Genetic influences on F cells and other hematologic variables: a twin heritability study

Blood online

SEARCH:

Advanced

This Article

Abstract

Full Text (PDF)

Alert me when this article is cited

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Rights and Permissions

Citing Articles

Citing Articles via HighWire

Citing Articles via CrossRef

Citing Articles via Google Scholar

Google Scholar

Articles by Garner, C.

Articles by Thein, S. L.

Search for Related Content

PubMed

PubMed Citation

Articles by Garner, C.

Articles by Thein, S. L.

Related Collections

Red Cells

Social Bookmarking


What's this?

Previous Article  |  Table of Contents  |  Next Article

Blood, Vol. 95 No. 1 (January 1), 2000: pp. 342-346
RED CELLS

Genetic influences on F cells and other hematologic variables: a twin heritability study

C. Garner, T. Tatu, J. E. Reittie, T. Littlewood, J. Darley, S. Cervino, M. Farrall, P. Kelly, T. D. Spector, and S. L. Thein
From the Wellcome Trust Centre for Human Genetics, Oxford; Medical Research Council (MRC) Molecular Hematology Unit, Institute of Molecular Medicine, John Radcliffe Hospital, Headington, Oxford; Hematology Department, John Radcliffe Hospital, Headington, Oxford; Gemini Holdings PLC, Cambridge; and the Twin Research & Genetic Epidemiology Unit, St Thomas' Hospital, London, United Kingdom.

  Abstract

Top
Abstract
Introduction
Subjects and methods
Results
Discussion
Appendix
References

To assess the relative contribution of genetic factors in the variation of F cells (FC) and other hematologic variables, weconducted a classical twin study in unselected twins. The sampleincluded 264 identical (monozygotic [MZ]) twin pairs and 511 nonidentical(dizygotic [DZ]) same-sex twin pairs (aged 20 to 80 years) fromthe St. Thomas' UK Adult Twin Register. The FC values were distributedcontinuously and positively skewed, with values ranging from 0.6%to 22%. FC values were higher in women than in men and decreasedwith age, with the variables accounting for 2% of the total FCvariance. The intraclass correlations of FC values were higherin MZ (rMZ = 0.89) than in DZ (rDZ = 0.49) twins. The XmnI-^G $gamma$ polymorphism in the $beta$ -globin gene cluster had a significanteffect on FC levels, accounting for approximately 13% of the totalFC variance. Variance components analysis showed that the FC valueswere accounted for predominantly by additive genetic and nonsharedenvironmental influences, with an estimate of heritability of0.89. Hemoglobin levels and red blood cell, white blood cell,and platelet numbers were also substantially heritable, with heritabilityestimates of 0.37, 0.42, 0.62, and 0.57,respectively.
Previously, studies of sib pairs with sickle cell disease and isolated family studies showed that high levels of Hb F andFC tend to be inherited. Here, our classical twin study demonstratedthat the variance of FC levels in healthy adults is largely geneticallydetermined. (Blood. 2000;95:342-346)

© 2000 by The American Society of Hematology.

  Introduction

Top
Abstract
Introduction
Subjects and methods
Results
Discussion
Appendix
References

The switch from fetal to adult hemoglobin (Hb) synthesis that occurs just before birth is not complete in that it does notlead to a total extinction of fetal hemoglobin (Hb F) in adultlife.¹ The small amounts of Hb F are not homogeneously distributedbut are restricted to a subset of erythrocytes termed F cells(FC),² and generally there is good correlation between theproportions of Hb F and FC.³ Hb F and FC values in healthyadults vary considerably, with a continuous distribution thatis substantially positively skewed.^3-7 The high values of HbF and FC at the upper limits of the population range are transmittedin the condition referred to as heterocellular hereditary persistenceof fetal hemoglobin (HPFH), or Swiss HPFH, which should be regardedas a multifactorial quantitative trait, quite distinct from thepancellular HPFHs that are caused by point mutations in the promotersof the $gamma$ -globin genes or deletions of the $beta$ -globin gene complex.¹Although family studies have shown that high levels of Hb F andFC tend to be inherited, the number of genetic factors involvedand the mode of inheritance remainuncertain.

