Theria-specific homeodomain and cis-regulatory element evolution of the Dlx3-4 bigene cluster in 12 different mammalian species.

The mammalian Dlx3 and Dlx4 genes are configured as a bigene cluster, and their respective expression patterns are controlled temporally and spatially by cis-elements that largely reside within the intergenic region of the cluster. Previous work revealed that there are conspicuously conserved elements within the intergenic region of the Dlx3-4 bigene clusters of mouse and human. In this paper we have extended these analyses to include 12 additional mammalian taxa (including a marsupial and a monotreme) in order to better define the nature and molecular evolutionary trends of the coding and non-coding functional elements among morphologically divergent mammals. Dlx3-4 regions were fully sequenced from 12 divergent taxa of interest. We identified three theria-specific amino acid replacements in homeodomain of Dlx4 gene that functions in placenta. Sequence analyses of constrained nucleotide sites in the intergenic non-coding region showed that many of the intergenic conserved elements are highly conserved and have evolved slowly within the mammals. In contrast, a branchial arch/craniofacial enhancer I37-2 exhibited accelerated evolution at the branch between the monotreme and therian common ancestor despite being highly conserved among therian species. Functional analysis of I37-2 in transgenic mice has shown that the equivalent region of the platypus fails to drive transcriptional activity in branchial arches. These observations, taken together with our molecular evolutionary data, suggest that theria-specific episodic changes in the I37-2 element may have contributed to craniofacial innovation at the base of the mammalian lineage.

Essential functions of the Williams-Beuren syndrome-associated TFII-I genes in embryonic development.

GTF2I and GTF2IRD1 encoding the multifunctional transcription factors TFII-I and BEN are clustered at the 7q11.23 region hemizygously deleted in Williams-Beuren syndrome (WBS), a complex multisystemic neurodevelopmental disorder. Although the biochemical properties of TFII-I family transcription factors have been studied in depth, little is known about the specialized contributions of these factors in pathways required for proper embryonic development. Here, we show that homozygous loss of either Gtf2ird1 or Gtf2i function results in multiple phenotypic manifestations, including embryonic lethality; brain hemorrhage; and vasculogenic, craniofacial, and neural tube defects in mice. Further analyses suggest that embryonic lethality may be attributable to defects in yolk sac vasculogenesis and angiogenesis. Microarray data indicate that the Gtf2ird1 homozygous phenotype is mainly caused by an impairment of the genes involved in the TGFbetaRII/Alk1/Smad5 signal transduction pathway. The effect of Gtf2i inactivation on this pathway is less prominent, but downregulation of the endothelial growth factor receptor-2 gene, resulting in the deterioration of vascular signaling, most likely exacerbates the severity of the Gtf2i mutant phenotype. A subset of Gtf2ird1 and Gtf2i heterozygotes displayed microcephaly, retarded growth, and skeletal and craniofacial defects, therefore showing that haploinsufficiency of TFII-I proteins causes various developmental anomalies that are often associated with WBS.

Identification of the TFII-I family target genes in the vertebrate genome.

GTF2I and GTF2IRD1 encode members of the TFII-I transcription factor family and are prime candidates in the Williams syndrome, a complex neurodevelopmental disorder. Our previous expression microarray studies implicated TFII-I proteins in the regulation of a number of genes critical in various aspects of cell physiology. Here, we combined bioinformatics and microarray results to identify TFII-I downstream targets in the vertebrate genome. These results were validated by chromatin immunoprecipitation and siRNA analysis. The collected evidence revealed the complexity of TFII-I-mediated processes that involve distinct regulatory networks. Altogether, these results lead to a better understanding of specific molecular events, some of which may be responsible for the Williams syndrome phenotype.

Multiple roles of hoxc8 in skeletal development.

We are interested in investigating the function of Hoxc8 in skeletogenesis during mouse development. Previous studies have shown that deregulation of Hoxc8 expression in the mouse leads to several skeletal defects, such as homeotic transformation in the thoracic vertebrae, abnormal development of the rib cage, and overproliferation of chondrocytes in the hypertrophic area. By deleting a crucial enhancer of Hoxc8 in vivo, we found that precise temporal expression of Hoxc8 is important for determining the correct identity of the vertebral column in early embryos. We also identified downstream targets of Hoxc8 relevant to osteoblast differentiation at later developmental stages.

A yeast-based recombinogenic targeting toolset for transgenic analysis of human disease genes.

