Fetal Mouse Lung Research Articles

Hydroxyurea (HU)-induced apoptosis in the mouse fetal lung

In this study, the cytotoxicologic effects of HU on the fetal lung were assessed by exposing pregnant mice to HU on day 13 of gestation. The number of TUNEL-positive cells, i.e., apoptotic cells, in the fetal lung began to increase at 3 h after treatment (h), peaked at 6 h, and decreased thereafter, and the sequence of the number of cleaved caspase 3-positive cells corresponded to that of TUNEL-positive cells. Such positive reactivity for TUNEL and cleaved caspase 3 was mainly seen in pulmonary mesenchymal cells. Prior to the induction of apoptosis, the number of p53-positive cells in the fetal lung prominently increased at 1 and 3 h, and decreased thereafter. Among p53 transcriptional target genes ( p21, fas, bax, apaf1, cyclin G, mdm2, and gad 45) examined, the expression levels of p21, bax, and cyclin G mRNAs were significantly elevated. In addition, the expression of fas mRNA tended to show higher levels compared with controls until 24 h. In addition, the results of flow cytometric analysis suggested that cell cycle arrest might be induced in S phase at 3 h. The present results suggest that HU-induced apoptosis in the mouse fetal lung may be closely related with the induction of p53.

Toll‐like receptor signaling inhibits structural development of the distal fetal mouse lung

We tested the hypothesis that innate immune signaling in utero could disrupt the structural development of the fetal lung, contributing to the pathogenesis of bronchopulmonary dysplasia. Injection of Escherichia coli lipopolysaccharide (LPS) into the amniotic fluid of E15 BALB/cJ mice increased the luminal volume density of fetal mouse lungs at embryonic day (E) 17 and E18. LPS also increased luminal volume and decreased distal lung branching in fetal mouse lung explants. This effect required NF-kappaB activation and functional Toll-Like Receptor 4. Airway branching may require fibronectin-dependent epithelial-mesenchymal interactions, representing a potential target for innate immune signaling. Anti-fibronectin antibodies and LPS both blocked distal lung branching. By immunofluorescence, fibronectin localized to the clefts between newly formed airways but was restricted to peripheral mesenchymal cells in LPS-exposed explants. These data suggest that LPS may alter the expression pattern of mesenchymal fibronectin, potentially disrupting epithelial-mesenchymal interactions and inhibiting distal airway branching and alveolarization. This mechanism may link innate immune signaling with defects in structural development of the fetal lung.

PI3K–AKT pathway mediates growth and survival signals during development of fetal mouse lung

We examined the roles of the PI3K–AKT signalling pathway in fetal lung development. By Western blotting, phosphorylated AKT (pAKT) was highly expressed in fetal days 12 and 14 with decreased expression thereafter. By immunohistochemistry, pAKT was expressed mainly in the respiratory epithelium of early fetal days. We examined the effects of fibroblast growth factor 1 (FGF1), PI3K inhibitors (LY294002 and wortmannin), MAPK inhibitor (PD98059) and both of FGF1 and each inhibitor on lung morphogenesis, BrdU incorporation and apoptosis. In the FGF1-treated explants, the number of terminal buds and BrdU-labelled cells increased significantly, while the LY294002-, wortmannin-, PD98059-treated explants demonstrated obvious decreases. The effects by FGF1 were inhibited by LY294002, wortmannin and PD98059. Regardless of the presence of FGF1, the LY294002-, wortmannin- and PD98059-treated explants increased apoptosis revealed by terminal deoxynucleotidyl transferase-mediated dUTP nick end labelling assay in the mesenchyme of the explants. At the same time, the effect of LY294002, wortmannin, PD98059 on expression of surfactant apoprotein C (SPC) were also studied. The LY294002 and wortmannin treatments showed decreased expression of SPC. These findings suggest that the PI3K–AKT signalling pathway plays a pivotal role in mouse lung development through various biological processes.

