A human homoeo box gene specifically expressed in spinal cord during embryonic development

Genome-wide reduction in H3K9 acetylation during human embryonic stem cell differentiation

Epigenetic marks are important factors regulating the pluripotency and differentiation of human embryonic stem cells (hESCs). In this study, we analyzed H3K9 acetylation, an epigenetic mark associated with transcriptionally active chromatin, during endoderm-like differentiation of hESCs. ChIP-on-chip analysis revealed that differentiation results in a genome-wide decrease in promoter H3K9 acetylation. Among the 24,659 promoters analyzed, only 117 are likely to be involved in pluripotency, while 25 acetylated promoters are likely to be responsible for endoderm-like differentiation. In pluripotent hESCs, the chromosomes with the highest absolute levels of H3K9 acetylation are chromosomes 1, 6, 2, 17, 11, and 12 (listed in order of decreasing acetylation). Chromosomes 17, 19, 11, 20, 22, and 12 are the most prone to differentiation-related changes (both increased acetylation and deacetylation). When chromosome size (in Mb) was accounted for, the highest H3K9 acetylation levels were found on chromosome 19, 17, 6, 12, 11, and 1, and the greatest differentiation-associated decreases in H3K9 acetylation occurred on chromosomes 19, 17, 11, 12, 16, and 1. The gene density and size of individual chromosomes were strongly correlated with the levels of H3K9 acetylation. Our analyses point to chromosomes 11, 12, 17, and 19 as being critical for hESC pluripotency and endoderm-like differentiation. J. Cell. Physiol. 219: 677-687, 2009. (c) 2009 Wiley-Liss, Inc.

Expression and role of Lhx8 in murine tooth development

We examined the expression and possible functions of Lhx8, a member of the LIM-homeobox gene family, during tooth morphogenesis of the mouse. Lhx8 was expressed in the dental mesenchyme between the bud and early bell stage of the molar tooth germ. Tooth germ explants from embryonic day 12.5 mice treated for 5 to 7 days with antisense-oligodeoxynucleotides (AS-ODN) against Lhx8 showed a marked decrease in the number of mesenchymal cells. The explants treated with AS-ODN for 11 to 14 days were filled with a large number of undifferentiated epithelial cells and a limited number of undifferentiated mesenchymal cells, but did not contain a tooth germ. Treatment of explants with AS-ODN for 7 days suppressed the proliferation of dental mesenchymal cells and induced apoptosis; the latter was confirmed by histochemical and ultrastructural examinations. Moreover, the expression of Lhx6, Msx1, Msx2, Bmp4 and Gsc, which are also known to be involved in tooth morphogenesis, were suppressed after the application of AS-ODN against Lhx8 for 7 days. The present results suggest that Lhx8 plays an important role in the survival of mesenchymal cells of the tooth germ during development.

Additional hox clusters in the zebrafish: divergent expression patterns belie equivalent activities of duplicate hoxB5 genes

The evolution of metazoan body plans has involved changes to the Hox genes, which are involved in patterning the body axis and display striking evolutionary conservation of structure and expression. Invertebrates contain a single Hox cluster whereas tetrapods possess four clusters. The zebrafish has seven unlinked hox clusters, a finding that is difficult to reconcile with the notion that genomic complexity, reflected by Hox cluster number, and morphological complexity are causally linked, as the body plan of the zebrafish is not obviously more complex than that of the mouse or human. Why have the additional hox genes in zebrafish been conserved? To address the role of these additional zebrafish hox genes, we have examined the duplicate hoxB5 genes, hoxB5a, and hoxB5b. Conservation of gene duplicates can occur when one gene acquires a new function (neofunctionalization), or when the ancestral function is divided between the two duplicates (subfunctionalization). hoxB5a and hoxB5b are expressed in distinct domains, and their combined expression domain is strikingly similar to that of single Hoxb5 genes in other species. The biochemical functions encoded by the two genes were studied by overexpression, which resulted in identical developmental defects in the anterior hindbrain and cranial neural crest, suggesting strongly that hoxB5a and hoxB5b have equivalent biochemical properties with respect to early development. From these studies, we conclude that conservation of hoxB5a and hoxB5b is likely the result of division of the ancestral Hoxb5 function between the two genes, without significant changes in biochemical activity. These results suggest a resolution to the conundrum of the extra hox genes and clusters in the zebrafish, since if any of the additional hox genes in the zebrafish are similarly subfunctionalized, they are unlikely to supply novel genetic functions. Thus, the morphological complexity potentially conferred by the majority of additional zebrafish hox clusters may not be substantially greater than that conferred by the four tetrapod clusters.

Deregulated expression of homeobox-containing genes, HOXB6, B8, C8, C9, and Cdx-1, in human colon cancer cell lines

Previously we have demonstrated a reciprocal deregulation of various homeobox genes (HOXB6, B8, C8 and C9 vs Cdx-1) in human colorectal cancer (CRC). In the present study, using RT-PCR, we have investigated the expression pattern of these homeobox genes in various human colon cell lines, representing various stages of colon cancer progression and differentiation. Thus, we have tested polyposis coli Pc/AA adenoma cells, Caco-2, HT-29 and LS174T adenocarcinoma cell lines. All cell lines, except LS174T, demonstrated a pattern of deregulated homeobox gene expression which resembled that of CRC. In contrast, the pattern of expression of these genes in the highly oncogenic LS174T cells, as well as in Caco-2 cells transfected with activated Ha-ras or Polyoma middle T oncogene, resembled that of the normal mucosa. The reciprocal deregulation of HOX and Cdx-1 genes in CRC and in CRC-derived cell lines suggests a possible role in human CRC development.

Human colorectal carcinogenesis is associated with deregulation of homeobox gene expression

In the present study, the possible involvement of homeobox-containing genes in colorectal cancer (CRC) development was investigated. Using a stepwise screening approach and RT-PCR, we have demonstrated that the human HOXB6, B8, C8 and C9 are overexpressed at various stages of CRC. In contrast, all CRC cases exhibited a marked decrease in the homeodomain-containing Cdx1 gene expression. Recent data which suggest a regulatory link between HOXB8 and several tumor suppressor genes, such as DCC, APC, and TGF beta, sustain a possible implication of homeobox genes in colon carcinogenesis. Moreover, our data showing a decrease in Cdx1 expression are consistent with the notion that genes functioning in the establishment and maintenance of the intestinal epithelium might, upon deregulation, disturb the normal control of cellular proliferation, differentiation, and death, thus leading to cancer development.

