Gadd45a, Gadd45b and Gadd45g expression during mouse embryonic development

Gadd45 proteins have been implicated in the cellular response to physiological or environmental stress and the accompanying cell cycle arrest, DNA repair, cell survival and senescence or apoptosis. Although their molecular function is well studied, the expression and role of Gadd45 genes during embryonic development in mice is largely unknown. Here we provide a comprehensive comparison of Gadd45a, Gadd45b and Gadd45g expression during mouse embryonic development. In situ hybridizations on sectioned and whole mouse embryos show most prominent Gadd45a expression in the tip of the closing neural tube, the cranial and dorsal root ganglia and the somites. Mouse Gadd45b is expressed strongly in the chorion, but only weakly in the embryo proper, including somites and limb buds. Murine Gadd45g expression strongly resembles Xenopus and medaka fish expression in primary neuron precursors and post-mitotic neurons, indicating a conserved role for Gadd45g in vertebrate neurogenesis. Additionally, Gadd45 genes show conserved expression during somitogenesis. In summary, Gadd45 genes are expressed in evolutionary conserved, but also divergent domains, which predominantly encompass areas of cell differentiation, consistent with their established function in growth arrest and DNA demethylation.     

The club‐shaped gland of amphioxus: export of secretion to the pharynx in pre‐metamorphic larvae and apoptosis during metamorphosis

In amphioxus larvae, the club‐shaped gland is a tube connecting the pharyngeal lumen with the external environment. The functions of the gland and its fate during the larva‐to‐juvenile metamorphosis have long been controversial. Here we use a fixative including ruthenium red to preserve extracellular secretions (presumably glycoproteins) in late pre‐metamorphic larvae. This procedure reveals reddish, fibrogranular material in the lumen of the club‐shaped gland and in the pharynx adjacent to the gland's inner opening. This finding strengthens the idea that secretions of the club‐shaped gland are exported to the pharyngeal lumen to help form a mucous trap for capturing food particles entering the mouth. We also use the terminal desoxynucleotidyl transferase‐mediated dUTP nick end labelling (TUNEL) assay to study apoptosis in the tissues of metamorphosing larvae. One of the earliest events of metamorphosis is the massive apoptotic destruction of the club‐shaped gland. Therefore, despite some previous opinions to the contrary, the cells of the gland do not survive to participate in the genesis of the definitive endostyle or any other post‐larval structures.     

Strength training during pregnancy influences hippocampal plasticity but not body development in neonatal rats

Objective:To describe the effects of strength exercise practice during pregnancy on the offspring’s development parameters: growth and motor performance, hippocampal neuroplasticity, and stress levels.Methods:Pregnant Wistar rats were divided into two groups: sedentary and exercised rats. Exercised pregnant rats were subjected to a strength training protocol (vertical ladder climbing) throughout the gestational period. Male offspring’s body weight, length, and head size were evaluated during the neonatal period (postnatal days [P]2–P21), as well as motor milestones during P0–P8. At P8, a set of male pups were subjected to global hippocampal DNA methylation, hippocampal cell proliferation, and plasma corticosterone concentration.Results:Offspring from trained mothers presented a transient change in body morphometric evaluations, no differences in milestone assessments, enhancement of cell proliferation in the dentate gyrus of the hippocampus, and decreased global hippocampal DNA methylation compared with the offspring from sedentary mothers. Furthermore, strength training during pregnancy did not change the corticosterone concentration of exercised mothers and their offspring.Conclusions:These data indicate that strength training can protect offspring’s development and could impact positively on parameters linked to cognitive function. This study provides a greater understanding of the effects of strength exercise practiced during pregnancy on the offspring’s health.     