Lipopolysaccharide increases alveolar type II cell number in fetal mouse lungs through Toll-like receptor 4 and NF-kappaB.

Chorioamnionitis is a major cause of preterm delivery. Infants exposed to inflammation in utero and then born preterm may have improved lung function in the immediate postnatal period. We developed a mouse model of chorioamnionitis to study the inflammatory signaling mechanisms that might influence fetal lung maturation. With this in vivo model, we found that Escherichia coli lipopolysaccharide (LPS) increased the number of alveolar type II cells in the fetal mouse lung. LPS also increased type II cell number in cultured fetal lung explants, suggesting that LPS could directly signal the fetal lung in the absence of maternal influences. Using immunostaining, we localized cells within the fetal mouse lung expressing the LPS receptor molecule Toll-like receptor 4 (TLR4). Similar to the signaling pathways in inflammatory cells, LPS activated NF-kappaB in fetal lung explants. Activation of the TLR4/NF-kappaB pathway appeared to be required, as LPS did not increase the number of type II cells in C.C3H-Tlr4(Lps-d) mice, a congenic strain containing a loss of function mutation in tlr4. In addition, the sesquiterpene lactone parthenolide inhibited NF-kappaB activation following LPS exposure and blocked the LPS-induced increase in type II cells. On the basis of these data from our mouse model of chorioamnionitis, it appears that LPS specifically activated the TLR4/NF-kappaB pathway, leading to increased type II cell maturation. These data implicate an important signaling mechanism in chorioamnionitis and suggest the TLR4/NF-kappaB pathway can influence lung development.

43 Increased MMP-9 and MMP-12 Production in The Lungs of Fetal and Newborn Transgenic Mice Expressing IL-1 in The Pulmonary Epithelium

43 Increased MMP-9 and MMP-12 Production in The Lungs of Fetal and Newborn Transgenic Mice Expressing IL-1 in The Pulmonary Epithelium

42 IL-1 Decreases The Production of Cellular Retinoic Acid Binding Protein-I (Crabp-I) in The Lungs of Transgenic Mice: A Possible Link Between Inflammation and The Retinoic Acid Pathway in The Pathogenesis of Bronchopulmonary Dysplasia (BPD)

Background: Pulmonary inflammation, increased production of the inflammatory cytokine IL-1, and vitamin A deficiency are associated with the development of BPD. In order to determine the mechanisms by which IL-1 influences lung development, we have developed a transgenic mouse overexpressing IL-1 in the lung epithelium in an externally regulatable manner. Lung histology of these mice after perinatal induction of IL-1 production shows impaired alveolar and vascular development of the lung, similar to the histological characteristics of BPD. Retinoic acid (RA), one of the most biologically active derivatives of vitamin A, increases septation. We hypothesized that a mechanism by which IL-1 decreases septation, is inhibition of RA action. Cellular retinoic acid binding protein I (CRABP-I) is an intracellular protein that binds RA with high affinity. Lack of CRABP-I results in decreased intracellular RA concentrations when the extracellular RA level is low. OBJECTIVE: To study CRABP-I mRNA expression and protein production in the lungs of fetal and newborn IL-1 overexpressing mice and their wild-type littermates.

Surfactant lipid synthesis and lamellar body formation in glycogen-laden type II cells.