Several factors have been shown to influence Hb F and FC levels in healthy adults, including age,⁵ sex,³^,⁵ and geneticvariants linked^7-9 and unlinked to the $beta$ -globin locus on chromosome11p.⁸^,¹⁰ Two trans-acting quantitative trait loci (QTLs) forFC variance have been mapped, one on chromosome 6q in an extensivekindred with heterocellular HPFH and $beta$ thalassemia¹¹ and theother on Xp in families with sickle cell disease.¹² Recently,studies in a large English family indicated the presence of atleast one other trans-acting QTL associated with Hb F and FC variance.¹³It is clear from the isolated family studies that there are severalsuch QTLs for Hb F and FC, but their frequency in the generalpopulation and their contribution to the FC variance are notapparent.

To address this issue, we undertook a classical twin study. The aim of this study was to explore the role of genetic influenceson the variance of FC values in healthy adults, in parallel withother hematologic variables, in a sample population of unselectedtwin pairs. Percentages of FC rather than Hb F were used as thevariable for study because measurement of FC by immunofluorescenceusing an anti- $gamma$ -globin chain antibody is more sensitive and reproduciblethan currently available techniques for measuring the low-rangeHb F levels in individuals with heterocellularHPFH.

  Subjects and methods

Top
Abstract
Introduction
Subjects and methods
Results
Discussion
Appendix
References

Subjects
Seven hundred seventy-five pairs of twins aged 20-80 years were recruited from the St Thomas' UK Adult Twin Register,¹⁴which is a large cohort of volunteer twins unselected for anyparticular disease or trait. The study population consisted of264 (27 male and 237 female) monozygotic (MZ) twin pairs and 511(40 male and 471 female) dizygotic (DZ) same-sex twin pairs. Allsubjects were of European descent, and both members of a pairattended the clinic on the same day. Informed consent was obtainedin all cases before the collection of blood samples. Zygositywas determined by a standard questionnaire¹⁵ and confirmed bymultiplex DNA analysis of highly polymorphic short tandem repeats(microsatellites). Genotyping and phenotyping were carried outby evaluators blinded to the zygosity of the subjects from whomthe samples wereobtained.

Hematologic studies. Blood samples were collected in EDTA as anticoagulant. Hb level, red blood cell (RBC) counts, mean red blood cell volume (MCV),white blood cell (WBC) counts, and platelet counts were determinedwith an automated blood cell analyzer (Bayer H3 RTX, Newbury,UK). From these measurements, the instrument then derived thevalues for hematocrit (packed-cell volume [PCV]), mean red bloodcell hemoglobin (mean corpuscular hemoglobin [MCH]), and meanred blood cell hemoglobin (mean corpuscular hemoglobin concentration[MCHC]).

FC assays were performed in peripheral blood by using a monoclonal mouse anti- $gamma$ -globin chain antibody and fluorescence-activatedcell sorting (10⁴ cells counted per assay) in all cases.¹⁶ In a proportion ofthe samples, FC measurements were counterchecked by using thesame anti- $gamma$ -globin chain antibody and microscopy (2 × 10³ RBCs were counted).¹⁷ Hb F levels were also estimated in allsamples with use of an automated high-performance liquid chromatographysystem (Bio-Rad Variant, $beta$ Thalassemia Short Program, Hercules,CA).

DNA analysis. DNA was extracted from peripheral blood leukocytes by using standard procedures. The polymerase chain reaction (PCR) was usedto specifically amplify the 5' region of the ^G $gamma$ -globin gene and the T-C polymorphism at position $-$ 158 of the^G $gamma$ -globin gene, determined by XmnI restriction analysis of thePCR product.¹⁸ Similarly, PCR was used to specifically amplifythe ^A $gamma$ -globin promoter region, and the sequence variant due to a 4-bpdeletion at positions $-$ 221 to $-$ 224 relative to the messenger RNAcap site was detected by Fnu4HI restriction analysis of the PCRproduct.¹⁸

Statistical analysis
Because MZ twins share all their genes, any intrapair variation is due to environmental factors (both shared and unique).However, for DZ twins, who share on average half of their genes,any intrapair variation is due to both environmental and geneticfactors. Thus, a comparison between the similarity of values inMZ and DZ twins allows estimation of the extent to which geneticfactors determine variation in a quantitativetrait.

