Semaphorin 3A (Sema3A) is a neural guidance cue that also mediates cell migration, proliferation and apoptosis, and inhibits branching morphogenesis. Because we have shown that genetic deletion of neuropilin-1, which encodes an obligatory Sema3A co-receptor, influences airspace remodeling in the smoke-exposed adult lung, we sought to determine whether genetic deletion of Sema3A altered distal lung structure.
To determine whether loss of Sema3A signaling influenced distal lung morphology, we compared pulmonary histology, distal epithelial cell morphology and maturation, and the balance between lung cell proliferation and death, in lungs from mice with a targeted genetic deletion of Sema3A (Sema3A-/-) and wild-type (Sema3A+/+) littermate controls.
Genetic deletion of Sema3A resulted in significant perinatal lethality. At E17.5, lungs from Sema3A-/- mice had thickened septae and reduced airspace size. Distal lung epithelial cells had increased intracellular glycogen pools and small multivesicular and lamellar bodies with atypical ultrastructure, as well as reduced expression of type I alveolar epithelial cell markers. Alveolarization was markedly attenuated in lungs from the rare Sema3A-/- mice that survived the immediate perinatal period. Furthermore, Sema3A deletion was linked with enhanced postnatal alveolar septal cell death.
These data suggest that Sema3A modulates distal pulmonary epithelial cell development and alveolar septation. Defining how Sema3A influences structural plasticity of the developing lung is a critical first step for determining if this pathway can be exploited to develop innovative strategies for repair after acute or chronic lung injury.
Citation: Becker PM, Tran TS, Delannoy MJ, He C, Shannon JM, McGrath-Morrow S (2011) Semaphorin 3A Contributes to Distal Pulmonary Epithelial Cell Differentiation and Lung Morphogenesis. PLoS ONE 6(11): e27449. doi:10.1371/journal.pone.0027449
Editor: Rory Edward Morty, University of Giessen Lung Center, Germany
Received: May 2, 2011; Accepted: October 17, 2011; Published: November 11, 2011
Copyright: © 2011 Becker et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by the National Institutes of Health RO1HL083286 (PMB), RO1HL098319 (JMS), and Flight Attendant Medical Research Institute CIA 052365 (PMB). No authors have any financial interests related to this work, and the funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
The semaphorins are a family of evolutionarily conserved secreted and transmembrane proteins that participate in diverse biological processes, including central and peripheral nervous system development and regeneration, cardiovascular, renal and olfactory morphogenesis, immune system function, and cancer progression , , , , , . Class 3 semaphorins comprise a subfamily of 7 secreted proteins (3A-3G) best characterized as chemorepellants for growing neurons and axons. More recently it has been recognized that semaphorin 3 family members participate in a wide range of neuronal and non-neuronal processes in addition to the cytoskeletal remodeling involved in axonal pathfinding (reviewed in ). Semaphorin 3A (Sema3A) was the first identified vertebrate semaphorin, and has been extensively studied as a repulsive axon guidance cue , , , . Sema3A also influences cortical dendritic morphology ,  and neuronal migration , as well as apoptosis and proliferation of multiple cell types , , , . Most of the neuronal effects of Sema3A are transduced by a holoreceptor complex, in which an obligatory co-receptor, neuropilin-1 (Nrp-1), functions as the ligand-binding subunit, and signaling occurs through activation of class A plexin receptor family members. Cell type-specific expression of different Sema3A receptor complexes is a key determinant of how this guidance cue exerts selective effects on cellular morphology.
Both Sema3A and Nrp-1 are expressed in fetal, neonatal, and adult lung, yet data regarding how Sema3A signals influence lung morphology and function, or lung structural maintenance in response to injury, are scant. Studies published several years ago suggested that Sema3A signaling through Nrp-1 attenuated branching morphogenesis of fetal lung explants maintained in culture . We recently demonstrated that cigarette smoke-induced airspace enlargement and alveolar epithelial cell death is potentiated by conditional deletion of pulmonary epithelial Nrp-1 in the lungs of adult animals . These findings led us to hypothesize that Sema3A might be an essential mediator of distal airspace homeostasis.