AmphiNk2-tin,an amphioxus homeobox gene expressed in myocardial progenitors: insights into evolution of the vertebrate heart

We isolated a full-length cDNA clone of amphioxus AmphiNk2-tin, an NK2 gene similar in sequence to vertebrate NK2 cardiac genes, suggesting a potentially similar function to Drosophila tinman and to vertebrate NK2 cardiac genes during heart development. During the neurula stage of amphioxus, AmphiNk2-tin is expressed first within the foregut endoderm, then transiently in muscle precursor cells in the somites, and finally in some mesoderm cells of the visceral peritoneum arranged in an approximately midventral row running beneath the midgut and hindgut. The peritoneal cells that express AmphiNk2-tin are evidently precursors of the myocardium of the heart, which subsequently becomes morphologically detectable ventral to the gut. The amphioxus heart is a rostrocaudally extended tube consisting entirely of myocardial cells (at both the larval and adult stages); there are no chambers, valves, endocardium, epicardium, or other differentiated features of vertebrate hearts. Phylogenetic analysis of the AmphiNk2-tin sequence documents its close relationship to vertebrate NK2 class cardiac genes, and ancillary evidence suggests a relationship with the Drosophila NK2 gene tinman. Apparently, an amphioxus-like heart, and the developmental program directing its development, was the foundation upon which the vertebrate heart evolved by progressive modular innovations at the genetic and morphological levels of organization.     

An amphioxus homeobox gene: sequence conservation, spatial expression during development and insights into vertebrate evolution.

The embryology of amphioxus has much in common with vertebrate embryology, reflecting a close phylogenetic relationship between the two groups. Amphioxus embryology is simpler in several key respects, however, including a lack of pronounced craniofacial morphogenesis. To gain an insight into the molecular changes that accompanied the evolution of vertebrate embryology, and into the relationship between the amphioxus and vertebrate body plans, we have undertaken the first molecular level investigation of amphioxus embryonic development. We report the cloning, complete DNA sequence determination, sequence analysis and expression analysis of an amphioxus homeobox gene, AmphiHox3, evolutionarily homologous to the third-most 3' paralogous group of mammalian Hox genes. Sequence comparison to a mammalian homologue, mouse Hox-2.7 (HoxB3), reveals several stretches of amino acid conservation within the deduced protein sequences. Whole mount in situ hybridization reveals localized expression of AmphiHox3 in the posterior mesoderm (but not in the somites), and region-specific expression in the dorsal nerve cord, of amphioxus neurulae, later embryos and larvae. The anterior limit to expression in the nerve cord is at the level of the four/five somite boundary at the neurula stage, and stabilises to just anterior to the first nerve cord pigment spot to form. Comparison to the anterior expression boundary of mouse Hox-2.7 (HoxB3) and related genes suggests that the vertebrate brain is homologous to an extensive region of the amphioxus nerve cord that contains the cerebral vesicle (a region at the extreme rostral tip) and extends posterior to somite four.(ABSTRACT TRUNCATED AT 250 WORDS)     

Genic DNA methylation changes during in vitro organogenesis: organ specificity and conservation between parental lines of epialleles

During differentiation, in vitro organogenesis calls for the adjustment of the gene expression program toward a new fate. The role of epigenetic mechanisms including DNA methylation is suggested but little is known about the loci affected by DNA methylation changes, particularly in agronomic plants for witch in vitro technologies are useful such as sugar beet. Here, three pairs of organogenic and non-organogenic in vitro cell lines originating from different sugar beet (Beta vulgaris altissima) cultivars were used to assess the dynamics of DNA methylation at the global or genic levels during shoot or root regeneration. The restriction landmark genome scanning for methylation approach was applied to provide a direct quantitative epigenetic assessment of several CG methylated genes without prior knowledge of gene sequence that is particularly adapted for studies on crop plants without a fully sequenced genome. The cloned sequences had putative roles in cell proliferation, differentiation or unknown functions and displayed organ-specific DNA polymorphism for methylation and changes in expression during in vitro organogenesis. Among them, a potential ubiquitin extension protein 6 (UBI6) was shown, in different cultivars, to exhibit repeatable variations of DNA methylation and gene expression during shoot regeneration. In addition, abnormal development and callogenesis were observed in a T-DNA insertion mutant (ubi6) for a homologous sequence in Arabidopsis. Our data showed that DNA methylation is changed in an organ-specific way for genes exhibiting variations of expression and playing potential role during organogenesis. These epialleles could be conserved between parental lines opening perspectives for molecular markers.     

