Human globin locus activation region (LAR): role in temporal control

Pharmacologic induction of fetal hemoglobin production

Reactivation of fetal hemoglobin (HbF) expression is an important therapeutic option in adult patients with hemoglobin disorders. The understanding of the developmental regulation of γ-globin gene expression was followed by the identification of a number of chemical compounds that can reactivate HbF synthesis in vitro and in vivo in patients with hemoglobin disorders. These HbF inducers can be grouped in several classes based on their mechanisms of action. This article focuses on pharmacologic agents that were tested in humans and discusses current knowledge about the mechanisms by which they induce HbF.

Persistent fetal gamma-globin expression in adult transgenic mice following deletion of two silencer elements located 3' to the human Agamma-globin gene

Natural deletions of the human gamma-globin gene cluster lead to specific syndromes characterized by increased production of fetal hemoglobin in adult life and provide a useful model to delineate novel cis-acting elements involved in the developmental control of hemoglobin switching. A hypothesis accounting for these phenotypic features assumes that silencers located within the Agamma-to delta-gene region are deleted in hereditary persistence of fetal hemoglobin (HPFH) and deltabeta-thalassemias, leading to failure of switching. In the present study, we sought to clarify the in vivo role of two elements, termed Enh and F, located 3' to the Agamma-globin, in silencing the fetal genes. To this end, we generated three transgenic lines using cosmid constructs containing the full length of the globin locus control region (LCR) linked to the 3.3-kb Agamma-gene lacking both the Enh and F elements. The Enh/F deletion resulted in high levels of Agamma-globin gene expression in adult mice in all single copy lines, whereas, the LCR-Agamma single copy lines which retain the Enh and F elements exhibited complete normal switching of the fetal Agamma-gene. Our study documents directly for the first time the in vivo role of these two gene-proximal negative regulatory elements in silencing the fetal globin gene in the perinatal period, and thus these data may permit their eventual exploitation in therapeutic approaches for thalassemias.

Oct4 dependence of chromatin structure within the extended Nanog locus in ES cells

Embryonic stem (ES) cells offer insight into early developmental fate decisions, and their controlled differentiation may yield vast regenerative potential. The molecular determinants supporting ES cell self-renewal are incompletely understood. The homeodomain proteins Nanog and Oct4 are essential for mouse ES cell self-renewal. Using a high-throughput approach, we discovered DNaseI hypersensitive sites and potential regulatory elements along a 160-kb region of the genome that includes GDF3, Dppa3, and Nanog. We analyzed gene expression, chromatin occupancy, and higher-order chromatin structure throughout this gene locus and found that expression of the reprogramming factor Oct4 is required to maintain its integrity.

Nuclear factor Y drives basal transcription of the human TLX3, a gene overexpressed in T-cell acute lymphocytic leukemia

Based on a knocked-out mouse model and a few expression studies, TLX3 is regarded as a homeobox gene crucial for the development of the autonomic nervous system. This gene can undergo rearrangements or deregulation, giving rise to T-cell acute lymphocytic leukemia. The present report is focused on the identification of elements and factors playing a role in the TLX3 physiologic expression regulation and therefore likely to be involved in cancer development. In particular, after identifying the transcription start points, we have made use of in vitro transfection assays to show that the 5'-untranslated region of the gene is necessary for the basal promoter activity in cell lines from different origin. By site-directed mutagenesis, two tandem CCAAT boxes have been localized as critical elements of this region. In vivo chromatin immunoprecipitation and electrophoretic mobility shift assays have indicated that nuclear factor Y (NFY) recognizes these sites in all the analyzed cell lines. The physiologic role of such an interaction has been confirmed by a dominant-negative version of the NFY transcription factor that has turned out to decrease both in vitro TLX3 promoter activity and endogenous amount of mRNA. Finally, a consistent in vivo TLX3 expression impairment was also achieved after NFY mRNA knockdown. The full characterization of the TLX3 transcription regulation will ultimately provide crucial elements to define the involvement of this gene in T-cell acute lymphocytic leukemia development.

Understanding mechanisms of gamma-globin gene regulation to develop strategies for pharmacological fetal hemoglobin induction

The developmental regulation of gamma-globin gene expression has shaped research efforts to establish therapeutic modalities for individuals affected with sickle cell disease (SCD). Fetal hemoglobin (Hb F) synthesis is high at birth, followed by a decline to adult levels by 10 months of age. The expression of gamma-globin is controlled by a developmentally regulated transcriptional program that is recapitulated during normal erythropoiesis in the adult bone marrow. It is known that naturally occurring mutations in the gamma-gene promoters cause persistent Hb F synthesis after birth, which ameliorates symptoms in SCD by inhibiting hemoglobin S polymerization and vaso-occlusion. Several pharmacological agents have been identified over the past 2 decades that reactivate gamma-gene transcription through different cellular systems. We will review the progress made in our understanding of molecular mechanisms that control gamma-globin expression and insights gained from Hb F-inducing agents that act through signal transduction pathways.

Identification of novel candidate genes for globin regulation in erythroid cells containing large deletions of the human β-globin gene cluster

The genetic mechanisms underlying the continued expression of the gamma-globin genes during the adult stage in deletional hereditary persistence of fetal hemoglobin (HPFH) and deltabeta-thalassemias are not completely understood. Herein, we investigated the possible involvement of transcription factors, using the suppression subtractive hybridization (SSH) method as an initial screen to identify differentially expressed transcripts in reticulocytes from a normal and a HPFH-2 subject. Some of the detectable transcripts may participate in globin gene regulation. Quantitative real-time PCR (qRT-PCR) experiments confirmed the downregulation of ZHX2, a transcriptional repressor, in two HPFH-2 subjects and in a carrier of the Sicilian deltabeta-thalassemia trait. The chromatin remodeling factors ARID1B and TSPYL1 had a very similar pattern of expression with an incremental increase in HPFH and decreased expression in deltabeta-thalassemia. These differences suggest a mechanism to explain the heterocellular and pancellular distribution of fetal hemoglobin in deltabeta-thalassemia and deletional HPFH, respectively. Interestingly, alpha-globin mRNA levels were decreased, similar to beta-globin in all reticulocyte samples analyzed.