Pulmonary surfactant is a lipoprotein complex that functions to reduce surface tension at the air liquid interface in the alveolus of the mature lung. In late gestation glycogen-laden type II cells shift their metabolic program toward the synthesis of surfactant, of which phosphatidylcholine (PC) is by far the most abundant lipid. To investigate the cellular site of surfactant PC synthesis in these cells we determined the subcellular localization of two key enzymes for PC biosynthesis, fatty acid synthase (FAS) and CTP:phosphocholine cytidylyltransferase-alpha (CCT-alpha), and compared their localization with that of surfactant storage organelles, the lamellar bodies (LBs), and surfactant proteins (SPs) in fetal mouse lung. Ultrastructural analysis showed that immature and mature LBs were present within the glycogen pools of fetal type II cells. Multivesicular bodies were noted only in the cytoplasm. Immunogold electron microscopy (EM) revealed that the glycogen pools were the prominent cellular sites for FAS and CCT-alpha. Energy-filtering EM demonstrated that CCT-alpha bound to phosphorus-rich (phospholipid) structures in the glycogen. SP-B and SP-C, but not SP-A, localized predominantly to the glycogen stores. Collectively, these data suggest that the glycogen stores in fetal type II cells are a cellular site for surfactant PC synthesis and LB formation/maturation consistent with the idea that the glycogen is a unique substrate for surfactant lipids.

Oral docosahexaenoic acid given to pregnant mice increases the amount of surfactant in lung and amniotic fluid in preterm fetuses

Objective Our purpose was to determine whether docosahexaenoic acid increased surfactant production, as reflected by increased dipalmitoyl phosphatidylcholine, in mouse fetal lung and amniotic fluid. Study design On day 9.5 of gestation, pregnant mice were given docosahexaenoic acid orally at 0, 5, 10, or 20 mg per day and were killed at day 16.5 (preterm) and day 19.5 (term) of gestation. Dipalmitoyl phosphatidylcholine was measured in fetal lung homogenates and amniotic fluid by high-performance thin-layer chromatography. Results Dipalmitoyl phosphatidylcholine values in lung were 0.22 ± 0.27 μg/mg of total protein in preterm versus 1.96 ± 0.57 μg/mg in term control fetuses. Pretreatment with 5, 10, or 20 mg docosahexaenoic acid increased dipalmitoyl phosphatidylcholine levels in preterm fetuses to 1.20 ± 0.75, 1.60 ± 0.67, and 3.28 ± 0.44 μg/mg of protein, respectively. A similar trend was observed in amniotic fluid in which dipalmitoyl phosphatidylcholine levels were 1.86 ± 3.70 μg/mL in preterm fetuses at baseline and increased to 7.81 ± 1.21, 16.83 ± 1.62 and 22.72 ± 3.44 μg/mL after pretreatment for 7 days with 5, 10, and 20 mg docosahexaenoic acid ( P<.05 compared to untreated mice). Dipalmitoyl phosphatidylcholine levels in amniotic fluid were 24.46 ± 10.3 μg/mL in term control mice. Conclusion The oral administration of docosahexaenoic acid to pregnant mice during pregnancy can induce dipalmitoyl phosphatidylcholine production and secretion, which is the major lipid component of surfactant.

A Signal from Surfactant

Condon et al. uncovered a new role for lung surfactant as a signal whereby a developing fetus announces that it's ready for birth. Labor that starts too early or too late can endanger the fetus. For example, premature infants are at risk of respiratory distress syndrome, a serious condition that results from a lack of surfactant in the immature lung. Labor is associated with an inflammatory response, in which leukocytes infiltrate the myometrium, but the initiating stimulus and source of these leukocytes--as well as the trigger for labor--have remained unclear. Condon et al. found that secretion of surfactant protein A (SP-A) mRNA in mouse amniotic fluid (AF) increased late in gestation along with production of interleukin-1β (IL-1β, a marker for activation) in AF macrophages and the number of macrophages in the uterine wall. The authors used wild-type mice carrying transgenic embryos to demonstrate that at least some of these uterine macrophages were of fetal origin. Intra-amniotic injection of SP-A promoted migration of fetal macrophages into the uterine wall and caused preterm labor, whereas intra-amniotic injection of antibodies to SP-A delayed labor. SP-A stimulated the expression of IL-1β and nuclear factor κB (NF-κB) in macrophages isolated from AF. NF-κB p50 and p65 proteins redistributed from uterine cytoplasm to nucleus late in gestation, an effect that was mimicked by intra-amniotic injection of SP-A. Intra-amniotic injection of an NF-κB inhibitor delayed the onset of labor and prevented premature labor in response to SP-A. Thus, the authors propose that SP-A from fetal lung acts as a labor-initiating signal to the myometrium of fetal maturity. J. C. Condon, P. Jeyasuria, J. M. Faust, C. R. Mendelsohn, Surfactant protein secreted by the maturing mouse fetal lung acts as a hormone that signals the initiation of parturition. Proc. Natl. Acad. Sci. U.S.A. 101 , 4978-4983 (2004). [Abstract] [Full Text]

