Kanako Saitoh

Developmental patterning in chondrocytic cultures by morphogenic gradients: BMP induces expression of indian hedgehog and noggin.

The maturation of chondrocytes is essential for endochondral bone formation. The Indian Hedgehog (Ihh) gene is expressed in prehypertropic chondrocytes and has been proposed to regulate chondrocyte maturation. While such secretary factors as PTHrP and BMP are thought to be involved in Ihh expression, the mechanism of the restricted expression of Ihh is not clear.

High-level expression of exogenous genes by replication-competent retrovirus vectors with an internal ribosomal entry site

We report the construction of two types of Rous sarcoma virus (RSV)-based replication-competent avian retrovirus vectors, IR1 and IR2 to express an exogenous gene at a very high level. In these vectors, the internal ribosomal entry site (IRES) derived from encephalomyocarditis virus (EMCV) was inserted between the env gene and an exogenous gene. The IR1 vector retains the splicing acceptor site that is present in the downstream of the env gene while the IR2 vector lacks it. Using a v-fos mutant (v-fos-CD3) as an example of exogenous genes, we show here that both IR1 and IR2 vectors expressed the gene product, CD3, at expression levels 5- and 8-fold higher than that of their parental vector without IRES, respectively. These vectors were moderately stable and kept a high-level expression of CD3 for at least three passages through the cells. Analysis of viral transcripts indicate that exogenous genes carried by both IR vectors were translated exclusively from the IRES that is present in all the species of the viral transcripts. High-level expression of exogenous genes was also observed in the case of the Hoxa-13 gene in the IR1 vector or the fra-2 gene in the IR2 vector, indicating that the extremely high-level expression characteristic of these vectors is applicable to several exogenous genes.

Analysis of cartilage maturation using micromass cultures of primary chondrocytes

A micromass culture (MM‐C) system of primary immature chondrocytes for functional analysis of soluble factors involved in the maturation step of cartilage was previously developed. Ectopically expressed BMP‐2 was shown to induce the expression of the Ihh and Noggin genes. Here it is demonstrated that, upon longer culture, secreted bone morphogenetic protein‐2 (BMP‐2) further promotes the maturation step as judged by the induction of type X collagen and BMP‐6 expression, which are known to be detectable in the later phase of cartilage maturation. Induction of all of these genes by secreted BMP‐2 was not inhibited by ectopic expression of parathyroid hormone‐related peptide (PTHrP) induced by retrovirus vector infection, although the same virus vector showed strong inhibitory effects on the expression of type X collagen gene or alkaline phosphatase activity in mature chondrocytes. These results suggest that the maturation‐promoting activity exhibited by BMP‐2 is dominant over the suppressive effect of PTHrP in immature chondrocytes. When the BMP‐6 gene was introduced into the same virus vector as that used for BMP‐2, it induced the same sets of genes (Ihh, Noggin, type X collagen and endogenous BMP‐6) as BMP‐2 did. These results also suggest that BMP‐6 would autonomously maintain and/or promote a later stage of chondrocytic maturation.

Application of efficient and specific gene transfer systems and organ culture techniques for the elucidation of mechanisms of epithelial- mesenchymal interaction in the developing gut

Epithelial–mesenchymal interactions are very important in the development of the vertebrate gut. In the avian embryonic stomach (proventriculus), expression of embryonic chick pepsinogen (ECPg) gene, which is specific to developing glandular cells in stomach epithelium, is regulated by mesenchymal influence. Molecular mechanisms of tissue‐specific transcriptional regulation of the ECPg gene and the molecular nature of the mesenchymal signals were analyzed using a combination of the classic organ culture system and gene transfer strategies. In the present review, three methods for the introduction of DNA into tissues are described: lipofection, electroporation and retroviral infection, and characteristics of each system are discussed.

Differential expression of fos and jun family members in the developing chicken gastrointestinal tract

We have analysed the expression patterns of all the known fos/jun family genes, which encode the components of the transcription factor AP-1, in the chicken embryonic digestive tract that develops into the esophagus, proventriculus, gizzard, small intestine, ceca and large intestine. From soon after formation of the tubular structure, each gene transcript was localized in distinct domains of the epithelium and mesenchyme in all of these major gastrointestinal organs, independently of the anterior-posterior axis. fra-2 was expressed predominantly in epithelium, which also expressed junD, while low-level expression of junD was also detected in smooth muscle cell precursors in mesenchyme. Expression of c-jun and c-fos was detectable in both mesenchyme and epithelium through the whole tract. In the differentiated proventriculus, the developed glandular epithelium expressed c-jun and junD, but not fra-2, while luminal epithelium expressed fra-2 and junD, but not c-jun. These results suggest that distinct Fos/Jun protein heterodimers play important roles in maintaining the epithelial-mesenchymal interactions. Similar expression patterns to those of fra-2 and junD were established from earlier stages by Sonic hedgehog gene and the Indian hedgehog gene, respectively, both of which are important in forming the inductive network between epithelium and mesenchyme of the digestive tract.

Kinetics of v- src -induced epithelial–mesenchymal transition in developing glandular stomach

The oncogene function in primary epithelial cells is largely unclear. Recombination organ cultures in combination with the stable and transient gene transfer techniques by retrovirus and electroporation, respectively, enable us to transfer oncogenes specifically into primary epithelial cells of the developing avian glandular stomach (proventriculus). In this system, the epithelium and mesenchyme are mutually dependent on each other for their growth and differentiation. We report here that either stable or transient expression of v-src in the epithelium causes budding and migration of epithelial cells into mesenchyme. In response to the transient expression of v-Src or a constitutive active mutant of MEK, we observed immediate downregulation of the Sonic hedgehog gene and subsequent elimination of E-cadherine expression in migrating cells, suggesting the involvement of MAP kinase signaling pathway in these processes. v-src-expressing cells that were retained in the epithelium underwent apoptosis (anoikis) and detached from the culture. Continuous expression of v-src by, for example, Rous sarcoma virus (RSV) was required for the epithelial cells to acquire the ability to express type I collagen and fibronectin genes (mesenchymal markers), and finally to establish the epithelial–mesenchymal transition. These observations would partly explain why RSV does not apparently cause carcinoma formation, but induces sarcomas exclusively.

Down-regulation of endodermal Shh is required for gland formation in chicken stomach

During the development of the proventriculus (glandular stomach) of the chicken embryo, the endodermal epithelium invades into the surrounding mesenchyme and forms glands. The glandular epithelial cells produce pepsinogen, while the non-glandular (luminal) epithelial cells secrete mucus. Sonic hedgehog is expressed uniformly in the proventricular epithelium before gland formation, but its expression ceases in gland cells. Here we present evidence that down-regulation of Sonic hedgehog is necessary for gland formation in the epithelium using a specific inhibitor of Sonic hedgehog signaling and virus mediated overexpression of Sonic hedgehog. We also show that gland formation is not induced by down-regulation of Sonic hedgehog alone; a mesenchymal influence is also required.