Transgenic mouse models are valuable resources for analyzing functions of genes involved in human diseases. Mouse models provide critical insights into biological processes, including in vivo visualization of vasculature critical to our understanding of the immune system. Generating transgenic mice requires the capture and modification of large-insert DNAs representing genes of interest. We have developed a methodology using a yeast-bacterial shuttle vector, pClasper, that enables the capture and modification of bacterial artificial chromosomes (BAC)-sized DNA inserts. Numerous improvements and technical advances in the original pClasper vector have allowed greater flexibility and utility in this system. Examples of such pClasper mediated gene modifications include: Claspette-mediated capture of large-insert genomic fragments from BACs-human polycystic kidney disease-1 (PKD1); modification of pClasperA clones by the RareGap method-PKD1 mutations; Claspette-mediated modification of pClasper clones-mouse albumin-1 gene; and, of most relevance to our interest in lymph node vasculature-Claspimer-mediated modification of pClasper clones-high endothelial venule and lymphatic vessel genes. Mice that have been generated with these methods include mice with fluorescent high endothelial venules.

Mouse naked cuticle 2 (mNkd2) as a direct transcriptional target of Hoxc8 in vivo.

Mouse naked cuticle 2 (mNkd2), the mammalian homolog of the Drosophila segment polarity gene naked cuticle (nkd), encodes an EF hand protein that regulates early Wg activity by acting as an inducible antagonist. The transcription factor, Hoxc8, a member of the homeobox gene family, is vital for growth and differentiation. Chromatin immunoprecipitation (ChIP) assay, an electrophoretic mobility shift assay (EMSA), and a reporter assay demonstrated that endogenous Hoxc8 protein binds directly to the enhancer region of the mNkd2 gene, implying a Hoxc8-dependent transcriptional activity. Introduction of exogenous Hoxc8 into NIH3T3 cell lines lacking wild-type Hoxc8 dramatically reduced expression of mNkd2 mRNA. If, as the results suggest, mNkd2 is a direct target of Hoxc8, it represents a novel mechanism by which Hoxc8 might cross-talk with the Wnt signaling pathway by regulating mNkd2.

Transgenic LacZ under control of Hec-6st regulatory sequences recapitulates endogenous gene expression on high endothelial venules.

Hec-6st is a highly specific high endothelial venule (HEV) gene that is crucial for regulating lymphocyte homing to lymph nodes (LN). The enzyme is also expressed in HEV-like vessels in tertiary lymphoid organs that form in chronic inflammation in autoimmunity, graft rejection, and microbial infection. Understanding the molecular nature of Hec-6st regulation is crucial for elucidating its function in development and disease. However, studies of HEV are limited because of the difficulties in isolating and maintaining the unique characteristics of these vessels in vitro. The novel pClasper yeast homologous recombination technique was used to isolate from a BAC clone a 60-kb DNA fragment that included the Hec-6st (Chst4) gene with flanking sequences. Transgenic mice were generated with the beta-galactosidase (LacZ) reporter gene inserted in-frame in the exon II of Hec-6st within the isolated BAC DNA fragment. LacZ was expressed specifically on HEV in LN, as indicated by its colocalization with peripheral node vascular addressin. LacZ was increased in nasal-associated lymphoid tissue during development and was reduced in LN and nasal-associated lymphoid tissue by LTbetaR-Ig (lymphotoxin-beta receptor human Ig fusion protein) treatment in a manner identical to the endogenous gene. The transgene was expressed at high levels in lymphoid accumulations with characteristics of tertiary lymphoid organs in the salivary glands of aged mice. Thus, the Hec-6s-LacZ construct faithfully reproduces Hec-6st tissue-specific expression and can be used in further studies to drive expression of reporter or effector genes, which could visualize or inhibit HEV in autoimmunity.

Identification of a Hoxc8-regulated transcriptional network in mouse embryo fibroblast cells.

The transcription factor, Hoxc8, is a member of the homeobox gene family that is vital for growth and differentiation. Previously, we identified 34 genes whose expression levels were changed at least 2-fold by forced expression of Hoxc8 in C57BL/6J mouse embryo fibroblast cells using a mouse 16,463-gene oligonucleotide microarray. In the present study, we used the combined power of microarray profiling, global Hoxc8 DNA-binding site analysis, and high-throughput chromatin immunoprecipitation assays to identify direct and biologically relevant targets of Hoxc8 in vivo. Here we show that 19 of the 34 responsive genes contain Hoxc8 consensus DNA-binding sequence(s) in their regulatory regions. Chromatin immunoprecipitation analysis indicated that Hoxc8-DNA interaction was detected in five of the 19 candidate genes. All of these five target genes have been implicated in oncogenesis, cell adhesion, proliferation, and apoptosis. Overall, the genes described here should aid in the understanding of global regulatory networks of Hox genes and to provide valuable insight into the molecular basis of Hoxc8 in development and carcinogenesis.

