1 Patterning the limb before and after SHH.

The Summer Meeting of the Anatomical Society of Great Britain and Ireland was held at the University of Dundee, from 23rd to 25th July 2002. It included a symposium on 'How to make a hand'. The following are abstracts of communications and posters presented at the meeting.

Severe nasal clefting and abnormal embryonic apoptosis in Alx3/Alx4 double mutant mice.

A group of mouse aristaless-related genes has been implicated in functions in the development of the craniofacial skeleton. We have generated an Alx3 mutant allele in which the lacZ coding sequence is inserted in-frame in the Alx3 gene and the sequences encoding the conserved protein domains are deleted. Mice homozygous for this null allele are indistinguishable from wild-type mice. Compound mutants of Alx3 and Alx4, however, show severe craniofacial abnormalities that are absent in Alx4 single mutants. Alx3/Alx4 double mutant newborn mice have cleft nasal regions. Most facial bones and many other neural crest derived skull elements are malformed, truncated or even absent. The craniofacial defects in Alx3/Alx4 double mutant embryos become anatomically manifest around embryonic day 10.5, when the nasal processes appear to be abnormally positioned. This most probably leads to a failure of the medial nasal processes to fuse in the facial midline and subsequently to the split face phenotype. We detected a significant increase in apoptosis localised in the outgrowing frontonasal process in embryonic day 10.0 double mutant embryos, which we propose to be the underlying cause of the subsequent malformations.

Automated topographical cell proliferation analysis.

BACKGROUND: Cell proliferation is often studied using the incorporation of bromodeoxyuridine (BrdU). Immunohistochemical staining is then used to detect BrdU in the nucleus. To circumvent the observer bias and labor-intensive nature of manually counting BrdU-labeled nuclei, an automated topographical cell proliferation analysis method is developed. METHODS: Sections stained with fluorescein-labeled anti-BrdU and counterstained with To-Pro-3 are scanned using confocal laser scanning microscopy (CLSM). For every point in the image, the nucleus density of BrdU-labeled nuclei and the total nucleus density of the neighborhood of that point are calculated from the BrdU and the To-Pro-3 signal, respectively. The ratio of these densities gives an indication of the amount of cell proliferation at that point. The automated measure is validated by comparing it with the ratio of BrdU-stained nuclei to the total number of nuclei obtained from a manual count. RESULTS: A positive correlation is found between the automated measure and the ratios calculated from the manual counting (r = 0.86, P < 0.001). Calculating the topographical cell proliferation using the automated method is faster and does not suffer from interobserver variability. CONCLUSIONS: Automated topographical cell proliferation analysis is a fast method to objectively find differences in cell proliferation within a tissue. This can be visualized by a topographical map that corresponds to the tissue under study.

Prx1 and Prx2 are upstream regulators of sonic hedgehog and control cell proliferation during mandibular arch morphogenesis.

The aristaless-related homeobox genes Prx1 and Prx2 are required for correct skeletogenesis in many structures. Mice that lack both Prx1 and Prx2 functions display reduction or absence of skeletal elements in the skull, face, limbs and vertebral column. A striking phenotype is found in the lower jaw, which shows loss of midline structures, and the presence of a single, medially located incisor. We investigated development of the mandibular arch of Prx1(-/-)Prx2(-/-) mutants to obtain insight into the molecular basis of the lower jaw abnormalities. We observed in mutant embryos a local decrease in proliferation of mandibular arch mesenchyme in a medial area. Interestingly, in the oral epithelium adjacent to this mesenchyme, sonic hedgehog (Shh) expression was strongly reduced, indicative of a function for Prx genes in indirect regulation of SHH: Wild-type embryos that were exposed to the hedgehog-pathway inhibitor, jervine, partially phenocopied the lower jaw defects of Prx1(-/-)Prx2(-/-) mutants. In addition, this treatment led to loss of the mandibular incisors. We present a model that describes how loss of Shh expression in Prx1(-/-)Prx2(-/-) mutants leads to abnormal morphogenesis of the mandibular arch.

Expression patterns of group-I aristaless-related genes during craniofacial and limb development.

Aristaless-related proteins are structurally defined by the presence of a paired-type homeodomain and an additional conserved domain, known as aristaless domain or OAR-domain. These proteins can be further categorized in three groups (Int. J. Dev. Biol., 43 (1999) 651). Group-I aristaless-related genes are linked to functions in the development of the craniofacial and appendicular skeleton and are expressed predominantly in the mesenchyme in stages from gastrulation through at least mid-gestation (Mech. Dev., 48 (1994) 245; Mech. Dev., 52 (1995) 51; Development, 124 (1997) 3999; Dev. Biol., 199 (1998) 11; Development, 126 (1999) 495). In view of the highly redundant character of the functions of these genes in patterning craniofacial and limb structures, we found it important to directly compare their expression patterns at critical stages of craniofacial and limb development.

