The expression of human alpha -like globin genes in transgenic mice mediated by bacterial artificial chromosome

Functional validation of mouse tyrosinase non-coding regulatory DNA elements by CRISPR-Cas9-mediated mutagenesis

Newly developed genome-editing tools, such as the clustered regularly interspaced short palindromic repeat (CRISPR)-Cas9 system, allow simple and rapid genetic modification in most model organisms and human cell lines. Here, we report the production and analysis of mice carrying the inactivation via deletion of a genomic insulator, a key non-coding regulatory DNA element found 5' upstream of the mouse tyrosinase (Tyr) gene. Targeting sequences flanking this boundary in mouse fertilized eggs resulted in the efficient deletion or inversion of large intervening DNA fragments delineated by the RNA guides. The resulting genome-edited mice showed a dramatic decrease in Tyr gene expression as inferred from the evident decrease of coat pigmentation, thus supporting the functionality of this boundary sequence in vivo, at the endogenous locus. Several potential off-targets bearing sequence similarity with each of the two RNA guides used were analyzed and found to be largely intact. This study reports how non-coding DNA elements, even if located in repeat-rich genomic sequences, can be efficiently and functionally evaluated in vivo and, furthermore, it illustrates how the regulatory elements described by the ENCODE and EPIGENOME projects, in the mouse and human genomes, can be systematically validated.

Identification of long range regulatory elements of mouse alpha-globin gene cluster by quantitative associated chromatin trap (QACT)

Chromatin from different regions of the genome frequently forms steady associations that play important roles in regulating gene expression. The widely used chromatin conformation capture (3C) assay allows determination of the in vivo structural organization of an active endogenous locus. However, unpredicted chromatin associations within a given genomic locus can not be identified by 3C. Here, we describe a new strategy, quantitative associated chromatin trap (QACT), which incorporates a modified 3C method and a quantitative assay tool, to capture and quantitatively analyzes all possible associated chromatin partners (ACPs) of a given chromatin fragment. Using QACT, we have analyzed the chromatin conformation of the mouse alpha-globin gene cluster and proved the extensive interaction between HS26 and alpha-globin genes. In addition, we have identified a candidate alpha1-globin gene specific silencer 475A8 which shows the differentiation-stage specific DNase I hypersensitivity. Functional analysis suggests that 475A8 may regulate the alpha1-globin gene during terminal differentiation of committed erythroid progenitor cells. ChIP (chromatin immunoprecipitation) and cotransfection assays demonstrate that GATA-1, a hemopoietic specific transcriptional factor, may increase alpha1-globin gene expression by suppressing the function of 475A8 in terminally differentiated erythroid cells.

Cluster specific regulation pattern of upstream regulatory elements in human alpha- and beta-globin gene clusters

Located in different chromatin contexts and with different developmental switching mode, human alpha- and beta-globin gene clusters are co-regulated temporally and quantitatively to keep balanced expression. Here, by exchanging their key upstream regulatory elements (UREs) in cluster level, and investigating the expression level of exogenous globin genes in the bacterial artificial chromosome (BAC) mediated transgenic mice, we explored the similarities and differences in the regulatory effects between alpha-upstream regulatory element (alpha-URE) and beta-locus control region (beta-LCR). The results showed that, after exchange, the developmental switching modes of human alpha- and beta-like globin genes had changed, with lost expression of epsilon- and alpha1-genes. Their expression levels also decreased. Our study suggests that the regulation of alpha-URE and beta-LCR on the expression level and developmental switching mode of downstream globin genes is cluster specific.

Unravelling the world of cis-regulatory elements

Genome-wide comparisons indicate that only studying the coding regions will not be enough for explaining the biological complexity of an organism, while the genetic variants and the epigenetic differences of cis-regulatory elements are crucial to elucidate many complicated biological phenomena. Their various regulatory functions also play indispensable roles in forming organismal polymorphism. Recent studies showed that the cis-regulatory elements can regulate gene expression as nuclear organizers, and involve in functional noncoding transcription and produce regulatory noncoding RNA molecules. Novel high-throughput strategies and in silico analysis make a great amount data of cis-regulatory elements available. Particularly, the computational methods could help to combine reductionist studies with network biomedical investigations, and begin the era to understand organismal regulatory events at systems biology level.