Differential binding of erythroid Krupple-like factor to embryonic/fetal globin gene promoters during development

The competition model for beta-like globin gene switching during development predicts that differential binding of transcription factors to globin gene promoters and/or proximal enhancers regulate the competitive interactions of globin gene family members with the powerful locus control region (LCR). Direct interactions of individual genes with the LCR are essential for high level expression in erythroid cells. In this paper, we have demonstrated, by chromatin immunoprecipitation, that erythroid-Krupple-like factor (EKLF) binds to embryonic/fetal globin gene promoters in primitive (but not in definitive) erythroid cells. EKLF binds strongly to adult globin gene promoters and to LCR sequences HS4, HS3, HS2, and HS1 in both primitive and definitive erythroid cells. Trimethylation of histone H3K4 and H3K27 at the embryonic/fetal and adult globin gene promoters is equivalent in definitive cells; therefore, the differential binding of EKLF to these promoters does not appear to result from changes in chromatin configuration. Interestingly, the level of EKLF in definitive cells is 3-fold higher than the level in primitive cells. These results suggest that temporal-specific changes in EKLF abundance result in differential binding of this essential erythroid transcription factor to embryonic/fetal globin gene promoters during development and that these changes in EKLF binding specificity mediate the competitive interactions of globin gene family members with the LCR.

Regulatory elements of the melanocortin 1 receptor

Among more than 120 genes that are now known to regulate mammalian pigmentation, one of the key genes is MC1R, which encodes the melanocortin 1 receptor, a seven transmembrane G protein-coupled receptor expressed on the surface of melanocytes. Since the monoexonic sequence of the gene was cloned and characterized more than a decade ago, tremendous efforts have been dedicated to the extensive genotyping of mostly red-haired populations all around the world, thus providing allelic variants that may or may not account for melanoma susceptibility in the presence or absence of ultraviolet (UV) exposure. Soluble factors, such as proopiomelanocortin (POMC) derivatives, agouti signal protein (ASP) and others, regulate MC1R expression, leading to improved photoprotection via increased eumelanin synthesis or in contrast, inducing the switch to pheomelanin. However, there is an obvious lack of knowledge regarding the numerous and complex regulatory mechanisms that govern the expression of MC1R at the intra-cellular level, from gene transcription in response to an external stimulus to the expression of the mature receptor on the melanocyte surface.

The functional mapping of long-range transcription control elements of the HOX11 proto-oncogene

Mapping of transcriptional control elements normally depends on the generation of a series of deletion mutants. The consequences of particular deletions are then functionally assessed by their ability to alter gene expression. The information derived from such investigations provides a general regulatory profile of the gene of interest, as well as generating a focus for future experiments. Due to the limitations of conventional DNA cloning methods, it has previously not been possible to use such an approach to rapidly assess the role of long-range regulatory elements that frequently lie further than 20 kb away from the coding region. In order to identify regulatory elements of the proto-oncogene HOX11 that may be mutated in a subset of childhood T-cell acute lymphoblastic leukaemia specimens, we generated nested deletions from a P1 artificial chromosome (PAC). This clone contained 95 kilobases (kb) of the HOX11 locus at 10q24; including 63 kb of 5' regulatory DNA. The deletion series was produced by the use of a recombination based cloning system and clones were subsequently transfected into mammalian cells. We have identified several long-range regulatory elements that mediate transcriptional control of HOX11. This approach is simple, rapid, and inexpensive. Furthermore, it generates multiple deletion clones in a single experiment. This novel approach opens up a new avenue for investigating long-range transcription control. Additionally, by allowing analysis of these elements in the natural context of large integrants the approach does not require the use of artificial extrachromosomal elements. This methodology can be applied to any gene cloned into a PAC or BAC vector and could also be useful in identifying appropriately sized deletion mutants for functional testing in transgenic models.

Developmental stage-specific epigenetic control of human beta-globin gene expression is potentiated in hematopoietic progenitor cells prior to their transcriptional activation

To study epigenetic regulation of the human beta-globin locus during hematopoiesis, we investigated patterns of histone modification and chromatin accessibility along this locus in hematopoietic progenitor cells (HPCs) derived from both humans and transgenic mice. We demonstrate that the developmentally related activation of human beta-like globin genes in humans and transgenic mice HPCs is preceded by a wave of gene-specific histone H3 hyperacetylation and K4 dimethylation. In erythroid cells, expression of beta-like globin genes is associated with histone hyperacetylation along these genes and, surprisingly, with local deacetylation at active promoters. We also show that endogenous mouse beta major and human beta-like genes are subject to different epigenetic control mechanisms in HPCs. This difference is likely due to intrinsic properties of the human beta-globin locus since, in transgenic mice, this locus is epigenetically regulated in the same manner as in human HPCs. Our results suggest that a defined pattern of histone H3 acetylation/dimethylation is important for specific activation of human globin promoters during development in human and transgenic HPCs. We propose that this transient acetylation/dimethylation is involved in gene-specific potentiation in HPCs (ie, before extensive chromatin remodeling and transcription take place in erythroid cells).

DNase I hypersensitivity patterns of the serglycin proteoglycan gene in resting and phorbol 12-myristate 13-acetate-stimulated human erythroleukemia (HEL), CHRF 288-11, and HL-60 cells compared with neutrophils and human umbilical vein endothelial cells

We mapped the DNase I-hypersensitive sites (DHSS) of the serglycin gene in resting and phorbol 12-myristate 13-acetate (PMA)-stimulated human erythroleukemia (HEL) and CHRF 288-11 cells, which have megakaryocytic characteristics, and HL-60 promyelocytic leukemia cells. We compared these DHSS with those of normal primary neutrophils and human umbilical vein endothelial cells. Several DHSS appear to be involved in regulating the level of endogenous expression and in the PMA response of hematopoietic cell lines. A DHSS unique to resting HL-60 cells and induced in CHRF 288-11 by PMA may explain the high degree of endogenous expression in HL-60 relative to HEL and CHRF (Schick, B. P., Petrushina, I., Brodbeck, K. C., and Castronuevo, P. (2001) J. Biol. Chem. 276, 24726-24735). A total of 4 DHSS in intron 1 and 6 in intron 2 are associated with the PMA response in a cell-specific manner. A DHSS in the 5'-flanking region and another in intron 1 lie in areas that have high homology with the orthologous murine serglycin locus and are rich in potential transcription factor binding sites. One DHSS in intron 1 and one in intron 2 are located within Alu repeats. Two DHSS found in DNA of normal primary neutrophils were different from those of the cell lines. One DHSS in exon 2 unique to neutrophils correlated with a previously unrecognized alternative splicing that removes exon 2. Human umbilical vein endothelial cells had a DHSS in intron 1 that was common with the cell lines. The different patterns of DHSS exhibited by the cells studied suggest that cell- and differentiation-specific alterations in chromatin structure may control serglycin gene expression.

