Chicken lens delta-crystallin gene expression and methylation in several non-lens tissues.

RNA sequences coding for the most abundant chicken lens proteins, delta-crystallin, were detected at very low levels in day old post hatch chick lung, heart, kidney and liver, and in 6 day embryo headless bodies. The pattern of cytosine methylation within the CCGG sequences of the delta-crystallin genes was also examined and shown to vary in several non-lens tissues, from several stages of development. Embryonic neural retina, which expresses a higher level of delta-crystallin RNA than the above tissues, is no less methylated in the sites studied than the tissues which have no association with the eye, and is actually more heavily methylated than the kidney. Thus no obvious correlation was found between undermethylation and gene expression.     

Delta-crystallin mRNA in chick lens cells: mRNA accumulates during differential stimulation of delta-crystallin synthesis in cultured cells.

Increasing specialization for δ-crystallin synthesis is a prominent feature of the differentiation of chick lens epithelial cells into lens fiber cells and can be studied in cultured embryonic lens epithelia. Quantitation of δ-crystallin mRNA by molecular hybridizaton to a [³H]DNA complementary to δ-crystallin mRNA demonstrates that differentiation, both in ovo and in tissue culture, is associated with the accumulation of δ-crystallin mRNA. In the cultures, there is an overall stimulation of protein synthesis, including δ-crystallin mRNA during the first 5 hr in vitro. Between 5 and 24 hr in vitro there is a differential stimulation of δ-crystallin synthesis and an accumulation of δ-crystallin mRNA that can quantitatively account for this stimulation.     

Transient expression of a 'lens-specific' gene, delta-crystallin, in the embryonic chicken adenohypophysis

A characteristic protein of the lens, delta-crystallin, has been reported previously to be present in the embryonic chicken adenohypophysis. We confirmed this earlier finding by biochemical detection of delta-crystallin protein using a monoclonal antibody and delta-crystallin mRNA using a specific cDNA probe. We estimate the concentration of delta-crystallin and its mRNA in the 3.5-day embryonic chicken adenohypophysis to be approximately 1/3,000 and 1/5,000 of the respective value found in lens. Tissue culture revealed that cells positive for delta-crystallin comprise about 30% of embryonic adenohypophysis and are randomly scattered in this organ. No lentoid formation was observed during the culture period.     

Unique patterns of androgen regulation of the expression of two genes in murine kidney

The kidneys of androgen stimulated mice exhibit a hypertrophic response but no hyperplasia or concomitant DNA replication. Androgens increase the expression of several genes in mouse kidney. The response of the beta-glucuronidase gene to testosterone in this tissue is characterized by a 1-2 day lag and relatively slow induction kinetics. The gene coding for kidney androgen-regulated protein (KAP) exhibits quite a different response to the hormone when compared on the basis of initial response to a given dose, dose required to produce maximal response, and apparent sensitivity to low levels of androgen-receptor complexes in renal nuclei. The analysis of the accumulation of the mRNAs produced by these two genes suggests that gene-specific differential sensitivity to androgen receptor complexes governs the development of the cellular male phenotype in this tissue.     

Tet-system for the regulation of gene expression during embryonic development

The ability to control gene expression in a temporal and spatial manner provides a new tool for the study of mammalian gene function particularly during development and oncogenesis. In this study the suitability of the tet-system for investigating embryogenesis was tested in detail. The tTA ^CMV (M1) and rTA ^CMV-3 (reverse Tc-controlled transactivator) transgenic mice were bred with NZL-2 bi-reporter mice containing the vector with a tTA/rTA responsive bidirectional promoter that allows simultaneous regulation of expression of two reporter genes encoding luciferase and -galactosidase. In both cases reporter genes were found to be expressed in a wide spectrum of tissues of double transgenic embryos and adult mice. The earliest expression was detected in tTA ^CMV (M1)/NZL-2 embryos at embryonic day 10.5 (E10.5) and rTA ^CMV -3/NZL-2 embryos at E13.5. Doxycycline abolished -gal expression in tTA ^CMV (M1)/NZL-2 but induced it in rTA ^CMV -3/NZL-2 embryos including late stages of embryogenesis. The tTA and rtTA transactivators thus revealed a partially complementary mode of action during second half of embryonic development. These experiments demonstrated that both Tet regulatory systems function during embryonic development. We conclude that the Tet systems allows regulation of gene expression during embryonic development and that double reporter animals like the NZL-2 mice are useful tools for the characterization of newly generated tet transactivator lines expressing tTA (or rtTA) in embryonic as well as in adult tissues.     

Embryonic expression patterns of the mouse and chick Gas1 genes

Control of cell proliferation is essential to generate the defined form of a multi-cellular organism. While much is known about the regulators for cell cycle progression, relatively little is known about the state of growth arrest. Growth arrest (G0) is defined as a cell in a metabolically active but proliferation-quiescent state (reviewed in Baserga (1985) The Biology of Cell Reproduction), typically induced by serum starvation in vitro. Using subtractive hybridization, Schneider et al. (Cell 54 (1988) 787) identified six genes (Gas1 through Gas6) whose expressions are upregulated in serum-deprived NIH3T3 cells. Among the Gas genes, Gas1 is the only one that can cause growth arrest when expressed in cultured cell (Cell 70 (1995) 595; Int. J. Cancer 9 (1998) 569). Here, we describe for the first time the expression pattern of Gas1 during mouse embryogenesis. Our data reveal that Gas1 is expressed in many regions that the cells are actively proliferating and suggest that it may have other roles during development than negatively regulating cell proliferation. Furthermore, we have cloned the chick GAS1 gene and documented the similarity and divergence of Gas1 gene expression patterns between the two species.     

