Multistep signaling and transcriptional requirements for pituitary organogenesis in vivo.

During development of the mammalian pituitary gland, specific hormone-producing cell types, critical in maintaining homeostasis, emerge in a spatially and temporally specific fashion from an ectodermal primordium. We have investigated the molecular basis of generating diverse cell phenotypes from a common precursor, providing in vivo and in vitro evidence that development of these cell types involves at least four sequential phases of signaling events and the action of a gradient at an ectodermal boundary. In the first phase, we hypothesize that this notochord induces invagination of Rathke's pouch from the oral ectoderm. This is followed by appearance of an ectodermal boundary, formed with exclusion of Shh from the nascent pouch. Next, signals from the ventral diencephalon--expressing BMP4, Wnt5a, FGF10, and FGF8--in concert with Shh represent critical in vivo signals for pituitary determination. Subsequently, a dorsal-ventral BMP2 signal gradient emanates from a ventral pituitary organizing center, forming at the boundary to oral ectoderm region from which Shh expression is selectively excluded. In concert with a dorsal FGF8 signal, this creates opposing gradients that generate overlapping patterns of specific transcription factors that underlie cell lineage specification events. The mechanisms by which these transient gradients of signaling molecules lead to the appearance of four ventral pituitary cell types appear to involve the reciprocal interactions of two transcription factors, Pit-1 and GATA-2, which are epistatic to the remainder of the cell type-specific transcription programs and serve as a molecular memory of the transient signaling events. Unexpectedly, this program includes a DNA-binding-independent function of Pit-1, suppressing the ventral GATA-2-dependent gonadotrope program by inhibiting GATA-2 binding to gonadotrope- but not thyrotrope-specific genes. This indicates that both DNA-binding-dependent and-independent actions of abundant determining factors contribute to generate distinct cell phenotypes. In the fourth phase, temporally specific loss of the BMP2 signal is required to allow terminal differentiation. The consequence of these sequential organ and cellular determination events is that each of the pituitary cell types--gonadotropes, thyrotropes, somatotropes, lactotropes, corticotropes, and melanotropes appears to be determined, in a ventral to dorsal gradient, respectively, apparently based on a combinatorial code of transcription factors induced by the gradient of specific signaling molecules.

Pax6 is essential for establishing ventral-dorsal cell boundaries in pituitary gland development.

Pax6, a highly conserved member of the paired homeodomain transcription factor family that plays essential roles in ocular, neural, and pancreatic development and effects asymmetric transient dorsal expression during pituitary development, with its expression extinguished before the ventral --> dorsal appearance of specific cell types. Analysis of pituitary development in the Small eye and Pax6 -/- mouse mutants reveals that the dorsoventral axis of the pituitary gland becomes ventralized, with dorsal extension of the transcriptional determinants of ventral cell types, particularly PFrk. This ventralization is followed by a marked decrease in terminally differentiated dorsal somatotrope and lactotrope cell types and a marked increase in the expression of markers of the ventral thyrotrope cells and SF-1-expressing cells of gonadotrope lineage. We suggest that the transient dorsal expression of Pax6 is essential for establishing a sharp boundary between dorsal and ventral cell types, based on the inhibition of Shh ventral signals.

Body's left side.

The generation of left-right organ asymmetry during development involves a cascade of signaling events, while the initiating event is not proven, the mechanism of such organ asymmetry involves a number of genetically defined signaling molecules and, potentially specific transcription factors. Development of asymmetry appears to involve regulation of cell migration and proliferation events, and may be mechanistically distinct for different organs, such as pulmonary asymmetry versus cardiac situs. While the precise mechanisms by which genetically linked factors exert their effects still remains incompletely defined, an outline of those events can be deduced.

Pitx2 regulates lung asymmetry, cardiac positioning and pituitary and tooth morphogenesis.