Surfactant protein secreted by the maturing mouse fetal lung acts as a hormone that signals the initiation of parturition.

Parturition is timed to begin only after the developing embryo is sufficiently mature to survive outside the womb. It has been postulated that the signal for the initiation of parturition arises from the fetus although the nature and source of this signal remain obscure. Herein, we provide evidence that this signal originates from the maturing fetal lung. In the mouse, secretion of the major lung surfactant protein, surfactant protein A (SP-A), was first detected in amniotic fluid (AF) at 17 days postcoitum, rising progressively to term (19 days postcoitum). Expression of IL-1beta in AF macrophages and activation of NF-kappaB in the maternal uterus increased with the gestational increase in SP-A. SP-A stimulated IL-1beta and NF-kappaB expression in cultured AF macrophages. Studies using Rosa 26 Lac-Z (B6;129S-Gt(rosa)26Sor) (Lac-Z) mice revealed that fetal AF macrophages migrate to the uterus with the gestational increase in AF SP-A. Intraamniotic (i.a.) injection of SP-A caused preterm delivery of fetuses within 6-24 h. By contrast, injection of an SP-A antibody or NF-kappaB inhibitor into AF delayed labor by >24 h. We propose that augmented production of SP-A by the fetal lung near term causes activation and migration of fetal AF macrophages to the maternal uterus, where increased production of IL-1beta activates NF-kappaB, leading to labor. We have revealed a response pathway that ties augmented surfactant production by the maturing fetal lung to the initiation of labor. We suggest that SP-A secreted by the fetal lung serves as a hormone of parturition.

Birth-related genomic and transcriptional changes in mouse lung. Modulation by transplacental N-acetylcysteine.

Birth is characterized by a sudden transition from the maternal-mediated respiration to the autonomous pulmonary respiration. Notwithstanding the importance of the involved functional and metabolic changes, little is known about possible DNA alterations occurring in the lung during the perinatal period. We comparatively evaluated genomic and transcriptional changes in the lung of fetuses and newborn Swiss albino mice, whose dams had either been untreated or treated with oral N-acetyl-L-cysteine (NAC) throughout the pregnancy period. In the less than 24h period elapsing between the end of fetal life and the start of post-natal life, nucleotide alterations occurred in mouse lung, as shown by a significant increase of both bulky DNA adducts and 8-hydroxy-2'-deoxyguanosine levels, detected by 32P post-labeling procedures. The frequency of micronuclei in peripheral blood erythrocytes was not significantly increased after birth. Multigene expression analysis of 746 selected genes, by cDNA arrays, showed that 33 of them (4.4%) were upregulated in the lung of newborn mice, as compared with fetuses. The overexpressed genes were mainly involved in protective mechanism as a response to oxidative changes, alterations of glutathione metabolism, cellular stress, and damage to DNA and proteins. The transplacental treatment with NAC totally prevented birth-related genomic alterations in lung DNA. NAC did not change the basal gene expression in mouse fetal lung, but attenuated the upregulation of most genes involved in oxidative stress, stress response, and DNA repair in the lung of newborn mice. In fact, only 13 genes (1.7%) were overexpressed in newborns from NAC-treated dams. It therefore appears that administration of NAC during pregnancy is beneficial not only to counteract the adverse effects of toxic agents, as supported by previous studies, but also to attenuate birth-related DNA alterations.