A general approach for identifying distant regulatory elements applied to the Gdf6 gene

Regulatory sequences in higher genomes can map large distances from gene coding regions, and cannot yet be identified by simple inspection of primary DNA sequence information. Here we describe an efficient method of surveying large genomic regions for gene regulatory information, and subdividing complex sets of distant regulatory elements into smaller intervals for detailed study. The mouse Gdf6 gene is expressed in a number of distinct embryonic locations that are involved in the patterning of skeletal and soft tissues. To identify sequences responsible for Gdf6 regulation, we first isolated a series of overlapping bacterial artificial chromosomes (BACs) that extend varying distances upstream and downstream of the gene. A LacZ reporter cassette was integrated into the Gdf6 transcription unit of each BAC using homologous recombination in bacteria. Each modified BAC was injected into fertilized mouse eggs, and founder transgenic embryos were analyzed for LacZ expression mid-gestation. The overlapping segments defined by the BAC clones revealed five separate regulatory regions that drive LacZ expression in 11 distinct anatomical locations. To further localize sequences that control expression in developing skeletal joints, we created a series of BAC constructs with precise deletions across a putative joint-control region. This approach further narrowed the critical control region to an area containing several stretches of sequence that are highly conserved between mice and humans. A distant 2.9-kilobase fragment containing the highly conserved regions is able to direct very specific expression of a minimal promoter/LacZ reporter in proximal limb joints. These results demonstrate that even distant, complex regulatory sequences can be identified using a combination of BAC scanning, BAC deletion, and comparative sequencing approaches.

A locus for hereditary hypotrichosis localized to human chromosome 18q21.1

Hereditary hypotrichosis is a rare autosomal recessive condition characterized clinically by alopecia. Three consanguineous kindreds with multiple affected individuals were ascertained from different regions of Pakistan. A novel hypotrichosis locus was mapped to a 5.5 cM region on chromosome 18q21.1. A maximum two-point LOD score of 5.25 was obtained at marker D18S36 (theta=0.0). Three genes each for desmoglein and desmocollin proteins are located in this region. The expression in epidermal desmosomes and their connection to the keratin intermediate filaments make these genes excellent candidates for recessive hypotrichosis.

Further understanding of the beta-globin locus regulation at the molecular level: looping or linking models?

The human beta-globin locus is a classic model of the eukaryotic multigene family with tissue- and temporally specific expression. Over the past few years, great advances have been achieved in studies of beta-globin locus regulation. The dominant role of the beta-globin locus control region (LCR) in chromatin opening and developmental switching has been challenged, and elements beyond the LCR have been studied in depth. More recently, the fields of research have been expanded to intergenic transcription, nuclear localization and histone modification. Several models have been proposed to elucidate the regulation mechanism; among them, the looping and linking models are the most prevalent. Different models are the summarization of the observations made at different times and a persuasive model must be based on a systematic understanding of the numerous observations. The objective of this review is to provide an overview of progress in the area of beta-globin regulation and then to discuss models for it.

Identification of distal regulatory regions in the human alpha IIb gene locus necessary for consistent, high-level megakaryocyte expression

The alphaIIb/beta3-integrin receptor is present at high levels only in megakaryocytes and platelets. Its presence on platelets is critical for hemostasis. The tissue-specific nature of this receptor's expression is secondary to the restricted expression of alphaIIb, and studies of the alphaIIb proximal promoter have served as a model of a megakaryocyte-specific promoter. We have examined the alphaIIb gene locus for distal regulatory elements. Sequence comparison between the human (h) and murine (m) alphaIIb loci revealed high levels of conservation at intergenic regions both 5' and 3' to the alphaIIb gene. Additionally, deoxyribonuclease (DNase) I sensitivity mapping defined tissue-specific hypersensitive (HS) sites that coincide, in part, with these conserved regions. Transgenic mice containing various lengths of the h(alpha)IIb gene locus, which included or excluded the various conserved/HS regions, demonstrated that the proximal promoter was sufficient for tissue specificity, but that a region 2.5 to 7.1 kb upstream of the h(alpha)IIb gene was necessary for consistent expression. Another region 2.2 to 7.4 kb downstream of the gene enhanced expression 1000-fold and led to levels of h(alpha)IIb mRNA that were about 30% of the native m(alpha)IIb mRNA level. These constructs also resulted in detectable h(alpha)IIb/m(beta)3 on the platelet surface. This work not only confirms the importance of the proximal promoter of the alphaIIb gene for tissue specificity, but also characterizes the distal organization of the alphaIIb gene locus and provides an initial localization of 2 important regulatory regions needed for the expression of the alphaIIb gene at high levels during megakaryopoiesis.

Chromatin structure and control of beta-like globin gene switching

The human beta-globin locus is a complex genetic system widely used for analysis of eukaryotic gene expression. The locus consists of five functional beta-like globin genes, epsilon, (G)gamma, (A)gamma, delta, and beta, arrayed on the chromosome in the order that they are expressed during ontogeny. Globin gene expression is regulated, in part, by the locus control region, which physically consists of five DNaseI-hypersensitive sites located 6-22 Kb upstream of the epsilon -globin gene. During ontogeny two switches occur in beta-globin gene expression that reflect the changing oxygen requirements of the fetus. The first switch from embryonic epsilon - to fetal gamma-globin occurs at six weeks of gestation. The second switch from gamma- to adult delta- and beta-globin occurs shortly after birth. Throughout the locus, cis-acting elements exist that are dynamically bound by trans-acting proteins, including transcription factors, co-activators, repressors, and chromatin modifiers. Discovery of novel erythroid-specific transcription factors and a role for chromatin structure in gene expression have enhanced our understanding of the mechanism of globin gene switching. However, the hierarchy of events regulating gene expression during development, from extracellular signaling to transcriptional activation or repression, is complex. In this review we attempt to unify the current knowledge regarding the interplay of cis-acting elements, transcription factors, and chromatin modifiers into a comprehensive overview of globin gene switching.

Molecular aspects of embryonic hemoglobin function

In order to provide the appropriate level of oxygen transport to respiring tissues, we need to produce a molecular oxygen transporting system to supplement oxygen diffusion and solubility. This supplementation is provided by hemoglobin. The role of hemoglobin in providing oxygen transport from lung to tissues in the adult is well-documented and functional characteristics of the fetal hemoglobin, which provide placental oxygen exchange, are also well understood. However the characteristics of the three embryonic hemoglobins, which provide oxygen transport during the first three months of gestation, are not well recognized. This review seeks to describe the state of our understanding of the temporal control of the expression of these proteins and the oxygen binding characteristics of the individual protein molecules. The modulation of the oxygen binding properties of these proteins, by the various allosteric effectors, is described and the structural origins of these characteristics are probed.