Cadherin mRNAs during rat embryo development in vivo and in vitro.

Whole rat embryo cultures are being used in increasing numbers of laboratories to study the mechanisms by which teratogens disturb development. The development of early somite stage embryos in vitro is very similar morphologically to that in vivo, yet few biochemical comparisons have been made. The purpose of this study was to determine the steady-state mRNA concentrations of a family of Ca(2+)-dependent cell adhesion molecules, the cadherins, during rat embryonic development in vivo and in vitro. Embryos and yolk sacs were collected on days 10, 11, and 12 of gestation (in vivo); they were also obtained from day 10 embryos after growth in culture for 24 hr (day 11 in vitro) or 45 hr (day 12 in vitro). Total RNAs isolated from embryos and yolk sacs were studied by Northern blot analysis using specific cDNA probes for three cadherins, E-cadherin, N-cadherin, and P-cadherin. Although E-cadherin mRNA was detected in embryos, it was present at much higher concentrations in yolk sacs. In addition, multiple species of E-cadherin mRNA ranging from 3.0 to 13 kb were detected. Interestingly, the concentration of the major 4.5-kb E-cadherin mRNA species in yolk sac after 45 hr in culture was increased 2.8-fold over that on day 12 of gestation in vivo. Second, two species (4.3 and 3.5 kb) of N-cadherin mRNA were detected, almost exclusively in embryos. In yolk sac, N-cadherin mRNA was detected only after 45 hr in culture. Third, P-cadherin mRNA was detected as a single 3.5-kb species, mainly in embryos. P-cadherin mRNA concentrations in yolk sac after 45 hr in culture were 5.6-fold higher than in vivo. Thus, these results demonstrate that there is a differential distribution of cadherin mRNAs in rat embryos and yolk sacs. Further, there appear to be multiple species of mRNAs for E-cadherin and N-cadherin. Finally, while whole embryo culture in vitro did not significantly alter the steady-state concentrations of cadherin mRNAs in the embryo, these concentrations were dramatically increased in the yolk sac.     

Mutational specificity of N-nitrosodimethylamine: Comparison between in vivo and in vitro assays

We have determined the DNA alterations recovered after treatment with Aroclor 1254-treated rat S9-activated N-nitrosodimethylamine (NDMA) in the N-terminal region of the LacI gene of E. coli. A total of 125 independent Lacl^-d mutants of E. Coli were characterized by DNA sequencing. Consistent with the known methylating ability of this compound, the predominant mutation was the G:C → A:T transition, which accounted for 90% of all the mutations recovered. Non G:C → A:T events include 2 G:C → T:A 2 G:C → C:G, 2 A:T → G:C, 3 A:T → T:A and 3 frameshifts. Contingency analysis reveals that NDMA-induced mutation recovered after in vitro activation (S9) have a spectrum very similar to that previously obtained after in vivo activation employing a mouse host-mediated assay. In both systems, G:C → A:T events clearly dominate and their distribution reveals similar site-specificity Moreover, the proportion and kind of non-G:C → A::T events are also similar     

Comparison of gene expression during in vivo and in vitro postnatal retina development