To test this hypothesis, we evaluated the distal lung morphology of mice with a targeted genetic deletion of Sema3A (Sema3A-/-), maintained on a C57B/6 genetic background . This strain of mice was initially reported to show no significant embryonic or early postnatal mortality despite severe abnormalities in peripheral nerve projection, although Sema3A-/- mice independently generated on the sv129 strain background died within a few days of birth, and the rare survivors exhibited right ventricular hypertrophy and right atrial dilatation . In this study, we demonstrate that the absence of Sema3A was associated with significant perinatal lethality. During late embryonic development, maturation and/or differentiation defects of distal lung epithelium were observed in Sema3A-/- mice, and the rare Sema3A-/- mice surviving to postnatal day 14 (P14) or beyond exhibited profound developmental emphysema. Taken together, these data suggest that Sema3A is a critical determinant of distal lung morphogenesis.
Mouse generation and genotyping
Animal studies were approved by the Johns Hopkins Animal Care and Use Committee (protocol number MO10M66). Mouse breeding was performed in central animal facilities. Sema3A-/- animals on a C57B/6 background were generated by mating Sema3A+/- mice . Genotyping was performed by tail snip and PCR amplification of tail lysates, using standard techniques and previously reported primers . The morning when a vaginal plug was observed was designated as embryonic day (E) 0.5, and the day of birth as postnatal (P) day 0.
Lung histology and immunohistochemistry
Embryonic lungs were fixed by submersion in 4% paraformaldehyde overnight at 4oC. Postnatal animals were anesthetized, the trachea was cannulated, then the lungs were inflated for histology and immunohistochemical analysis. Lung inflation was performed with 0.5% low-melting agarose at a constant pressure of 25 cm H2O, as previously described . The lungs were then fixed in toto in 4% paraformaldehyde overnight and subsequently embedded in paraffin. Five µm sections were stained with hematoxylin and eosin, or Periodic Acid-Schiff (PAS) stain for cellular glycogen.
Quantitative lung morphometry was performed as previously described . Briefly, random H&E stained lung sections were photographed with a 10x objective (Nikon Instruments Inc., Melville, NY). Mean linear intercept (MLI) was measured using NIS-Elements AR (Nikon Instruments Inc., Melville, NY).
To localize expression patterns of endogenous Sema3A protein, a placental alkaline-phosphatase (AP)-Nrp-1 ectodomain fusion protein (AP-Nrp1ecto; 4 nM) was bound to tissue sections from Sema3A+/+ (wild-type) and Sema3A-/- (null) mice, using previously reported methods . This probe recognizes endogenous Nrp-1 ligands in the tissue sections. Specificity of AP-Nrp1ecto binding to Sema3A was determined by comparing the binding patterns in lung sections from Sema3A+/+ and Sema3A-/- mice. Nrp-1 protein expression was determined by hybridizing tissue sections with an AP-Sema3A fusion protein which recognizes endogenous Sema3A receptor complexes. Because Nrp-1 is the ligand binding subunit of the Sema3A receptor complex, it is presumed that staining for AP-Sema3A binding primarily reflects sites of endogenous Nrp-1 expression. Nrp-1 protein expression was also evaluated by immunohistochemical staining with an anti-rat Nrp-1 antibody (1:500, R&D Systems, Minneapolis, MN).
Distal lung epithelial cells were identified using pro-SPC (1:500; Seven Hills Bioreagents, Cincinnati, OH) or T-1-alpha antibodies (1:200, DSHB, Iowa City, IO). Determination of cell turnover was evaluated by immunostaining lung sections with an antibody recognizing proliferating cell nuclear antigen (PCNA; 1:50; Santa Cruz Biotechnology, Santa Cruz, CA), or terminal deoxynucleotide nick-end labeling (TUNEL) of sections for DNA fragmentation (Promega, Boston, MA). Quantification of PCNA and TUNEL positive cells to generate cell proliferative and death indices was performed as previously described .