The identification of Hoxc8 target genes.

Hox genes encode transcription factors that control spatial patterning during embryogenesis. To date, downstream targets of Hox genes have proven difficult to identify. Here, we describe studies designed to identify target genes under the control of the murine transcription factor Hoxc8. We used a mouse 16,463 gene oligonucleotide microarray to identify mRNAs whose expression was altered by the overexpression of Hoxc8 in C57BL/6J mouse embryo fibroblasts (MEF) in cell culture (in vitro). We identified a total of 34 genes whose expression was changed by 2-fold or greater: 16 genes were up-regulated, and 18 genes were down-regulated. The majority of genes encoded proteins involved in critical biological processes, such as cell adhesion, migration, metabolism, apoptosis, and tumorigenesis. Two genes showed high levels of regulation: (i) secreted phosphoprotein 1 (Spp1), also known as osteopontin (OPN), was down-regulated 4.8-fold, and (ii) frizzled homolog 2 (Drosophila) (Fzd2) was up-regulated 4.4-fold. Chromatin immunoprecipitation (ChIP) analysis confirmed the direct interaction between the OPN promoter and Hoxc8 protein in vivo, supporting the view that OPN is a direct transcriptional target of Hoxc8.

HnRNP A3 genes and pseudogenes in the vertebrate genomes.

The hnRNP A/B type proteins are abundant nuclear factors that bind to Pol II transcripts and are involved in numerous RNA-related activities. To date most data on the hnRNP A/B family have been obtained with recombinant proteins and cell cultures. Further characterization can result from an examination of the impact of various modifications in intact functional loci; however, such characterization is hampered by the presence of numerous and widely dispersed hnRNP A/B-related sequences in the mammalian genome. We have found hnRNP A3, a poorly recognized member of the hnRNP A/B family, among candidate transcription factors that interact with the regulatory region of the Hoxc8 gene and screened the human and mouse genomes for genes that encode hnRNP A3. We demonstrate that the sequence reported previously as the human hnRNP A3 gene (Accession number S63912) and located on 10p11.1 belongs to a processed pseudogene of the functional intron-containing locus HNRPA3, which we have identified on 2q31.2. We have also identified its murine orthologs on mouse chromosome 2D and rat chromosome 3q23. Alternative splices were revealed at the N-terminus and in the middle of hnRNP A3. 14 and 28 additional loci in the human and mouse genome, respectively, were mapped and identified as hnRNP A3 processed pseudogenes. In addition, we have found and compared hnRNP A3 orthologous genes in Gallus gallus, Xenopus tropicalis, and Danio rerio. The present in silico analysis serves as a necessary step toward a further functional characterization of hnRNP A3.

Impact of transgenic technologies on functional genomics.

Gene transfer technologies in mammals are the focus of renewed interest owing to the recent emphasis on analyzing gene function in the postgenomic era. Three important developments in this area include transgenics, gene targeting and nuclear transfer or animal cloning. These technological innovations have enhanced our ability to analyze gene function at the level of the whole organism and have provided the means to modify gene expression. This review discusses the origins and current status of transgenic technologies. Various applications and technologies including chromosome engineering, stem cells, gene traps and modification of livestock are presented. The impact of mouse technologies and genomics on functional analyses is also discussed.

Regulation of Dlx3 gene expression in visceral arches by evolutionarily conserved enhancer elements.