Differences in the efficiency and stability of gene expression after transfection and nuclear injection: a study with a chick delta-crystallin gene

The efficiency of an exogenous gene's expression was compared after its transfection and injection into various mouse cells to systematically evaluate these two gene transfer techniques. Special attention was paid to the period of transient expression. The gene used was a derivative of chicken delta-crystallin gene with the 5' end region replaced by a promoter base sequence of a retrovirus. Nuclear injection was more efficient than transfection in several respects: it was roughly one thousand times more efficient in producing gene-expressing cells than the transfection technique; it produced positive cells in every challenged cell line in contrast to the results of some unsuccessful trials found with transfection; and the maximum expression of the exogenous gene in a gene-transferred cell was much higher after injection than after transfection. With the transfection technique, use of a DNA-calcium phosphate coprecipitate was slightly more efficient than the use of DEAE-dextran. The stability of gene expression in transfected and nuclear-injected cells differed greatly: Expression of the exogenous gene in transfected cells was transmitted to 92% of the daughter cells per division, whereas its expression in injected cells was transmitted to only 32% of the daughter cells. This great difference in stability probably reflects different states of the major fraction of the exogenous gene: integration into chromosomes in transfected cells versus extrachromosomal localization in injected cells.     

Distinct expression patterns of two zebrafish homologues of the human APP gene during embryonic development

The human amyloid protein precursor (APP) gene correlates with early onset of Alzheimer's disease in humans. We have identified two APP homologues in zebrafish, which we call appa and appb. They show a high degree of identity to human APP particularly in the beta APP42 and the transmembrane domain. Widespread expression of both appa and appb was detected from mid-gastrulation until the bud stage. During segmentation, the two genes diverged in their pattern of expression: at 14 h post-fertilisation (hpf) and 18 hpf both genes were expressed rostrally in the prospective CNS, but only appa was found caudally in the paraxial segmental plate and presomitic mesoderm, excluding the midline. In contrast, appb was found caudally in the neural rod at 14 hpf and the developing spinal cord at 18 hpf. Later, at 24 hpf both genes shared common expression domains, namely the telencephalon, the ventral diencephalon, the trigeminal ganglia, and the posterior lateral line ganglia. Unique expression domains for appa were the lens, the otic vesicles and the somites, while appb was expressed in a serially repeated set of nuclei within the hindbrain, the ventral mesencephalon and the motoneurones of the developing spinal cord.     

The embryonic expression patterns of zebrafish genes encoding LysM-domains

The function and structure of LysM-domain containing proteins are very diverse. Although some LysM domains are able to bind peptidoglycan or chitin type carbohydrates in bacteria, in fungi and in plants, the function(s) of vertebrate LysM domains and proteins remains largely unknown. In this study we have identified and annotated the six zebrafish genes of this family, which encode at least ten conceptual LysM-domain containing proteins. Two distinct sub-families called LysMD and OXR were identified and shown to be highly conserved across vertebrates. The detailed characterization of LysMD and OXR gene expression in zebrafish embryos showed that all the members of these sub-families are strongly expressed maternally and zygotically from the earliest stages of a vertebrate embryonic development. Moreover, the analysis of the spatio-temporal expression patterns, by whole mount and fluorescent in situ hybridizations, demonstrates pronounced LysMD and OXR gene expression in the zebrafish brain and nervous system during stages of larval development. None of the zebrafish LysMD or OXR genes was responsive to challenge with bacterial pathogens in embryo models of Salmonella and Mycobacterium infections. In addition, the expression patterns of the OXR genes were mapped in a zebrafish brain atlas.     

Distinct expression patterns for two Xenopus Bar homeobox genes

The BarH1 and BarH2 homeobox genes are coexpressed in cells of the fly retina and in the central and peripheral nervous systems. The fly Bar genes are required for normal development of the eye and external sensory organs. In Xenopus we have identified two distinct vertebrate Bar-related homeobox genes, XBH1 and XBH2. XBH1 is highly related in sequence and expression pattern to a mammalian gene, MBH1, suggesting that they are orthologues. XBH2 has not previously been identified but is clearly related to the Drosophila Bar genes. During early Xenopus embryogenesis XBH1 and XBH2 are expressed in overlapping regions of the central nervous system. XBH1, but not XBH2, is expressed in the developing retina. By comparing the expression of XBH1 with that of hermes, a marker of differentiated retinal ganglion cells, we show that XBH1 is expressed in retinal ganglion cells during the differentiation process, but is down-regulated as cells become terminally differentiated. Received: 12 August 1999 / Accepted: 5 October 1999