a role in the regulation of HbF production. To assess both the linkage of these sites with the beta-cluster haplotype and the extent of the polymorphism, we examined several black and Mediterranean chromosomes, by PCR amplification followed by both EspI digestion and oligonucleotide hybridization. Our data indicate that these sequence variations in the enhancer element are absent in Mediterranean haplotypes I, V, and VII but are consistently associated with Mediterranean haplotypes II, III, and IX, as well as with the black beta c-associated haplotype. The common feature of all the latter haplotypes is the presence of a polymorphic PvuII site between A gamma and psi beta, which is thus in linkage disequilibrium with the variations in the A gamma enhancer.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cystic fibrosis gene mutations and linked RFLPs in the Slovenian population.

The authors used polymerase chain reaction to analyse 56 Slovenian cystic fibrosis (CF) chromosomes for the presence of delta F508 and eight other most frequent mutations located in exons 7,11 and 20 (R347P, R334W, G551D, R553X, S549RA, S549RT, S549I and S1255X) of the CF gene. We also determined the frequency of haplotypes associated with CF for six linked RFLP markers (MetD/TaqI, MetH/TaqI, XV-2c/TaqI, KM-19/PstI, MP6d9/MspI and J3.11/MspI) in 27 Slovenian CF families. delta F508 mutation was present in 55.4 percent of the CF chromosomes. No case of the other mutations were detected in the sample of tested CF chromosomes. A very high degree of association (0.88) has been found between DNA marker MetH and CF (as measured by the Yule's association coefficient) in our population. Using the RFLP markers XV-2c and KM-19, we found that 85% of delta F508 mutated chromosomes have a single 1 2 (B) haplotype, and that this haplotype is present on only 15.4 percent of CF chromosomes without this deletion.     

Nucleotide sequence of the Belgian G gamma+(A gamma delta beta)0-thalassemia deletion breakpoint suggests a common mechanism for a number of such recombination events

Various types of thalassemia or hereditary persistence of fetal hemoglobin (HPFH) are caused by deletions at the human beta-globin gene cluster. Many of these molecular lesions show a clear clustering as far as size and location of their breakpoints are concerned. This might indicate common recombination mechanisms responsible for the generation of these deletions. The Belgian G gamma+(A gamma delta beta)zero-thalassemia results from a large deletion spanning the beta-globin gene cluster 3' of the A gamma gene. The extent of this deletion, analyzed by field-inversion gel electrophoresis, is approximately 50 kb and is very similar to that of the Indian HPFH (G gamma A gamma HPFH III) previously characterized by P. S. Henthorn et al. (1986). Proc. Natl. Acad. Sci. USA 83: 5194-5198. Isolation of the deletion junction of the Belgian G gamma+(A gamma delta beta)zero-thalassemia by means of inverse polymerase chain reaction confirmed a very close relationship between these two independent deletions. The 3' breakpoint of the Belgian deletion is located at the midpoint of a 160-bp palindrome, only four nucleotides 5' from the correspondent endpoint of the Indian HPFH.     

Y chromosomes traveling south: the cohen modal haplotype and the origins of the Lemba--the "Black Jews of Southern Africa"

The Lemba are a traditionally endogamous group speaking a variety of Bantu languages who live in a number of locations in southern Africa. They claim descent from Jews who came to Africa from "Sena." "Sena" is variously identified by them as Sanaa in Yemen, Judea, Egypt, or Ethiopia. A previous study using Y-chromosome markers suggested both a Bantu and a Semitic contribution to the Lemba gene pool, a suggestion that is not inconsistent with Lemba oral tradition. To provide a more detailed picture of the Lemba paternal genetic heritage, we analyzed 399 Y chromosomes for six microsatellites and six biallelic markers in six populations (Lemba, Bantu, Yemeni-Hadramaut, Yemeni-Sena, Sephardic Jews, and Ashkenazic Jews). The high resolution afforded by the markers shows that Lemba Y chromosomes are clearly divided into Semitic and Bantu clades. Interestingly, one of the Lemba clans carries, at a very high frequency, a particular Y-chromosome type termed the "Cohen modal haplotype," which is known to be characteristic of the paternally inherited Jewish priesthood and is thought, more generally, to be a potential signature haplotype of Judaic origin. The Bantu Y-chromosome samples are predominantly (>80%) YAP+ and include a modal haplotype at high frequency. Assuming a rapid expansion of the eastern Bantu, we used variation in microsatellite alleles in YAP+ sY81-G Bantu Y chromosomes to calculate a rough date, 3,000-5,000 years before the present, for the start of their expansion.     