The human gamma-globin TATA and CACCC elements have key, distinct roles in suppressing beta-globin gene expression in embryonic/fetal development

The competition model of globin gene regulation states that the gamma-globin gene precludes expression of the beta-globin gene in early development by competing for the enhancing activity of the locus control region. The gamma-globin gene with a -161 promoter is sufficient for suppressing beta-globin gene expression, and the gamma-globin TATA and CACCC elements are necessary for this effect. In this work, stable transfection and transgenic mouse assays have been performed with constructs containing HS3 and HS2 from the locus control region, the gamma-globin gene with promoter mutation(s), and the beta-globin gene. The data indicate that the gamma-globin TATA and CACCC elements together have at least an additive effect on the beta/gamma-globin mRNA ratio in early erythroid cells, suggesting that the elements work coordinately to suppress beta-globin gene expression. The TATA and CACCC are the major gamma-globin promoter elements responsible for this effect. Transgenic mouse experiments indicate that the gamma-globin TATA element plays a role in gamma-globin expression and beta-globin suppression in the embryo and fetus; in contrast, the CACCC element has a stage-specific effect in the fetus. The results suggest that, as is true for the erythroid Krüppel-like factor (EKLF) and the beta-globin promoter CACCC, a protein(s) binds to the gamma-globin CACCC element to coordinate stage-specific gene expression.

Targeted deletion of 5'HS1 and 5'HS4 of the beta-globin locus control region reveals additive activity of the DNaseI hypersensitive sites

The mammalian beta-globin locus is a multigenic, developmentally regulated, tissue-specific locus from which gene expression is regulated by a distal regulatory region, the locus control region (LCR). The functional mechanism by which the beta-globin LCR stimulates transcription of the linked beta-like globin genes remains unknown. The LCR is composed of a series of 5 DNaseI hypersensitive sites (5'HSs) that form in the nucleus of erythroid precursors. These HSs are conserved among mammals, bind transcription factors that also bind to other parts of the locus, and compose the functional components of the LCR. To test the hypothesis that individual HSs have unique properties, homologous recombination was used to construct 5 lines of mice with individual deletions of each of the 5'HSs of the endogenous murine beta-globin LCR. Here it is reported that deletion of 5'HS1 reduces expression of the linked genes by up to 24%, while deletion of 5'HS4 leads to reductions of up to 27%. These deletions do not perturb the normal stage-specific expression of genes from this multigenic locus. In conjunction with previous studies of deletions of the other HSs and studies of deletion of the entire LCR, it is concluded that (1) none of the 5'HSs is essential for nearly normal expression; (2) none of the HSs is required for proper developmental expression; and (3) the HSs do not appear to synergize either structurally or functionally, but rather form independently and appear to contribute additively to the overall expression from the locus.

Site-specific acetylation by p300 or CREB binding protein regulates erythroid Krüppel-like factor transcriptional activity via its interaction with the SWI-SNF complex

Recruitment of modifiers and remodelers to specific DNA sites within chromatin plays a critical role in controlling gene expression. The study of globin gene regulation provides a convergence point within which to address these issues in the context of tissue-specific and developmentally regulated expression. In this regard, erythroid Krüppel-like factor (EKLF) is critical. EKLF is a red cell-specific activator whose presence is crucial for establishment of the correct chromatin structure and high-level transcriptional induction of adult beta-globin. We now find, by metabolic labeling-immunoprecipitation experiments, that EKLF is acetylated in the erythroid cell. EKLF residues acetylated by CREB binding protein (CBP) in vitro map to Lys-288 in its transactivation domain and Lys-302 in its zinc finger domain. Although site-specific DNA binding by EKLF is unaffected by the acetylation status of either of these lysines, directed mutagenesis of Lys-288 (but not Lys-302) decreases the ability of EKLF to transactivate the beta-globin promoter in vivo and renders it unable to be superactivated by coexpressed p300 or CBP. In addition, the acetyltransferase function of CBP or p300 is required for superactivation of wild-type EKLF. Finally, acetylated EKLF has a higher affinity for the SWI-SNF chromatin remodeling complex and is a more potent transcriptional activator of chromatin-assembled templates in vitro. These results demonstrate that the acetylation status of EKLF is critical for its optimal activity and suggest a mechanism by which EKLF acts as an integrator of remodeling and transcriptional components to alter chromatin structure and induce adult beta-globin expression within the beta-like globin cluster.

Novel transactivation domain in erythroid Kruppel-like factor (EKLF)

Erythroid Kruppel-like Factor (EKLF) is an erythroid-specific transcription factor that plays a critical role in gamma- to beta-globin gene switching during development. To identify essential domains required for EKLF transactivation function, we cotransfected a human erythroleukemia cell line (K562) with a locus control region gamma/Luc-beta/Cat reporter and an EKLF expression vector. In this assay EKLF mediates a 500-fold induction of beta/CAT expression compared with controls. To map essential transactivation domains, progressive NH(2)-terminal and internal deletion mutants of EKLF were constructed. All EKLF mutants were expressed at wild-type levels, localized to the nucleus, and bound DNA. When mutant EKLF proteins were tested for beta/CAT activation, a novel transactivation domain was identified. This novel domain, encompassing amino acids (aa) 140-358, is sufficient for maximal beta/CAT activation. An 85-amino acid subdomain within this region (aa 140-225) is essential for its activity. Interestingly, this central transactivation subdomain is functionally redundant with the amino-terminal domain (aa 1-139). Thus, EKLF possesses at least two potent transactivation domains that appear to function in a redundant manner.

Novel control motif cluster in the IgH delta-gamma 3 interval exhibits B cell-specific enhancer function in early development

The majority of the human Ig heavy chain (IgH) constant (C) region locus has been cloned and mapped. An exception is the region between C delta and C gamma 3, which is unstable and may be a recombination hot spot. We isolated a pBAC clone (pHuIgH3'delta-gamma 3) that established a 52-kb distance between C delta and C gamma 3. Sequence analysis identified a high number of repeat elements, explaining the instability of the region, and an unusually large accumulation of transcription factor-binding motifs, for both lymphocyte-specific and ubiquitous transcription activators (IKAROS, E47, Oct-1, USF, Myc/Max), and for factors that may repress transcription (Delta EF1, Gfi-1, E4BP4, C/EBP beta). Functional analysis in reporter gene assays revealed the importance of the C delta-C gamma 3 interval in lymphocyte differentiation and identified independent regions capable of either enhancement or silencing of reporter gene expression and interaction with the IgH intron enhancer E mu. In transgenic mice, carrying a construct that links the beta-globin reporter to the novel delta-gamma 3 intron enhancer (E delta-gamma 3), transgene transcription is exclusively found in bone marrow B cells from the early stage when IgH rearrangement is initiated up to the successful completion of H and L locus recombination, resulting in Ab expression. These findings suggest that the C delta-C gamma 3 interval exerts regulatory control on Ig gene activation and expression during early lymphoid development.