Pitx1 and Pitx2 are highly homologous, bicoid-related transcription factors. Pitx2 was initially identified as the gene responsible for the human Rieger syndrome, an autosomal dominant condition that causes developmental abnormalities. Pitx2 is asymmetrically expressed in the left lateral-plate mesoderm, and mutant mice with laterality defects show altered patterns of Pitx2 expression that correlate with changes in the visceral symmetry (situs). Ectopic expression of Pitx2 in the right lateral-plate mesoderm alters looping of the heart and gut and reverses body rotation in chick and Xenopus embryos. Here we describe the phenotype of Pitx2 gene-deleted mice, characterized by defective body-wall closure, right pulmonary isomerism, altered cardiac position, arrest in turning and, subsequently, a block in the determination and proliferation events of anterior pituitary gland and tooth organogenesis. Thus, Pitx2 is a transcription factor that encodes 'leftness' of the lung.

A model for the development of the hypothalamic-pituitary axis: transcribing the hypophysis.

Mammalian organogenesis involves a sequential program to generate cells with specific fates and phenotypes from a common primordium, which is hypothesized to be the consequence of regulated overlapping patterns of expression of specific sets of transcription factors in a precise spatiotemporal manner. The hypothalamic-pituitary axis is critical for survival and homeostasis, controlling growth, reproduction, metabolism and behavior, and constitutes an ideal model in which to define the molecular markers to emergence of specific cell phenotypes from a common primordium. Development of the anterior pituitary gland is controlled by sequential series of gradients of specific signaling molecules that, in turn, appear to coordinate the expression of specific combinations of transcription factor-encoding genes, many of which as tissue-specific or tissue restricted factors that serially dictate cell-type determination and terminal differentiation events that underlie the differentiated cell phenotype.

Role of the Bicoid-related homeodomain factor Pitx1 in specifying hindlimb morphogenesis and pituitary development.

Pitx1 is a Bicoid-related homeodomain factor that exhibits preferential expression in the hindlimb, as well as expression in the developing anterior pituitary gland and first branchial arch. Here, we report that Pitx1 gene-deleted mice exhibit striking abnormalities in morphogenesis and growth of the hindlimb, resulting in a limb that exhibits structural changes in tibia and fibula as well as patterning alterations in patella and proximal tarsus, to more closely resemble the corresponding forelimb structures. Deletion of the Pitx1 locus results in decreased distal expression of the hindlimb-specific marker, the T-box factor, Tbx4. On the basis of similar expression patterns in chick, targeted misexpression of chick Pitx1 in the developing wing bud causes the resulting limb to assume altered digit number and morphogenesis, with Tbx4 induction. We hypothesize that Pitx1 serves to critically modulate morphogenesis, growth, and potential patterning of a specific hindlimb region, serving as a component of the morphological and growth distinctions in forelimb and hindlimb identity. Pitx1 gene-deleted mice also exhibit reciprocal abnormalities of two ventral and one dorsal anterior pituitary cell types, presumably on the basis of its synergistic functions with other transcription factors, and defects in the derivatives of the first branchial arch, including cleft palate, suggesting a proliferative defect in these organs analogous to that observed in the hindlimb.

Mouse deformed epidermal autoregulatory factor 1 recruits a LIM domain factor, LMO-4, and CLIM coregulators.

Nuclear LIM domains interact with a family of coregulators referred to as Clim/Ldb/Nli. Although one family member, Clim-2/Ldb-1/Nli, is highly expressed in epidermal keratinocytes, no nuclear LIM domain factor is known to be expressed in epidermis. Therefore, we used the conserved LIM-interaction domain of Clim coregulators to screen for LIM domain factors in adult and embryonic mouse skin expression libraries and isolated a factor that is highly homologous to the previously described LIM-only proteins LMO-1, -2, and -3. This factor, referred to as LMO-4, is expressed in overlapping manner with Clim-2 in epidermis and in several other regions, including epithelial cells of the gastrointestinal, respiratory and genitourinary tracts, developing cartilage, pituitary gland, and discrete regions of the central and peripheral nervous system. Like LMO-2, LMO-4 interacts strongly with Clim factors via its LIM domain. Because LMO/Clim complexes are thought to regulate gene expression by associating with DNA-binding proteins, we used LMO-4 as a bait to screen for such DNA-binding proteins in epidermis and isolated the mouse homologue of Drosophila Deformed epidermal autoregulatory factor 1 (DEAF-1), a DNA-binding protein that interacts with regulatory sequences first described in the Deformed epidermal autoregulatory element. The interaction between LMO-4 and mouse DEAF-1 maps to a proline-rich C-terminal domain of mouse DEAF-1, distinct from the helix-loop-helix and GATA domains previously shown to interact with LMOs, thus defining an additional LIM-interacting domain.