One member of each twin pair was chosen at random for testing the effects of age, sex, and the XmnI-^G $gamma$ and ^A $gamma$ 4-bp genotypes. A t test was used to test for differences betweenmen and women in the means of the variables. The equality of variancesbetween the sexes was tested with an F statistic. The effectsof age and the XmnI-^G $gamma$ and ^A $gamma$ 4-bp genotypes on the variables were tested with Pearson correlationcoefficients and linear regression. All the above statisticalanalyses were done with Statistical Analysis Software.¹⁹ Thedistributions of the variables were tested for deviations fromnormal by using the Shapiro-Wilk statistic; values for MCV, MCH,and MCHC were squared and the natural logarithm of the FC levelswas used to improve the fit to the normaldistribution.

A classical twin variance components analysis²⁰ (Appendix) was carried out by using structural equation modeling with theMx package.²¹ Each model (ACE, ADE, AE, and CE in Appendix) wastested for how well it fit the twin data by a $chi$ ² goodness-of-fit statistic, with a smaller $chi$ ² indicating a better fit. The number of degrees of freedom foreach model was the difference between the number of parametersestimated by the model and the number of statistics in the model.In cases in which more than one model could not be rejected bythe goodness-of-fit test, $chi$ ² likelihood ratio tests were done to determine which model fitthe data better; generally, a full model (ACE or ADE) was comparedwith a simpler model (AE or CE). The $chi$ ² likelihood ratio test takes the difference between the $chi$ ² goodness-of-fit statistics of the simpler model and the fullmodel, with the number of degrees of freedom equal to the differencein the number of parameters between the 2 models. The full modelis rejected in favor of the simpler model if the $chi$ ² yields a significance level > 0.05. The simplest model that cannotbe rejected by the goodness-of-fit or the likelihood ratio testis the most parsimonious model, and maximum likelihood estimatesof the parameters arecalculated.

  Results

Top
Abstract
Introduction
Subjects and methods
Results
Discussion
Appendix
References

A total of 775 twin pairs aged 20-80 years were recruited. Table 1 shows the values for FC and the other hematologic variablesmeasured by the cell analyzer. There were no significant differencesbetween the MZ and DZ twins within each sex in the mean levelsor variances of the variables.


View this table:
[in this window]
[in a new window]
Table 1. Hematologic variables before statistical transformation, according to sex and zygosity

Hematologic variables and the effects of the covariates
Table 2 shows the t statistics and the Pearson correlation coefficients (r) between the hematologic variables and age andsex that were significant at the P < 0.05 level, as well as thepercentage of variance attributed to the covariates calculatedas the total coefficient of determination (R²). A positive t statistic indicates a higher mean in men, anda positive r indicates an increase with age. FC levels were, onaverage, higher in women than in men (t = $-$ 2.57, P = .01) andhad a negative correlation with age (r = $-$ .12, P < .001), withthe variables accounting for only 2% of the total FC variance.Men had significantly higher Hb, PCV, and RBC levels than women,with age and sex accounting for 24%, 18%, and 18%, respectively,of the total variance in the variables. Hb, MCH, and MCHC levelsincreased with age; however, age accounted for only 1% of thevariance in each instance. Women had a significantly higher meanvalue for platelets; however, the effect accounted for only 1%of the variance in the variable.


View this table:
[in this window]
[in a new window]
Table 2. Effects of age and sex on hematologic traits

The effects of the XmnI-^G $gamma$ and ^A $gamma$ 4-bp genotypes on the variables were estimated by linear regression analysis. FC level wasthe only variable that had a significant relation with the $beta$ -globincomplex sites. The XmnI-^G $gamma$ polymorphism had a much larger effect than the ^A $gamma$ 4-bp site (R² = 0.13 compared with R² = 0.03), indicating that it was more strongly associated withthe high-FCtrait.

Variance components analysis
The number of twin pairs used in the variance components analysis of each standardized variable and the Pearson correlationcoefficientscalculated for MZ and DZ twin pairs are shown in Table3. Although there was a difference between men and women in themeans for 5 of the variables, an F test for the equality of thevariances showed that there was not a significant difference betweenmen and women in the variance for any of the variables (resultsnot shown). Therefore, the male and female twins were treatedas a single group for each zygosity class. The intraclass correlationfor MZ twins greatly exceeded that for DZ twins for all the measuredvariables (FC, Hb, RBCs, MCV, WBCs, and platelets), with the rangeof intraclass correlations for MZ twins being 0.61 to 0.89 andthat for DZ twins being 0.36 to 0.53.