Altered epithelial cell proportions in the fetal lung of glucocorticoid receptor null mice.

Glucocorticoids provide important signals for maturation of the fetal lung and antenatal glucocorticoids are used to reduce the respiratory insufficiency suffered by preterm infants. To further understand the role of glucocorticoids in fetal lung maturation, we have analyzed mice with a targeted null mutation for the glucocorticoid receptor (GR) gene, which severely retards lung development. The lungs of fetal GR-null mice have increased lung weight and DNA content, are condensed and hypercellular, with reduced septal thinning leading to a 6-fold increase in the airway to capillary diffusion distance. In fetal GR-null mice, mRNA levels of the type II epithelial cell surfactant protein genes A and C were reduced by approximately 50%. Analysis of epithelial cell types by electron microscopy revealed that the proportions of type II cells were increased by approximately 30%, whereas the proportions of type-I cells were markedly reduced (by approximately 50%). Similarly, we found a 50% reduction in mRNA levels for T1alpha and aquaporin-5, two type I cell-specific markers, and a 20% reduction in aquaporin-1 mRNA levels. This demonstrates that during murine embryonic development, receptor-mediated glucocorticoid signaling facilitates the differentiation of epithelial cells into type I cells, but is not obligatory for type II cell differentiation.

P66 Shc attenuates fetal mouse lung development

p66 Shc attenuates fetal mouse lung development

Developmental fate of embryonic germ cells (EGCs), in vivo and in vitro

Embryonic germ cells (EGCs) derived from mouse primordial germ cells (PGCs) are known both to colonize all cell lineages of the fetus and to make tumors in vivo. When aggregated with eight-cell embryos, EGCs from a new EGC line expressing green fluorescent protein (GFP) were found to contribute preferentially to the epiblast but unexpectedly were also capable of colonizing primary endoderm. When injected under the kidney capsule, EGCs derived from 12.5 days post coitum (dpc) PGCs formed differentiated tumors. The ability of EGCs to differentiate in an organ culture system depends upon their partners in cell culture. When EGCs, marked with a LacZ transgene, were mixed with disaggregated and reaggregated mouse fetal lung in an organ culture system, they remained undifferentiated. In urogenital ridge reaggregates on the other hand, some EGCs were capable of differentiating to form small epithelial cysts.

Conditional gene expression in the respiratory epithelium of the mouse.

Transgenic mouse models mediating conditional temporal and spatial regulation of gene expression to the respiratory epithelium were developed utilizing the reverse tetracycline transactivator (rtTA) expressed under the control of SP-C and CCSP promoters. Luciferase activity was detected in the lungs of fetal and adult double transgenic mice but was not detected in other tissues or in single transgenic mice. In adult mice, maximal luciferase activity was detected 16 h after the administration of doxycycline in the drinking water, or 2 h after the injection of doxycycline. Activation of the transgene was observed after the administration of doxycycline in food pellets. After prolonged exposure to doxycycline, luciferase activity decreased slowly following removal of doxycycline, suggesting the importance of tissue pools which maintained expression of the transgene. In SP-C-rtTA mice, exposure of the pregnant dam to doxycycline induced luciferase activity in fetal lung tissue as early as E10.5. Luciferase activity was maintained in the lung tissue of pups during the period of lactation when the mother received doxycycline in the drinking water. In the CCSP-rtTA mice, luciferase was not detected in the absence of doxycycline. In the SP-C-rtTA mice, luciferase activity was detected in the absence of doxycycline but was enhanced approximately 10-fold by administration of drugs. The SP-C-rtTA and CCSP-rtTA activator mice control the expression of transgenes in the developing and mature respiratory epithelium, and will be useful for the study of gene function in the lung.

Liquid and ion transport by fetal airway and lung epithelia of mice deficient in sodium-potassium-2-chloride transporter.