Human gamma-globin gene promoter element regulates human beta-globin gene developmental specificity

The persistence of fetal hemoglobin in many patients with deletion type beta thalassemias and the expression patterns of human globin genes in transgenic mice suggest that gamma- to beta-globin gene switching results primarily from competition of gamma- and beta-globin genes for interaction with the beta-globin locus control region (LCR). To define regulatory sequences that are essential for the competitive advantage of the gamma gene at early developmental stages, stable transgenic mouse lines were produced with LCR gamma-beta constructs containing deletions of gamma 5'-flanking DNA. All constructs contained the full 22 kb LCR, a 4.1 kb beta-globin gene and a gamma-globin gene with 1348, 383, 202, 130, 72 or 52 bp of 5'-flanking sequence. Primer extension analysis of yolk sac, fetal liver and blood RNA from these lines demonstrated that a region between -202 and -130 of the human gamma-globin gene promoter was required to suppress beta-globin gene expression at early developmental stages. Four transcription factor binding sites within this region [GATA(p), Oct1, GATA(d) and CACCC] were mutated independently in LCR gamma-beta constructs and transgenic mouse lines were produced. Only the gamma CACCC box mutation resulted in high levels of beta-globin gene expression in early embryos. These results demonstrate that the CACCC box of the human gamma-globin gene plays a critical role in human beta-globin gene developmental specificity. The data also suggest that gamma CACCC box binding factors mediate LCR-gamma interactions which normally enhance gamma-globin and suppress beta-globin gene expression in fetal erythroid cells.

The gammaPE complex contains both SATB1 and HOXB2 and has positive and negative roles in human gamma-globin gene regulation

A large nuclear protein complex, termed gammaPE (for gamma-globin promoter and enhancer binding factor), binds to five sites located 5' and 3' of the human y-globin gene. Two proteins, SATB1 (special A-T-rich binding protein 1) and HOXB2, can bind to yPE binding sites. SATB1 binds to nuclear matrix-attachment sites, and HOXB2 is a homeodomain protein important in neural development that is also expressed during erythropoiesis. The present work showed that antisera directed against either SATB1 or HOXB2 reacted specifically with the entire gammaPE complex in electrophoretic mobility shift assays (EMSAs), suggesting that the two proteins can bind to the gammaPE binding site simultaneously. When SATB1 or HOXB2 was expressed in vitro, they could bind independently to gammaPE binding sites in EMSA. Interestingly, the proteins expressed in vitro competed effectively with each other for the gammaPE binding site, suggesting that this may occur under certain conditions in vivo. Transient cotransfections of a HOXB2 cDNA and a y-globin-luciferase reporter gene construct into cells expressing SATB1 suggested that SATB1 has a positive and HOXB2 a negative regulatory effect on transcription. Taking into account their potentially opposing effects and binding activities, SATB1 and HOXB2 may modulate the amount of gamma-globin mRNA expressed during development and differentiation.

Structural analysis and mapping of DNase I hypersensitivity of HS5 of the beta-globin locus control region

The beta-globin locus control region (LCR) is a cis regulatory element that is located in the 5' part of the locus and confers high-level erythroid lineage-specific and position-independent expression of the globin genes. The LCR is composed of five DNase I hypersensitive sites (HSs), four of which are formed in erythroid cells. The function of the 5'-most site, HS5, remains unknown. To gain insights into its function, mouse HS5 was cloned and sequenced. Comparison of the HS5 sequences of mouse, human, and galago revealed two extensively conserved regions, designated HS5A and HS5B. DNase I hypersensitivity mapping revealed that two hypersensitive sites are located within the HS5A region (designated HS5A(major) and HS5A(minor)), and two are located within the HS5B region (HS5B(major), HS5B(minor)). The positions of each of these HSs colocalize with either GATA-1 or Ap1/NF-E2 motifs, suggesting that these protein binding sites are implicated in the formation of HS5. Gel retardation assays indicated that the Ap1/NF-E2 motifs identified in murine HS5A and HS5B interact with NF-E2 or similar proteins. Studies of primary murine cells showed that HS5 is formed in all hemopoietic tissues tested (fetal liver, adult thymus, and spleen), indicating that this HS is not erythroid lineage specific. HS5 was detected in murine brain but not in murine kidney or adult liver, suggesting that this site is not ubiquitous. The presence of GATA-1 and NF-E2 motifs (which are common features of the DNase I hypersensitive sites of the LCR) suggests that the HS5 is organized in a manner similar to that of the other HSs. Taken together, our results suggest that HS5 is an inherent component of the beta-globin locus control region.

Human epidermal differentiation complex in a single 2.5 Mbp long continuum of overlapping DNA cloned in bacteria integrating physical and transcript maps

Terminal differentiation of keratinocytes involves the sequential expression of several major proteins which can be identified in distinct cellular layers within the mammalian epidermis and are characteristic for the maturation state of the keratinocyte. Many of the corresponding genes are clustered in one specific human chromosomal region 1q21. It is rare in the genome to find in such close proximity the genes belonging to at least three structurally different families, yet sharing spatial and temporal expression specificity, as well as interdependent functional features. This DNA segment, termed the epidermal differentiation complex, contains 27 genes, 14 of which are specifically expressed during calcium-dependent terminal differentiation of keratinocytes (the majority being structural protein precursors of the cornified envelope) and the other 13 belong to the S100 family of calcium binding proteins with possible signal transduction roles in the differentiation of epidermis and other tissues. In order to provide a bacterial clone resource that will enable further studies of genomic structure, transcriptional regulation, function and evolution of the epidermal differentiation complex, as well as the identification of novel genes, we have constructed a single 2.45 Mbp long continuum of genomic DNA cloned as 45 p1 artificial chromosomes, three bacterial artificial chromosomes, and 34 cosmid clones. The map encompasses all of the 27 genes so far assigned to the epidermal differentiation complex, and integrates the physical localization of these genes at a high resolution on a complete NotI and SalI, and a partial EcoRI restriction map. This map will be the starting resource for the large-scale genomic sequencing of this region by The Sanger Center, Hinxton, U.K.