View this table:
[in this window]
[in a new window]
Table 3. Pearson correlation coefficients between monozygotic (MZ) and dizygotic (DZ) twin pairs for standardized hematologic traits, calculated with variance components analysis

Results of the variance components analysis are shown in Table 4. $chi$ ² goodness-of-fit statistics and the corresponding significancelevels are given for each model tested. The model with a dominancegenetic variance component and the model of no family resemblance,E, were rejected for all variables. The most parsimonious model(ie, the simplest model that cannot be rejected) for each variableis shown. All the variables except MCHC had best-fitting modelswith an additive variance component (ie, AE or ACE). The maximumlikelihood estimates (h², c², and e²) for each variableunder the best-fitting model are also shown in Table 4. Heritability(h²) estimates between 0.20 and 0.42 were found for Hb, PCV,RBCs, MCV, and MCH. These variables had estimates of the commonand specific environmental effects in a similar range, and allfit the full ACE model best. There was no significant additivegenetic effect for MCHC ( $chi$ ² likelihood ratio = 1.288-0.258 = 1.03, 1 df); the family resemblancewas explained entirely by common and specific environment (CEmodel). The highest heritability estimates were found for FC values,WBC counts, and platelet counts (0.89, 0.62, and 0.57, respectively).A common environmental effect could be rejected for FC ( $chi$ ² likelihood ratio = 6.409-4.825 = 1.584, 1 df) and WBCs ( $chi$ ² likelihood ratio = 2.303-0.885 = 1.48, 1 df) so that, for FCand WBCs, the best models included additive genetic and specificenvironmental effects only (ie, the AE model). It should be notedthat the power to exclude the C or D components of variance isweak in this structural equation modeling method.²² The varianceof platelet numbers fit the ACE model best. Of all the hematologicvariables, FC had the highest heritability estimate (0.89).


View this table:
[in this window]
[in a new window]
Table 4. Results of the variance components analysis

  Discussion

Top
Abstract
Introduction
Subjects and methods
Results
Discussion
Appendix
References

It has long been suspected that the values of Hb F and FC in healthy adults are genetically influenced. The evidence, however,was circumstantial and based on population and family studiesshowing that individuals with Hb F and FC levels at the upperlimits of the population range, who are considered to have heterocellularHPFH, tend to have at least one parent with similarly increasedHb F (or FC levels).⁴^,^23-26 Hence, there has been a tendencyto regard heterocellular HPFHs as discrete variables controlledby single genes. We would like to make the case for consideringHb F or FC levels a quantitative trait, with heterocellular HPFHrepresenting the upper tail of the trait distribution. The numberof QTLs contributing to the trait remains to bedetermined.

To explore the role and extent of genetic factors in controlling FC levels, we analyzed FC variance in a sample of unselectedMZ and DZ twin pairs of European descent. Our findings provideoverwhelming evidence for a strong genetic component in the controlof Hb F and FC in healthy adults. FC levels were consistentlymore similar in identical twins (rMZ = 0.89) than in nonidenticaltwins (rDZ = 0.49), and 89% of the FC variance could be attributedto geneticfactors.

Many genetic variants have been associated with elevated FC levels in healthy adults, including several in the $beta$ -globin genecomplex-XmnI-^G $gamma$ site,⁷^,²⁷ the 4-bp deletion at positions $-$ 224 to $-$ 221 ofthe ^A $gamma$ -globin gene,²⁸^,²⁹ sequence variations in the DNase 1 hypersensitivesite 2 of the $beta$ -locus control region,³⁰^,³¹ and several variantsunlinked to the $beta$ complex, such as the QTLs on Xp¹² and 6q.¹¹In this study, the effects of the XmnI-^G $gamma$ site and ^A $gamma$ 4-bp deletion were estimated for all the hematologic variables.FC level was the only variable that had a significant relationwith the $beta$ -globin complex sites. Our data confirm previous reportsof the effects of age and sex on FC: levels were higher in womenand decreased with age, and age and sex combined accounted for2% of the total FC variance. Regression analysis indicated thatonly 13% of the total FC variation could be attributed to theXmnI-^G $gamma$ site, thereby implicating the presence of one or more otherQTLs controlling FC levels in adults. These data should be relevantto the variation in Hb F levels observed in patients with $beta$ thalassemiaand sickle cell disease who have different racial or genetic backgrounds.Inheritance of certain QTLs controlling FC production could alsoexplain the different Hb F response in situations of acute erythroidexpansion, such as in bone marrow regeneration after bone marrowtransplantation,³² in healthy individuals after acute bloodloss,³³ and in patients with severe iron deficiency anemia aftertreatment with iron.³⁴