In additional groups of E17.5 Sema3A+/+ and Sema3A-/- mice, the right upper lobe was snap frozen in liquid nitrogen for subsequent RNA extraction , and the left lung was snap frozen in liquid nitrogen for subsequent protein extraction . The right lower lobe was processed for analysis by transmission electron microscopy (TEM). For TEM, embryonic lung lobes were isolated, submerged briefly (30–45 min, 4°C) in fixative containing 2% paraformaldehyde and 2% glutaraldehyde in 0.05M sodium cacodylate buffer with 3mM CaCl2 (360mOsm), pH 7.2, then cut into 2 mm cubes and submerged in fresh fixative overnight at 4°C. Following buffer rinse with the addition of 0.18 M sucrose (350 mOsm), samples were post-fixed in 2% osmium tetroxide in 0.1 M sodium cacodylate, 0.09 M sucrose, 3 mM CaCl2 (350 mOsm) for 1 hr on ice in the dark. Samples were dehydrated through a graded series of ethanol to 100%, transferred through propylene oxide then embedded in Eponate 12 (Pella) and cured at 60°C for two days. Sections were cut on a Riechert Ultracut E with a Diatome Diamond knife. Eighty nm sections were picked up on formvar coated 1×2 mm copper slot grids and stained with uranyl acetate followed by lead citrate. Some sections were treated for 30 min with 1% aqueous low molecular weight tannic acid (Malinkrodt; after filtration through a 0.22 µm syringe filter), then rinsed with water prior to uranyl acetate staining. Grids were viewed on a Hitachi 7600 TEM operating at 80 kV, and digital images were captured with an AMT 1 K x 1 K CCD camera.
RNA, protein and satPC expression in lung tissue homogenate
Quantitative real time PCR (qPCR) of Sema3A RNA isolated from lung homogenate was performed using previously described methods , after isolation of RNA from frozen tissue samples (SV Total RNA Isolation Kit; Promega, Boston, MA), and conversion to cDNA (iScript cDNA Synthesis Kit; BioRad, Hercules, CA). qPCR was performed was performed using TaqMan probes and primer sets (Applied Biosystems), with Actb as an internal control. The PCR reactions and relative quantifications were performed using 25 ng of cDNA per reaction on a 7300 Real-Time PCR system (Applied Biosystems).
Expression of Aquaporin-5 (Aqp5), and T1-alpha protein were determined by Western blot analysis of whole left lung homogenate form E17.5 mice, using methods previously described . Primary antibodies for T1-alpha were purchased from The Developmental Studies Hybridoma Bank, and Aqp 5 antibodies were a generous gift from Ramana Sidhaye. Protein expression was quantified using densitometry, and normalized to expression of GAPDH on the same membranes. Disaturated phosphatidylcholine (SatPC) levels were measured in whole lung homogenate from E18.5 mice, using methods previously described .
Statistical analysis was performed using the StatView program (SAS Institute). To determine the age-dependent effects of Sema3A deletion on body weight, MLI, and cell proliferative and death indices, comparisons between groups were made using two-way ANOVA (genotype by age). If significant interactions (p≤0.05) were identified, least-significant differences were calculated to allow comparison of individual group means. Differences in lung homogenate expression of T1-alpha and Aquaporin-5 protein were determined using non-parametric analysis (Mann-Whitney) of densitometric data.
Targeted genetic deletion of Sema3A reduces viability
As was previously reported , in our hands the Sema3A-/- mice were born from heterozygous matings at expected Mendelian ratios. Complete genotype analysis was performed on offspring from 15 matings between Sema3A+/- mice. Twenty-two percent (29/129) of pups were wild type (Sema3A+/+), 54% (70/129) were heterozygous (Sema3A+/-), and 23.2% (30/129) were homozygous null (Sema3A-/-). These ratios were similar for 7 litters harvested at E17.5, suggesting that fetal viability is not affected by loss of Sema3A. However, almost two-thirds of Sema3A-/- mice died during the first postnatal day, and only rare survivors lived to P14 or beyond. No discernible differences in body weight were noted for the subset of surviving Sema3A-/- mice in the immediate postnatal period (Table 1). However, some newborn Sema3A-/- animals were dead prior to observation. The few Sema3A-/- animals surviving beyond P1 generally became distinguishable from their littermates between P7 and P14 on the basis of smaller body size. It was sometimes possible to predict impending late postnatal mortality of a Sema3A-/- pup because of increasingly labored respiration for approximately 24 hrs prior to death.