Induction of globin synthesis in K562 cells is associated with differential expression of transcription factor genes

Globin gene switching may be mediated by proteins expressed during different stages of development. Their identification may clarify the mechanisms of the conversion from fetal to adult globin production and lead to new approaches to reversing or retarding the gamma- to beta-globin gene switch. To explore this hypothesis, K562 erythroleukemia cells were induced to differentiate with 1.25, 2.5, and 5 mM sodium butyrate and gene expression was studied after 24, 48, and 72 h. Erythroid differentiation was verified by benzidine staining and by measuring the activity of a transduced A gamma-globin gene promoter linked to a luciferase reporter gene. Using differential display polymerase chain reaction (PCR), total mRNA extracted from induced cells at each time point of induction was reverse transcribed in the presence of A, G, and C anchored primers and 16 arbitrary primers, calculated to amplify approximately 50% of expressed genes. Amplified mRNAs from induced and uninduced cells were separated in polyacrylamide gels and compared. More than 110 cDNA fragments which appeared to represent either up- or downregulated mRNA species in induced K562 cells were identified. Sixty-four of these fragments had more than 95% homology to known GenBank sequences. Seventeen fragments with characteristics of transcription factors were cloned. These include differentiation-related gene-1 (drg-1), PAX 3/forkhead transcription factor, HZF2 which is a Kruppel-related zinc finger protein, three helix-loop-helix proteins (heir-1, Id3, and GOS8), alpha-NAC transcriptional coactivator, LIM domain protein, and trophoblast hypoxia regulating factor. Differential expression of all 17 fragments over 72 h was confirmed by reverse Northern dot blot analysis, semiquantitative PCR using nested primers, and Northern analysis. Erythroid maturation in induced K562 cells is associated with differential expression of numerous genes. Some encode transcription factors that could effect the initiation of HbF synthesis. Almost half of the differentially expressed clones contained cDNAs of unidentified open reading frames and these are the object of continued study.

Phage Mu transposition immunity reflects supercoil domain structure of the chromosome

Transposition immunity is the negative influence that the presence of one transposon sequence has on the probability of a second identical element inserting in the same site or in sites nearby. A transposition-defective Mu derivative (MudJr1) produced transposition immunity in both directions from one insertion point in the Salmonella typhimurium chromosome. To control for the sequence preference of Mu transposition proteins, Tn10 elements were introduced as targets at various distances from an immunity-conferring MudJr1 element. Mu transposition into a Tn10 target was not detectable when the distance of separation from MudJr1 was 5 kb, and transposition was unencumbered when the separation was 25 kb. Between 5 kb and 25 kb, immunity decayed gradually with distance. Immunity decayed more sharply in a gyrase mutant than in a wild-type strain. We propose that Mu transposition immunity senses the domain structure of bacterial chromosomes.

The roles of 5'-HS2, 5'-HS3, and the gamma-globin TATA, CACCC, and stage selector elements in suppression of beta-globin expression in early development

The roles of HS2 and HS3 from the human beta-globin locus control region and of the TATA, CACCC, and stage selector elements of the gamma-globin promoter, in competitive inhibition of beta-globin gene expression in early development, were tested using stable transfections of HEL and K562 cells. Cells with an HS3gamma beta construct demonstrate that HS3 exhibits enhancing activity, but compared with HS2, this site participates less consistently in the inhibition of embryonic/fetal beta-globin expression. In cells with HS3HS2gamma beta constructs, the two HS sites act in concert to more effectively enhance gamma-globin gene expression and to drive stage-specific expression of the gamma- and beta-globin genes. A gamma-globin gene with a -161 promoter can competitively inhibit beta-globin gene expression. HS3HS2gamma beta constructs were used to determine the effects of gamma-globin promoter mutations within this region on competition. The CACCC and TATA elements, but not the stage selector element, inhibit inappropriate embryonic/fetal stage expression of the beta-globin gene. The mutation in the gamma-globin TATA element results in the use of two major alternative transcription start sites. The data suggest that proteins binding to the gamma-globin CACCC and TATA elements interact with those binding to HS2 and/or HS3 to preclude beta-globin transcription in early development.

The gamma-globin promoter has a major role in competitive inhibition of beta-globin gene expression in early erythroid development

The human gamma-globin gene competitively inhibits beta-globin gene expression in early erythroid development. To identify the gamma-globin gene sequences required for this effect, transgenic mice and stable transfection analyses with constructs containing 5'HS2 from the locus control region, modified gamma-globin genes, and the beta-globin gene were used. The -136 to +56 region of the gamma-globin promoter is necessary for competitive inhibition, as the beta-globin gene was inappropriately expressed in mouse embryos and in K562 and HEL cells containing constructs in which this region was deleted. Independently, the -140 to +56 region of gamma-globin gene was not sufficient to inhibit beta-globin transcription in mouse embryos or in cultured cells. Competitive inhibition of beta-globin gene expression was observed in K562 and HEL cells having a gamma-globin gene with a -161 promoter. The data suggest that the -161 gamma-globin promoter, which includes the CACCC box, two CCAAT boxes, the stage selector element (SSE), and TATA box, has a major role in suppressing beta-globin transcription early in development. Proteins binding to these or other gamma-globin promoter elements may interact with those binding to the locus control region, consequently precluding beta-globin transcription.

Description and Targeted Deletion of 5′ Hypersensitive Site 5 and 6 of the Mouse β-Globin Locus Control Region

The most upstream hypersensitive site (HS) of the β-globin locus control region (LCR) in humans (5′ HS 5) and chickens (5′ HS 4) can act as an insulating element in some gain of function assays and may demarcate a β-globin domain. We have mapped the most upstream HSs of the mouse β-globin LCR and sequenced this region. We find that mice have a region homologous to human 5′ HS 5 that is associated with a minor HS. In addition we map a unique HS upstream of 5′ HS 5 and refer to this novel site as mouse 5′ HS 6. We have also generated mice containing a targeted deletion of the region containing 5′ HS 5 and 6. We find that after excision of the selectable marker in vivo, deletion of 5′ HS 5 and 6 has a minimal effect on transcription and does not prevent formation of the remaining LCR HSs. Taken together these findings suggest that the most upstream HSs of the mouse β-globin LCR are not necessary for maintaining the β-globin locus in an active configuration or to protect it from a surrounding repressive chromatin environment.

Description and Targeted Deletion of 5′ Hypersensitive Site 5 and 6 of the Mouse β-Globin Locus Control Region

The most upstream hypersensitive site (HS) of the β-globin locus control region (LCR) in humans (5′ HS 5) and chickens (5′ HS 4) can act as an insulating element in some gain of function assays and may demarcate a β-globin domain. We have mapped the most upstream HSs of the mouse β-globin LCR and sequenced this region. We find that mice have a region homologous to human 5′ HS 5 that is associated with a minor HS. In addition we map a unique HS upstream of 5′ HS 5 and refer to this novel site as mouse 5′ HS 6. We have also generated mice containing a targeted deletion of the region containing 5′ HS 5 and 6. We find that after excision of the selectable marker in vivo, deletion of 5′ HS 5 and 6 has a minimal effect on transcription and does not prevent formation of the remaining LCR HSs. Taken together these findings suggest that the most upstream HSs of the mouse β-globin LCR are not necessary for maintaining the β-globin locus in an active configuration or to protect it from a surrounding repressive chromatin environment.