We also found evidence of a genetic effect on several hematologic variables other than FC levels. Additive genetic effectsaccounted for 37%, 42%, 62%, and 57%, respectively, of the phenotypicvariance in Hb levels, RBC counts, WBC counts, and platelet counts.These results support the data from a previous heritability studythat showed that WBC and platelet numbers were accounted for bygenetic and nonshared environmental influences only.³⁵ Unlikethe previous study, however, our study found that the phenotypicvariance related to the RBC mass (Hb levels, RBC count, and MCV)can be attributed in equal proportions to additive genetic effects(A), shared environment (C), and nonshared environment(E).

A general conclusion that can be drawn from this study is that variation in the proportions of FC, WBC numbers, and plateletnumbers and, to some extent, RBC numbers, is largely geneticallydetermined. The aim now must be to determine the combination ofcommon genes that pleiotropically influence the variance of thesetraits. Previous sib-pair analyses of patients with sickle cellanemia demonstrated the presence of genetic factors controllingthe production of FC, both linked and unlinked to the $beta$ -globincluster.³⁶^,³⁷ A more recent study of Jamaican sickle cell sibpairs estimated that the locus on Xp, the $beta$ -globin cluster, the $alpha$ -globin genes, and age accounted for about 50% of the Hb F variationobserved in these subjects, with the Xp locus being the majorcontributor (35% to 41% of the variation). Nonetheless, about50% of the variance in Hb F levels in the subjects remained unexplained.³⁸We propose using data from the DZ twins in a genome scan to mapfor the principal QTLs influencing these traits and to test thetrans-acting factors that have been reported on chromosomes 6q23¹¹and Xp22.2-22.3.¹² DZ twins have several advantages over ordinarysib pairs: the confounding effect of age is removed, common environmentis likely to be more similar, and nonpaternity is less of a problem.In this study, the confounding effect of sex was removed becauseonly same-sex DZ twins were recruited and, with respect to FC,the presence of hemoglobinopathies was not aconfounder.

QTLs that are candidates for influencing the hematologic variables we studied include a combination of the numerous hemopoieticgrowth factors and lineage-specific cytokines, such as thrombopoietin,thrombopoietin receptor, erythropoietin, various colony-stimulatingfactors (CSF) (granulocyte-macrophage CSF and granulocyte CSF),interleukins (IL-3 and IL-6), and negative regulators such astransforming growth factor $beta$ 1.³⁹^,⁴⁰ The results of analysesof these influences will have immense practical implications inmedicine. For example, an understanding of the role and extentof the genetic factors responsible for increased Hb F and FC levelswould not only provide further insights into the normal developmentalcontrol of Hb F production in general, but could also pave theway to innovative approaches for therapeutic manipulations ofHb F in the treatment of sickle cell disease and $beta$ thalassemia.

View larger version (16K):
[in this window]
[in a new window]
Classic path model for analyzing a sample of monozygotic (MZ) and dizygotic (DZ) twins. The single-headed arrows (h, c, d, e) reflect the additive genetic (A), dominance genetic (D), common environmental (C), and specific environmental (E) effects on the phenotypes of twins (P_T1 and P_T2). The double-headed arrows across the top show the expected relations among the additive genetic, dominance genetic, and common environmental effects for MZ and DZ twins.

  APPENDIX

Top
Abstract
Introduction
Subjects and methods
Results
Discussion
Appendix
References

Classical variance component twin analysis using the Mx package
Under the models tested, the phenotypic variance can be partitioned into (A) the additive genetic effects or heritability,(D) dominance genetic effects, (C) the common or shared environment,and (E) the specific environment with the expected relations indicatedin the Appendix Figure. The following 5 models were tested: (1)family resemblance due to additive genetic and common environmentaleffects (the ACE model); (2) family resemblance due to additiveand dominance genetic effects (the ADE model); (3) family resemblancedue to additive genetic effects alone (the AE model); (4) familyresemblance due to common environmental effects alone (the CEmodel); and (5) no family resemblance (the Emodel).
The parameters D and C are confounded in that the dominance effects cause twins to be less similar and common environmentaleffects cause twins to be more similar; therefore, a model withboth these parameters is not possible. $chi$ ² goodness-of-fit statistics were calculated for each model, andthe most parsimonious model was determined by a $chi$ ² likelihood ratio test with degrees of freedom equal to the differencein the number of parameters estimated by the 2 models. The maximumlikelihood estimates of the parameters under the most parsimoniousmodel arereported.