Retina explants are widely used as a model of neural development. To define the molecular basis of differences between the development of retina in vivo and in vitro during the early postnatal period, we carried out a series of microarray comparisons using mouse retinas. About 75% of 8,880 expressed genes from retina explants kept the same expression volume and pattern as the retina in vivo. Fewer than 6% of the total gene population was changed at two consecutive time points, and only about 1% genes showed more than a threefold change at any time point studied. Functional Gene Ontology (GO) mapping for both changed and unchanged genes showed similar distribution patterns, except that more genes were changed in the GO clusters of response to stimuli and carbohydrate metabolism. Three distinct expression patterns of genes preferentially expressed in rod photoreceptors were observed in the retina explants. Some genes showed a lag in increased expression, some showed no change, and some continued to have a reduced level of expression. An early downregulation of cyclin D1 in the explanted retina might explain the reduction in numbers of precursors in explanted retina and suggests that external factors are required for maintenance of cyclin D1. The global view of gene profiles presented in this study will help define the molecular changes in retina explants over time and will provide criteria to define future changes that improve this model system.     

Protein synthesis in imaginal disks ofPlodia interpunctella during development in vivo and in vitro

Summary Wing imaginal disks were dissected from larvae ofPlodia interpunctella (Hübner) at various stages during the larval-pupal transformation. The wing-disk proteins separated by electrophoresis and scanned with a densitometer changed quantitatively but not qualitatively during development in vivo. Treatment of wing disks in vitro with β-ecdysone resulted in a 2-fold increase in synthesis of proteins after only 2 hr incubation. The maximum rate of protein synthesis was reached 16 hr after treatment with hormone. The pattern of proteins separated by electrophoresis of wing disks that were incubated in vitro with β-ecdysone did not change qualitatively. The major features of protein synthesis during wing-disk development in vivo were similar to those observed during β-ecdysone-induced development in vitro. Mention of a commercial or proprietary product in this paper does not constitute an endorsement of that product by the USDA.     

Presenilin 1 and 2 are expressed differentially in the cerebral cortex of mice during development

Presenilin (PS) 1 and PS2 are multi-pass transmembrane proteins involved in vital brain functions. Studies using transgenic or conditional knockout models show that PS1 is implicated in crucial brain developmental processes. Conversely, PS2 knockout mice do not exhibit any abnormality in the brain morphology, suggesting that PS2 may not be involved in brain development. However, there is no holistic information available for endogenous expression of PS during brain development. Therefore, we have examined the distribution and expression profile of PS1 and PS2 mRNA and protein in the cerebral cortex of prenatal, neonatal and postnatal mice. The results revealed that the distribution and expression profile of PS1 and PS2 mRNA varied significantly in the cerebral cortex during development. In prenatal stages, both PS1 and PS2 mRNA showed high expression at embryonic day (E) 12.5 and downregulation at E18.5. Postnatally, PS1 mRNA showed upregulation from postnatal day 0 (P0) to P45 and thereafter reduction at 20weeks, but PS2 mRNA showed no significant alteration. However, they did not exhibit any significant regional variation except at E18.5, when PS2 showed reduction in temporal and medial temporal lobes as compared to frontal and parietal lobes. Furthermore, PS1 showed significant change in protein expression similar to its mRNA profile. However, PS2 protein expression did not correspond to its mRNA; it was highest at E12.5, downregulated up to P20 and then upregulated at P45 and 20weeks. Taken together, our study demonstrates for the first time that the distribution and expression profile of PS2 is different from PS1 in the mouse cerebral cortex during development.     

An amphioxus netrin gene is expressed in midline structures during embryonic and larval development