Retinoic acid stimulates alpha-CAMKII gene expression in PC12 cells at a distinct transcription initiation site

The promoter region of the alpha-subunit of the calcium/calmodulin-dependent protein kinase II (alpha-CaMKII) gene was inserted into a beta-galactosidase (beta-gal) reporter plasmid, and beta-gal activities were examined in neuroblastoma (NB2a) and pheochromocytoma (PC12) cells after transient or stable transfections. The alpha-CaMKII promoter was 12- to 45-fold more active in NB2a compared with PC12 cells after transient or stable transfections. All-trans retinoic acid (RA) stimulated reporter gene expression at both protein and mRNA levels in transfected PC12 cells. RA increased the level of endogenous alpha-CaMKII mRNA in untransfected PC12 cells by 4.4-fold. The transcription initiation site(s) (TIS) of the alpha-CaMKII gene in PC12 cells and rat brain was examined by RNase protection assays (RPA) and reverse transcriptase PCRs. The TIS for the alpha-CaMKII/beta-gal reporter gene in transfected PC12 cells was indistinguishable from the TIS+1 in rat hippocampus. In contrast, the only detectable TIS for the alpha-CaMKII gene in untransfected PC12 cells was located near the ATG translation start codon, 147 nucleotides 3' to TIS+1 in hippocampus. This unusual TIS was also the predominant TIS in rat cerebellum. These results suggest that the alpha-CaMKII promoter may contain sequences that respond directly or indirectly to RA. In addition, the unusual TIS of the alpha-CaMKII gene in PC12 cells and rat cerebellum may contribute to the very low expression of this gene compared with that in hippocampus.

Expression of homeobox gene-GBX2 in human prostatic cancer cells

BACKGROUND

Homeobox genes encode transcription factors involved in the genetic control of normal development and differentiation, as well as in malignant transformation. To begin to assess the possible role of homeobox genes in prostatic cell carcinogenesis, we surveyed initially for expression of homeobox-containing genes in the TSU-PR1 cell line.

METHODS

This was performed by RT-PCR using degenerate oligodeoxyribonucleotide primers to the homeobox-binding sequence to generate partial cDNAs which were cloned and sequenced.

RESULTS

Using this method, expression of 14 members of homeobox-containing genes were detected in TSU-PR1 cells. All of these expressed genes correspond to previously identified homeobox genes located within the HOXA, B, C, and D clusters. We further examined the expression of these homeobox genes in different human prostatic cell lines by using whole cDNA slot blot and Northern blot analysis. One of the sequences corresponding to the human GBX2 homeobox gene is overexpressed in TSU-PR1, LNCaP, PC-3, and DU145 metastatic prostate cell lines relative to the normal prostate.

CONCLUSIONS

Our results suggest that the homeobox gene GBX2 may participate in metastatic progression in prostatic cancer.

Coordinate expression and proliferative role of HOXB genes in activated adult T lymphocytes

We investigated the expression of HOXB cluster genes in purified phytohemagglutinin (PHA)-activated T lymphocytes from normal adult peripheral blood by reverse transcription PCR and RNase protection. These genes are not expressed in quiescent T cells, except for barely detectable B1 RNA. After the PHA stimulus, HOXB gene activation initiates coordinately as a rapid induction wave in the 3'-->5' cluster direction (i.e., from HOXB1 through B9 genes). Thus, (i) expression of the foremost 3'-located B1 and B2 genes peaks 10 min after PHA addition and then rapidly declines, (ii) activation of B3, B4, and B5 begins 10 min after PHA addition and peaks at later times (i.e., at 120 min for B5), (iii) B6, B7, and B9 are expressed at a low level starting at later times (45 to 60 min), and (iv) B8 remains silent. Treatment of PHA-activated T lymphocytes with antisense oligonucleotides to B2 or B4 mRNA causes a drastic inhibition of T-cell proliferation and a decreased expression of T-cell activation markers (i.e., interleukin 2 and transferrin receptors). Similarly, treatment of CEM-CCRF, Peer, and SEZ627 T acute lymphocytic leukemia cell lines with anti-B4 oligomer markedly inhibits cell proliferation. Finally, T cells stimulated by a low dosage of PHA in the presence of 1 microM retinoic acid show a marked increase of both HOXB expression, particularly B2, and cell proliferation. These studies provide novel evidence on the role of HOX genes in adult cell proliferation. (i) Coordinate, early activation of HOXB genes from the 3'-->5' cluster side apparently underlies T-cell activation. (ii) The expression pattern in adult PHA-activated T cells is strikingly similar to that observed in retinoic acid-induced teratocarcinoma cells (A. Simeone, D. Acampora, L. Arcioni, P. W. Andres, E. Boncinelli, and F. Mavilio, Nature (London) 346:763-766, 1990), thus suggesting that molecular mechanisms underlying HOX gene expression in the earliest stages of development may also operate in activated adult T lymphocytes.

Coordinate expression and proliferative role of HOXB genes in activated adult T lymphocytes

We investigated the expression of HOXB cluster genes in purified phytohemagglutinin (PHA)-activated T lymphocytes from normal adult peripheral blood by reverse transcription PCR and RNase protection. These genes are not expressed in quiescent T cells, except for barely detectable B1 RNA. After the PHA stimulus, HOXB gene activation initiates coordinately as a rapid induction wave in the 3'-->5' cluster direction (i.e., from HOXB1 through B9 genes). Thus, (i) expression of the foremost 3'-located B1 and B2 genes peaks 10 min after PHA addition and then rapidly declines, (ii) activation of B3, B4, and B5 begins 10 min after PHA addition and peaks at later times (i.e., at 120 min for B5), (iii) B6, B7, and B9 are expressed at a low level starting at later times (45 to 60 min), and (iv) B8 remains silent. Treatment of PHA-activated T lymphocytes with antisense oligonucleotides to B2 or B4 mRNA causes a drastic inhibition of T-cell proliferation and a decreased expression of T-cell activation markers (i.e., interleukin 2 and transferrin receptors). Similarly, treatment of CEM-CCRF, Peer, and SEZ627 T acute lymphocytic leukemia cell lines with anti-B4 oligomer markedly inhibits cell proliferation. Finally, T cells stimulated by a low dosage of PHA in the presence of 1 microM retinoic acid show a marked increase of both HOXB expression, particularly B2, and cell proliferation. These studies provide novel evidence on the role of HOX genes in adult cell proliferation. (i) Coordinate, early activation of HOXB genes from the 3'-->5' cluster side apparently underlies T-cell activation. (ii) The expression pattern in adult PHA-activated T cells is strikingly similar to that observed in retinoic acid-induced teratocarcinoma cells (A. Simeone, D. Acampora, L. Arcioni, P. W. Andres, E. Boncinelli, and F. Mavilio, Nature (London) 346:763-766, 1990), thus suggesting that molecular mechanisms underlying HOX gene expression in the earliest stages of development may also operate in activated adult T lymphocytes.

