Connexin 43 gene expression in mice with cardiopulmonary developmental defects.

Gap junctions are vital for cellular integrity, including homeostasis, morphogenesis, differentiation and growth in normal development of organs such as heart. Connexin 43 (Cx43) is a major gap junction protein. Our cDNA microarray analysis of normal and nitrofen-exposed neonatal mice with hypoplastic lungs, associated congenital diaphragmatic hernia (CDH) and heart developmental defects showed up-regulation of Cx43. Our objective was to establish if cardiopulmonary defects in nitrofen-exposed mice may be linked to altered expression of the Cx43 gene. We addressed our objective by performing northern blot analysis, real-time RT-PCR, immunoblotting and immunohistochemistry by localizing Cx43 in hearts and lungs of normal and nitrofen-exposed mice at different gestational stages. The data confirmed up-regulation of Cx43 expression in both hearts and lungs of CDH neonate mice and in lungs at other developmental stages except the pseudoglandular stage. However, Cx43 protein levels were either the same or less in hearts and lungs of nitrofen-exposed mice than in normal tissues except in pseudoglandular lungs. Different expressions of mRNA and protein suggest possible post-transcriptional or translational defects in Cx43. We observed dysmorphic hearts with exaggerated interventricular grooves and deep notches at the apex of the hearts in nitrofen-exposed fetal/neonatal mice; narrowed pulmonary out-flow and various degrees of craniofacial defects in 15-20% of the affected mice. Our data suggest a possible involvement of Cx43 in craniofacial, heart and lung defects in nitrofen-exposed mice. Such cardiopulmonary defects are also observed in human newborns with CDH. Thus, the murine data may help elucidate the pathways of cardiopulmonary defects in the human newborn condition.

Lung growth and development.

The organogenesis of lung involves several complex mechanisms, including interactions between cells originating from two germ layers--endoderm and mesoderm. Regulation of lung branching morphogenesis with reference to its architecture, growth pattern, differentiation, interactions between epithelium and mesenchyme and / or endothelium, as well as genes regulating these processes have been addressed by the pulmonary biologists through careful molecular biology and genetic experimental approaches. The mammalian lung develops by outpouching from the foregut endoderm as two lung buds into the surrounding splanchnic mesenchyme. Several different regions of the foregut are specified to develop into different thoracic and visceral organs. The lung-buds further elongate and branch, and the foregut longitudinally gets separated into esophagus and trachea. In rodents (mice and rats), this occurs around embryonic day 11, where the right lung bud develops into four different lobes and left lung develops as a single lobe. In humans, these processes occur by 3-4 weeks of embryonic development, where the right lung is a trilobar lung and the left lung is a bilobar lung. Several generations of dichotomous branching occur during embryonic development, followed by secularization and alveolarization pre- and post-natally, which transform a fluid-filled lung into an air-breathing lung able to sustain the newborn. During these different developmental stages from embryonic to newborn stage, the lung architecture undergoes profound changes, which are marked by a series of programmed events regulated by master genes (e.g., homeobox genes), nuclear transcription factors, hormones, growth factors and other factors. These programmed events can be altered by undesirable exposure to overdoses of hormones/vitamins/growth factors, synthetic drugs, environmental toxins, radiation and other agents. In the recent years molecular techniques have opened avenues to study specific functions of genes or their products (proteins) in vivo or in vitro at a cellular or an organelle level, some of these include targeted disruption, knock-in / knock-out genes, in vitro mutagenesis, use of sense and anti-sense oligonucleotides. Some of these aspects with reference to regulation of normal lung development and growth and a specific example of pulmonary hypoplasia as an abnormal lung formation are discussed in this review.

Relevance of tenascin-C and matrix metalloproteinases in vascular abnormalities in murine hypoplastic lungs.