Chloride (Cl(-)) movement across fetal lung epithelia is thought to be mediated by the sodium-potassium-2-Cl(-) cotransporter NKCC1. We studied the role of NKCC1 in Cl(-) and liquid secretion in late-gestation NKCC-null (-/-) and littermate control fetal mouse lung. NKCC -/- mice had decreased lung water compared with littermate controls (wet/dry: control, 8.01 +/- 0.09; NKCC -/-, 7.06 +/- 0.14). Liquid secretion by 17-d NKCC -/- distal lung explants was similar to control explants. Bumetanide inhibited basal liquid secretion in control but not NKCC -/- explants (expansion over 48 h: control, 35 +/- 4%; NKCC -/- 46 +/- 7%). Treatment with 4,4'-diisothiocyanto-stilbene-2,2'-disulfonic acid (DIDS) decreased liquid secretion in both control and NKCC -/- explants. Basal transepithelial potential difference (PD) of control tracheal explants was higher than that of NKCC -/- (control, -13.7 +/- 0.5 mV; NKCC -/-, -11.6 +/- 0.6 mV). Amiloride (10(-)(4) M) inhibited basal PD to the same extent in control and NKCC -/- mice. Terbutaline-stimulated hyperpolarization was less in NKCC -/- than in control tracheas (DeltaPD: control, -10.8 +/- 1.33 mV; NKCC -/-, -6.1 +/- 0.7 mV) and was inhibited by DIDS and acetazolamide in NKCC -/- but not wild-type explants. We conclude that NKCC is rate-limiting for transcellular Cl(-) transport, and that alternative anion transport mechanisms can sustain liquid production at near-normal levels in the fetal NKCC -/- mouse lung.

TGF-beta1 perturbs vascular development and inhibits epithelial differentiation in fetal lung in vivo.

Members of the transforming growth factor beta (TGF-beta) family of polypeptides have been implicated in morphogenesis and differentiation in numerous tissues, including the lung. In order to further define effects of TGF-beta signaling in lung morphogenesis, a constitutively active form of TGF-beta1 was expressed in respiratory epithelial cells of the fetal mouse lung in vivo. Expression of TGF-beta1 arrested lung morphogenesis in the pseudoglandular stage of development, inhibiting synthesis of differentiation-dependent proteins, SP-B, SP-C, and CCSP, and maintaining embryonic patterns of staining for thyroid transcription factor-1 (TTF-1) and hepatocyte nuclear factor-3beta (HNF-3beta). The pulmonary mesenchyme was thickened and vascular density was increased by TGF-beta1. TGF-beta1 decreased expression of vascular endothelial growth factor-A (VEGF-A) mRNA and protein, and the abundance of Flk-1 mRNA in the lung mesenchyme. Distribution of platelet-endothelial cell adhesion molecule (PECAM)-1, a marker of pulmonary blood vessels, was altered, and ultrastructural studies demonstrated that TGF-beta1 inhibited vascular development in the fetal lung. TGF-beta1 perturbed both epithelial cell differentiation and formation of the pulmonary vasculature, supporting the concept that precise control of signaling via the TGF-beta receptor pathway is critical for normal lung morphogenesis.

Spatial and temporal distribution of nerves, ganglia, and smooth muscle during the early pseudoglandular stage of fetal mouse lung development.

Neural tissue and smooth muscle appear early in the developing fetal lung, but little is known of their origin and subsequent distribution. To investigate the spatial and temporal distribution of nerves, ganglia, and airway smooth muscle during the early pseudoglandular stage, fetal mouse lungs at embryonic days (E) 11 to 14 were immunostained as whole-mounts and imaged by confocal microscopy. At E11, the primordial lung consisted of the future trachea and two budding epithelial tubules that were covered in smooth muscle to the base of the growing buds. The vagus and processes entering the lung were positive for the neural markers PGP 9.5 (protein gene product 9.5) and synapsin but no neurons were stained at this stage. An antibody to p75NTR revealed neural crest cells on the future trachea as well as in the vagus and in processes extending from the vagus to the lung. This finding indicates that even though neuronal precursors are already present at this stage, they are still migrating into the lung. By E12, neural tissue was abundant in the proximal part of the lung and nerves followed the smooth muscle-covered tubules to the base of the growing buds. At E13 and E14, a neural network of interconnected ganglia, innervated by the vagus, covered the trachea. The postganglionic nerves mainly followed the smooth muscle-covered tubules, but some extended out into the mesenchyme beyond the epithelial buds. Furthermore, we show in a model of cultured lung explants that neural tissue and smooth muscle persist and continue to grow and differentiate in vitro. By using fluorescent markers and confocal microscopy, we present the developing lung as a dynamic structure with smooth muscle and neural tissue in a prime position to influence growth and development.