A role of retinoic acid in the regulation of the morphology and the levels of intermediate filament proteins and mRNAs in PC12 cells

An adrenal tumor-derived cell line (PC12W) cultured in the presence of nerve growth factor exhibited a spindle-shaped cell morphology resembling neuronal cells. The shape of these cells can be specifically changed in vitamin A-depleted medium supplemented with retinoic acid. Retinoic acid promoted an epithelial-like cell morphology except for occasional neuronal processes. These morphological results were correlated with differential expression of intermediate filaments at the mRNA and protein levels in these cells. Retinoic acid suppressed the synthesis of peripherin, an intermediate filament protein predominantly found in peripheral nerve cells, but a high level of simple keratins, normally found in simple epithelial cells, was present in retinoic acid-treated PC12 cells. The neurofilaments typically expressed in neurons remained virtually unaffected under the same conditions. In contrast, nerve growth factor induced the production of neurofilaments, but suppressed the synthesis of simple keratins. Since intermediate filament expression is known to be tissue-specific, these changes in expression together with the cell morphology changes are consistent with PC12 cells undergoing an epithelial-like differentiation in the presence of retinoic acid and a neuronal-like differentiation in the presence of nerve growth factor. These results suggest that retinoic acid and nerve growth factor are both effective regulators of PC12 cell differentiation but stimulate opposing pathways.

HOX gene expression in normal and neoplastic human kidney

As a consequence of transformation, cancer cells generally lose some of their differentiative properties. Thus, alterations interfering with the genetic mechanisms required to maintain embryonic determination could lead to tumorigenesis. Homeobox genes are a network of genes encoding nuclear proteins containing DNA-binding homeodomains that are highly conserved throughout evolution. They are expressed in a stage-related fashion in the developing embryo and, in adult life, in normal tissues. In mice and humans, homeobox genes of the HOX family are organized in 4 clusters on different chromosomes which have presumably evolved by duplication of a primordial gene cluster. Strikingly, the order of genes within each cluster is also highly conserved throughout evolution, suggesting that the physical organization of HOX genes might be essential for their expression. Recent reports indicate that homeobox mutant mice display morphological abnormalities or show neoplastic alterations, and that growth factors can turn on homeobox genes. We have studied the expression of the Antennapedia-like HOX genes in normal human kidney and in renal carcinomas. The great majority of the HOX genes analyzed are expressed in a peculiar manner in normal kidney: blocks of genes, even entire HOX loci, are coordinately regulated. Alterations in HOX gene expression in renal carcinoma can be observed in 2 genes of the HOX-2 locus, HOX-2A and HOX-2E, which are actively expressed in normal kidney and silent in cancer biopsies. The HOX-3H gene is not expressed in normal kidney whereas the HOX-3H transcripts are present in renal carcinomas. Homeobox genes within the 4 HOX loci can be aligned on the basis of the maximal sequence homology of their homeodomains: this alignment defines 13 paralogous gene groups. In renal carcinomas, genes of group 10 (HOX-1D, 2F, 3E, 4B) display a marked difference in their transcript classes when compared to those of normal kidney. Our findings suggest an association between altered HOX gene expression and kidney cancer.

The gene encoding the transcription factor SCIP has features of an expressed retroposon

SCIP is a POU domain transcription factor expressed by glial progenitor cells in the peripheral and central nervous systems (dividing Schwann cells and O-2A cells, respectively), where it appears to act as a repressor of myelin-specific genes. We have isolated genomic clones encoding the rat SCIP gene. Comparison of the structure of these clones with genomic Southern blots and SCIP cDNAs demonstrates that SCIP is encoded in a single-copy, intronless gene that has the general features of an expressed retroposon. This gene contributes to an extended CpG island. It is transcribed to produce a 3.1-kb mRNA that encodes a 451-amino-acid protein with a predicted molecular mass of 45 kDa. Immunopurified SCIP antibodies specifically recognize a nuclear protein of this size in cultured proliferating Schwann cells, and gel shift analyses demonstrate that this protein is the predominant octamer-binding protein in these cells.

The gene encoding the transcription factor SCIP has features of an expressed retroposon

SCIP is a POU domain transcription factor expressed by glial progenitor cells in the peripheral and central nervous systems (dividing Schwann cells and O-2A cells, respectively), where it appears to act as a repressor of myelin-specific genes. We have isolated genomic clones encoding the rat SCIP gene. Comparison of the structure of these clones with genomic Southern blots and SCIP cDNAs demonstrates that SCIP is encoded in a single-copy, intronless gene that has the general features of an expressed retroposon. This gene contributes to an extended CpG island. It is transcribed to produce a 3.1-kb mRNA that encodes a 451-amino-acid protein with a predicted molecular mass of 45 kDa. Immunopurified SCIP antibodies specifically recognize a nuclear protein of this size in cultured proliferating Schwann cells, and gel shift analyses demonstrate that this protein is the predominant octamer-binding protein in these cells.

Coordinate regulation of HOX genes in human hematopoietic cells

Hematopoiesis is a continuous process in which precursor cells proliferate and differentiate throughout life. However, the molecular mechanisms that govern this process are not clearly defined. Homeobox-containing genes, encoding DNA-binding homeodomains, are a network of genes highly conserved throughout evolution. They are organized in clusters expressed in the developing embryo with a positional hierarchy. We have analyzed expression of the four human HOX loci in erythroleukemic, promyelocytic, and monocytic cell lines to investigate whether the physical organization of human HOX genes reflects a regulatory hierarchy involved in the differentiation process of hematopoietic cells. Our results demonstrate that cells representing various stages of hematopoietic differentiation display differential patterns of HOX gene expression and that HOX genes are coordinately switched on or off in blocks that may include entire loci. The entire HOX4 locus is silent in all lines analyzed and almost all the HOX2 genes are active in erythroleukemic cells and turned off in myeloid-restricted cells. Our observations provide information about the regulation of HOX genes and suggest that the coordinate regulation of these genes may play an important role in lineage determination during early steps of hematopoiesis.

EVX2, a human homeobox gene homologous to the even-skipped segmentation gene, is localized at the 5' end of HOX4 locus on chromosome 2

We isolated and mapped three new human homeoboxes located on chromosome 2 upstream from the reported seven HOX4 homeobox sequences. Two of them, HOX41 and HOX4H, clearly belong to the HOX gene family, in particular to homology groups 1 and 2, and possibly represent the most 5' HOX4 homeoboxes. A third homeobox 13 kb upstream from HOX41 was identified. Sequencing data show that this is the human homolog of the murine Evx-2 homeobox. Both homeoboxes are closely related to the murine Evx-1 and to the frog Xhox-3 homeoboxes. The four genes represent vertebrate homologs of Drosophila even-skipped (eve), a segmentation gene of the pair-rule class. Human EVX2 sequences belong to an active gene because they are transcribed and properly processed in cells and tissues. We have identified for the first time a homeogene of a different class at a HOX locus. These findings are relevant to the understanding of the evolution of HOX gene clusters and their regulation.