BACKGROUND: Tenascin-C (TN-C), an extracellular matrix glycoprotein, is crucial to cell-migration, proliferation, apoptosis and remodeling of tissues, with a potential role in pathobiology of pulmonary hypertension. Matrix metalloproteinases (MMPs) and tissue inhibitors of metalloproteinases (TIMPs) are crucial to the integrity of the extracellular matrix. TN-C and MMPs are counter-regulatory molecules, which influence the vascular integrity through modulations of elastin. We have a murine model of pulmonary hypoplasia with coexistent diaphragmatic hernia, vascular abnormalities and excessive arterial smooth muscle cell (SMC) proliferation. OBJECTIVES: Our objective was to investigate modulations of TN-C and MMPs in hypoplastic lungs and their possible contribution to the observed pulmonary vascular abnormalities. METHODS: We addressed our objectives by pursing immunoblotting and immunohistochemistry and zymography/reverse zymography to assess the alterations in activities of MMPs and their inhibitors. RESULTS: We observed significant down-regulation of MMP-9 activity in hypoplastic lungs at the later fetal developmental stages, whereas MMP-2 activity assessed by gelatin zymography remained unaltered. Reverse zymography revealed up-regulation of activities of TIMP-1, -2, -3 and -4 in hypoplastic lungs during later fetal development, with pronounced increases in TIMP-3 and -4 activities. Furthermore, immunoblot analyses and immunohistochemistry revealed that TN-C protein was down-regulated in developing hypoplastic lungs, compared to normal lungs. CONCLUSIONS: (1)TN-C is known to inhibit vascular SMC proliferation. But, decrease in TN-C in hypoplastic lungs may support the observed arterial SMC proliferation. (2) Our studies showed that in hypoplastic lungs the SMC apoptosis is not affected, thus suggesting that SMC proliferation and apoptosis may be two separate processes in pulmonary hypoplasia with coexistent diaphragmatic hernia. Together, our data showed an imbalance in the extracellular matrix proteins, which may contribute to the pulmonary vascular abnormalities.

Expression profile of IGF system during lung injury and recovery in rats exposed to hyperoxia: a possible role of IGF-1 in alveolar epithelial cell proliferation and differentiation.

Although several studies have shown that an induction of insulin-like growth factor (IGF) components occurs during hyperoxia-mediated lung injury, the role of these components in tissue repair is not well known. The present study aimed to elucidate the role of IGF system components in normal tissue remodeling. We used a rat model of lung injury and remodeling by exposing rats to > 95% oxygen for 48 h and allowing them to recover in room air for up to 7 days. The mRNA expression of IGF-I, IGF-II, and IGF-1 receptor (IGF-1R) increased during injury. However, the protein levels of these components remained elevated until day 3 of the recovery and were highly abundant in alveolar type II cells. Among IGF binding proteins (IGFBPs), IGFBP-5 mRNA expression increased during injury and at all the recovery time points. IGFBP-2 and -3 mRNA were also elevated during injury phase. In an in vitro model of cell differentiation, the expression of IGF-I and IGF-II increased during trans-differentiation of alveolar epithelial type II cells into type-I like cells. The addition of anti-IGF-1R and anti-IGF-I antibodies inhibited the cell proliferation and trans-differentiation to some extent, as evident by cell morphology and the expression of type I and type II cell markers. These findings demonstrate that the IGF signaling pathway plays a critical role in proliferation and differentiation of alveolar epithelium during tissue remodeling.

Basic science faculty in surgical departments: advantages, disadvantages and opportunities.

The number of Ph.D. faculty in clinical departments now exceeds the number of Ph.D. faculty in basic science departments. Given the escalating pressures on academic surgeons to produce in the clinical arena, the recruitment and retention of high-quality Ph.D.s will become critical to the success of an academic surgical department. This success will be as dependent on the surgical faculty understanding the importance of the partnership as the success of the Ph.D. investigator. Tighter alignment among the various clinical and research programs and between surgeons and basic scientists will facilitate the generation of new knowledge that can be translated into useful products and services (thus improving care). To capitalize on what Ph.D.s bring to the table, surgery departments may need to establish a more formal research infrastructure that encourages the ongoing exchange of ideas and resources. Physically removing barriers between the research groups, encouraging the open exchange of techniques and observations and sharing core laboratories is characteristic of successful research teams. These strategies can meaningfully contribute to developing successful training program grants, program projects and bringing greater research recognition to the department of surgery.

Persistent vascular defects in lung allografts attributed to defective endogenous endothelial progenitors.

BACKGROUND: A major pathological finding in human newborns with pulmonary hypoplasia and congenital diaphragmatic hernia is the presence of vascular abnormalities in lungs. Vasculogenesis/angiogenesis are crucial to lung development. To study lung alveolar development, including microvascular formation in fetal lung implants, Schwarz et al. [1] developed a subcutaneous allograft model. We adopted their model to assess the influence of neovascularization or the "host-graft vascular development" on hypoplastic lung structure and growth. MATERIALS AND METHODS: Normal and hypoplastic lungs at pseudoglandular stage were implanted subcutaneously under the dorsolateral fold of immunocompromised nude mice (athymic, nu/nu). Lung allografts were removed and assessed at 2, 4, 6, and 8 weeks postimplantation. RESULTS: Neovascularization of implanted lungs from subcutaneous vasculature of nude mice resulted in varying degrees of maturation of implanted normal and hypoplastic lungs. By 4 weeks, implanted normal lungs contained Type 2-like cells and by 7 to 8 weeks, Type 2 and Type 1-like cells, air spaces had enlarged, and surfactant secretion was observed. Despite some differentiation and maturation of hypoplastic lungs, there was more mesenchymal tissue, no secondary septa, and smaller air spaces compared to normal lungs. CONCLUSIONS: (a) Neovascularization or host-graft vascular development occurs in both normal and hypoplastic lung allografts. (b) Development and maturation of implanted normal and hypoplastic lungs follow the establishment of the vascular connections between the host and grafts. (c) The host-graft vascular connections do not improve the growth of normal or hypoplastic lungs. (d) Neovascularization failed to overcome the embryonic defects in vascular formation and the pulmonary vasculogenesis remained defective in hypoplastic lung allografts, which may be attributed to the defective endogenous endothelial progenitor cells.