Targeted inactivation of Hoxb8 affects survival of a spinal ganglion and causes aberrant limb reflexes.

Hoxb8 mutant mice were generated by inserting the lacZ coding sequence in frame with the first exon of Hoxb8. These mice express a fusion protein with a functional beta-galactosidase activity instead of Hoxb8. Mutant embryos were analyzed for anatomical changes. The results indicate that Hoxb8 is not an indispensable regulator of A-P patterning in the forelimb, unlike suggested by our Hoxb8 gain of function experiments (Charité J, DeGraaff W, Shen S, Deschamps J. Cell 1994;78:589-601). The null mutant phenotypic traits include degeneration of the second spinal ganglion (C2), an abnormality opposite to the alteration in the gain of function transgenic mice. Subtle changes in the thoracic part of the vertebral column were observed as well. Adult homozygous mutants exhibit an abnormal clasping reflex of the limbs.

Vertebrate aristaless-related genes.

Aristaless-related genes, a subset of the Paired-related homeobox genes, have in the past few years emerged as a group of regulators of essential events during vertebrate embryogenesis. One group of aristaless-related genes has been linked to the morphogenesis of the craniofacial and appendicular skeleton by their expression patterns and by the phenotypes of natural and artificial mouse mutants. Expression and function in the nervous system characterise a second group, and a third group, the Pitx genes, have been shown to have many different roles, including functions in the pituitary, left-right determination and limb development.

Prx1 and Prx2 in skeletogenesis: roles in the craniofacial region, inner ear and limbs.

Prx1 and Prx2 are closely related paired-class homeobox genes that are expressed in very similar patterns predominantly in mesenchyme. Prx1 loss-of-function mutants show skeletal defects in skull, limbs and vertebral column (Martin, J. F., Bradley, A. and Olson, E. N. (1995) Genes Dev. 9, 1237-1249). We report here that mice in which Prx2 is inactivated by a lacZ insertion had no skeletal defects, whereas Prx1/Prx2 double mutants showed many novel abnormalities in addition to an aggravation of the Prx1 single mutant phenotype. We found defects in external, middle and inner ear, reduction or loss of skull bones, a reduced and sometimes cleft mandible, and limb abnormalities including postaxial polydactyly and bent zeugopods. A single, or no incisor was present in the lower jaw, and ectopic expression of Fgf8 and Pax9 was found medially in the mandibular arch. A novel method to detect &bgr ;-galactosidase activity in hydroxyethylmethacrylate sections allowed detailed analysis of Prx2 expression in affected structures. Our results suggest a role for Prx genes in mediating epitheliomesenchymal interactions in inner ear and lower jaw. In addition, Prx1 and Prx2 are involved in interactions between perichondrium and chondrocytes that regulate their proliferation or differentiation in the bones of the zeugopods.

Patterns of paired-related homeobox genes PRX1 and PRX2 suggest involvement in matrix modulation in the developing chick vascular system.

PRX1 (MHox) and PRX2 (S8) were previously shown to be expressed throughout embryogenesis in complex, mostly mesenchyme-specific patterns. In the developing cardiovascular system both genes were highly expressed in prospective connective tissues, that is, endocardial cushions and valves, the epicardium, and the wall of the great arteries and veins. We further scrutinised expression of PRX1 and PRX2 in the developing vascular system of the chicken embryo and compared patterns with those of established vascular differentiation markers (muscle-actin, procollagen I, and fibrillin-2). PRX1 and PRX2 expression were associated with the primary vessel wall from early stages onward and became increasingly restricted to the adventitial and outer medial cell layers. PRX1 eventually colocalised strikingly with procollagen I and fibrillin-2 expression and generally excluded high smooth muscle actin expression. Furthermore, PRX1 expression preceded the segregation of very distinct nonmuscular cells and smooth muscle cells in the media of the great arteries. PRX2 patterns deviated at later stages from those of PRX1 and showed specific and high transcript levels in the ductus arteriosus from embryonic day 6 onward. Results suggest that PRX genes are not essential in smooth muscle contractile differentiation, but may be involved in matrix modulation in the vascular system and possibly in defining the noncontractile cellular phenotype and in media-adventitia definition.