Differential use of CREB binding protein-coactivator complexes.

CREB binding protein (CBP) functions as an essential coactivator of transcription factors that are inhibited by the adenovirus early gene product E1A. Transcriptional activation by the signal transducer and activator of transcription-1 (STAT1) protein requires the C/H3 domain in CBP, which is the primary target of E1A inhibition. Here it was found that the C/H3 domain is not required for retinoic acid receptor (RAR) function, nor is it involved in E1A inhibition. Instead, E1A inhibits RAR function by preventing the assembly of CBP-nuclear receptor coactivator complexes, revealing differences in required CBP domains for transcriptional activation by RAR and STAT1.

Barx2, a new homeobox gene of the Bar class, is expressed in neural and craniofacial structures during development.

Homeobox genes are regulators of place-dependent morphogenesis and play important roles in controlling the expression patterns of cell adhesion molecules (CAMs). To identify proteins that bind to a regulatory element common to the genes for two neural CAMs, Ng-CAM and L1, we screened a mouse cDNA expression library with a concatamer of the sequence CCATTAGPyGA and found a new homeobox gene, which we have called Barx2. The homeodomain encoded by Barx2 is 87% identical to that of Barx1, and both genes are related to genes at the Bar locus of Drosophila melanogaster. Barx1 and Barx2 also encode an identical stretch of 17 residues downstream of the homeobox; otherwise, they share no appreciable homology. In vitro, Barx2 stimulated activity of an L1 promoter construct containing the CCATTAGPyGA motif but repressed activity when this sequence was deleted. Localization studies showed that expression of Barx1 and Barx2 overlap in the nervous system, particularly in the telencephalon, spinal cord, and dorsal root ganglia. Barx2 was also prominently expressed in the floor plate and in Rathke's pouch. During craniofacial development, Barx1 and Barx2 showed complementary patterns of expression: whereas Barx1 appeared in the mesenchyme of the mandibular and maxillary processes, Barx2 was observed in the ectodermal lining of these tissues. Intense expression of Barx2 was observed in small groups of cells undergoing tissue remodeling, such as ectodermal cells within indentations surrounding the eye and maxillo-nasal groove and in the first branchial pouch, lung buds, precartilagenous condensations, and mesenchyme of the limb. The localization data, combined with Barx2's dual function as activator and repressor, suggest that Barx2 may differentially control the expression of L1 and other target genes during embryonic development.

Pax3: a paired domain gene as a regulator in PNS myelination.

Pax3 RNA is expressed in neural crest when Schwann cell (SC) precursors migrate to the PNS. Pax3 RNA and SC markers were monitored in sciatic nerves of mice during development and nerve repair. An inverse correlation was observed between expression of Pax3 RNA and myelin basic protein (MBP). Inverse correlation was also observed in SC primary cultures. Treating cultures with forskolin, an adenylate cyclase agonist, repressed Pax3 RNA, GFAP, NGFR, N-CAM, and L1 and elevated MBP. Subsequent microinjection with Pax3 expression vector elevated Pax3 RNA, GFAP, NGFR, N-CAM, and L1 and repressed MBP. Thus, Pax3 is likely involved in the differentiation pathway to myelinating SCs. Pax3 repressed a 1.3 kb MBP promoter fragment in cotransfection assays, suggesting that it represses MBP transcription.

Expression of endopeptidase-24.11 (common acute lymphoblastic leukaemia antigen CD10) in the sciatic nerve of the adult rat after lesion and during regeneration.