Members of the netrin gene family have been identified in vertebrates, Drosophila and Caenorhabditis elegans and found to encode secreted molecules involved in axon guidance. Here I use the conserved function of netrins in triploblasts, coupled with the phylogenetic position of amphioxus (the closest living relative of the vertebrates), to investigate the evolution of an axon guidance cue in chordates. A single amphioxus netrin gene was isolated by PCR and cDNA library screening and named AmphiNetrin. The predicted AmphiNetrin protein showed high identity to other netrin family members but differed in that the third of three EGF repeats found in other netrins was absent. Molecular phylogene-tic analysis showed that despite the absent EGF repeat AmphiNetrin is most closely related to the vertebrate netrins. AmphiNetrin expression was identified in embryonic notochord and floor plate, a pattern similar to that of vertebrate netrin-1 expression. AmphiNetrin expression was also identified more widely in the posterior larval brain, and in the anterior extension of the notochord that underlies the anterior of the amphioxus brain. All of these areas of expression are correlated with developing axon trajectories: The floor plate with ventrally projecting somatic motor neurons and Rohde cell projections, the posterior brain with the ventral commissure and primary motor centre and the anterior extension of the notochord with ventrally projecting neurons associated with the median eye. Amphioxus is naturally cyclopaedic and also lacks the ventral brain cells that the induction of which results in the splitting of the vertebrate eye field and, when missing, result in cyclopaedia. These cells normally express netrins required for developing axon tracts in the brain, and the expression of AmphiNetrin in the anterior extension of the notochord underlying the brain may explain how amphioxus is able to maintain ventral guidance cues while lacking these cells. Received: 15 November 1999 / Accepted: 27 January 2000     

Estrogen-regulated synaptogenesis in the hippocampus: sexual dimorphism in vivo but not in vitro

Hippocampal neurons are capable of synthesizing estradiol de novo. Estradiol synthesis can be suppressed by aromatase inhibitors and by knock-down of steroid acute regulatory protein (StAR), whereas elevated levels of substrates of steroidogenesis enhance estradiol synthesis. In rat hippocampal cultures, the expression of estrogen receptors (ERs) and synaptic proteins, as well as synapse density, correlated positively with aromatase activity, regardless of whether the cultures originated from males or females. All effects induced by the inhibition of aromatase activity were rescued by application of estradiol to the cultures. In vivo, however, systemic application of letrozole, an aromatase inhibitor, induced synapse loss in female rats, but not in males. Furthermore, in the female hippocampus, density of spines and spine synapses varied with the estrus cycle. In addressing this in vivo-in vitro discrepancy, we found that gonadotropin-releasing hormone (GnRH) regulated estradiol synthesis via an aromatase-mediated mechanism and consistently regulated spine synapse density and the expression of synaptic proteins. Along these lines, GnRH receptor density was higher in the hippocampus than in the cortex and hypothalamus, and estrus cyclicity of spinogenesis was found in the hippocampus, but not in the cortex. Since GnRH receptor expression also varies with the estrus cycle, the sexual dimorphism in estrogen-regulated spine synapse density in the hippocampus very likely results from differences in the GnRH responsiveness of the male and the female hippocampus. This article is part of a Special Issue entitled 'Neurosteroids'.     

Ornithine decarboxylase activity during development of the mouse inner ear in vivo and in vitro

Summary Ornithine decarboxylase activity was determined during the development of the peripheral auditory system in the murine otocyst with the goal of understanding the role of this enzyme in the morphological and functional maturation of the inner ear. At gestational days 11 and 12 enzyme activity was more than 10-fold higher than adult levels. A sharp decline occured between day 12 and 13 after which activity rose to a peak around day 15. Activity then dropped continuously until near-adult levels were reached at birth. A lower specific activity of ODC but a similar time-course was seen in otocysts explanted at gestational day 13 and subsequently cultured for 6 days. For two stages of development, enzyme activity and binding of ³H--difluoromethylornithine were compared. The four-fold difference in enzymatic activity on gestational days 15 and 17 was paralleled by a similar difference in binding. Ornithine decarboxylase activity during inner ear development therefore seems primarily regulated at the level of protein synthesis. Ornithine decarboxylase activity correlates with major inductive events in the morphogenesis of the cartilagenous otic capsule that serves as a template for the formation of the bony labyrinth. The pattern of activity may reflect the changes in the head mesenchyme that is recruited by the otocyst to aggregate and form its protective otic capsule.