EGF stimulates transcription of CaN19 (S100A2) in HaCaT keratinocytes

CaN19 (S100A2), a member of the S100 family of calcium-binding proteins, was originally isolated in a screen for tumor suppressor genes. Recent work from our laboratory suggests that CaN19 is likely to be an effector of the regenerative hyperplasia pathway of epidermal differentiation. As other work from our laboratory in a human skin organ culture model suggests that this response is mediated by activation of the epidermal growth factor (EGF) receptor and/or related receptors of the ErbB family, we asked whether CaN19 expression could be increased by organ culture and by EGF treatment of human keratinocytes. CaN19 was strongly induced after 24 h of organ culture, and its induction could be blocked by PD153035, a specific inhibitor of EGF receptor tyrosine kinase activity. EGF treatment of immortalized human keratinocytes (HaCaT cells) increased CaN19 mRNA levels by 4.5-fold within 8 h, and a corresponding increase in CaN19 protein was observed by western blotting. EGF treatment had no effect on the expression of five other members of the S100A gene cluster. As assessed by nuclear run-off assay, CaN19 transcription increased rapidly in response to EGF, reaching a maximum induction of 16-fold after 2 h. In contrast, EGF treatment had no detectable effects on the decay of CaN19 transcripts, which were long lived (t1/2 > 6 h) in the presence or absence of EGF. PD153035 also blocked CaN19 transcription and the accumulation of CaN19 mRNA and protein in HaCaT cells. These results demonstrate that EGF receptor activation selectively stimulates CaN19 gene expression at the transcriptional level in human keratinocytes, and support the hypothesis that CaN19 is an important mediator of regenerative epidermal hyperplasia.

Beta-thalassemias: expression, molecular mechanisms and mutations in Indians

The beta-thalassemias are a heterogenous group of inherited disorders of hemoglobin (Hb) synthesis characterized by a reduction (beta+) or absence (beta zero) of synthesis of the beta globin chains of Hb, resulting in an imbalanced chain synthesis. To understand their expression and molecular basis in Indians, it is essential to review briefly the genetic control of normal Hb production and the structure, organization and regulation of different globin genes. The Indian beta-thalassemia mutations and strategies for prevention are described.

Apolipoprotein B gene expression in a series of human apolipoprotein B transgenic mice generated with recA-assisted restriction endonuclease cleavage-modified bacterial artificial chromosomes. An intestine-specific enhancer element is located between 54 and 62 kilobases 5' to the structural gene

Prior studies have established that the expression of the human apolipoprotein B (apoB) gene in the intestine is dependent on DNA sequences located a great distance from the structural gene. To identify the location of those sequences, we used recA-assisted restriction endonuclease (RARE) cleavage to truncate the 5'- or 3'-flanking sequences from a 145-kilobase (kb) bacterial artificial chromosome spanning the entire human apoB gene. Seven RARE cleavage- modified bacterial artificial chromosomes with different lengths of flanking sequences were used to generate transgenic mice. An analysis of those mice revealed that as little as 1.5 kb of 3' sequences or 5 kb of 5' sequences were sufficient to confer apoB expression in the liver. In contrast, apoB gene expression in the intestine required DNA sequences 54-62 kb 5' to the structural gene. Those sequences retained their ability to direct apoB expression in the intestine when they were moved closer to the gene. These studies demonstrate that the intestinal expression of the apoB gene is dependent on DNA sequences located an extraordinary distance from the structural gene and that the RARE cleavage/transgenic expression strategy is a powerful approach for analyzing distant gene-regulatory sequences.

Acetylation and modulation of erythroid Krüppel-like factor (EKLF) activity by interaction with histone acetyltransferases

Erythroid Krüppel-like factor (EKLF) is a red cell-specific transcriptional activator that is crucial for consolidating the switch to high levels of adult beta-globin expression during erythroid ontogeny. EKLF is required for integrity of the chromatin structure at the beta-like globin locus, and it interacts with a positive-acting factor in vivo. We find that EKLF is an acetylated transcription factor, and that it interacts in vivo with CBP, p300, and P/CAF. However, its interactions with these histone acetyltransferases are not equivalent, as CBP and p300, but not P/CAF, utilize EKLF as a substrate for in vitro acetylation within its trans-activation region. The functional effects of these interactions are that CBP and p300, but not P/CAF, enhance EKLF's transcriptional activation of the beta-globin promoter in erythroid cells. These results establish EKLF as a tissue-specific transcription factor that undergoes post-translational acetylation and suggest a mechanism by which EKLF is able to alter chromatin structure and induce beta-globin expression within the beta-like globin cluster.

Abnormal cornified cell envelope formation in mutilating palmoplantar keratoderma unrelated to epidermal differentiation complex

Mutilating palmoplantar keratoderma represents a heterogeneous group of disorders, unified by characteristic mutilation of the fingers or toes, associated with palmoplantar keratoderma. Although loricrin gene mutations were recently reported in Vohwinkel's syndrome and erythrokeratoderma, the genetic basis of mutilating palmoplantar keratoderma is largely unexplored. We studied a family of non-Vohwinkel's syndrome, nonerythrokeratoderma mutilating palmoplantar keratoderma. The proband and his sister were similarly affected. Recessive inheritance was expected from the consanguineous family history. The patients had hyperkeratosis restricted to the palms and the soles. No other body sites were affected. Digital constriction was seen on all the fingers and the mutilation was severe on the distal interphalangeal region of several fingers. Histopathologically, hyperkeratosis without parakeratosis was seen in the lesional skin. Ultrastructural, immunohistochemical, and immunoelectron microscopic analyses revealed malformed cornified cell envelopes, the abnormal intracytoplasmic loricrin retention, and reduced deposition of loricrin to cornified cell envelopes. Involucrin and small proline-rich proteins 1 and 2 were normally distributed. Sequencing of the entire exons and exon-intron borders of loricrin gene of the patients excluded a mutation in loricrin DNA sequence. Linkage analysis excluded the possibility of causative mutation in the epidermal differentiation complex region of 1q21, including loricrin, involucrin, small proline-rich proteins, filaggrin, and trichohyalin. These data confirm the presence of non-Vohwinkel's syndrome mutilating palmoplantar keratoderma phenotype with abnormal loricrin cross-linking at the final stage of cornified cell envelope formation, which is caused by mutations outside the epidermal differentiation complex region.