Endopeptidase-24.11, which is identical with the common acute lymphoblastic leukaemia antigen CD10 (CALLA), is a cell surface Zn2+ metalloprotease that regulates peptide-induced responses in different tissues, including the nervous and immune systems. In the peripheral nervous system, high levels of the enzyme are present in all neonatal and early postnatal Schwann cells, while as myelination proceeds it is gradually suppressed in the majority of cells that form myelin but retained in non-myelin-forming cells in the adult animal. In the present study we have investigated the effects of transection, crush and regeneration of the adult rat sciatic nerve on the expression of the endopeptidase by Schwann cells in situ. Endopeptidase-24.11 was monitored by immunocytochemistry using the monoclonal anti-endopeptidase antibody 23B11. For comparison, a parallel study was carried out with a monoclonal antibody directed against the rat nerve growth factor receptor. We found that (i) all Schwann cells of the distal segment re-expressed endopeptidase-24.11 as early as 4 days after axotomy, the level of immunostaining reaching a maximum after 2 weeks, (ii) axonal regeneration repressed Schwann cell expression of endopeptidase-24.11, and (iii) the induction of the nerve growth factor receptor followed a similar pattern to that of endopeptidase-24.11 in the transected and crushed nerve. Enzymatic amplification of endopeptidase-24.11 cDNA from normal and axotomized adult rat sciatic nerve confirmed the expression of endopeptidase-24.11 in these tissues. Our results show that the expression of endopeptidase-24.11 in Schwann cells, as is the case with the nerve growth factor receptor, is induced by the loss of the normal axon-Schwann cell contact. The significant increase in the expression of endopeptidase-24.11 by Schwann cells after axonal damage suggests that the enzyme could play a role in axonal regeneration.

PAX5 expression correlates with increasing malignancy in human astrocytomas.

Rearrangements concerning chromosome 9p are a late event in the progression of human astrocytic tumors to their most malignant form. The expression of PAX5, which maps to chromosome 9p13, was studied in primary human brain tumors of astrocytic origin. Whereas murine Pax5 is not expressed in the forebrain at any stage, PAX5 expression was increased in a range of astrocytomas (WHO grades II-IV) which originated in the forebrain. Expression of PAX5 was limited to those cells which also expressed the oncogenes myc, fos, or jun singularly or in combination. The epidermal growth factor receptor was highly expressed in glioblastoma multiform tumors in areas which were also highly PAX5 positive. We conclude that the missappropriate expression of PAX5 may aid in promoting the progression of astrocytomal malignancy.

Differential induction of Pax genes by NGF and BDNF in cerebellar primary cultures.

The Pax genes encode sequence-specific DNA binding transcription factors that are expressed in embryonic development of the nervous system. Primary neuronal cell cultures derived from the cerebellar cortex of embryonic day 14, newborn and 7-d old mice, were used to investigate the cell-type specific expression patterns of three members of the murine paired box containing gene family (Pax gene family), in vitro. Cell types which express Pax-2, Pax-3, and Pax-6 RNA in primary cultures correspond to those found in regions of the cerebellum which show RNA signals in sections of the developing mouse brain. To find mechanisms regulating Pax gene expression during cerebellar development, the differential regulation of Pax-2, Pax-3, and Pax-6 by NGF and BDNF, two structurally related neurotrophins, was studied in such primary cultures. Pax-2 and Pax-6 RNA increased slightly by 1 h and remained elevated throughout a 24-h treatment with BDNF and NGF. Pax-3 RNA was not detected in newborn cultures, but underwent a rapid (1 h) and transient (2 h) induction upon treatment with either BDNF or NGF. No response was seen with EGF or FGF. Cycloheximide treatment amplified Pax-3 induction and prolonged the signal. Thus, Pax-3 induction resembles that of the immediate-early gene c-fos, which transduces growth factor signals during the development of particular neuronal/glial cell types. The changes in Pax expression were inductive rather than trophic.

Regulated expression of Brachyury(T), Nkx1.1 and Pax genes in embryoid bodies.

