Isolation and sequence analysis of a hybrid delta-globin pseudogene from the brown lemur

The β-globin gene cluster of the brown lemur, a prosimian, is very short and contains a single ?-, γ- and β-globin gene, with an additional β-related gene sequence between the γ- and β-globin genes. Brown lemur DNA was cloned into the bacteriophage vector λL47.1 and a recombinant was isolated which contained an 11 × 10³ base insert including the β-globin gene and the additional putative β-globin pseudogene. The nucleotide sequence of this β-related gene was completely determined. A complete gene sequence was found, containing four frameshift mutations sufficient to establish its pseudogene status. The gene was interrupted by two intervening sequences with sizes and locations typical of mammalian β-related globin genes. The pseudogene sequence was compared in detail with human ?-, γ-, δ- and β-globin genes. The beginning of the pseudogene, from the 5′ flanking region to the second exon, was homologous to the corresponding regions of the human ?- and γ-globin genes. In contrast, the second intron, third exon and 3′ flanking region showed a remarkably close homology to the δ-globin, but not β-globin, gene of man. This suggests that the δ-globin gene is not the product of a recent gene duplication, but instead is present in most or all primates. This gene has been silenced on at least two separate occasions in primate evolution (in lemurs and in old world monkeys). In addition, the 5′ end of the lemur ψδ gene appears to have exchanged sequences with an ?- or γ-globin gene, and an analogous exchange with the β-globin gene seems to have occurred recently in the human δ-globin gene. The evolution and function of the δ-globin gene are discussed.     

Organization of human δ- and β-globin genes in cellular DNA and the presence of intragenic inserts

We have analyzed human cellular DNA for its δ- and β-globin gene sequence content by separation of restriction enzyme fragments by agarose gel electrophoresis; transfer of the DNA fragments to nitrocellulose filters; hybridization of filters with ³²P-β-globin cDNA; and analysis by autoradiography. A short cDNA has been used to identify specifically the 3′ end of the genes and to orient the fragments. A comparison of the globin gene fragments generated by normal and Lepore DNA has been used to distinguish fragments representing DNA sequences between the δ and β genes and those containing sequences flanking either 5′ to the δ gene or 3′ to the β gene. The results indicate that unique restriction fragments are presented in normal DNA and absent in Lepore DNA, and allow preliminary ordering of these fragments on a restriction enzyme map. In addition, the Lepore, δ- and β-globin genes have been found to contain at least one inserted nucleotide sequence of about 1000 bases which is not represented in mature globin mRNA.     

Evolution of the β-globin gene cluster in man and the primates

The arrangement of primate β-related globin genes has been determined by restriction endonuclease mapping of genomic DNA from species ranging from prosimians to man. The arrangement of the entire ?γγδβ-globin gene cluster in the gorilla and the yellow baboon is indistinguishable from that of man. Restriction site differences between these species are consistent with a surprisingly low overall rate of intergenic DNA sequence divergence of approximately 1% in 5 million years. A new world monkey (owl monkey) has a single γ-globin gene, suggesting that the ^Gγ-^Aγ-globin gene duplication in man is ancient, and occurred about 20 to 40 million years ago. The β-globin gene cluster in the brown lemur, a prosimian, is remarkably short (about 20,000 base-pairs) and contains single ?-, γ- and β-globin genes. The γ- and β-globin genes in this animal are separated by a curious gene containing the 3′ end of a β-globin gene preceded by sequences related to the 5′ end of the ?-globin gene.     

Human globin knock-in mice complete fetal-to-adult hemoglobin switching in postnatal development

Elevated levels of fetal γ-globin can cure disorders caused by mutations in the adult β-globin gene. This clinical finding has motivated studies to improve our understanding of hemoglobin switching. Unlike humans, mice do not express a distinct fetal globin. Transgenic mice that contain the human β-globin locus complete their fetal-to-adult hemoglobin switch prior to birth, with human γ-globin predominantly restricted to primitive erythroid cells. We established humanized (100% human hemoglobin) knock-in mice that demonstrate a distinct fetal hemoglobin (HbF) stage, where γ-globin is the dominant globin chain produced during mid- to late gestation. Human γ- and β-globin gene competition is evident around the time of birth, and γ-globin chain production diminishes in postnatal life, with transient production of HbF reticulocytes. Following completion of the γ- to-β-globin switch, adult erythroid cells synthesize low levels of HbF. We conclude that the knock-in globin genes are expressed in a pattern strikingly similar to that in human development, most notably with postnatal resolution of the fetal-to-adult hemoglobin switch. Our findings are consistent with the importance of BCL11A in hemoglobin switching, since removal of intergenic binding sites for BCL11A results in human γ-globin expression in mouse definitive erythroid cells.     