Gene order in human alpha-globin locus is required for their temporal specific expressions

The human alpha-globin cluster represents a unique model of transcriptional regulation and provides challenges to the current understanding of interactions between distal and proximal regulatory elements. Although the gene proximal regions are believed to possess almost all the necessary elements for temporal and spatial specificity of gene transcription, it is still not clear whether the relative distance of embryonic zeta- and fetal/adult alpha-genes to their distal regulatory element alpha-URE plays any role in transcriptional switching. To investigate the role of gene order in regulating temporal expression, we inverted the entire structure gene region of human alpha-globin locus in a BAC clone bringing alpha-genes closest to alpha-URE and zeta-gene the farthest away. Expression analysis of the reverted locus in transgenic mice showed that alpha-globin genes, now relocated closer to alpha-URE, maintained their expression levels through all developmental stages. However, the zeta-globin gene suffered a total loss at both embryonic and fetal/adult stages. It indicates that proximal location of zeta-globin gene to alpha-URE is necessary for its normal embryonic expression and necessary to prevent embryonic expression of the alpha-globin gene. We proved that, in the human alpha-globin gene cluster, the normal order of structural genes relative to alpha-URE plays a crucial role in the regulation of developmental switching.

A general method to modify BACs to generate large recombinant DNA fragments

Bacterial artificial chromosome (BAC) has the capacity to clone DNA fragments in excess of 300 kb. It also has the considerable advantages of stable propagation and ease of purification. These features make BAC suitable in genetic research, such as library construction, transgenic mice production, and gene targeting constructs. Homologous recombination in Escherichia coli, a process named recombineering, has made the modification of BACs easy and reliable. We report here a modified recombineering method that can efficiently mediate the fusion of large DNA fragments from two or more different BACs. With the introduction of kanamycin-resistant gene and proposed rare-cutting restriction endonuclease (RCRE) sites into two BACs, a 82.6-kb DNA fragment containing the inverted human alpha-globin genes (theta, alpha1, alpha2, and zeta) from BAC191K2 and the locus control region (LCR) of human beta-globin gene locus (from the BAC186D7) was reconstructed. This approach for combining different BAC DNA fragments should facilitate many kinds of genomic experiments.

HS-48 alone has no enhancement role on the expression of human α-globin gene cluster

To investigate the in vivo function of the newly defined DNase I hypersensitive site HS-48 on the whole human alpha-globin gene cluster, the region containing all the other known 5 hypersensitive sites HS-4 to HS-40 was deleted from a 117 kb bacterial artificial chromosome clone bearing the whole human alpha-globin gene cluster. Transgenic mice were generated from this construct. The RNase protection assays showed that with HS-48 left and all the other 5 hypersensitive sites deleted, the expression of human alpha-like globin genes was completely silenced in embryonic, fetal and adult stages in all tissues. This finding indicates that HS-48 alone has no enhancer activity on the expression of human alpha-like globin genes, and that the region of HS-4 to HS-40 already contains all the upstream cis-elements needed for regulating human alpha-like globin genes.

Quantification of platelet composition in experimental venous thrombosis by real-time polymerase chain reaction

INTRODUCTION

Platelets play a key role in thrombus formation. Determination of the platelet component in a thrombus provides pathophysiological insights to the thrombotic event and aids in selecting an appropriate therapeutic intervention. In this study a sensitive and reliable method to characterize the cellular components of experimental thrombi was developed using real-time polymerase chain reaction (PCR).

METHODS AND RESULTS

Vena cava thrombosis was induced by either oxidative injury to topical FeCl(2) (FeCl(2)-VT) or stenosis-limited blood flow and a hypotonic pressure stress (stasis-VT) in rats. High levels of platelets were identified in the thrombus containing vessels by real-time PCR analysis of target gene amplification using the 2(-DeltaDeltaCT) values by normalizing the data with gene expression in naive vessels and with a housekeeping gene, ribosomal protein L32. By this analysis, the levels of PF-4 (as a platelet marker) mRNA were significantly higher in FeCl(2)-VT (2(-DeltaDeltaCT)=7.8) than in stasis-VT (2(-DeltaDeltaCT)=4.2, p<0.05). Enhanced platelet enrichment in FeCl(2)-VT was also confirmed qualitatively by scanning electronic microscopic analysis. In addition, real-time PCR using a panel of genes representing vascular injury, inflammation and thrombosis showed marked induction (2(-DeltaDeltaCT)>5) in MCP-1, IL-1beta, iNOS and P-selectin mRNA expression in both models.