Mouse Alx3: an aristaless-like homeobox gene expressed during embryogenesis in ectomesenchyme and lateral plate mesoderm.

Mouse Alx3 is a homeobox gene that is related to the Drosophila aristaless gene and to a group of vertebrate genes including Prx1, Prx2, Cart1, and Alx4. The protein encoded contains a diverged variant of a conserved peptide sequence present near the carboxyl terminus of at least 15 different paired-class-homeodomain proteins. Alx3 is expressed in mouse embryos from 8 days of gestation onward in a characteristic pattern, predominantly in neural crest-derived mesenchyme and in lateral plate mesoderm. We detected prominent expression in frontonasal head mesenchyme and in the first and second pharyngeal arches and some of their derivatives. High expression was also seen in the tail and in many derivatives of the lateral plate mesoderm including the limbs, the body wall, and the genital tubercle. aristaless-related genes like Alx3, Cart1, and Prx2 are expressed in overlapping proximodistal patterns in the pharyngeal arches. Similar, but more lateral patterns have been described for the Distal-less-related (Dlx) genes. Intriguingly, expression and to some extent function of aristaless and Distal-less in Drosophila also have overlapping as well as complementary aspects. Alx3 was localized to chromosome 3, near the droopy-ear (de) mutation.

Regulation of the Hoxb-8 gene: synergism between multimerized cis-acting elements increases responsiveness to positional information.

Hox genes play a key role in the specification of regional development in the vertebrate embryo. They are expressed in regionally restricted domains along the anterior-posterior axis, generally extending from a sharp rostral boundary toward the posterior end. We have studied the regulation of the murine Hoxb-8 gene in vivo using reporter constructs and found that 11 kb of genomic sequences upstream of Hoxb-8 confer a Hox-like pattern of expression on a lacZ reporter gene fused in-frame to the first exon of Hoxb-8. Reporter gene expression was detectable from early stages onwards, but reached rostral expression boundaries in mesoderm and neurectoderm that were more posterior than those of the endogenous gene. Within the upstream region, we have identified several cis-acting elements which are individually capable of driving regionally restricted expression in combination with the Hoxb-8 promoter, and we have investigated their relative contributions to the expression pattern. The results suggest that, in this experimental context, these upstream elements, as well as previously identified elements located within the Hoxb-8 gene, cooperate in setting the rostral expression boundaries. Furthermore, we show that multiple identical copies of cis-acting elements can cooperate, causing a pronounced anterior shift in the expression boundaries. This indicates that the rostral extent of expression is limited by the activity of a transcription factor binding to these elements and that this activity was, at some point in development, higher in precursors of more posterior structures than in precursors of anterior structures. This factor is thus very likely to be involved in the transduction of positional signals.

Expression patterns of the paired-related homeobox genes MHox/Prx1 and S8/Prx2 suggest roles in development of the heart and the forebrain.

Prx1 and Prx2 (previously called MHox and S8, respectively) are the members of a small subfamily of vertebrate homeobox genes expressed during embryogenesis from gastrulation onwards. We directly compared the expression domains of the Prx genes in detail in mouse and in addition some aspects of these patterns in chicken. In addition to the superficially similar expression patterns of Prx1 and Prx2 in cranial mesenchyme, limb buds, axial mesoderm, and branchial arches and their derivatives, we detect major differences at many sites particularly in heart and brain. Our analysis indicated in several cases a correlation with regions developing into connective tissues. From at least day 8.5, Prx-1 expression was observed in the heart, initially in the endocardial cushions and later in the developing semilunar and atrioventricular valves. Prx2 develops early on a diffuse myocardial expression pattern and is later higher expressed in the ventricular septum and in particular in the ductus arteriosus. Prx2 is never expressed in the brain, whereas Prx1 is expressed, from at least day 9.5 onwards, in a unique distinct domain in the ventral part of the hypothalamus, as well as in a broader region of the telencephalon.

DNA-binding specificity of the S8 homeodomain.

The murine S8 homeobox gene is expressed in a mesenchyme-specific pattern in embryos, as well as in mesodermal cell lines. The S8 homeodomain is overall similar to paired type homeodomains, but at position 50, which is crucial for specific DNA recognition, it contains a Gln, as is found in Antennapedia (Antp)-type homeodomains. We determined the DNA-binding specificity of the purified S8 homeodomain by in vitro selection of random oligonucleotides. The resulting 11-bp consensus binding site, ANC/TC/TAATTAA/GC resembles, but subtly differs from, the recognition sequences of Antp-type homeodomains. Equilibrium binding constants of down to 6.0 x 10(-10) M were found for binding of the S8 homeodomain to selected oligonucleotides. Using specific antibodies and an oligonucleotide containing an S8-site, we detected by band-shift two abundant DNA binding activities in mesodermal cell lines that correspond to S8 and two more that correspond to its close relative MHox. These S8 protein forms are differentially expressed in retinoic acid-treated P19 EC cells.