Localization of the human alpha-globin structural gene to chromosome 16 in somatic cell hybrids by molecular hybridization assay

We have used 16 human × mouse somatic cell hybrids containing a variable number of human chromosomes to demonstrate that the human α-globin gene is on chromosome 16. Globin gene sequences were detected by annealing purified human α-globin complementary DNA to DNA extracted from hybrid cells. Human and mouse chromosomes were distinguished by Hoechst fluorescent centromeric banding, and the individual human chromosomes were identified in the same spreads by Giemsa trypsin banding. Isozyme markers for 17 different human chromosomes were also tested in the 16 clones which have been characterized. The absence of chromosomal translocation in all hybrid clones strongly positive for the α-globin gene was established by differential staining of mouse and human chromosomes with Giemsa 11 staining. The presence of human chromosomes in hybrid cell clones which were devoid of human α-globin genes served to exclude all human chromosomes except 6, 9, 14 and 16. Among the clones negative for human α-globin sequences, one contained chromosome 2 (JFA 14a 5), three contained chromosome 4 (AHA 16E, AHA 3D and WAV R4D) and two contained chromosome 5 (AHA 16E and JFA14a 13 5) in >10% of metaphase spreads. These data excluded human chromosomes 2, 4 and 5 which had been suggested by other investigators to contain human globin genes. Only chromosome 16 was present in each one of the three hybrid cell clones found to be strongly positive for the human α-globin gene. Two clones (WAIV A and WAV) positive for the human α-globin gene and chromosome 16 were counter-selected in medium which kills cells retaining chromosome 16. In each case, the resulting hybrid populations lacked both human chromosome 16 and the α-globin gene. These studies establish the localization of the human α-globin gene to chromosome 16 and represent the first assignment of a nonexpressed unique gene by direct detection of its DNA sequences in somatic cell hybrids.     

Restriction endonuclease analysis of human globin genes in cellular DNA

Using samples of human cellular DNA digested with restriction endonucleases Eco RI, Hind III, Hinc II, Bam HI, Alu I, or Hae III, we were able to localize globin gene fragments separated by agarose gel electrophoresis. The fragments were transferred to nitro-cellulose filters and identified by hybridization to [³²P] cDNA for total adult globin mRNA. The α-globin gene fragments were specifically identified by their presence in normal controls and absence in DNA from homozygous α-thalassemia, a genetic disorder due to deletion of α-globin genes. In addition, the patterns with Hind III indicate a 4.1 kb distance between the centers of the normal duplicated α-globin gene loci.     

人胎儿γ-珠蛋白基因的再活化及在β血红蛋白病治疗中的

在个体发育过程中,人β类珠蛋白基因的表达存在从胎儿（γ）到成人（β）珠蛋白基因的表达转换（或称开关）.β-地中海贫血和镰刀型贫血症是两种最为常见的严重危害人类健康的单基因遗传病,通过诱导胎儿期血红蛋白（HbF,α2γ2）在成人期表达对该病的治疗是一种有效的策略.一些活化γ珠蛋白基因表达的转录因子和辅助因子已经被鉴定,一些可以增加胎儿血红蛋白在成人红细胞中表达的药物也已被鉴别和实验,它们的作用机制被部分揭示,这些研究为发展通过活化γ-珠蛋白基因治疗镰刀形细胞贫血和重型β-地中海贫血的方法提供了重要线索和实验依据.     

Effect of AGM and fetal liver-derived stromal cell lines on globin expression in adult baboon (P. anubis) bone marrow-derived erythroid progenitors

This study was performed to investigate the hypothesis that the erythroid micro-environment plays a role in regulation of globin gene expression during adult erythroid differentiation. Adult baboon bone marrow and human cord blood CD34+ progenitors were grown in methylcellulose, liquid media, and in co-culture with stromal cell lines derived from different developmental stages in identical media supporting erythroid differentiation to examine the effect of the micro-environment on globin gene expression. Adult progenitors express high levels of γ-globin in liquid and methylcellulose media but low, physiological levels in stromal cell co-cultures. In contrast, γ-globin expression remained high in cord blood progenitors in stromal cell line co-cultures. Differences in γ-globin gene expression between adult progenitors in stromal cell line co-cultures and liquid media required cell-cell contact and were associated with differences in rate of differentiation and γ-globin promoter DNA methylation. We conclude that γ-globin expression in adult-derived erythroid cells can be influenced by the micro-environment, suggesting new potential targets for HbF induction.     

Histone deacetylase 9 activates gamma-globin gene expression in primary erythroid cells

Strategies to induce fetal hemoglobin (HbF) synthesis for the treatment of β-hemoglobinopathies probably involve protein modifications by histone deacetylases (HDACs) that mediate γ-globin gene regulation. However, the role of individual HDACs in globin gene expression is not very well understood; thus, the focus of our study was to identify HDACs involved in γ-globin activation. K562 erythroleukemia cells treated with the HbF inducers hemin, trichostatin A, and sodium butyrate had significantly reduced mRNA levels of HDAC9 and its splice variant histone deacetylase-related protein. Subsequently, HDAC9 gene knockdown produced dose-dependent γ-globin gene silencing over an 80-320 nm range. Enforced expression with the pTarget-HDAC9 vector produced a dose-dependent 2.5-fold increase in γ-globin mRNA (p < 0.05). Furthermore, ChIP assays showed HDAC9 binding in vivo in the upstream Gγ-globin gene promoter region. To determine the physiological relevance of these findings, human primary erythroid progenitors were treated with HDAC9 siRNA; we observed 40 and 60% γ-globin gene silencing in day 11 (early) and day 28 (late) progenitors. Moreover, enforced HDAC9 expression increased γ-globin mRNA levels by 2.5-fold with a simultaneous 7-fold increase in HbF. Collectively, these data support a positive role for HDAC9 in γ-globin gene regulation.     