CONCLUSIONS

These data demonstrate the utility of real-time PCR to quantitate platelets and other cell components in vascular thrombosis, which may facilitate the characterization and thus therapeutic intervention of a particular thrombotic event in both preclinical animal models and clinical conditions.

Epidermal langerhans cell-deficient mice develop enhanced contact hypersensitivity

Epidermal Langerhans cells (LCs), a distinct skin-resident dendritic cell population, acquire antigen in the skin and migrate to draining lymph nodes where they are thought to initiate adaptive immune responses. To examine the functional requirement of LCs in skin immunity, we generated BAC transgenic mice in which the regulatory elements from human Langerin were used to drive expression of diphtheria toxin. The resulting mice have a constitutive and durable absence of epidermal LCs but are otherwise intact. Unexpectedly, we found that contact hypersensitivity (CHS) was amplified rather than abrogated in the absence of LCs. Moreover, we showed that LCs act during the priming and not the effector phase. Thus, LCs not only were dispensable for CHS, but they served to regulate the response, a previously unappreciated function.

Hematopoietic transcription factor GATA-2 promotes upregulation of alpha globin and cell death in FL5.12 cells

Recently we showed that alpha globin is a novel pro-apoptotic factor in programmed cell death in the pro-B cell line, FL5.12. Alpha globin was also upregulated in various other cell lines after different apoptotic stimuli. Under withdrawal of IL-3, overexpression of alpha globin accelerated apoptosis in FL5.12. Here, we have studied how transcription of alpha globin is placed in the broader context of apoptosis. We used Affymetrix chip technology and RT QPCR to compare expression patterns of FL5.12 cells growing with or without IL-3 to search for transcription factors which were concomitantly upregulated with alpha globin. The erythroid-specific transcription factor GATA-2 was the earliest and most prominently upregulated candidate. GATA-1 was expressed at low levels and was weakly induced while GATA-3 was completely absent. To evaluate the influence of GATA-2 on alpha globin expression and cell viability we overexpressed GATA-2 in FL5.12 cells. Interestingly, high expression of GATA-2 resulted in cell death and elevated alpha globin levels in FL5.12 cells. Transduction of antisense GATA-2 prevented both increase of GATA-2 and alpha globin under apoptotic conditions and delayed cell death. We suggest a role of GATA-2 in apoptosis besides its function in maintenance and proliferation of immature hematopoietic progenitors.

A 191-kb genomic fragment containing the human alpha-globin locus can rescue alpha-thalassemic mice

A 191-kb human bacterial artificial chromosome (BAC) containing the human alpha-globin genomic locus was used to generate transgenic mice that express, exclusively, human alpha-globin ((hu)alpha-globin). Expression of (hu)alpha-globin reaches a level of 36% of that of endogenous mouse alpha-globin ((mu)alpha-globin) on a heterozygous mouse alpha-thalassemia background ((mu)alpha-globin knockout, (mu)alpha(+/-)). Hemizygous transgenic mice carrying the (hu)alpha-globin locus on a heterozygous knockout background ((hu)alpha(+/0), (mu)alpha(++/--)) demonstrated complementation of most hematologic parameters. By crossing (hu)alpha(+/0), (mu)alpha(++/--) mice, we were able to generate mice entirely dependent on (hu)alpha-globin synthesis. Breeding and fluorescent in situ hybridization studies demonstrate that only mice homozygous for the transgene were able to rescue embryonic lethal homozygous (mu)alpha-globin knockout embryos ((mu)alpha(--/--)). Adult rescued mice produce hemoglobin at levels similar to wild-type mice, with partial red cell complementation based on mean corpuscular volume (MCV), mean corpuscular hemoglobin (MCH), and red cell distribution width (RDW) measurements. Significant erythrocythemia above wild-type levels seems to be the main compensatory mechanism for the normalization of the hemoglobin levels in the rescued animals. Our studies demonstrate that the (hu)alpha-globin locus in the 191-kb transgene contains all the necessary elements for the regulated expression of (hu)alpha-globin in transgenic mice. This animal model should be valuable for studying the mechanisms regulating (hu)alpha-globin production and for development of therapeutic strategies for beta-thalassemia based on downregulation of alpha-globin expression.