Mesenchymal nuclear transcription factors in nitrofen-induced hypoplastic lung.

BACKGROUND: Nitrofen-induced pulmonary hypoplasia (PH) with or without coexistent congenital diaphragmatic hernia (CDH) in animals mimics the human condition. We have demonstrated reduced steroid-thyroid-retinoid receptors in hypoplastic lungs. Therefore, we hypothesize that expression of two additional mesenchymally derived nuclear transcription factors, retinoid X receptor alpha (RXR-alpha) and homeobox b-5 (Hoxb-5), would also be altered in hypoplastic lungs. MATERIALS AND METHODS: We used timed-pregnant CD-1 mice either untreated or gavaged with nitrofen on gestational day (Gd) 8. Normal lungs were compared with hypoplastic lungs with severe left PH and CDH at Gd 14, 16, and 19 and from neonates. We performed immunoblotting for RXR-alpha and Hoxb-5 proteins and immunohistochemistry for Hoxb-5 protein. RESULTS: Almost 70-80% of nitrofen-exposed mice had no apparent external phenotypic abnormalities, such as craniofacial defects. Fetal body and lung weights were reduced. RXR-alpha and Hoxb-5 proteins were highest at Gd 14 and decreased as development progressed. Densitometric analysis of RXR-alpha or Hoxb-5 proteins in normal and hypoplastic lungs showed no significant difference; however, the immunolocalization pattern of Hoxb-5 protein differed. Hoxb-5 protein was primarily in mesenchymal cells of normal lungs on Gd 14; however, by Gd 19, it appeared to be mainly in the epithelial cells of prealveolar structures and in adjacent subepithelial mesenchymal cells. In hypoplastic lungs no significant changes were observed in Hoxb-5 staining in mesenchymal cells at Gd 14 nor at Gd 16; however, Hoxb-5 expression persisted in mesenchyme and epithelium at Gd 19 and in neonatal hypoplastic lungs, unlike normal lungs. CONCLUSIONS: (1) Unaltered RXR-alpha protein implies that despite altered retinoic acid receptors (RARs) in hypoplastic lungs, the mechanisms of nitrofen-induced PH may be independent of RXR-alpha pathways. (2) In hypoplastic lungs, the persistent mesenchymal expression of Hoxb-5, in later stages of development and at birth, suggests delayed development and maturation compared to normal lungs. We speculate that nitrofen induces PH via RAR-dependent but RXR-independent interactions, which may be downstream of the Hoxb-5 gene or may involve other more anteriorly expressed Hox genes.

Thyroid hormone affects embryonic mouse lung branching morphogenesis and cellular differentiation.

Although thyroid hormone (T(3)) influences epithelial cell differentiation during late fetal lung development, its effects on early lung morphogenesis are unknown. We hypothesized that T(3) would alter embryonic lung airway branching and temporal-spatial differentiation of the lung epithelium and mesenchyme. Gestational day 11.5 embryonic mouse lungs were cultured for 72 h in BGJb serum-free medium without or with added T(3) (0.2, 2.0, 10.0, or 100 nM). Evaluation of terminal bud counts showed a dose- and time-dependent decrease in branching morphogenesis. Cell proliferation was also significantly decreased with higher doses of T(3). Morphometric analysis of lung histology showed that T(3) caused a dose-dependent decrease in mesenchyme and increase in cuboidal epithelia and airway space. Immunocytochemistry showed that with T(3) treatment, Nkx2.1 and surfactant protein SP-C proteins became progressively localized to cuboidal epithelial cells and mesenchymal expression of Hoxb5 was reduced, a pattern resembling late fetal lung development. We conclude that exogenous T(3) treatment during early lung development accelerated epithelial and mesenchymal cell differentiation at the expense of premature reduction in new branch formation and lung growth.