Expression of HOX homeogenes in human neuroblastoma cell culture lines

Mammalian genes containing a class-I homeobox (HOX genes) are highly expressed in the embryonic nervous system. As a first step towards the molecular analysis of the role these genes play in neural cells, we studied the expression of four human HOX genes in five neuroblastoma (NB) cell lines - SK-N-BE, CHP-134, IMR-32, SK-N-SH and LAN-1 - during the process of differentiation induced by treatment with retinoic acid (RA). The four genes, HOX1D, 2F, 3E and 4B, located at corresponding positions in the four HOX loci, share a high degree of sequence similarity with the Drosophila Deformed homeotic gene and constitute a homology group, group 10. One of these genes, HOX1D, is not expressed in the cells used, whereas the other three are highly expressed in untreated and RA-induced NB cells, even though the expression pattern in the various lines is slightly different for the three genes. Our analysis reveals a complex and specific expression pattern in these lines, paving the way to an identification of different NB-cell populations by means of specific HOX gene expression schemes. On the other hand, in every line studied, morphological maturation toward a neuronal differentiated phenotype appears to be associated with increased HOX gene expression.

Sequential activation of HOX2 homeobox genes by retinoic acid in human embryonal carcinoma cells

RETINOIC acid had been implicated as a natural morphogen in chicken and frog embryogenesis, and is presumed to act through the gene regulatory activity of a family of nuclear receptors. Homeobox genes, which specify positional information in Drosophila and possibly in vertebrate embryogenesis, are among the candidate responsive genes. We previously reported that retinoic acid specifically induces human homeobox gene (HOX) expression in the embryonal carcinoma cell line NT2/D1. We now show that the nine genes of the HOX2 cluster are differentially activated in NT2/D1 cells exposed to retinoic acid concentrations ranging from 10(-8) to 10(-5) M. Genes located in the 3' half of the cluster are induced at peak levels by 10(-8) M retinoic acid, whereas a concentration of 10(-6) to 10(-5) M is required to fully activate 5' genes. At both high and low retinoic acid concentrations, HOX2 genes are sequentially activated in embryonal carcinoma cells in the 3' to 5' direction.

Human HOX genes are differentially activated by retinoic acid in embryonal carcinoma cells according to their position within the four loci

We studied the expression of 33 human homeobox genes belonging to four complex HOX loci in embryonal carcinoma NT2/D1 cells. These cells can be induced to differentiate by culturing them in media containing retinoic acid. Northern blot analysis reveals that no expression of these genes was detectable in NT2/D1 stem cells, whereas 22 HOX genes are well expressed in NT2/D1 cells treated with 10 microM retinoic acid for 14 days. The 11 HOX genes the expression of which remained undetectable in NT2/D1 cells after this treatment are located at the 5' end of their loci: four in HOX1, five in HOX3 and two in HOX4. The boundary between induced and silent genes roughly corresponds to the HOX genes constituting the homology group 5, related to the Abdominal-B homeotic gene of Drosophila. All nine identified HOX2 genes are well expressed in fully induced NT2/D1 cells and none of them maps 5' genes of this homology group. We conclude that HOX genes are differentially activated by retinoic acid in these cells according to their physical location within the four chromosomal loci.

Spatial and temporal expression of cellular retinoic acid binding protein (CRABP) along the anteroposterior axis in the central nervous system of mouse embryos

In the central nervous system of 11.5-day mouse embryos, the expression of CRABP was spatially restricted to the anteroposterior axis. CRABP was most strongly expressed in the rhombencephalon and the anterior part of the neural tube. In 14-day mouse embryo, CRABP drastically decreased in the brain and the anterior part of the neural tube. The transient expression and spatial distribution of CRABP in the central nervous system strongly suggest that retinoic acid is involved in the neurogenesis during development.

Lineage-restricted expression of homeobox-containing genes in human hematopoietic cell lines

We investigated the role of homeobox-containing genes in human hematopoiesis because homeobox genes (i) control cell fate in the Drosophila embryo, (ii) are expressed in specific patterns in human embryos, and (iii) appear to function as transcription factors that control cell phenotype in other mammalian organs. Using four homeobox probes from the HOX2 locus and a previously undescribed homeobox cDNA (PL1), we screened mRNAs from 18 human leukemic cell lines representing erythroid, myeloid, and T- and B-cell lineages. Complex patterns of lineage-restricted expression are observed: some are restricted to a single lineage, while others are expressed in multiple lineages. No single homeobox gene is expressed in all types of hematopoietic cells, but each cell type exhibits homeobox gene expression. HOX2.2 and -2.3 homeobox-containing cDNAs were cloned from an erythroleukemia cell (HEL) cDNA library, while the homeobox cDNA PL1 was isolated from a monocytic cell (U-937) library. Differentiation of HEL and K-562 cells with various inducers results in modulation of specific homeobox transcripts. In addition, HOX2.2 is expressed in normal bone marrow cells. We have demonstrated (i) lineage-restricted expression of five homeobox genes in erythroid and monocytic cell lines; (ii) expression of additional homeobox genes in other cell lineages (HL-60 and lymphoid cells); (iii) expression of one homeobox gene in normal marrow cells; and (iv) modulation of expression during differentiation. These data suggest that these genes play a role in human hematopoietic development and lineage commitment.

Differential expression of human HOX-2 genes along the anterior-posterior axis in embryonic central nervous system

We have investigated the structure of the human HOX-2 locus, which encompasses a 90-kb region on chromosome 17q21. Five new human HOX-2 homeoboxes, termed HOX-2.5, 2.4, 2.6, 2.7 and 2.8, have been identified, and their nucleotide sequences are reported. They have the same 5'-3' transcriptional orientation and are clustered with three previously described HOX-2 homeoboxes (5'-2.5-2.4-2.3-2.2-2.1-2.6-2.7-2.8-3'). We have also investigated the region-specific expression of HOX-2 genes in human embryonic-fetal life by Northern-blot analysis. All genes are expressed in whole embryos and fetuses at 5-9 weeks from conception. Their major site of expression lies within the central nervous system (CNS), although they are transcribed at a lower level in body structures other than the CNS. Their relatively abundant expression in CNS has been analyzed along the anterior-posterior axis by dissecting the brain, the medulla oblongata and the spinal cord proper. HOX-2.5, 2.4 and 2.3 transcripts are markedly more abundant in spinal cord than in medulla, whereas 2.2, 2.1, 2.6 and 2.7 mRNAs are progressively more abundant in the medulla. Additionally, expression in brain was detected, although at lower level, for HOX-2.1, 2.6, 2.7, 2.8. Thus, the relative position of HOX-2 homeobox genes along the chromosome in the 5'-3' direction appears to correlate with the relative position of their expression domains along the CNS longitudinal axis in the caudal-cephalic direction.