Differential expression of the HMG box factors TCF-1 and LEF-1 during murine embryogenesis.

The recent identification of a number of T lymphocyte-specific enhancers has allowed the cloning of several novel transcription factors. Two of these, TCF-1 and LEF-1, contain a virtually identical DNA-binding domain of the High Mobility Group (HMG-1) box type. TCF-1 and LEF-1 originate from a recent gene duplication event as evidenced by comparison with the chicken homologue, chTCF. We have now analyzed the differential expression of these two transcription factors. In a panel of lymphoid cell lines, TCF-1 was exclusively expressed in the T cell lineage. In contrast, LEF-1 mRNA was detected at equivalent levels in pro- and pre-B cells and in all T lineage cells. In situ hybridization on murine embryos revealed that TCF-1 and LEF-1 were widely expressed at day 7.5 of gestation. At later stages, the expression patterns were complex and only partially overlapping. The expression of TCF-1 and LEF-1 coincided until day 10.5, when mRNAs were detected in limb buds, neural crest, pharyngeal arches and nasal process. At later time points (day 13.5 to 14.5), sites of overlapping expression included lung, the urogenital system, tooth buds, thymus and choroid plexus. Unique expression sites for TCF-1 included Reichert's membrane and trophectoderm-derived cells, the ribs and thoracic prevertebrae, craniofacial structures, the adrenal gland and meninges. Unique LEF-1 expression was observed in the tail prevertebrae, brain and inner ear. Postnatally, expression of both genes could only be detected in lymphoid tissues. These observations suggest that TCF-1 and LEF-1 exert differential functions during murine embryogenesis.

The homeobox gene S8: mesoderm-specific expression in presomite embryos and in cells cultured in vitro and modulation in differentiating pluripotent cells.

The S8 gene of the mouse contains a paired-like homeobox and is expressed during organogenesis in a complex pattern in mesenchyme. Here we show that S8 is first expressed in extraembryonic mesoderm of primitive streak stage embryos and that it is strongly expressed in mesoderm of early-headfold/neural plate stage embryos. It is, however, absent from the primitive streak and its immediately adjacent areas. Early after initial mesoderm formation, this expression domain defines a specific region of the mesoderm that, to some extent, foreshadows the later S8 expression pattern. The pattern at this stage is roughly complementary to that of the brachyury (T) gene. Expression in cell lines was studied both at the level of RNA and protein. Mesoderm specificity of S8 expression was confirmed in terminally differentiated cell lines. S8 is activated by retinoic acid in certain embryonal carcinoma cells, embryonic stem cells, and neural crest cell lines, and also during spontaneous differentiation in embryonic stem cells.

Induction of HOX-2 genes in P19 embryocarcinoma cells is dependent on retinoic acid receptor alpha.

In vertebrate embryos retinoic acid can act as a teratogen and may have a natural function as a morphogen. In both cases the mechanism by which retinoic acid exerts its effect may involve alteration of the level of HOX gene transcription. We have investigated the role of retinoic acid receptor alpha (RAR alpha) in retinoic acid-dependent induction of HOX-2 gene expression in embryocarcinoma (EC) cells by using the P19 RAC65 EC cell line, which is retinoic acid-resistant due to the expression of a dominant negative RAR alpha. No induction of HOX-2 genes by retinoic acid was seen, while in P19 RAC65 EC cells stably transfected with human RAR alpha under the control of a constitutive promoter HOX-2 gene induction is restored. This shows that RAR alpha is involved in HOX gene induction by retinoic acid.

DNA-binding activity of the murine homeodomain protein Hox-2.3 produced by a hybrid phage T7/vaccinia virus system.