Understanding α-Globin Gene Regulation: Aiming to Improve the Management of Thalassemia

Over the past 50 years, many advances in our understanding of the general principles controlling gene expression during hematopoiesis have come from studying the synthesis of hemoglobin. Discovering how the alpha- and beta-globin genes are normally regulated and documenting the effects of inherited mutations that cause thalassemia have played a major role in establishing our current understanding of how genes are switched on or off in hematopoietic cells. Previously, nearly all mutations causing thalassemia have been found in or around the globin loci, but rare inherited and acquired trans-acting mutations are being found more often. Such mutations have demonstrated new mechanisms underlying human genetic disease. Furthermore, they are revealing new pathways in the regulation of globin gene expression that, in turn, may open up new avenues for improving the management of patients with common types of thalassemia.

Knockdown of mouse adult beta-globin gene expression in MEL cells by retrovirus vector-mediated RNA interference

RNA interference (RNAi) efficiently induces sequence-specific gene silencing in mammalian cells through short interfering RNA (siRNA) of 21-23 nucleotides synthesized in vitro or expressed by DNA-based vector. However, introduction of siRNA into mammalian cells by transfection limits the application of RNAi, especially when it is necessary to generate long-term gene silencing in vivo. Virus vector-mediated RNAi provides an alternative to transfection. In the present study, we investigated such transduction system and showed that retrovirus vector-mediated RNAi can substantially down-regulate expression of mouse adult beta-globin gene in MEL cells. The results suggest that retrovirus vector-delivered RNAi may find its use in functional genomics and in gene therapy.

Chromatin domain boundaries: insulators and beyond

The eukaryotic genome is organized into functionally and structurally distinct domains, representing regulatory units for gene expression and chromosome behavior. DNA sequences that mark the border between adjacent domains are the insulators or boundary elements, which are required in maintenance of the function of different domains. Some insulators need others enable to play insulation activity. Chromatin domains are defined by distinct sets of post-translationally modified histones. Recent studies show that these histone modifications are also involved in establishment of sharp chromatin boundaries in order to prevent the spreading of distinct domains. Additionally, in some loci, the high-order chromatin structures for long-range looping interactions also have boundary activities, suggesting a correlation between insulators and chromatin loop domains. In this review, we will discuss recent progress in the field of chromatin domain boundaries.

Complementation of alpha-thalassaemia in alpha-globin knockout mice with a 191 kb transgene containing the human alpha-globin locus

alpha-thalassaemia is an inherited blood disorder caused by a decrease in the synthesis of alpha-globin due to mutations in one or both of the alpha-globin genes located on human chromosome 16. A 191 kb transgene derived from a sequenced bacterial artificial chromosome (BAC) clone carrying the human alpha-globin gene cluster, together with about 100 kb of sequence upstream of DNase1 hypersensitive site HS-40 and 30 kb downstream of the alpha1-globin gene, was introduced into fertilised mouse oocytes by pronuclear microinjection. Three transgenic founder mice were obtained. Analysis of one transmitting line by fluorescent in situ hybridisation and quantitative PCR demonstrated a single copy integration of the human alpha-globin transgene on chromosome 1. Analysis of haemoglobins from the peripheral blood by cellulose acetate electrophoresis and high performance liquid chromatography (HPLC) demonstrated synthesis of human alpha-globin to about 36% of the level of each mouse alpha-globin locus. Breeding of transgenic mice with mice heterozygous for a knockout (KO) deletion of both murine alpha-globin genes showed that the human alpha-globin locus restored haemoglobin levels and red cell distribution width to normal in double heterozygous mice and significantly normalised other haematological parameters. Interestingly the human transgene also induced a significant increase in red cell production and haematocrit above wild type values. This is the first report demonstrating complementation of a murine alpha-globin KO mutation by human alpha-globin gene expression from an intact human alpha-globin locus. The transgenic mouse model described in this report should be very useful for the study of human alpha-globin gene regulation and for the development of strategies to down regulate alpha-globin production as a means of ameliorating the severity of beta-thalassaemia.