Isolation and chromosomal localization of the human En-2 gene

By low stringency hybridization we have isolated from a human cosmid genomic library sequences homologous with a probe from the Drosophila engrailed gene. Partial nucleotide sequence analysis shows a consensus splice acceptor site followed by an open reading frame (ORF) that can encode 104 amino acids; the first 94 amino acids have 71% identity with the Drosophila engrailed protein. The shared region contains a homeo domain and is within the region of engrailed shared with the Drosophila invected gene and the mouse En-1 and En-2 genes. At the amino acid level, the human sequence is 85% identical with the mouse En-1 gene and 100% identical with the mouse En-2 gene. Hybridization against a panel of human-hamster somatic cell hybrids maps this human En-2 gene to chromosome 7, and regional mapping by in situ hybridization to human chromosomes localizes it to region 7q36 at the end of the long arm.

The chicken homeo box genes CHox1 and CHox3: cloning, sequencing and expression during embryogenesis

Several Drosophila genes involved in the control of segmentation and segment identity share a 183-bp conserved sequence termed homeo box. Homeo box sequences have been detected and cloned from the genomes of insects like Drosophila to vertebrates such as mouse and man. Two chicken homeo box genes CHox1 and CHox3, are described. Cloning of the CHox1 and CHox3 homeo boxes was performed using Drosophila and murine homeo box sequences as probes under low-stringency conditions. Analysis of both chicken homeo box sequences revealed them to be homeo boxes that have diverged from the Antennapedia class with homologies to homeo boxes of other organisms in the range of 75-42% at the nucleotide level and 69-41% at the protein level. Analysis of CHox3 expression during early embryo development showed that the gene codes for five transcripts 1.3, 1.9, 2.6, 5.6 and 7.9 kb in size. Three of the transcripts (1.3, 1.9 and 5.6 kb) are also recognized by a flanking non-homeo box containing probe. The levels of the different transcripts changed during the first five days of development. The most abundant transcripts (1.3 and 1.9 kb) are already present at the time the egg is laid. Their transcription peaks at day 1 of incubation and then decreases. The CHox1 transcripts are present at very low levels between days 2.5 and 4 of development. These two chicken genes represent bona fide Hox genes in a branch of vertebrates that evolved parallel to mammals.

A new family of mouse homeo box-containing genes: molecular structure, chromosomal location, and developmental expression of Hox-7.1

Two families of homeo box-containing genes have been identified in mammals to date, the Antennapedia- and engrailed-like homeo boxes, based on the sequence similarity to those from Drosophila. Here, we report the isolation of a homeo box-containing gene that belongs to a new family of which there are at least three related genes in the mouse genome. The homeo box of this new gene shows remarkable similarity to the Drosophila Msh homeo box that we designate as the prototype for this family. The gene maps to the proximal end of mouse chromosome 5 and does not cosegregate with any known homeo box-containing gene. We designate this locus Hox-7.1. In situ hybridizations to mouse embryos at different stages show a unique pattern of expression, as compared to other homeo box-containing genes described thus far. Hox-7.1 transcripts are detected in 9.5-day-old embryos in the neural crest, developing limb bud, and visceral arches. Later, this gene is expressed in regions of the face that are derived from neural crest and in the interdigital mesenchymal tissues in both the fore- and hindlimbs.

Posttranscriptional control of human homeobox gene expression in induced NTERA-2 embryonal carcinoma cells

We have studied the expression of four human homeobox genes representative of four different clusters (i.e., HOX-1, HOX-2, HOX-3 and HOX-5) in the embryonal carcinoma (EC) cell line NT2/D1. Following treatment with retinoic acid (RA), these cells differentiate into several cell types, including neurons, and steadily accumulate polyadenylated transcripts derived from the genes in a period ranging from 18 hr to 14 days of RA treatment. The sizes of major transcripts in differentiated EC cells coincide with those previously detected by the same probes in human embryos. Nuclear run-on transcriptional analysis showed no difference in the transcription rate of the four homeobox genes in differentiated vs. undifferentiated EC cells. Inhibition of protein synthesis by 5-18 hr of treatment of undifferentiated cells with cycloeximide causes accumulation of some homeobox transcripts at levels comparable to those observed after 18 hr of RA induction, although it does not cause superinduction in fully differentiated cells. These data suggest that the activation of homeobox gene expression in RA-induced EC cells is controlled, at least in part, by posttranscriptional mechanisms.

Expression of homeobox genes in human erythroleukemia cells

Because homeobox-containing genes play a major role in embryogenesis and tissue identity in Drosophila and because similar genes encode tissue-specific transcription factors in mammalian cells, we hypothesized that homeobox genes might plan a role in hematopoietic differentiation and lineage commitment. We therefore surveyed a number of human leukemic cell lines for expression of homeobox-containing genes by Northern gel analysis with probes from the Hox 2 cluster of homeobox genes on chromosome 17. We observed transcripts for Hox 2.1, 2.2, 2.3 and 2.6 in the erythroid line HEL and for Hox 2.3 and 2.6 in the erythroid line K562. Using homeobox-specific probes we confirmed that the transcripts visualized contained the homeodomains for each gene as well as the flanking sequences. The myeloid lines HL60, KG1 and U937 did not express specific transcripts for any of the 4 genes studied. However, all these cell lines demonstrated bands when probed at low stringency with certain Hox 2 probes, indicating the expression of other homologous but as yet unidentified homeobox genes. Expression of Hox 2.3 and 2.6 was seen in some T and B lymphoid cell lines. Induction of differentiation in HEL cells resulted in complex modulation of expression of the Hox 2 genes. We have therefore observed erythroid-restricted expression of certain Hox 2 homeobox containing genes in human erythroid cell lines and modulation of that expression with differentiation, suggesting a role for these genes in the regulation of hematopoiesis. Different homeobox genes appear to be expressed in non-erythroid leukemic cell lines.