Shown in Figure 1A, qPCR demonstrated negligible amounts of Sema3A mRNA in lung homogenate from Sema3A-/- animals as compared with wild type (Sema3A+/+) littermate controls. Postnatal pulmonary Sema3A protein expression, assessed by AP-Nrp1ecto binding to tissue sections, was largely confined to small airway epithelium in Sema3A+/+ mice. Expression was greatest at P1, but was sustained through P28 (Figure 1B). This pattern of AP-Nrp1ecto binding was absent in lung sections from Sema3A-/- animals, suggesting specificity of the probe for Sema3A rather than another Nrp-1 ligand. Expression of Nrp-1, the Sema3A obligate co-receptor, was determined by tissue binding of AP-Sema3A. AP-Sema3A binding was seen in cells throughout alveolar septae as well as in bronchiolar epithelium at P1 (Figure 2A). Immunostaining suggested that some of the septal cells which express Nrp-1 were of epithelial origin, demonstrated by co-labeling with Nrp-1 and pro-SPC antibodies (Figure 2B).
A. Reduced Sema3A expression in the lungs of Sema3A-/- mice was assessed using qPCR. B. Representative AP-Nrp-1ecto binding in tissue sections from Sema3A+/+ (middle panels) and Sema3A-/- mice (bottom panels) at P1 (left) and P28 (right). Prominent AP-Nrp-1ecto binding was seen in bronchiolar epithelium of littermate control (Sema3A+/+) mice at both P1 and P28. This pattern of tissue binding of AP-Nrp1ecto was absent in lung sections from Sema3A-/- animals, suggesting specificity of the signal for Sema3A expression. Top panels represent non-specific AP staining in lung sections hybridized with a control AP-vector. (Magnification = 20x).
A. Representative AP-Sema3A binding in tissue sections from Sema3A-/- (right panels) and Sema3A+/+ littermate control (left panels) mice at P1. (Magnification = 20x) B. Representative dual immunostaining for Nrp-1 (green) and pro-SPC (red) in lungs from Sema3A-/- (right panels) and Sema3A+/+ (left panels) mice. A subset of Nrp-1 expressing cells stain positive for the ATII marker, pro-SPC (white arrows). (Magnification = 60x).
Sema3A deletion disrupts distal lung morphology
We next evaluated lung histology of Sema3A-/- pups and found that it was abnormal at all ages examined (E17.5, P1, P14 and P28) (Figure 3). Lungs from E17.5 Sema3A-/- mice had reduced airspace and thickened septae. In surviving Sema3A-/- mice, cellular debris was sometimes seen in the airspaces at P1 (Figure 3H, black arrowheads). Profound airspace enlargement, quantified by morphometric estimation of the mean linear intercept (MLI), was seen in the few Sema3A-/- mice that survived to P14 or beyond, when compared with both Sema3A+/+ (bar graph, Figure 3) and Sema3A+/- littermates. Because surviving Sema3A-/- mice were significantly smaller than their littermate controls at the later postnatal ages, we cannot definitively exclude the possibility that nutritional deficiencies contributed to attenuation of postnatal alveolarizaton. However, the feeding and nesting behavior of all neonatal mice we observed did not differ appreciably among littermates. Furthermore, MLI estimated in lungs harvested from Sema3A+/- mice (44.1+1.2, 32.6+2.1, and 33.6+1.0 microns at P1, P14, and P28, respectively) did not differ from age-matched Sema3A+/+ animals, despite their smaller body size.
Top panel. Representative lung histology from Sema3A-/- mice (right panels) and Sema3A+/+ littermate controls (left panels) at E17.5, P1, P14 and P28. Prominent septation defects were seen in all Sema3A-/- mice that survived to P14 or beyond. At the earlier ages, septae of lungs from many Sema3A-/- mice were thickened, and clusters of cellular debris were sometimes detected in airspaces at P1 (black arrowheads in panel H). Scale bar represents 50 µm. Bottom panel. Airspace size was quantitated morphometrically by calculation of the mean linear intercept (MLI). MLI increased in all Sema3A-/- mice (white bars) surviving to P14 or beyond as compared with Sema3A+/+ littermate control animals (black bars) and Sema3A+/- littermates (see text). Data represent mean ± SE for 4 mice/group at each time point.