The mammalian Distal-less (Dlx) clusters (Dlx1-2, Dlx5-6, and Dlx3-7) have a nested expression pattern in developing visceral (branchial) arches. Genetic regulatory mechanisms controlling Dlx spatial expression within the visceral arches have not yet been defined. Here we show that an enhancer in the Dlx3-7 cluster can regulate the visceral arch specific expression pattern of the Dlx3 gene. We have used a 79-kb transgene construct containing the entire Dlx3-7 bigene cluster with a LacZ reporter inserted in frame in the first exon of the Dlx3 gene. Visceral arch expression is absent when a 4-kb element located within the Dlx3-7 intergenic region is deleted. A 245-bp element (I37-2) whose DNA sequence is highly conserved between human and mouse located within the 4kb-deleted region can drive visceral arch expression when fused to a hsp68-lacZ reporter transgene construct. Reporter expression is detected in 9.5 and 10.5 days postcoitum transgenic embryos in a manner consistent with the endogenous Dlx3 expression pattern in the mesenchyme of the first and second visceral arches. Thus the I37-2 element is both necessary and sufficient for Dlx3 expression. The I37-2 element contains several putative binding sites for several transcription factors including Dlx and other homeodomain proteins within the evolutionarily conserved region. Significantly, the I37-2 element shows a sequence-match including a Dlx binding site to a cis-element in the Dlx5-6 intermediate region designated mI56i [Zerucha, T., Stuhmer, T., Hatch, G., Park, B. K., Long, Q., Yu, G., Gambarotta, A., Schultz, J. R., Rubenstein, J. L. & Ekker, M. (2000) J. Neurosci. 20, 709-721], despite distant phylogenetic relationship between these clusters. Our results provide evidence for a concerted role for DLX auto- and cross-regulation in the establishment of a nested expression pattern for Dlx3-7 and Dlx5-6 clusters within the visceral arches.

Enhancer timing of Hox gene expression: deletion of the endogenous Hoxc8 early enhancer.

The proper expression of Hox genes is necessary for the accurate patterning of the body plan. The elucidation of the developmental genetic basis of transcriptional regulation of Hox genes by the study of their cis-regulatory elements provides crucial information regarding the establishment of axial specification. In this report, we investigate the role of the early enhancer (EE) of the murine Hoxc8 gene to better understand its role in pattern formation. Previous reports show that knockouts of the endogenous Hoxc8 coding region result in a combination of neural, behavioral and skeletal phenotypes. In this report, we limit ourselves to a consideration of the skeletal abnormalities. Early reports from our laboratory based on exogenous transgenic reporter constructs implicate a 200 bp non-coding element 3 kb upstream of the Hoxc8 promoter as a crucial enhancer that regulates the transcription of Hoxc8. In the present work, we have deleted this regulatory region from the endogenous genome using embryonic stem cell technology. Our results show that the deletion of the EE results in a significant delay in the temporal expression of Hoxc8. We also show that the deletion of the EE does not eliminate the expression of the Hoxc8 protein, but delays the attainment of control levels of expression and anterior and posterior boundaries of expression on the AP axis. The temporal delay in Hoxc8 expression is sufficient to produce phenocopies of many of the axial skeletal defects associated with the complete absence of Hoxc8 gene product as previously reported for the Hoxc8-null mutation. Our results are consistent with emerging evidence that the precise temporal expression of Hox genes is crucial for the establishment of regional identities. The fact that the EE deletion does not eliminate Hoxc8 expression indicates the existence of a Hoxc8 transcriptional regulatory apparatus independent to some degree of the Hoxc8 EE. In a comparison of our results with those reported previously by others investigating temporal control of Hox gene expression, we have discovered a structural similarity between the Hoxc8 EE reported here and a transcriptional control element located in the Hoxd11 region. We speculate that a distributed system of expression timing control may exist that is similar the one we propose for Hoxc8. Last, our data is consistent with the position that disparate regulatory pathways are responsible for the expression of Hoxc8 in the organogenesis of somites, neural tube and limb bud.

The role of gene duplication in the evolution and function of the vertebrate Dlx/distal-less bigene clusters.

The Dlx gene family controls developmental patterning principally in the pharyngeal and cranial regions. We review the structure and function of these genes in the vertebrates and relate these properties to their evolution. We particularly focus on the Dlx3-7 bigene cluster which we postulate to be more derived phylogenetically and functionally than the other two bigene clusters, Dlx1-2 and Dlx5-6. We stress the transcriptional control of the Dlx3-7 bigene cluster, and postulate its control by Dlx1-2.

Physical and functional interactions of histone deacetylase 3 with TFII-I family proteins and PIASxbeta.