Stage- and tissue-specific expression of two homeo box genes in sea urchin embryos and adults

We report the isolation of two different homeo box genes, HB3 and HB4, from the Hawaiian sea urchin Tripneustes gratilla. DNA sequencing revealed a definitive Antennapedia (Antp) class homeo box in each gene. Southern transfer hybridizations showed the genes to be single-copy. A 5.7-kb transcript of the HB3 gene was found in ovary, testis, small intestine and gastrula poly(A)+ RNA. The HB4 gene produces three transcripts. A 3.7-kb and a 4.4-kb transcript are expressed during embryogenesis. A 3.5-kb transcript appears in each of the adult tissues studied. The HB4 gene appears to be the sea urchin cognate of the Drosophila infrabdominal-7 (iab-7) gene, the mouse Hox 1.7 and Hox 3.2 genes and the Xenopus X1Hbox 6 gene. An examination of Antp class homeo box genes in deuterostomes indicates that a chromosomal duplication has taken place in the evolutionary line leading to the vertebrates after the divergence of the echinoderms. Thus, the sea urchin represents the primitive condition.

Temporal and constitutive expression of homeobox-2 gene (Hu-2), human heat shock gene (hsp-70), and oncogenes C-sis and N-myc in early human trophoblast

Recent studies of the genetic basis of animal development indicate that homeobox genes, protooncogenes, and some heat shock genes may play a role in early embryogenesis. To investigate the possibility that these genes function in early human embryonic development, we monitored the expression of a human homeobox gene (Hu-2), two human protooncogenes (C-sis and N-myc), and a human heat shock gene (hsp-70) in human trophoblasts at 7 to 13 weeks gestational age. All these genes were found to be expressed in the tissues analyzed. The hsp-70 gene was expressed at nearly constant levels throughout the development period surveyed, whereas N-myc, C-sis, and Hu-2 showed a coordinated pattern of regulated expression. These results are consistent with a functional role of these genes in the early course of human development.

Characterization of a murine homeo box gene, Hox-2.6, related to the Drosophila Deformed gene

The Hox-2 locus on chromosome 11 represents one of the major clusters of homeo-box-containing genes in the mouse. We have identified two new members (Hox-2.6 and Hox-2.7), which form part of this cluster of seven linked genes, and it appears that the Hox-2 locus is related by duplication and divergence to at least one other mouse homeo box cluster, Hox-1. The Hox-2.6 gene encodes a predicted protein of 250 amino acids, which displays extensive similarity in multiple regions to certain mouse, human, Xenopus, and zebra fish homeo domain proteins. The Drosophila Deformed (Dfd) gene also shares these same regions of similarity, and based on this sequence conservation, we suggest that Hox-2.6 forms part of a vertebrate 'Dfd-like' family. Hox-2.6 is expressed in fetal and adult tissues and is modulated during the differentiation of F9 teratocarcinoma stem cells. In situ hybridization analysis of mouse embryos shows that the Hox-2.6 is expressed in ectodermal derivatives: spinal cord, hindbrain, dorsal root ganglia, and the Xth cranial ganglia. In the central nervous system, expression is observed in the most posterior parts of the spinal cord, with the anterior limit residing in a region of the hindbrain and no expression in the mid- or forebrain. In mesodermal structures, Hox-2.6 is expressed in the kidney, the mesenchyme of the stomach and lung, and the longitudinal muscle layer of the gut. Expression has not been observed in derivatives of embryonic endoderm. The patterns of Hox-2.6 expression in both mesoderm and ectoderm are spatially restricted and may reflect a role for the gene in the response to or establishment of positional cues in the embryo.

Primary structure, developmentally regulated expression and potential duplication of the zebrafish homeobox gene ZF-21

We report the molecular cloning and characterization of a cDNA derived from a zebrafish gene (ZF-21) related to the mouse homeobox containing gene Hox2.1. Interesting information about the differential conservation of various domains was gained from comparisons between the putative protein sequences from ZF-21 (275 amino acids) and Hox2.1 (279 aa). A separate DNA binding domain including the ZF-21 homeodomain and 36 additional flanking residues is completely identical to the C-terminal part of Hox2.1. As a consequence, these two mouse and zebrafish proteins must have identical DNA binding properties. A lower level of sequence identity between the N-terminal coding regions of ZF-21 and Hox2.1 reduces the total protein homology to 81%. However, short stretches of perfect homology in these N-terminals suggests that the essential biochemical functions are the same. As expected for true homologues, the ZF-21 and Hox2.1 genes also share extensive similarities with respect to non-coding sequences and temporal expression during embryogenesis. The finding of a potential ZF-21 duplication is discussed in relation to functional and evolutionary aspects of vertebrate homeobox genes.

Structure and expression of Hox-2.2, a murine homeobox-containing gene

The Hox-2.2 gene is one of a cluster of homeobox-containing genes on mouse chromosome 11. A cDNA clone containing the Hox-2.2 homeobox has been isolated from an adult spinal cord library. Our analysis of the Hox-2.2 cDNA and genomic clones indicates that there are at least two oxons and one intron. The largest open reading frame includes the homeobox and codes for a 224 amino acid protein of molecular weight 25,312. Comparisons of the predicted Hox-2.2 protein with other homeodomain-containing proteins revealed four regions of sequence similiarity: an N-terminal octapeptide, a hexapeptide upstream of the homeodomain, the homeodomain, and a glutamic acid-rich region at the C terminus. Possible functions of these regions are discussed. The Hox-2.2 gene is expressed in 13.5-day embryos in the developing hindbrain and spinal cord. The expression patterns of Hox-2.2 and Hox-2.1 in 13.5-day embryos are compared.

Pattern formation in the developing eye of Drosophila melanogaster is regulated by the homoeo-box gene, rough

Homoeo-box genes play a central role in the regulation of embryogenesis in Drosophila melanogaster. Their widespread phylogenetic distribution, and the tissue and stage specificity of their expression in other organisms, argue that they play a general and significant role in animal development. In D. melanogaster, all homoeo-box genes characterized to date are involved in major aspects of embryogenesis. We report here the molecular characterization of a Drosophila homoeo-box gene that has no apparent involvement in early embryogenesis. The gene appears to be rough, a gene implicated in pattern formation in the developing eye. It is expressed in cells within, and posterior to, the morphogenetic furrow, the site of the primary pattern forming events in the developing retina, and also in a region of the brain of the third instar larva. We have found no genetic or molecular evidence of a role for this gene in other aspects of fly development.

mec-3, a homeobox-containing gene that specifies differentiation of the touch receptor neurons in C. elegans

The mec-3 gene is essential for proper differentiation of the set of six touch receptor neurons in C. elegans. In mutants lacking mec-3 activity, the touch receptors express none of their unique differentiated features and appear to be transformed into other types of neurons. We cloned the mec-3 gene by transposon tagging and showed that a mec-3 mutant can be rescued by germ line transformation using a 5.6 kb genomic DNA fragment. In a strain in which transforming mec-3 DNA is present in about 50 copies per haploid genome, additional cells express a mec-3-dependent phenotype. The putative coding sequence of mec-3 contains a homeobox, suggesting that the mec-3 protein specifies the expression of touch cell differentiation by binding to DNA and regulating transcription of genes that encode the differentiated features of these cells.