  Acknowledgments

We thank Milly Graver and Liz Rose for preparation of the manuscript and Professor Sir David Weatherall for his continuingencouragement and support. We thank Professor Peter Beverley forallowing us to use the anti- $gamma$ -globinantibody.

  Footnotes

Submitted April 19, 1999; accepted September 2, 1999.

Supported by the Medical Research Council, United Kingdom. St Thomas' UK Adult Twin Registry is supported in part by grantsfrom the Arthritis ResearchCampaign, the Wellcome Trust, the MRC,the Chronic Disease Research Foundation, and Gemini HoldingsPLC.

Reprints: S. L. Thein, MRC Molecular Hematology Unit, Institute of Molecular Medicine, John Radcliffe Hospital, Headington,Oxford, OX3 9DS, UK; e-mail: swee.thein{at}imm.ox.ac.uk.

The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate thisfact, this article is hereby marked "advertisement" in accordancewith 18 U.S.C. section 1734.

  References

Top
Abstract
Introduction
Subjects and methods
Results
Discussion
Appendix
References

1. Stamatoyannopoulos G, Nienhuis AW, Majerus PW, Varmus E. The Molecular Basis of Blood Diseases. Philadelphia, PA: WB Saunders; 1994.
2. Boyer SH, Belding TK, Margolet L, Noyes AN. Fetal hemoglobin restriction to a few erythrocytes (F cells) in normal human adults. Science. 1975;188:361-363[Abstract/Free Full Text].
3. Miyoshi K, Kaneto Y, Kawai H, et al. X-linked dominant control of F-cells in normal adult life: characterization of the Swiss type as hereditary persistence of fetal hemoglobin regulated dominantly by gene(s) on X chromosome. Blood. 1988;72:1854-1860[Abstract/Free Full Text].
4. Zago MA, Wood WG, Clegg JB, Weatherall DJ, O'Sullivan M, Gunson H. Genetic control of F cells in human adults. Blood. 1979;53:977-986[Abstract/Free Full Text].
5. Rutland PC, Pembrey ME, Davies T. The estimation of fetal haemoglobin in healthy adults by radioimmunoassay. Br J Haematol. 1983;53:673-682[Medline] [Order article via Infotrieve].
6. Economou EP, Antonarakis SE, Kazazian HH Jr, Serjeant GR, Dover GJ. Variation in hemoglobin F production among normal and sickle cell adults is not related to nucleotide substitutions in the gamma promoter regions. Blood. 1991;77:174-177[Abstract/Free Full Text].
7. Sampietro M, Thein SL, Contreras M, Pazmany L. Variation of HbF and F-cell number with the ^G $gamma$ XmnI (C-T) polymorphism in normal individuals. Blood. 1992;79:832-833[Free Full Text].
8. Lu Z-H, Steinberg MH. Fetal hemoglobin in sickle cell anemia: relation to regulatory sequences cis to the $beta$ -globin gene. Blood. 1996;87:1604-1611[Abstract/Free Full Text].
9. Merghoub T, Maier-Redelsperger M, Labie D, et al. Variation of fetal hemoglobin and F-cell number with the LCR-HS2 polymorphism in nonanemic individuals. Blood. 1996;87:2607[Free Full Text].
10. Thein SL, Sampietro M, Rohde K, et al. Detection of a major gene for heterocellular hereditary persistence of fetal hemoglobin after accounting for genetic modifiers. Am J Hum Genet. 1994;54:214-228[Medline] [Order article via Infotrieve].
11. Craig JE, Rochette J, Fisher CA, et al. Dissecting the loci controlling fetal haemoglobin production on chromosomes 11p and 6q by the regressive approach. Nat Genet. 1996;12:58-64[Medline] [Order article via Infotrieve].
12. Dover GJ, Smith KD, Chang YC, et al. Fetal hemoglobin levels in sickle cell disease and normal individuals are partially controlled by an X-linked gene located at Xp22.2. Blood. 1992;80:816-824[Abstract/Free Full Text].
13. Craig JE, Rochette J, Sampietro M, et al. Genetic heterogeneity in heterocellular hereditary persistence of fetal hemoglobin. Blood. 1997;90:428-434[Abstract/Free Full Text].
14. Spector TD, Cicuttini F, Baker J, Loughlin J, Hart D. Genetic influences on osteoarthritis in women: a twin study. BMJ. 1996;312:940-943[Abstract/Free Full Text].
15. Martin NG, Martin PG. The inheritance of scholastic abilities in a sample of twins. I. Ascertainments of the sample and diagnosis of zygosity. Ann Hum Genet. 1975;39:213-218[Medline] [Order article via Infotrieve].
16. Thorpe SJ, Thein SL, Sampietro M, Craig JE, Mahon B, Huehns ER. Immunochemical estimation of haemoglobin types in red blood cells by FACS analysis. Br J Haematol. 1994;87:125-132[Medline] [Order article via Infotrieve].
17. Thein SL, Reittie JE. F cells by immunofluorescent staining of erythrocyte smears. Hemoglobin. 1998;22:415-417[Medline] [Order article via Infotrieve].