TFII-I family proteins are characterized structurally by the presence of multiple reiterated I-repeats, each containing a putative helix-loop-helix domain. Functionally, they behave as multifunctional transcription factors that are activated by a variety of extracellular signals. In studying their subcellular localization, we noticed that these transcription factors frequently reside in subnuclear domains/dots. Because nuclear dots are believed often to harbor components of histone deacetylase enzymes (HDACs), we investigated whether TFII-I family proteins colocalize and interact with HDACs. Here, we show that TFII-I and its related member hMusTRD1/BEN physically and functionally interact with HDAC3. The TFII-I family proteins and HDAC3 also show nearly identical expression patterns in early mouse development. Consistent with our earlier observation that TFII-I family proteins also interact with PIASxbeta, a member of the E3 ligase family involved in the small ubiquitin-like modifier (SUMO) pathway, we show further that PIASxbeta physically and functionally interacts with HDAC3 and relieves the transcriptional repression exerted by HDAC3 upon TFII-I-mediated gene activation. These results suggest a complex interplay between two posttranslational pathways-histone modification and SUMOylation-brokered in part by TFII-I family proteins.

Phylogenetic analysis of the mammalian Hoxc8 non-coding region.

The non-coding intergenic regions of Hox genes are remarkably conserved among mammals. To determine the usefulness of this sequence for phylogenetic comparisons, we sequenced an 800-bp fragment of the Hoxc9-Hoxc8 intergenic region from several species belonging to different mammalian clades. Results obtained from the phylogenetic analysis are congruent with currently accepted mammalian phylogeny. Additionally, we found a TC mini satellite repeat polymorphism unique to felines. This polymorphism may serve as a useful marker to differentiate between mammalian species or as a genetic marker in feline matings. This study demonstrates usefulness of a comparative approach employing non-coding regions of Hox gene complexes.

The shark HoxN cluster is homologous to the human HoxD cluster.

The statistical analysis of phylogenetic footprints in the two known horn shark Hox clusters and the four mammalian clusters shows that the shark HoxN cluster is HoxD-like. This finding implies that the most recent common ancestor of jawed vertebrates had at least four Hox clusters, including those which are orthologous to the four mammalian Hox clusters.

Homez, a homeobox leucine zipper gene specific to the vertebrate lineage.

This work describes a vertebrate homeobox gene, designated Homez (homeodomain leucine zipper-encoding gene), that encodes a protein with an unusual structural organization. There are several regions within Homez, including three atypical homeodomains, two leucine zipper-like motifs, and an acidic domain. The gene is ubiquitously expressed in human and murine tissues, although the expression pattern is more restricted during mouse development. Genomic analysis revealed that human and mouse genes are located at 14q11.2 and 14C, respectively, and are composed of two exons. The zebrafish and pufferfish homologs share high similarity to mammalian sequences, particularly within the homeodomain sequences. Based on homology of homeodomains and on the similarity in overall protein structure, we delineate Homez and members of ZHX family of zinc finger homeodomain factors as a subset within the superfamily of homeobox-containing proteins. The type and composition of homeodomains in the Homez subfamily are vertebrate-specific. Phylogenetic analysis indicates that Homez lineage was separated from related genes >400 million years ago before separation of ray- and lobe-finned fishes. We apply a duplication-degeneration-complementation model to explain how this family of genes has evolved.

GTF2IRD2 is located in the Williams-Beuren syndrome critical region 7q11.23 and encodes a protein with two TFII-I-like helix-loop-helix repeats.

Williams-Beuren syndrome (also known as Williams syndrome) is caused by a deletion of a 1.55- to 1.84-megabase region from chromosome band 7q11.23. GTF2IRD1 and GTF2I, located within this critical region, encode proteins of the TFII-I family with multiple helix-loop-helix domains known as I repeats. In the present work, we characterize a third member, GTF2IRD2, which has sequence and structural similarity to the GTF2I and GTF2IRD1 paralogs. The ORF encodes a protein with several features characteristic of regulatory factors, including two I repeats, two leucine zippers, and a single Cys-2/His-2 zinc finger. The genomic organization of human, baboon, rat, and mouse genes is well conserved. Our exon-by-exon comparison has revealed that GTF2IRD2 is more closely related to GTF2I than to GTF2IRD1 and apparently is derived from the GTF2I sequence. The comparison of GTF2I and GTF2IRD2 genes revealed two distinct regions of homology, indicating that the helix-loop-helix domain structure of the GTF2IRD2 gene has been generated by two independent genomic duplications. We speculate that GTF2I is derived from GTF2IRD1 as a result of local duplication and the further evolution of its structure was associated with its functional specialization. Comparison of genomic sequences surrounding GTF2IRD2 genes in mice and humans allows refinement of the centromeric breakpoint position of the primate-specific inversion within the Williams-Beuren syndrome critical region.