Molecular approaches to dysmorphology

The biochemical and physiological defects underlying human dysmorphic syndromes can now be approached using techniques of molecular biology. The genetic component of the causation of the dysmorphology can be studied in isolation from the environmental component by using large, rare families which exhibit the same phenotype as more complex multifactorial disorders, but inherit the mutation in a monogenic fashion. Such an analysis starts with the determination of linkage to a gene probe, followed by the use of newer techniques of molecular biology to enable cloning and sequencing of the mutated gene. Analysis of the gene product by amino acid sequence homology to other known proteins, and tissue specific expression, may place the defect within the cascade of events associated with development and differentiation. Once cloned, the gene can also be manipulated in transgenic laboratory animals and the effect of its mutation studied directly. The use of techniques of molecular biology to study the genetic aspects of dysmorphic syndromes will allow insight to be gained both into normal fetal development and into the causes of congenital malformations.

At least three human homeoboxes on chromosome 12 belong to the same transcription unit

Mammalian homeoboxes show a clustered chromosomal organization. In the mouse, at least seven homeoboxes on chromosome 6 and at least six on chromosome 11 identify the murine Hox-1 and Hox-2 loci, respectively. A number of homeoboxes on chromosome 7 define the human HOX-1 locus and homeoboxes on chromosome 17 define the human HOX-2 locus. We studied the genomic organization of three homeobox sequences of the HOX-3 locus on chromosome 12 and analyzed transcripts from this region. Structural characterization and sequencing of several cDNA clones reveal that the three homeobox sequences present in this chromosomal region identify a single transcription unit. Primary transcripts are alternatively processed to give mature messengers with a common 5' noncoding exon encoding different proteins containing one of the three homeodomains.

Primary structure and expression of a product from cut, a locus involved in specifying sensory organ identity in Drosophila

In the absence of cut gene activity in Drosophila, external sensory organs are transformed into chordotonal organs. Here we show that the cut locus encodes a large protein containing a homoeodomain and is expressed in nuclei of cells in external sensory organs but not in cells within chordotonal organs.

Control of neuronal fate by the Drosophila segmentation gene even-skipped

The central nervous system (CNS) contains a remarkable diversity of cell types. The molecular basis for generating this neuronal diversity is poorly understood. Much is known, however, about the regulatory genes which control segmentation and segment identity during early Drosophila embryogenesis. Interestingly, most of the segmentation and homoeotic genes in Drosophila, as well as many of their vertebrate homologues, are expressed during the development of the nervous system (for example, ref. 3). Are these genes involved in specifying the identity of individual neurons during neurogenesis, just as they specify the identity of cells during segmentation? We previously described the CNS expression of the segmentation gene fushi tarazu (ftz) and showed that ftz CNS expression is involved in the determination of an identified neuron. Here we show that another segmentation gene, even-skipped (eve), is expressed in a different but overlapping subset of neurons. Temperature-sensitive inactivation of the eve protein during neurogenesis alters the fate of two of these neurons. Our results indicate that the nuclear protein products of the eve and ftz segmentation genes are components of the mechanism controlling cell fate during neuronal development.

An engrailed class homeo box gene in sea urchins

The homeo box, a conserved DNA element first recognized in Drosophila development-controlling genes, is present in the genomes of many higher metazoan species and provides a valuable probe for the isolation of regulatory genes from diverse phylogenetic groups. We have employed these probes to isolate and study the homeo-box genes in sea urchins. As in other species, the sea urchin homeo boxes fall into at least two classes defined by nucleotide sequence similarity to the homeo boxes of the Drosophila Antennapedia (Antp) and engrailed (en) genes. In this study, we characterize the only detectable sea urchin en class homeo box. Its nucleotide sequence similarity and lack of an intron indicate that it is more closely related to the two mouse en class homeo boxes than to the two Drosophila en class homeo boxes. These relationships are most parsimoniously explained if the single sea urchin en class homeo-box gene represents the primitive condition and the two mouse and the two Drosophila en class homeo-box genes represent independent duplications which occurred in the evolutionary lines leading to the vertebrates and arthropods, respectively. The most abundant en class gene transcripts detected by gel transfer analysis of RNA extracted from sea urchin tissues were found in Aristotle's lantern. Rare transcripts were present in ovary, testis and coelomocytes.

Molecular cloning and characterization of ovine homeo-box-containing genes

The sheep genome contains at least eleven homeo-boxes (hox). Using two hox-specific 36-mer oligodeoxynucleotides to screen a sheep genomic library, constructed in lambda Charon28, clones of nine of the hox were identified. Six of the hox clones were analysed by nucleotide sequencing, Southern-blot hybridization and Northern-blot analysis. Two of the hox appear to be cognates of the human Hu-1 (or mouse Hox 2.1) and the mouse Hox 1-3, while another is closely related to the mouse Hox 1-4. These results suggest that there is strong sequence conservation in the hox-containing genes of different mammals, and highlight the possible occurrence of an ubiquitous set of hox-containing genes in mammals. Northern-blot analysis of four sheep hox-containing genes indicates that they are all expressed during embryogenesis and that expression is temporally regulated allowing hierarchical-regulatory interaction. Interestingly, none of the cloned hox-containing sequences contain repetitive sequences.

Activation of four homeobox gene clusters in human embryonal carcinoma cells induced to differentiate by retinoic acid

We have studied the expression of nine homeobox genes from Hox 1, Hox 2, Hox 3 and Hox 5 clusters in human embryonal carcinoma (EC) cell lines analyzed as both stem cells and after exposure to the differentiation-inducing agents retinoic acid (RA), hexamethylenebisacetamide (HMBA) and bromodeoxyuridine (BUdR). None of the homeobox genes was expressed in stem cells, whereas all were activated, although with different kinetics, in cultures of the pluripotent EC cell line NTERA-2, clone D1 (NT2/D1), following differentiation induced by RA. At least some homeobox genes were stably expressed in differentiated cells several weeks after removal of RA from the culture medium. However, the length of initial exposure to RA is a critical factor in achieving stable gene expression, and differs among the different sets of genes and, at least in one case, among different transcripts from the same gene. No homeobox gene expression was detected in NT2/D1 cells induced to differentiate with HMBA or BUdR. Also, no expression was detectable in xenograft tumors generated by NT2/D1 cells in nude mice, even though tumors of this type contain mostly differentiated cells. Other human EC lines tested, i.e., 833KE, 2102Ep or 1156QE, did not differentiate in response to RA and did not express homeobox genes. No expression was detectable in xenograft tumors of 833KE and 2102Ep, containing essentially EC cells. These data indicate that homeobox-gene activation specifically accompanies RA-induced differentiation of NT2/D1 cells, thereby providing an excellent model for studying the molecular basis of homeobox-gene regulation and the possible role of the homeobox in cell differentiation.

