DNaseI hypersensitivity and ultraconservation reveal novel, interdependent long-range enhancers at the complex Pax6 cis-regulatory region

The PAX6 gene plays a crucial role in development of the eye, brain, olfactory system and endocrine pancreas. Consistent with its pleiotropic role the gene exhibits a complex developmental expression pattern which is subject to strict spatial, temporal and quantitative regulation. Control of expression depends on a large array of cis-elements residing in an extended genomic domain around the coding region of the gene. The minimal essential region required for proper regulation of this complex locus has been defined through analysis of human aniridia-associated breakpoints and YAC transgenic rescue studies of the mouse smalleye mutant. We have carried out a systematic DNase I hypersensitive site (HS) analysis across 200 kb of this critical region of mouse chromosome 2E3 to identify putative regulatory elements. Mapping the identified HSs onto a percent identity plot (PIP) shows many HSs correspond to recognisable genomic features such as evolutionarily conserved sequences, CpG islands and retrotransposon derived repeats. We then focussed on a region previously shown to contain essential long range cis-regulatory information, the Pax6 downstream regulatory region (DRR), allowing comparison of mouse HS data with previous human HS data for this region. Reporter transgenic mice for two of the HS sites, HS5 and HS6, show that they function as tissue specific regulatory elements. In addition we have characterised enhancer activity of an ultra-conserved cis-regulatory region located near Pax6, termed E60. All three cis-elements exhibit multiple spatio-temporal activities in the embryo that overlap between themselves and other elements in the locus. Using a deletion set of YAC reporter transgenic mice we demonstrate functional interdependence of the elements. Finally, we use the HS6 enhancer as a marker for the migration of precerebellar neuro-epithelium cells to the hindbrain precerebellar nuclei along the posterior and anterior extramural streams allowing visualisation of migratory defects in both pathways in Pax6(Sey/Sey) mice.     

A survey of ancient conserved non-coding elements in the PAX6 locus reveals a landscape of interdigitated cis-regulatory archipelagos

Biological differences between cell types and developmental processes are characterised by differences in gene expression profiles. Gene-distal enhancers are key components of the regulatory networks that specify the tissue-specific expression patterns driving embryonic development and cell fate decisions, and variations in their sequences are a major contributor to genetic disease and disease susceptibility. Despite advances in the methods for discovery of putative cis-regulatory sequences, characterisation of their spatio-temporal enhancer activities in a mammalian model system remains a major bottle-neck. We employed a strategy that combines gnathostome sequence conservation with transgenic mouse and zebrafish reporter assays to survey the genomic locus of the developmental control gene PAX6 for the presence of novel cis-regulatory elements. Sequence comparison between human and the cartilaginous elephant shark (Callorhinchus milii) revealed several ancient gnathostome conserved non-coding elements (agCNEs) dispersed widely throughout the PAX6 locus, extending the range of the known PAX6 cis-regulatory landscape to contain the full upstream PAX6-RCN1 intergenic region. Our data indicates that ancient conserved regulatory sequences can be tested effectively in transgenic zebrafish even when not conserved in zebrafish themselves. The strategy also allows efficient dissection of compound regulatory regions previously assessed in transgenic mice. Remarkable overlap in expression patterns driven by sets of agCNEs indicates that PAX6 resides in a landscape of multiple tissue-specific regulatory archipelagos.     

Analysis of control elements for position‐independent expression of human α‐lactalbumin YAC

A major problem in the production of transgenic animal bioreactors using microinjections is the low production rate of high‐expressing transgenic animals due to the position effect. We previously reported that transgenic rats carrying the 210 kb yeast artificial chromosome (YAC) including the human α‐lactalbumin gene express the transgene in a position‐independent manner. The 210 kb YAC was thought to have all the elements necessary for position‐independent expression. In this paper, we constructed fragmented YAC clones and a cosmid clone, and produced transgenic rats to analyze these elements. Transgenic rats with both the 50 kb upstream and downstream regions of the α‐lactalbumin gene had position‐independent expression. Transgenic rats with the 20 kb upstream and downstream regions, however, had position‐dependent expression. Therefore, all the elements necessary for position‐independent expression are thought to be located in the 50 kb upstream to 50 kb downstream region of the α‐lactalbumin gene. Furthermore, we replaced the human α‐lactalbumin promoter with the bovine αS1‐casein promoter in the 210 kb YAC and produced transgenic rats. Position‐dependent expression was observed. The elements required for position‐independent expression of the bovine αS1‐casein gene are different from those required for the human α‐lactalbumin gene, despite the fact that the two genes have the same tissue and developmental specificity. Mol. Reprod. Dev. 54:17–23, 1999. © 1999 Wiley‐Liss, Inc.     

A locus control region at -12 kb of the tyrosinase gene.