Sema3A deletion is associated with enhanced cell death in postnatal mice
In order to determine whether the widened septae and reduced airspace seen in Sema3A-/- lungs during late embryogenesis were due to altered cell turnover, immunostaining for PCNA and TUNEL labeling of tissue sections were performed. Shown in Figure 4A, widespread immunostaining for PCNA was seen in E17.5 lungs from Sema3A+/+ littermate control and Sema3A-/- mice. By P1 and P14, PCNA positive cells were largely confined to airways, and the number and pattern of PCNA positive cells appeared similar between surviving Sema3A-/- mice and Sema3A+/+ littermate controls. Proliferative index was not significantly altered by Sema3A deletion at any age point examined (Figure 4B). In contrast, rare TUNEL positive cells were seen in E17.5 lungs from mice of either genotype (data not shown), but the cell death index (Figure 4D) was significantly enhanced in lungs from the few Sema3A-/- animals surviving birth, with TUNEL positive cells present within alveolar septae and along secondary crests (Figure 4C).
A. Widespread immunostaining for the proliferative marker PCNA (green) was seen in lungs from both E17.5 Sema3A+/+ and Sema3A-/- mice (top panels). By P1 (middle panels) and P14 (lower panels), PCNA staining was largely confined to cells lining small airways, and did not differ between Sema3A-/- animals and littermate controls. Nuclei are counterstained with DAPI (blue) (Magnification = 40x). B. Shown graphically, the average proliferative index did not significantly differ between Sema3A-/- (white bars) and Sema3A+/+ (black bars) mice at any time point evaluated (bars represent mean ± SE for n = 3 animals/group). C. Representative TUNEL labeling (green) in lungs from Sema3A-/- mice surviving to P1 (top right panel) and P14 (bottom right panel). Shown for comparison in the left panels are lungs from Sema3A+/+ littermate controls. Nuclei are counterstained with DAPI (blue). (Magnification = 40x). D. Apoptotic index increased significantly in Sema3A-/- animals (white bars) as compared with Sema3A+/+ littermate control mice (black bars) at both P1 and P14 (n.d. = not detected; bars represent mean ± SE for n = 3 animals/group).
Pulmonary epithelial cell maturation is impaired in Sema3A-/- mice
Because early perinatal respiratory lethality is often related to impaired epithelial maturation, and some of the Nrp-1 cells expressing cells in the lung periphery were of epithelial origin, we sought to determine whether Sema3A deletion might alter pulmonary epithelial cell development. Cytoplasmic glycogen is abundant in immature type II alveolar epithelial cells (ATII) cells prior to its utilization for surfactant production. Both PAS staining and TEM demonstrated increased prominence of intracellular glycogen in the distal alveolar epithelial cells of E17.5 Sema3A-/- mice (Figures 5A and B). In addition, ultrastructural evaluation of ATII in the lungs of Sema3A-/- animals at E17.5 suggested the presence of fewer multivesicular and lamellar bodies, and those seen were smaller with atypical membranous inclusions when compared with ATII in Sema3A+/+ littermate control lungs (Figure 5C), despite the fact that expression of mRNA for surfactant proteins in E17.5 whole lung homogenate did not differ significantly between Sema3A-/- mice and littermate control animals (data not shown). As an additional assessment of alveolar epithelial maturity, we measured SatPC levels in lungs from E18.5 Sema3A-/- and Sema3A+/+ mice, and found no significant differences (3.109±0841 and 3.196±0.2628 µmol SatPC/g lung weight for Sema3A-/- and Sema3A+/+ mice, respectively), although this does not preclude the possibility that SatPC levels differ at or after birth.
A. PAS staining was increased in lungs from E17.5 Sema3A-/- mice (right panels) as compared with Sema3A+/+ littermate controls (left panels). Bar = 10 µ. Results are representative of 3 animals/group. B. TEM confirmed reduced distal airspace size (Alv) and the presence of fewer ATI in Sema3A-/- mice (right panel) as compared with Sema3A+/+ littermate controls (left panel). Cytoplasmic glycogen (G) was seen in epithelial cells surrounding distal airspaces (Alv). Lamellar bodies were seen within airspaces (inset) and ATII of Sema3A+/+ animals (left panel), whereas ATII of Sema3A-/- mice contained primarily multivesicular bodies (inset; right panel). Images captured at 5000x, scale bar = 2 µ; insets captured at 30,000x, scale bar = 500nm. Results are representative of 3 animals/group. C. TEM images of ATII from lungs of Sema3A+/+ littermate control mice at E17.5 demonstrate normal multivesicular (MV; top right panel) and lamellar (LB; bottom left panel) body formation. In contrast, multivesicular (top right panel) and lamellar (bottom right panel) bodies in ATII from age-matched Sema3A-/- animals were often smaller and had poorly formed membranous inclusions. Scale bar = 500 nm in all panels. Results are representative of 3 mice/group.