Murine Hox-1.7 homeo-box gene: cloning, chromosomal location, and expression

A new murine homeo-box, called Hox-1.7, has been identified in a rare cDNA from F9 teratocarcinoma stem cells. The Hox-1.7 homeo-box is 68 and 72% homologous to the Drosophila antennapedia (Antp) and iab-7 homeo-boxes, respectively. A major 2.5-kilobase transcript and several minor transcripts were detected by Northern blot (RNA blot) analysis in adult tissues as well as in midgestational embryos. The posterior spinal cord was found to be a major site of Hox-1.7 expression in 12.5-day-old embryos. Somatic cell hybrids were used to map the Hox-1.7 gene to mouse chromosome 6. Restriction fragment length polymorphisms associated with either the Hox-1.7 gene or the previously known Hox-1 complex were identified. Their distribution patterns in recombinant inbred mouse strains were used to determine the linkage between the two loci as well as to other loci on chromosome 6. This maps Hox-1 and Hox-1.7 close to two mouse loci that affect morphogenesis, postaxial hemimelia (px) and hypodactyly (Hd).

Expression and function of the segmentation gene fushi tarazu during Drosophila neurogenesis

Segmentation genes control cell identities during early pattern formation in Drosophila. One of these genes, fushi tarazu (ftz), is now shown also to control cell fate during neurogenesis. Early in development, ftz is expressed in a striped pattern at the blastoderm stage. Later, it is transiently expressed in a specific subset of neuronal precursor cells, neurons (such as aCC, pCC, RP1, and RP2), and glia in the developing central nervous system (CNS). The function of ftz in the CNS was determined by creating ftz mutant embryos that express ftz in the blastoderm stripes but not in the CNS. In the absence of ftz CNS expression, some neurons appear normal (for example, the aCC, pCC, and RP1), whereas the RP2 neuron extends its growth cone along an abnormal pathway, mimicking its sibling (RP1), suggesting a transformation in neuronal identity.

Expression of the murine homeo box gene Hox 1.5 during embryogenesis

The spatial pattern of expression of the murine homeo box-containing gene Hox 1.5 was studied during embryogenesis. In situ hybridization of single-stranded RNA probes to mouse embryo sections revealed a specific spatial distribution of the Hox 1.5 transcripts in mouse embryos 8.5 to 12.5 days postcoitum (p.c.). Analysis of mouse embryos 8.5 days p.c. showed that the gene is expressed in a spatially restricted manner. Expression appears to be limited to the central nervous system with an anterior boundary in the hindbrain and extending posteriorly through caudal regions of the spinal cord. The same spatial pattern of expression was observed in embryos 9.5 to 12.5 days p.c. These results show that the murine Hox 1.5 gene is expressed in a spatially restricted manner during embryonic development similar to the patterns observed in Drosophila homeotic genes.

Post-transcriptional regulation of a murine homeobox gene transcript in F9 embryonal carcinoma cells

A 2.4 kb RNA encoded by the murine Hox 1.1 (m6) homeobox gene is induced when F9 stem cells are differentiated with retinoic acid and dibutyryl cyclic AMP. The regulation of Hox 1.1 expression was probed by using cycloheximide, an inhibitor of protein synthesis. Production of the Hox 1.1 RNA in differentiating F9 cells was not blocked by treatment with cycloheximide, indicating that new protein synthesis is not required for its induction. On the contrary, this transcript was detected in F9 stem cells treated with cycloheximide, anisomycin, or emetine alone. Nuclear transcription assays indicated that the Hox 1.1 gene was transcribed in F9 stem cells and that the rate of transcription did not change early in the differentiation of F9 cells. These observations indicate that the induction of Hox 1.1 transcripts in F9 stem cells during differentiation is not regulated at the level of transcription initiation but results from stabilization of the transcript.

Sequence analysis of the murine Hox-2.2, -2.3, and -2.4 homeo boxes: evolutionary and structural comparisons

We have determined the nucleotide sequences and deduced the amino acid sequences of three tandemly arranged murine boxes of the Hox-2 homeo box gene complex on mouse chromosome 11 (Hox-2.2, -2.3, and -2.4). The type and position of differences with other sequenced homeo boxes were analyzed. Hox-2.2 is nearly identical with its cognate human homeo box Hu-2. Hox-2.3 shares 59 of 61 amino acids with the Antennapedia homeo domain of Drosophila and the MM-3 homeo domain of Xenopus and shows 60 of 61 amino acid identity with human HuC1. Hox-2.3, MM-3, and HuC1 also share a stretch of six glutamic acid residues followed by a stop codon 15-20 amino acids 3' of the homeo domain. Hox-2.4 is relatively divergent from most of the other homeo boxes sequenced to date; however, it matches the Hox-3.1 murine homeo domain at 60 of 61 positions. Sequence comparisons with other murine homeo domains, together with previous studies of their genomic organization and chromosomal location, provide support for the hypothesis of a large-scale duplication resulting in the two major murine homeo box gene complexes Hox-1 and Hox-2.

Region-specific expression of mouse homeobox genes in the embryonic mesoderm and central nervous system

The homeobox is a 180-base-pair sequence characteristically found in homeotic and segmentation genes in Drosophila. Several copies of homeoboxes are also found in the mammalian genome, but it is not known whether these are components of morphogenetic loci in mammals as well. As a step toward understanding the function of mammalian homeoboxes, we have used in situ hybridization to define the spatial pattern of expression of two mouse homeobox genes in the midgestational mouse embryo. The two mouse homeoboxes studied here, Hox 1.2 and Hox 1.4, are located 20 kilobases apart on mouse chromosome 6. Our results demonstrate the following: (i) Hox 1.2 transcripts are localized mainly in the posterior myelencephalon, in the cervical central nervous system (CNS), and in several thoracic prevertebrae; (ii) Hox 1.4 transcripts are localized mainly in the posterior myelencephalon and in the cervical CNS; (iii) within the CNS region expressing Hox 1.4, the level of Hox 1.4 transcripts is higher in the mantle layer than in the ependymal layer and higher in the dorsal than in the ventral area. The specific localization of Hox 1.2 and Hox 1.4 transcripts in the embryonic CNS and the restricted pattern of expression along the rostrocaudal axis are strikingly reminiscent of the expression pattern of Drosophila homeoboxes in the fly embryo and larvae. Despite the different developmental strategies adopted by Drosophila and mammals, functional similarities may exist between Drosophila and mammalian homeobox genes.