Embryonic stem cells (ES) can be exploited to analyze in vitro mechanisms of cellular differentiation. We have utilized ES-derived embryoid body formation in an attempt to study cell types resulting from in vitro differentiation. To this end, a variety of molecular markers, preferably those which have been associated with regulatory events during mouse embryogenesis, was employed. Specifically, Brachyury (T), Pax-3 and Pax-6 genes as well as Nkx-1.1 were used. We could demonstrate that the expression of these genes in vitro was regulated by growth factors such as activin A or bFGF. Implications of these findings and the possible applications for identifying new genes are discussed.

Endopeptidase-24.11 is suppressed in myelin-forming but not in non-myelin-forming Schwann cells during development of the rat sciatic nerve.

Endopeptidase-24.11, which is identical with the common acute lymphoblastic leukemia antigen (CALLA), is a cell surface zinc metalloprotease that has the ability to hydrolyse a variety of physiologically active peptides. Interest in this enzyme is based on the view that it may play a role in the regulation of peptide signals in different tissues, including the nervous and immune systems. We have previously shown that endopeptidase-24.11 is present in Schwann cells in the peripheral nervous system of newborn pigs [Kioussi C. and Matsas R. (1991) J. Neurochem. 57, 431-440]. In the present study we have investigated the developmental expression of the endopeptidase by Schwann cells in the rat sciatic nerve, from embryonic day 16 to maturity. Endopeptidase-24.11 was monitored enzymatically as well as by immunoblotting and immunocytochemistry using the monoclonal anti-endopeptidase antibody 23B11. We found an age-dependent decline in both the enzyme activity and the levels of immunoreactive protein. Endopeptidase-24.11 was first detected at embryonic day 18 and was present in all neonatal and early postnatal Schwann cells. However, as myelination proceeded the endopeptidase was gradually suppressed in the majority of cells that form myelin but retained in non-myelin-forming cells in the adult animal. At this stage, only very few large diameter myelinated fibers expressed weakly endopeptidase-24.11. Schwann cells dissociated from postnatal day 5 nerves and cultured up to one week in the absence of axons expressed endopeptidase-24.11. These results show that the endopeptidase has a distinct developmental profile in the rat sciatic nerve, similar to that of a group of other Schwann cell surface antigens, including the cell adhesion molecules N-CAM and L1 and the nerve growth factor receptor. We suggest that, as is the case with these antigens, endopeptidase-24.11 may play a role in nerve development and/or regeneration. In addition, persistence of endopeptidase-24.11 in a minority of adult myelin-forming Schwann cells suggests a possible role for the enzyme in axon-myelin apposition and maintenance, especially of larger diameter axons.

Endopeptidase-24.11, a cell-surface peptidase of central nervous system neurons, is expressed by Schwann cells in the pig peripheral nervous system.

Endopeptidase-24.11 is a 90-kDa surface glycoprotein with the ability to hydrolyze a variety of biologically active peptides. Interest in this enzyme is based on the consensus that it may play a role in the termination of peptide signals in the central nervous system. In the present study, we have investigated the distribution of endopeptidase-24.11 in two nerves of the peripheral nervous system of newborn pigs: the sciatic, composed of a mixture of myelinated and nonmyelinated axons, and cervical sympathetic trunk in which greater than 99% of the axons are nonmyelinated. The endopeptidase was monitored enzymatically, as well as by immunoblotting and immunocytochemistry using mono- and polyclonal anti-endopeptidase antibodies. Endopeptidase-24.11 was detected in both the sciatic nerve and the cervical sympathetic trunk. Membrane preparations from sciatic nerve hydrolyzed 125I-insulin B-chain, and more than 50% of the activity was inhibited by phosphoramidon with an IC50 concentration of 3.2 nM. Moreover, a 90-kDa polypeptide was detected by immunoblotting of sciatic nerve membranes. The type of cells expressing the endopeptidase was determined by immunohistochemistry. In teased nerve preparations, these cells were identified morphologically as myelin- and non-myelin-forming Schwann cells. Endopeptidase-24.11 was also expressed by cultured Schwann cells from sciatic nerve and cervical sympathetic trunk maintained for 3 h in vitro. The presence of endopeptidase-24.11 on the Schwann cell surface raises the possibility of a potential role for the enzyme in nerve development and/or regeneration.