18. Craig JE, Sheerin SM, Barnetson R, Thein SL. The molecular basis of HPFH in a British family identified by heteroduplex formation. Br J Haematol. 1993;84:106-110[Medline] [Order article via Infotrieve].
19. SAS: Statistical Analysis Software [computer program]. Version 6. Cary, NC: SAS Institute Inc; 1997.
20. Neale MC, Cardon LR. Methodology for Genetic Studies of Twins and Families. Boston, MA: Kluwer Academic Publishers; 1992.
21. Mx: Statistical Modeling [computer program]. Richmond: VA; 1997.
22. Hopper JL. Why "common environmental effects" are so uncommon in the literature. In: Spector TD,Snieder H,MacGregor AJ, eds. Advances in twin and sibling analysis. London, UK: Grenwich Medical Media; 1999:151-166.
23. Marti HR. Normale und anormale mensliche Haemoglobine. Berlin, Germany: Springer; 1963.
24. Stamatoyannopoulos G, Wood WG, Papayannopoulou T. A new form of hereditary persistence of fetal hemoglobin in blacks and its association with sickle cell trait. Blood. 1975;46:683-692[Abstract/Free Full Text].
25. Gianni AM, Bregni M, Cappellini MD, et al. A gene controlling fetal hemoglobin expression in adults is not linked to the non- $alpha$ globin cluster. EMBO J. 1983;2:921-925[Medline] [Order article via Infotrieve].
26. Giampaolo A, Mavilio F, Sposi NM, et al. Heterocellular hereditary persistence of fetal hemoglobin (HPFH). Molecular mechanisms of abnormal $gamma$ -gene expression in association with $beta$ thalassemia and linkage relationship with the $beta$ -globin gene cluster. Hum Genet. 1984;66:151-156[Medline] [Order article via Infotrieve].
27. Gilman JG, Huisman TH. DNA sequence variation associated with elevated fetal ^G $gamma$ globin production. Blood. 1985;66:783-787[Abstract/Free Full Text].
28. Gilman JG, Johnson ME, Mishima N. Four base-pair DNA deletion in human ^A $gamma$ globin-gene promoter associated with low ^A $gamma$ expression in adults. Br J Haematol. 1988;68:455-458[Medline] [Order article via Infotrieve].
29. Manca L, Cocco E, Gallisai D, Masala B, Gilman JG. Diminished ^A $gamma$ ^T fetal globin levels in Sardinian haplotype II $beta$ ^o-thalassaemia patients are associated with a four base pair deletion in the ^A $gamma$ ^T promoter. Br J Haematol. 1991;78:105-107[Medline] [Order article via Infotrieve].
30. Merghoub T, Perichon B, Maier-Redelsperger M, et al. Dissection of the association status of two polymorphisms in the $beta$ -globin gene cluster with variations in F-cell number in non-anemic individuals. Am J Hematol. 1997;56:239-243[Medline] [Order article via Infotrieve].
31. Öner C, Dimovski AJ, Altay C, et al. Sequence variations in the 5' hypersensitive site-2 of the locus control region of $beta$ ^s chromosomes are associated with different levels of fetal globin in hemoglobin S homozygotes. Blood. 1992;79:813-819[Abstract/Free Full Text].
32. Alter BP, Rappeport JM, Huisman THJ, Schroeder WA, Nathan DG. Fetal erythropoiesis following bone marrow transplantation. Blood. 1976;48:843-853[Abstract/Free Full Text].
33. Papayannopoulou T, Vichinsky E, Stamatoyannopoulous G. Fetal Hb production during acute erythroid expansion. I. Observations in patients with transient erythroblastopenia and post-phlebotomy. Br J Haematol. 1980;44:535-546[Medline] [Order article via Infotrieve].
34. Dover GJ, Boyer SH, Zinkham WH. Production of erythrocytes that contain fetal hemoglobin in anemia. Transient in vivo changes. J Clin Invest. 1979;63:173-176.
35. Whitfield JB, Martin NG. Genetic and environmental influences on the size and number of cells in the blood. Genet Epidemiol. 1985;2:133-144[Medline] [Order article via Infotrieve].
36. Milner PF, Leibfarth JD, Ford J, Barton BP, Grenett HE, Garver FA. Increased HbF in sickle cell anemia is determined by a factor linked to the $beta$ ^s gene from one parent. Blood. 1984;63:64-72[Abstract/Free Full Text].
37. Boyer SH, Dover GJ, Serjeant GR, et al. Production of F cells in sickle cell anemia: regulation by a genetic locus or loci separate from the $beta$ -globin gene cluster. Blood. 1984;64:1053-1058[Abstract/Free Full Text].
38. Chang YC, Smith KD, Moore RD, Serjeant GR, Dover GJ. An analysis of fetal hemoglobin variation in sickle cell disease: the relative contributions of the X-linked factor, $beta$ -globin haplotypes, $alpha$ -globin gene number, gender, and age. Blood. 1995;85:1111-1117[Abstract/Free Full Text].
39. Wendling F, Han Z-C. Positive and negative regulation of megakaryocytopoiesis. Baillieres Clin Haematol. 1997;10:29-45[Medline] [Order article via Infotrieve].
40. Dale DC. Hematopoietic growth factors. Curr Opin Hematol. 1998;5:161-169.