We have shown previously that the tyrosinase gene encompassed in a 250 kb yeast artificial chromosome (YAC) is expressed faithfully in transgenic mice. To define the sequences important for this qualitatively and quantitatively correct expression pattern, we have generated transgenic mice with YACs carrying several deletions in the mouse tyrosinase locus. In particular, we wanted to address the in vivo relevance of a regulatory element indicated by a cell-specific DNase I hypersensitive site (HS) located -12 kb upstream of the gene. Wild-type level expression was observed only when the YACs transferred contained this HS. Constructs in which the HS was deleted gave rise to much weaker expression and variable patterns of expression. In conclusion, this HS region appears to harbour the essential regulatory element for the correct expression of the tyrosinase gene. Moreover, it behaves as a locus control region in that it commands the functional status of this expression domain, protecting it from position effects.     

Disruption of Autoregulatory Feedback by a Mutation in a Remote,Ultraconserved PAX6 Enhancer Causes Aniridia

The strictly regulated expression of most pleiotropic developmental control genes is critically dependent on the activity of long-range cis-regulatory elements. This was revealed by the identification of individuals with a genetic condition lacking coding-region mutations in the gene commonly associated with the disease but having a variety of nearby chromosomal abnormalities, collectively described as cis-ruption disease cases. The congenital eye malformation aniridia is caused by haploinsufficiency of the developmental regulator PAX6. We discovered a de novo point mutation in an ultraconserved cis-element located 150 kb downstream from PAX6 in an affected individual with intact coding region and chromosomal locus. The element SIMO acts as a strong enhancer in developing ocular structures. The mutation disrupts an autoregulatory PAX6 binding site, causing loss of enhancer activity, resulting in defective maintenance of PAX6 expression. These findings reveal a distinct regulatory mechanism for genetic disease by disruption of an autoregulatory feedback loop critical for maintenance of gene expression through development.     

Position independence and proper developmental control of gamma-globin gene expression require both a 5'' locus control region and a downstream sequence element.

We have analyzed the expression of human gamma-globin genes during development in F2 progeny of transgenic mice carrying two types of constructs. In the first type, gamma-globin genes were linked individually to large (approximately 4-kb) sequence fragments spanning locus control region (LCR) hypersensitive site 2 (HS2) or HS3. These LCR fragments contained not only the core HS elements but also extensive evolutionarily conserved flanking sequences. The second type of construct contained tandem gamma- and beta-globin genes linked to identical HS2 or HS3 fragments. We show that gamma-globin expression in transgenic mice carrying HS2 gamma or HS3 gamma constructs is highly sensitive to position effects and that such effects override the cis regulatory elements present in these constructs to produce markedly different developmental patterns of gamma-globin expression in lines carrying the same transgene. In contrast, gamma-globin expression in both HS2 gamma beta and HS3 gamma beta mice is sheltered from position effects and the developmental patterns of gamma-globin expression in lines carrying the same transgene are identical and display stage-specific regulation. The results suggest that cis regulatory sequences required for proper developmental control of fetal globin expression in the presence of an LCR element reside downstream from the gamma genes.     

Appropriate expression of the mouse H19 gene utilises three or more distinct enhancer regions spread over more than 130 kb

H19 and Igf2 are closely linked, reciprocally imprinted genes which lie on distal chromosome 7 in the mouse. Data suggests that common elements are used for expression and imprinting of both genes, and simple models have been proposed based on the presence of a single set of enhancers located downstream of H19. In this study we have investigated the H19 expression pattern from a 130 kb YAC transgene, which imprints H19 appropriately at ectopic loci. However, we show that while enhancers for expression in many cell types are present on the YAC, those for expression in mesodermal components of the heart, kidney, lung and thymus are located at a greater distance. Based on the available evidence, we conclude that regulation of H19 is complex, requiring contribution from at least three different sets of cell-type specific enhancers. Thus, the mechanism of reciprocal imprinting of H19 and Igf2 utilises different regulatory elements in different cell types during mouse development.     

Cell-type-specific long-range looping interactions identify distant regulatory elements of the CFTR gene

Identification of regulatory elements and their target genes is complicated by the fact that regulatory elements can act over large genomic distances. Identification of long-range acting elements is particularly important in the case of disease genes as mutations in these elements can result in human disease. It is becoming increasingly clear that long-range control of gene expression is facilitated by chromatin looping interactions. These interactions can be detected by chromosome conformation capture (3C). Here, we employed 3C as a discovery tool for identification of long-range regulatory elements that control the cystic fibrosis transmembrane conductance regulator gene, CFTR. We identified four elements in a 460-kb region around the locus that loop specifically to the CFTR promoter exclusively in CFTR expressing cells. The elements are located 20 and 80 kb upstream; and 109 and 203 kb downstream of the CFTR promoter. These elements contain DNase I hypersensitive sites and histone modification patterns characteristic of enhancers. The elements also interact with each other and the latter two activate the CFTR promoter synergistically in reporter assays. Our results reveal novel long-range acting elements that control expression of CFTR and suggest that 3C-based approaches can be used for discovery of novel regulatory elements.     