Evolution of the mouse beta-globin genes: a recent gene conversion in the Hbbs haplotype

We have determined the complete nucleotide sequence of the two nonallelic adult beta-globin genes of the C57BL/10 mouse. These genes, designated beta s and beta t, show a sequence similarity of 99.6% over the region bordered by the translational start and stop codons. Both beta s and beta t encode functional polypeptide chains that are identical. A comparison of the C57BL/10 beta-globin haplotype, Hbbs, with that of the BALB/c mouse, Hbbd, suggests that the two haplotypes have distinct evolutionary histories. The two adult beta-globin genes of the Hbbd haplotype, beta dmaj and beta dmin, are 16% divergent at the nucleotide level and encode distinct polypeptides that are synthesized in differing amounts. Our analysis indicates that a gene correction mechanism has been operating on the Hbbs chromosome to keep beta s and beta t evolving in concert, whereas on the Hbbd chromosome, beta dmin has diverged considerably from beta dmaj. We suggest that gene conversion is responsible for the maintained similarity of the Hbbs genes. Furthermore, we attribute the divergence of the Hbbd genes in part to the absence of a region of simple-sequence DNA within the large intervening sequence of beta dmin. We propose that this region of DNA plays a role in facilitating gene conversion. The deletion of this area in beta dmin introduced a block of nonhomology between the beta dmaj-beta dmin gene pair and thus may have inhibited further gene correction within the Hbbd haplotype.      

Chromosomal localization of the genes encoding two forms of the G protein beta polypeptide, beta 1 and beta 3, in man

The signal-transducing G proteins are heterotrimers composed of three subunits, alpha, beta, and gamma. Multiple distinctive forms of the alpha, beta, and gamma subunits, each encoded by a distinct gene, have been described. To investigate further the structural diversity of the beta subunits, we recently cloned and characterized a novel cDNA encoding a third form of the G protein beta subunit, which we have termed beta 3. The protein corresponding to beta 3 has not yet been identified. The three forms of the beta subunit show 81-90% amino acid sequence identity. Previous studies had localized the human genes for the beta 1 and beta 2 subunits to chromosomes 1 and 7, respectively. The present studies were designed to determine whether the gene encoding beta 3 is linked to either the beta 1 or the beta 2 gene. Genomic DNA was isolated from a panel of rodent-human hybrid cell lines and analyzed by hybridization to cDNAs for beta 1 and beta 3. Discordancy analysis allowed assignment of the beta 3 gene to chromosome 12 and confirmed the previous assignment of the beta 1 gene to chromosome 1. These results were confirmed and extended by using in situ chromosome hybridization, which permitted the regional localization of the beta 1 gene to 1pter----p31.2 and the beta 3 gene to 12pter----p12.3. Digestion of human genomic DNA with 10 restriction enzymes failed to disclose a restriction fragment length polymorphism for the beta 3 gene. These data indicate that there is considerable diversity in the genomic organization of the beta subunit family.     

G gamma and A gamma globin genes are identical from -471 of the promoter midway through gamma IVSII in a Benin beta s haplotype associated with elevated fetal hemoglobin.

In seven kindreds in which sickle cell (SS) patients had elevated (greater than 12%) fetal hemoglobin (Hb F), Milner and colleagues reported that a determinant for elevated Hb F and elevated F cells was linked to the beta s gene. Independently, the Senegal (SEN) beta s haplotype has been found in association with elevated Hb F in SS and beta-thalassemia patients. We have used the kindreds of Milner and colleagues to characterize further the association of haplotype and gamma gene DNA sequence variation with Hb F expression. For the largest kindred, Wi, all four SS had high (greater than 14%) Hb F and both SEN and Benin (BEN) haplotypes. Two AS cases carrying SEN had low Hb F and low F cells, while three AS and one CS carrying BEN had elevated Hb F and elevated F cells; only one AS carrying BEN had low Hb F and low F cells. In order to look for genetic alterations that could account for the elevated Hb F of kindred Wi, we sequenced both the G gamma and A gamma genes of the Wi BEN haplotype. The data showed largely identical G gamma and A gamma genes which may have been generated by two gene conversions: the A gamma promoter was like that of G gamma 3' to -471, while the G gamma IVSII was like that of A gamma in its 5' half. In addition, three new mutations were found in gamma IVSII.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular Analysis of the β-Globin Gene Cluster in the Niokholo Mandenka Population Reveals a Recent Origin of the βS Senegal Mutation

A large and ethnically well-defined Mandenka sample from eastern Senegal was analyzed for the polymorphism of the beta-globin gene cluster on chromosome 11. Five RFLP sites of the 5' region were investigated in 193 individuals revealing the presence of 10 different haplotypes. The frequency of the sickle-cell anemia causing mutation (beta(S)) in the Mandenka estimated from this sample is 11.7%. This mutation was found strictly associated with the single Senegal haplotype. Approximately 600 bp of the upstream region of the beta-globin gene were sequenced for a subset of 94 chromosomes, showing the presence of four transversions, five transitions, and a composite microsatellite polymorphism. The sequence of 22 beta(S) chromosomes was also identical to the previously defined Senegal haplotype, suggesting that this mutation is very recent. Monte Carlo simulations (allowing for a specific balancing selection model, a logistic growth of the population, and variable initial frequencies of the Senegal haplotype) were used to estimate the age of the beta(S) mutation. Resulting maximum-likelihood estimates are 45-70 generations (1,350-2,100 years) for very different demographic scenarios. Smallest confidence intervals (25-690 generations) are obtained under the hypothesis that the Mandenka population is large (N(e) >5,000) and stationary or that it has undergone a rapid demographic expansion to a current size of >5,000 reproducing individuals, which is quite likely in view of the great diversity found on beta(A) chromosomes.