Homeobox-containing genes encode transcription factors that, via the homeodomain, bind specifically to DNA. To study the DNA-binding properties of the murine homeodomain-containing protein, Hox-2.3, a hybrid expression system was used, combining gene expression by recombinant vaccinia virus (reVV) with bacteriophage T7 transcription. Expression was achieved by co-infecting HeLa cells with two reVVs, one expressing the T7-RNA polymerase-encoding gene directed by the VV promoter, P7.5, and another containing the Hox-2.3 coding sequence under control of a T7 promoter [Fuerst et al., Mol. Cell. Biol. 7 (1987) 2538-2544]. Co-infected HeLa cells produced large amounts of full-length Hox-2.3 protein. Cytoplasmic and nuclear extracts from these cells were used to examine DNA-binding specificity in vitro. reVV-produced Hox-2.3 protein bound to oligos that contained one or several copies of the common homeodomain-binding site, 5'-TCA-ATTAAAT, and to a lesser extent to multiple (TAA) repeats. Using Southwestern blot analysis, no Hox-2.3-binding sites were detected in a region of the Hox-2 cluster containing the Hox-2.3, Hox-2.4 and Hox-2.5 genes.

The murine Hox-2.4 promoter contains a functional octamer motif.

Like other HOX genes the murine Hox-2.4 gene is thought to be involved in regional specification along the antero-posterior axis. In addition it has been reported to have oncogenic potential. We studied expression Hox-2.4 in murine EC cells and determined the transcription start site. Studies of DNA-protein interactions in the promoter region showed that the Hox-2.4 promoter contains a CCAAT box and a perfect octamer motif, which is capable of binding Oct-factors. Cotransfection of Oct expression vectors influences the transcriptional activity of the promoter, suggesting that the Oct-gene family may be involved in regulating HOX genes.

Mammalian homeobox genes in normal development and neoplasia.

This review aims at providing an evaluation of the currently available data concerning the role of homeobox genes in mammalian embryonic pattern formation, and their involvement in oncogenic processes. The literature dealing with mouse and human homeobox genes is covered, with some excursions into Xenopus and chicken work because studies regarding particular aspects of development in the latter systems often complement those in mammals. Other studies in amphibians, chicken, and fish are omitted as they fall outside the scope of this survey devoted to mammalian genes. Emphasis is placed on expression and regulation during normal embryogenesis, on present hypotheses regarding gene function, on effects on development of modifying the expression patterns, and on observed aberrations in structure or expression associated with and possibly causally linked to neoplasia. The studies specifically dealing with the structure of the homeodomain and the mechanism of its interactions with DNA, which have been recently reviewed, are not considered here. The most thoroughly studied mammalian homeobox genes bear sequence homology to the Drosophila Antennapedia (Antp) homeotic gene and are thought to be involved in determination of regional identity along the anteroposterior (A-P) axis. Studies on these genes, the HOX genes, are oftem compared with related investigations in flies. In addition to the HOX genes, a number of genes containing a homeobox related to that in other Drosophila developmental control genes have been isolated from the mammalian genome and are being intensively studied. Homeodomains divergent from the Antp prototype have been discovered in an increasing number of transcription factors. Some of these may play a crucial role in local pattern formation, while others are tissue-specific or ubiquitous transcription regulators. As is unsurprising of genes, whose products regulate transcription, some of the homeobox-containing genes have been associated with malignancy, usually on the basis of abnormal structure, or deletions found to occur in tumor cells. The degree of probability that these mutated forms were causative in the generation of the tumors in which they were found is discussed.

Cloning of murine TCF-1, a T cell-specific transcription factor interacting with functional motifs in the CD3-epsilon and T cell receptor alpha enhancers.

CD3-epsilon gene expression is confined to the T cell lineage. We have recently identified and cloned a human transcription factor, TCF-1, that binds to a functional element in the T lymphocyte-specific enhancer of CD3-epsilon. In a panel of human cell lines, TCF-1 expression was restricted to T lineage cells. TCF-1 belonged to a novel family of genes that contain the so-called high mobility group 1 (HMG) box. Here we report the cloning of murine TCF-1. Two splice alternatives were identified that were not previously observed in human TCF-1. Murine and human TCF-1 displayed a 95.5% overall amino acid homology. Recombinant murine and human TCF-1 recognized the same sequence motif in the CD3-epsilon enhancer as judged by gel retardation and methylation interference assays. With the murine cDNA clones several aspects of TCF-1 were analyzed. First, deletion analysis revealed that a region of TCF-1 containing the HMG box was sufficient for sequence-specific binding. Second, by high stringency Northern blotting and in situ hybridization, TCF-1 expression was shown to be confined to the thymus and to the T cell areas of the spleen. Third, TCF-1 bound specifically to a functional T cell-specific element in the T cell receptor alpha (TCR-alpha) enhancer. The T lineage-specific expression and the affinity for functional motifs in the TCR-alpha and CD3-epsilon enhancers imply an important role for TCF-1 in the establishment of the mature T cell phenotype.