The expression of intact and mutant human apoAI/CIII/AIV/AV gene cluster in transgenic mice

The apoAI/CIII/AIV gene cluster is involved in lipid metabolism and has a complex pattern of gene expression modulated by a common regulatory element, the apoCIII enhancer. A new member of this cluster, apolipoprotein (apo) AV, has recently been discovered as a novel modifier in triglyceride metabolism. To determine the expression of all four apo genes in combination and, most importantly, whether the transcription of apoAV is coregulated by the apoCIII enhancer in the cluster, we generated an intact transgenic line carrying the 116-kb human apoAI/CIII/AIV/AV gene cluster and a mutant transgenic line in which the apoCIII enhancer was deleted from the 116-kb structure. We demonstrated that the apoCIII enhancer regulated hepatic and intestinal apoAI, apoCIII, and apoAIV expression; however, it did not direct the newly identified apoAV in the cluster. Furthermore, human apo genes displayed integrated position-independent expression and a closer approximation of copy number-dependent expression in the intact transgenic mice. Because apoCIII and apoAV play opposite roles in triglyceride homeostasis, we analyzed the lipid profiles in our transgenic mice to assess the effects of human apoAI gene cluster expression on lipid metabolism. The triglyceride level was elevated in intact transgenic mice but decreased in mutant ones compared with nontransgenic mice. In addition, the expression of human apoAI and apoAIV elevated high density lipoprotein cholesterol in transgenic mice fed an atherogenic diet. In conclusion, our studies with human apoAI/CIII/AIV/AV gene cluster transgenic models showed that the apoCIII enhancer regulated expression of apoAI, apo-CIII, and apoAIV but not apoAV in vivo and showed the influences of expression of the entire cluster on lipid metabolism.

No existence of translocus balancer to coordinate the expression and regulation of human hemoglobin genes in transgenic mice study

All mammals use hemoglobin (Hb) to transport oxygen. Each Hb molecule is a tetramer of two pairs of unlike globin polypeptide chains. Equal amount of subunit globin chains derived from the corresponding alpha- and beta-like genes can always result during development though the two separate gene clusters are located on two different chromosomes and spatially transcribed within different nuclear domains. Disturbance of this balance will result in degradation or precipitation of the excessive globin chains, which is the character of various thalassemic syndromes. In previous studies, we had established two kinds of bacterial artificial chromosome (BAC) mediated transgenic mouse models, which contain respectively the entire human alpha- and beta-globin cluster. Here, we investigated the regulatory relationship between the two clusters by interbreeding these two kinds of transgenic mice. The levels of human alpha- and beta-mRNA in the various hybrid lines reflect the levels in the original transgenic lines that contain either the alpha- or beta-globin cluster alone. The results suggested that there is no apparent cross talk or regulatory interaction between the two human globin clusters in transgenic mice.

Ham-Wasserman Lecture

Over the past fifty years, many advances in our understanding of the general principles controlling gene expression during hematopoiesis have come from studying the synthesis of hemoglobin. Discovering how the α and β globin genes are normally regulated and documenting the effects of inherited mutations which cause thalassemia have played a major role in establishing our current understanding of how genes are switched on or off in hematopoietic cells. Previously, nearly all mutations causing thalassemia have been found in or around the globin loci, but rare inherited and acquired trans-acting mutations are being found with increasing frequency. Such mutations have demonstrated new mechanisms underlying human genetic disease. Furthermore, they are revealing new pathways in the regulation of globin gene expression which, in turn, may eventually open up new avenues for improving the management of patients with common types of thalassemia.