© 2000 by The American Society of Hematology.

Add to CiteULike CiteULike    Add to Connotea Connotea    Add to Del.icio.us Del.icio.us    Add to Digg Digg    Add to Reddit Reddit    Add to Technorati Technorati    What's this?

This article has been cited by other articles:

M. Uda, R. Galanello, S. Sanna, G. Lettre, V. G. Sankaran, W. Chen, G. Usala, F. Busonero, A. Maschio, G. Albai, et al.
Genome-wide association study shows BCL11A associated with persistent fetal hemoglobin and amelioration of the phenotype of {beta}-thalassemia
PNAS, February 5, 2008; 105(5): 1620 - 1625.
[Abstract] [Full Text] [PDF]

S. Menzel, J. Jiang, N. Silver, J. Gallagher, J. Cunningham, G. Surdulescu, M. Lathrop, M. Farrall, T. D. Spector, and S. L. Thein
The HBS1L-MYB intergenic region on chromosome 6q23.3 influences erythrocyte, platelet, and monocyte counts in humans
Blood, November 15, 2007; 110(10): 3624 - 3626.
[Abstract] [Full Text] [PDF]

S. L. Thein, S. Menzel, X. Peng, S. Best, J. Jiang, J. Close, N. Silver, A. Gerovasilli, C. Ping, M. Yamaguchi, et al.
Intergenic variants of HBS1L-MYB are responsible for a major quantitative trait locus on chromosome 6q23 influencing fetal hemoglobin levels in adults
PNAS, July 3, 2007; 104(27): 11346 - 11351.
[Abstract] [Full Text] [PDF]

A Iliadou, D M Evans, G Zhu, D L Duffy, I H Frazer, G W Montgomery, and N G Martin
Genomewide scans of red cell indices suggest linkage on chromosome 6q23
J. Med. Genet., January 1, 2007; 44(1): 24 - 30.
[Abstract] [Full Text] [PDF]

J. Jiang, S. Best, S. Menzel, N. Silver, M. I. Lai, G. L. Surdulescu, T. D. Spector, and S. L. Thein
cMYB is involved in the regulation of fetal hemoglobin production in adults
Blood, August 1, 2006; 108(3): 1077 - 1083.
[Abstract] [Full Text] [PDF]

H-Y Luo, W Tang, S H Eung, J E Coad, P Canfield, F Keller, E H Crowell Jr, M H Steinberg, and D H K Chui
Domina