Erythroid Krüppel-Like Factor Is Essential for β-Globin Gene Expression Even in Absence of Gene Competition, But Is Not Sufficient to Induce the Switch From γ-Globin to β-Globin Gene Expression

Different genes in the β-like globin locus are expressed at specific times during development. This is controlled, in part, by competition between the genes for activation by the locus control region. In mice, gene inactivation of the erythroid Krüppel-like factor (EKLF) transcription factor results in a lethal anemia due to a specific and substantial decrease in expression of the fetal/adult-stage–specific β-globin gene. In transgenic mice carrying the complete human β-globin locus, EKLF ablation not only impairs human β-globin–gene expression but also results in increased expression of the human γ-globin genes during the fetal/adult stages. Hence, it may appear that EKLF is a determining factor for the developmental switch from γ-globin to β-globin transcription. However, we show here that the function of EKLF for β-globin–gene expression is necessary even in absence of gene competition. Moreover, EKLF is not developmental specific and is present and functional before the switch from γ-globin to β-globin–gene expression occurs. Thus, EKLF is not the primary factor that controls the switch. We suggest that autonomous repression of γ-globin transcription that occurs during late fetal development is likely to be the initiating event that induces the switch.

Erythroid Krüppel-Like Factor Is Essential for β-Globin Gene Expression Even in Absence of Gene Competition, But Is Not Sufficient to Induce the Switch From γ-Globin to β-Globin Gene Expression

Different genes in the β-like globin locus are expressed at specific times during development. This is controlled, in part, by competition between the genes for activation by the locus control region. In mice, gene inactivation of the erythroid Krüppel-like factor (EKLF) transcription factor results in a lethal anemia due to a specific and substantial decrease in expression of the fetal/adult-stage–specific β-globin gene. In transgenic mice carrying the complete human β-globin locus, EKLF ablation not only impairs human β-globin–gene expression but also results in increased expression of the human γ-globin genes during the fetal/adult stages. Hence, it may appear that EKLF is a determining factor for the developmental switch from γ-globin to β-globin transcription. However, we show here that the function of EKLF for β-globin–gene expression is necessary even in absence of gene competition. Moreover, EKLF is not developmental specific and is present and functional before the switch from γ-globin to β-globin–gene expression occurs. Thus, EKLF is not the primary factor that controls the switch. We suggest that autonomous repression of γ-globin transcription that occurs during late fetal development is likely to be the initiating event that induces the switch.

Prenatal diagnosis and screening of the haemoglobinopathies

This paper reviews the most important aspects of carrier detection procedures, genetic counselling, population screening and prenatal diagnosis of the thalassaemias and sickle cell anaemia. Carrier detection can be made retrospectively, following the birth of an affected child, or prospectively. Carrier detection and genetic counselling in at-risk populations for alpha-thalassaemia and sickle cell anaemia is carried out mostly retrospectively. However prospective carrier screening is ongoing in Cuba and Guadeloupe for sickle cell anaemia and, in a very limited way, in some South East Asian populations, for alpha-thalassaemia. For beta-thalassaemia, several programmes, based on carrier screening and counselling of couples at marriage, preconception or early pregnancy, are operating in several Mediterranean at-risk populations. These programmes have been very effective, as indicated by increasing knowledge on thalassaemia and its prevention by the target population and by the marked decline of the incidence of thalassaemia major. Carrier detection is carried out by haematological methods followed by mutation detection by DNA analysis. Prenatal diagnosis is accomplished by mutation analysis on PCR-amplified DNA from chorionic villi. Future prospects include automation of the process of mutation-detection, simplification of preconception and preimplantation diagnosis and fetal diagnosis by analysis of fetal cells in maternal circulation.

Positional cloning and gene identification

After genetic mapping and physical representation of a particular genomic region containing the gene underlying a particular Mendelian trait, a successful positional cloning strategy depends on the efficient detection and analysis of genes in the critical interval. Several gene detection strategies are presently available to compile an inventory of genes from large genomic regions. Here, the principle of these methods is briefly reviewed and their relative value for positional cloning projects compared.

Locus control regions of mammalian beta-globin gene clusters: combining phylogenetic analyses and experimental results to gain functional insights

Locus control regions (LCRs) are cis-acting DNA segments needed for activation of an entire locus or gene cluster. They are operationally defined as DNA sequences needed to achieve a high level of gene expression regardless of the position of integration in transgenic mice or stably transfected cells. This review brings together the large amount of DNA sequence data from the beta-globin LCR with the vast amount of functional data obtained through the use of biochemical, cellular and transgenic experimental systems. Alignment of orthologous LCR sequences from five mammalian species locates numerous conserved regions, including previously identified cis-acting elements within the cores of nuclease hypersensitive sites (HSs) as well as conserved regions located between the HS cores. The distribution of these conserved sequences, combined with the effects of LCR fragments utilized in expression studies, shows that important sites are more widely distributed in the LCR than previously anticipated, especially in and around HS2 and HS3. We propose that the HS cores plus HS flanking DNAs comprise a 'unit' to which proteins bind and form an optimally functional structure. Multiple HS units (at least three: HS2, HS3 and HS4 cores plus flanking DNAs) together establish a chromatin structure that allows the proper developmental regulation of genes within the cluster.

Position effects in mice carrying a lacZ transgene in cis with the beta-globin LCR can be explained by a graded model

We studied transgenic mice carrying the lacZ reporter gene linked to the erythroid-specific beta-globin promoter and beta-globin locus control region (LCR). Previously, we had demonstrated that the total level of expression of beta-galactosidase enzyme, which is the product of the lacZ gene, varies widely between different transgenic mice due to position effects at the sites of transgene integration. Here, using the X-gal based in situ assay for beta-galactosidase activity, we found that the percent erythroid cells that expressed the transgene also varied widely between the mice. Moreover, a kinetic analysis showed that the average beta-galactosidase content per expressing cell varied both between samples of different transgenic descent and between erythroid cells within each sample, demonstrating that the variable expression of this lacZ transgene was being controlled in a graded manner. These results suggest that the beta-globin LCR enhancers function through a graded model, which is described, rather than the binary mechanism that has been proposed previously for other enhancers.

The enhancer shift: a model to explain the developmental control of IgH gene expression in B-lineage cells

The roles attributed to the E mu enhancer and the downstream 3' regions acting as locus control regions (LCRs) have allowed comparisons to be drawn between regulation of the IgH locus in early and late B-cell development and other systems governed by LCR activity. Here, the importance of the IgH 3'LCR and its putative functional role in the control of IgH gene expression is evaluated and compared with the 5'LCR regulatory region of the human beta-globin locus.