γ-珠蛋白基因表达调控机制与临床应用

成人体内的血红蛋白是由2个 α-珠蛋白和2个β-珠蛋白组成的四聚体,负责氧气的运输。珠蛋白基因在基因组中成簇分布,其表达受到多种顺式作用元件和反式作用因子的共同调控,具有高度的组织特异性和发育时序性。β-地中海贫血和镰刀型细胞贫血是两种最常见的由于β-珠蛋白基因突变引起的常染色体隐性遗传病。γ-珠蛋白是一种主要在胎儿时期表达的类β-珠蛋白,同样具有载氧功能,但编码该蛋白的基因在上述贫血患者中却保持完好。因此,临床上优选的治疗方案之一是重新激活患者体内沉默的γ-珠蛋白基因的表达来弥补缺损的β-珠蛋白,从而缓解临床症状。目前已有多种能提高γ-珠蛋白基因表达的药物,在临床上用于治疗β-地中海贫血和镰刀型细胞贫血。随着基因组编辑技术的发展,针对这两种贫血的精准基因治疗研究也在进行中。本文着重介绍了参与γ-珠蛋白基因调控的转录因子和表观遗传修饰分子,以及目前相关的β-地中海贫血和镰刀型细胞贫血的临床治疗药物和手段,以期为深入阐明γ-珠蛋白基因的转录表达分子调控机制提供参考。     

Hb switching in chickens

We have taken advantage of the preferential digestion of active genes by DNAase I to investigate the chromosomal structure of embryonic and adult β-globin genes during erythropoiesis in chick embryos, and in particular to examine the question of hemoglobin switching during development. DNA in isolated red cell nuclei was mildly digested with DNAase I to about 10–15 kb, purified and restricted with a variety of restriction enzymes. The DNA was then separated on agarose gels, transferred to nitrocellulose filters and hybridized with an adult-specific β-globin cDNA clone or a genomic clone containing the genes coding for both an embryonic and an adult β-globin chain. Preferential sensitivity of the respective globin genes was monitored by the disappearance of specific restriction bands after DNAase I digestion of nuclei. In embryonic red cells, both adult and embryonic β-globin genes are very sensitive to DNAase I; however, in adult erythroid lines, the embryonic β-globin gene becomes relatively more resistant but the adult gene remains highly sensitive. Controls showed that all globin genes were resistant to DNAase I in brain nuclei and nuclei from lymphoid cells. Thus the switch from embryonic to adult globin expression is associated with an apparent change in the chromosome structure of the embryonic globin gene as reflected in the gene becoming less accessible to DNAase I in adult red cell nuclei. Our results also show that the chromosomal structure of both adult and embryonic genes is altered in embryonic red cell nuclei; thus the nonexpressed globin gene (that is, the adult gene in embryonic red cells) has already been “recognized” to some degree and marked by the erythroid compartment. The sensitivity of the adult globin gene in embryonic cells may represent a “pre-activation” state of the chromosome.     

SATB1 regulates β-like globin genes through matrix related nuclear relocation of the cluster

The nuclear location and relocation of genes play crucial regulatory roles in gene expression. SATB1, a MAR-binding protein, has been found to regulate β-like globin genes through chromatin remodeling. In this study, we generated K562 cells over-expressing wild-type or nuclear matrix targeting sequences (NMTS)-deficient SATB1 and found that like wild-type SATB1, NMTS-deficient SATB1 induces out loop of β-globin cluster from its chromosome territory (CT), while it is unable to associate the cluster with the nuclear matrix as wild-type SATB1 does and had no regulatory functions to the β-globin cluster. Besides, our data showed that the transacting factor occupancies and chromatin modifications at β-globin cluster were differentially affected by wild-type and NMTS-deficient SATB1. These results indicate that SATB1 regulates β-like globin genes at the nuclear level interlaced with chromatin and DNA level, and emphasize the nuclear matrix binding activity of SATB1 to its regulatory function.     

Absence of messenger RNA and gene DNA for β-globin chains in hereditary persistence of fetal hemoglobin

The relative amounts of α- and β-globin mRNA and globin gene DNA were measured in reticulocyte RNA and lymphocyte DNA of an individual with homozygous hereditary persistence of fetal hemoglobin whose red blood cells contain 100% fetal hemoglobin (Hb F: α₂γ₂). Molecular hybridization assays used as probes full-length DNA copies of human α- and β-globin messenger RNA. The results of these hybridization assays demonstrated the expected amounts of α-globin mRNA and gene DNA, but absence of β-globin mRNA and absence of β-globin gene DNA. In the individual studied, hereditary persistence of fetal hemoglobin is associated with total deletion of the β-globin structural gene.