In vivo analysis of DNase I hypersensitive sites in the human CFTR gene.

BACKGROUND: The cystic fibrosis transmembrane conductance regulator gene (CFTR) shows a complex pattern of expression. The regulatory elements conferring tissue-specific and temporal regulation are thought to lie mainly outside the promoter region. Previously, we identified DNase I hypersensitive sites (DHS) that may contain regulatory elements associated with the CFTR gene at -79.5 and at -20.5 kb with respect to the ATG and at 10 kb into the first intron. MATERIALS AND METHODS: In order to evaluate these regulatory elements in vivo we examined these DHS in a human CFTR gene that was introduced on a yeast artificial chromosome (YAC) into transgenic mice. The 310 kb human CFTR YAC was shown to restore the pheno-type of CF-null mice and so is likely to contain most of the regulatory elements required for tissue-specific expression of CFTR. RESULTS: We found that the YAC does not include the -79.5 kb region. The DHS at -20.5 kb is present in the chromatin of most tissues of the transgenic mice, supporting its non-tissue-specific nature. The DHS in the first intron is present in a more restricted set of tissues in the mice, although its presence does not show complete concordance with CFTR expression. The intron I DHS may be important for the higher levels of expression found in human pancreatic ducts and in lung submucosal glands. CONCLUSION: These data support the in vivo importance of these regulatory elements.     

Regulation of growth differentiation factor 9 expression in oocytes in vivo: a key role of the E-box

Growth differentiation factor 9 (GDF9) is preferentially expressed in oocytes and is essential for female fertility. To identify regulatory elements that confer high-level expression of GDF9 in the ovary but repression in other tissues, we generated transgenic mice in which regions of the Gdf9 locus were fused to reporter genes. Two transgenes (-10.7/+5.6mGdf9-GFP) and (-3.3/+5.6mGdf9-GFP) that contained sequences either 10.7 or 3.3 kb upstream and 5.6 kb downstream of the Gdf9 initiation codon demonstrated expression specifically in oocytes, thereby mimicking endogenous Gdf9 expression. In contrast, transgenes -10.7mGdf9-Luc and -3.3mGdf9-Luc, which lacked the downstream 5.6-kb region, demonstrated reporter expression not only in oocytes but also high expression in male germ cells. This suggests that the downstream 5.6-kb sequence contains a testis-specific repressor element and that 3.3 kb of 5'-flanking sequence contains all the cis-acting elements for directing high expression of Gdf9 to female (and male) germ cells. To define sequences responsible for oocyte expression of Gdf9, we analyzed sequences of Gdf9 genes from 16 mammalian species. The approximately 400 proximal base pairs upstream of these Gdf9 genes are highly conserved and contain a perfectly conserved E-box (CAGCTG) sequence. When this 400-bp region was placed upstream of a luciferase reporter (-0.4mGdf9-Luc), oocyte-specific expression was observed. However, a similar transgene construct (-0.4MUT-mGdf9-Luc) with a mutation in the E-box abolished oocyte expression. Likewise, the presence of an E-box mutation in a longer construct (-3.3MUT-mGdf9-Luc) abolished expression in the ovary but not in the testis. These observations indicate that the E-box is a key regulatory sequence for Gdf9 expression in the ovary.     

Far-upstream elements are dispensable for tissue-specific proenkephalin expression using a Cre-mediated knock-in strategy

Several cis-regulatory DNA elements are present in the 5' upstream regulatory region of the enkephalin gene (ENK) promoter. To determine their role in conferring organ-specificity of ENK expression in mice and to circumvent the position effects from random gene insertion that are known to often frustrate such analysis in transgenic mice, we used a Cre-mediated gene knock-in strategy to target reporter constructs to a "safe haven" loxP-tagged locus in the hypoxanthine phosphoribosyltransferase (HPRT) gene. Here we report reliable and reproducible reporter gene expression under the control of the 5' upstream regulatory region of the mouse ENK gene in gene-modified mice using this Cre-mediated knock-in strategy. Comparison of two 5'ENK regulatory regions (one with and the other without known cis-regulatory DNA elements) in the resulting adult mice showed that conserved far-upstream cis-regulatory DNA elements are dispensable for correct organ-specific gene expression. Thus the proximal 1.4 kb of the murine ENK promoter region is sufficient for organ-specificity of ENK gene expression when targeted to a safe-haven genomic locus. These results suggest that conservation of the far-upstream DNA elements serves more subtle roles, such as the developmental or cell-specific expression of the ENK gene.