FGF-10 disrupts lung morphogenesis and causes pulmonary adenomas in vivo.

Transgenic mice in which fibroblast growth factor (FGF)-10 was expressed in the lungs of fetal and postnatal mice were generated with a doxycycline-inducible system controlled by surfactant protein (SP) C or Clara cell secretory protein (CCSP) promoter elements. Expression of FGF-10 mRNA in the fetal lung caused adenomatous malformations, perturbed branching morphogenesis, and caused respiratory failure at birth. When expressed after birth, FGF-10 caused multifocal pulmonary tumors. FGF-10-induced tumors were highly differentiated papillary and lepidic pulmonary adenomas. Epithelial cells lining the tumors stained intensely for thyroid transcription factor (TTF)-1 and SP-C but not CCSP, indicating that FGF-10 enhanced differentiation of cells to a peripheral alveolar type II cell phenotype. Withdrawal from doxycycline caused rapid regression of the tumors associated with rapid loss of the differentiation markers TTF-1, SP-B, and proSP-C. FGF-10 disrupted lung morphogenesis and induced multifocal pulmonary tumors in vivo and caused reversible type II cell differentiation of the respiratory epithelium.

PLACEBO-CONTROLLED, BLINDED COMPARISON OF ANTENATAL BETAMETHASONE ON MOUSE LIVER DEVELOPMENT

The objective of this investigation was to evaluate, in a placebo-controlled manner, the developing mouse liver after antenatal exposure either to a single dose or to a multidose of betamethasone. Ninety gravid CD-1 mice were randomly divided into three groups (n = 30/group) to receive either saline (0.25 mL sc) or betamethasone (0.10 mg sc) as a single dose on gestational day (GD) 14 of a 19-day gestation or as a 0.10 mg dose given twice daily on GD 14 and on GD 15 (4 doses). GD 0 is defined by the presence of a copulatory plug. These exposures of betamethasone cause fetal mouse lung maturation as would be observed in premature humans at 24–34 weeks of gestation. The livers were removed either from the fetuses on GD 16.5 or from the offspring on postnatal day 1, 3, 5, and 120. Special stains were used to evaluate hepatocyte architecture, glycoprotein and glycogen content, extramedullary hematopoiesis and iron storage. Hepatocyte intranuclear DNA content, cell size, and cell shape were measured by image analysis (CAS 200). At GD 16.5, betamethasone produced a significant decrease in the liver/body weight ratio that, when compared with the placebo group, was greater with the multidose (p < 0.01) than with the single dose (p < 0.05). 16.5 GD single dose hepatocytes were smaller in size as compared to placebo without impact on intranuclear DNA (p < 0.01). Single dose PND 1 hepatocytes demonstrated an increase in intranuclear DNA as compared to placebo but without change in cell size (p < 0.001). The prenatal reduced liver weight recovered in the newborn period. No difference in microscopic architecture of the hepatocytes or histologic differences between either of the three treatment groups was found in glycogen deposition, extramedullary hematopoiesis or iron metabolism at GD 16.5 and postnatally. It was concluded antenatal betamethasone can cause a decrease in the liver/body weight ratio in the fetal mouse that recovers eventually without any functional impact as assessed histologically.