Developmental markers of B cells are superior to those of T cells for identification of stages with distinct gene expression profiles

B and T lymphocytes develop through a series of cellular stages, which are defined by recombination status of the immunoglobulin and T cell receptor loci and can be separated by analysis of cell-surface markers. We evaluated how well 26 and 41 samples from five and eight developmental stages of B and T cell development, respectively, could be correctly assigned to their lineage of origin and developmental stage by analysis of the expression of 13,026 genes and expressed sequence tags (ESTs). The RNA expression patterns of eight genes correctly classified all 67 samples as belonging to the B cell or to the T cell lineage. Ninety-two to 100% of B-lineage samples could be correctly assigned to the protein-defined developmental stage by the RNA expression pattern of 29 genes. By contrast, RNA expression patterns of 39 genes were necessary to correctly assign 85-100% of T-lineage samples to the correct developmental stage. The sets of genes used for these classifications contain ESTs as well as known genes that have not previously been associated with lymphocyte development. Graphical display of the classifications shows that B-lineage samples are well separated from T-lineage samples, and samples from the five stages of B cell development are well separated from each other. By contrast, samples from the eight stages of T cell development cannot be separated precisely. We conclude that the protein markers currently widely used for separating stages of B cell development better identify molecularly distinct stages than those used for separating stages of T cell development.

Evaluation of optimal expression cassette in retrovirus vector for beta-thalassemia gene therapy

Trials of retroviral vector-mediated human beta-globin gene transfer were hampered by low titers, unstable vector transmission, and low-level expression of transferred gene. With the goal of optimizing the retrovirally encoded human beta-globin gene expression cassette for gene therapy of beta-thalassemia, we generated 3 series of vector constructs (a total of 12 constructs) and investigated the effects of the proximal promoter, 3' - enhancer, and derivatives from the beta-locus control region or alpha-major regulatory element on virus titer, vector transmission stability, and gene expression. The virus titers for 9 of the 12 vector constructs ranged between 2.8 x 10(4) cfu/mL and 1.0 x 10(6) cfu/mL. We found that proviral DNA was intact in most G418- resistant murine erythroleukemia (MEL) cell clones for 5 vector constructs, while obvious genetic instability was observed for 4 other vector constructs. MEL cells harboring the intact provirus were induced to differentiate, and human beta-globin gene expression was analyzed with RNase protection assay. The percentage of human beta-globin transcript relative to endogenous murine alpha-globin transcript were 101.8 +/- 64.3% (n = 10), 40.1 +/- 28.7% (n = 4), 31.1 +/- 31.9% (n = 12), 52.4 +/- 11.2% (n = 12), and 53.6 +/- 8.6% (n = 12) for the 5 constructs, respectively, demonstrating the development of optimized retroviral vectors for beta-globin gene therapy with murine erythroid cell lines as a model. Unexpectedly, we also documented that the point mutation 8700(C-->T) in DNase I hypersensitive site 2 (HS2) core fragment might contribute to low-level expression of the human beta-globin gene, based on a comparison of results from transfected and transduced MEL cells and sequence analysis of proviral DNA.

The control of expression of the alpha-globin gene cluster

The alpha-globin gene cluster is located at the very tip of the short arm of chromosome 16. It produces the alpha-like globins, which is combined with the beta-like globins to form hemoglobin, and its mutants cause alpha-thalassemia, which is one of the most common genetic diseases. Its expression shows a tissue and developmental stage specificity that is balanced with that of the beta-globin gene cluster. In this article, we summarize the research on the control of expression of the alpha-globin gene cluster, mainly with respect to the alpha-major regulatory element (alpha-MRE): HS-40, the tissue-specific and developmental control of its expression, and its chromosomal environment. In summary, the alpha-globin gene cluster is expressed in an open chromosomal environment; HS-40, the 5'-flanking sequence, the transcribed region, and the 3'-flanking sequence interact to fully regulate its expression.

Deletion of the mouse alpha-globin regulatory element (HS -26) has an unexpectedly mild phenotype

Natural deletions of the region upstream of the human alpha-globin gene cluster, together with expression studies in cell lines and transgenic mice, identified a single element (HS -40) as necessary and perhaps sufficient for high-level expression of the alpha-globin genes. A similar element occupies the corresponding position upstream of the mouse (m) alpha-globin genes (mHS -26) and was thought to have similar functional properties. We knocked out mHS -26 by homologous recombination and observed the surprising result that instead of the expected severe alpha-thalassemia phenotype, the mice had a mild disease. Transcription levels of the mouse genes were reduced by about 50%, but homozygotes were healthy, with normal hemoglobin levels and only mild decreases in mean corpuscular volume and mean corpuscular hemoglobin. These results may indicate differences in the regulation of the alpha-globin clusters in mice and humans or that additional cis-acting elements remain to be characterized in one or both clusters.