Thyroid hormone affects distal airway formation during the late pseudoglandular period of mouse lung development.

We recently showed that T3 treatment of cultured gestational day 11.5 early pseudoglandular period mouse lungs, accelerated terminal airway development at the expense of decreased branching morphogenesis. As the ability of T3 to influence epithelial cell differentiation increases with advancing development, we hypothesized that in the late pseudoglandular period, T3 would cause further premature changes in the morphology of the distal airways leading to abnormal saccular development. Gestational day 13.5 embryonic mouse lungs were cultured for 3 and 7 days without or with added T3. Increasing T3 dose and time in culture resulted in progressive development of thin walled, abnormal saccules, an increase in cuboidal and flattened epithelia and airway space with a concomitant decrease in mesenchymal cell volume. Consistent with increased cuboidal and flattened epithelial cell volume identified by morphometry, immunostaining suggested increased cell proliferation detected by localization of proliferating cell nuclear antigen (PCNA) in epithelial cells of T3 treated lungs. T3 decreased mesenchymal expression of Hoxb-5 protein and caused progressive localization of Nkx2.1 and SP-C proteins to distal cuboidal epithelia of early abnormal saccules, evidence that T3 prematurely and abnormally advanced mesenchymal and epithelial cell differentiation. Western blot showed a T3-dependent decrease in Hoxb-5 and a trend towards decreased Nkx2.1 and SP-C, after 3 and 7 days of culture, respectively. We conclude that exogenous T3 treatment during the late pseudoglandular period prematurely and abnormally accelerates terminal saccular development. This may lead to abnormal mesenchymal and epithelial cell fate.

Angiopoietin-1 and VEGF in vascular development and angiogenesis in hypoplastic lungs.

We hypothesized that exposure of murine fetuses to environmental toxins, such as nitrofen, during early embryogenesis alters vasculogenesis. To address our hypothesis, we assessed protein levels of endothelial cell-selective angiogenic factors: angiopoietin (ANG)-1, vascular endothelial growth factor (VEGF), and mediator of VEGF signaling, VEGF receptor-2 [fetal liver kinase (Flk)-1], a transmembrane receptor tyrosine kinase. VEGF and Flk-1 proteins were lower in hypoplastic lungs from pseudoglandular to alveolar stages than in normal lungs at equivalent developmental time points significant for induction of pulmonary vasculogenesis and angiogenesis. ANG-1 protein was higher in hypoplastic lungs than in normal lungs at all the developmental stages considered in this study, i.e., pseudoglandular, canalicular, saccular, and alveolar stages. We assessed exogenous VEGF-mediated endothelial cell response on extracellular signal-regulated kinase (ERK) 1/2, also referred to as p44/42 mitogen-activated protein kinase. Hypoplastic lungs had more elevated ERK 1/2 protein than normal developing lungs. Exposure to exogenous VEGF activated ERK 1/2 in normal developing lungs but not in hypoplastic lungs. Our results suggest that in hypoplastic lungs: 1) low VEGF signifies negative effects on vasculogenesis/angiogenesis and indicates altered endothelial-mesenchymal interactions; 2) increased ANG-1 protein may be required to maintain vessel integrity and quiescence; and 3) regulation of ERK 1/2 protein is affected in hypoplastic lungs. We speculate that extensive remodeling of blood vessels in hypoplastic lungs may occur to compensate for structurally and functionally defective vasculature.

Histology-based screen for zebrafish mutants with abnormal cell differentiation.

The power of histology to define states of cell differentiation was used as the basis of a mutagenesis screen in zebrafish. In this screen, 7-day-old parthenogenetic half-tetrad larvae from potential carrier females were screened for mutations affecting cell differentiation in hematoxylin and eosin-stained tissue sections. Seven, noncomplementing, recessive mutations were found. Two mutations affect only the retina: segmented photoreceptors (spr) show a discontinuous photoreceptor cell layer; vestigial outer segments (vos) has fewer photoreceptor cells and degenerated outer segments within this cell layer. Three mutants have gut-specific defects: the epithelial cells of kirby (kby) are replaced by ballooned cells; the intestines of stuffy (sfy) and stuffed (sfd) contain increased luminal mucus. Two mutations affect multiple organs: disordered neural retina (dnr) has disrupted retinal layering and mild nuclear abnormalities in the gut and liver; and in huli hutu (hht), the retinal cell layers are disorganized and multiple organs have mild to severe nuclear abnormalities that are reminiscent of the atypia of human neoplasia. Each mutation appears to be homozygous lethal. This screen is proof of principle for the feasibility of histologic screens to yield novel mutations, including potential models of human disease. The throughput for this type of screen may be enhanced by automation.