ATII cells are precursors of the Type I alveolar epithelial cells (ATI) required for gas exchange in the maturing distal lung. We therefore compared immunohistochemical expression of the ATI surface protein, T1-alpha, in lungs from Sema3A-/- mice and Sema3A+/+ littermate controls. Shown in Figure 6A, T1-alpha staining was widespread in cells lining the distal airspaces in Sema3A+/+ lungs at E17.5, but expression appeared attenuated in lungs from Sema3A-/- animals. Western blotting of whole lung homogenates was used to confirm reduced expression of both T1-alpha and another ATI protein, Aqp-5, in lungs from Sema3A-/- mice (Figure 6B). Additionally, ATI were seen less frequently by TEM in lung sections from Sema3A-/- mice, as compared with Sema3A+/+ littermate controls (Figure 5B). Taken together, these data support a role for Sema3A in maturation and/or differentiation of the distal lung epithelium during development.
A. Reduced immunostaining for the type I alveolar epithelial cell marker, T1-alpha (red), is seen in lung from a Sema3A-/- mouse at E17.5 (right) as compared with a Sema3A+/+ littermate control (left). Nuclei are counterstained with Fast Yellow (green). Results are representative of 3 animals/group. (Magnification = 10x). B. Western blotting demonstrates decreased expression of both T1-alpha (left) and Aqp5 (right) protein in lung homogenate from Sema3A-/- animals as compared with Sema3A+/+ littermate controls. Results are representative of 7-9 animals/genotype.
Although first identified as a mediator of axonal pathfinding during morphogenesis of the peripheral nervous system , , several studies support a role for Sema3A in development and patterning of non-neuronal tissues, including salivary gland, ureter, and kidney , , , , . Prior reports demonstrated that exogenous Sema3A protein attenuated branching morphogenesis of E11.5 fetal lung explants maintained in culture , , but the role of Sema3A in lung development has not been fully characterized. Using in vivo loss of function modeling, we show here that Sema3A signals modulate distal lung epithelial cell development and postnatal alveolarization.
Using a tissue binding assay and an AP-Nrp1ecto probe, our data demonstrate patterns of early postnatal pulmonary Sema3A protein expression that are comparable with previously reported data using in situ hybridization  or immunohistochemistry  for Sema3A localization. Because Sema3A is a secreted protein, we also localized sites of expression for Sema3A receptor complexes, by hybridizing lung tissue sections with an AP-Sema3A fusion protein. The alveolar pattern of AP-Sema3A binding to lung sections harvested from P1 mice was similar to previously reported Nrp-1 gene expression assessed using in situ hybridization during late embryogenesis . Our results extend previous observations by demonstrating that a subset of Nrp-1 expressing cells in the lung periphery are of epithelial origin, since they co-express pro-SPC.
Because targeted deletion of Sema3A was associated with significant lethality following the transition to air breathing, we evaluated fetal lungs from Sema3A-/- mice for both structural abnormalities and disruption of distal epithelial maturation and differentiation. Alveolar septae in lungs from Sema3A-/- animals at E17.5 were thickened with reduced distal airspace. In addition, morphologic characterization suggested incomplete or delayed maturation and/or differentiation of alveolar epithelial cells. Perinatal lethality from respiratory failure has been reported after genetic deletion of the ATI protein T1-alpha, and in several murine models of transgenic misexpression or deletion of transcription factors which disrupt distal pulmonary epithelial cell development , , , , , , . Mortality in these prior reports has been linked with either dysregulation of surfactant gene expression and function , ,  or a reduction in Type I alveolar epithelial cell development , , . It is of interest to note that in at least two of these previously reported models, downregulation of Sema3A expression was detected using microarray analysis of lung tissue homogenate. In the first instance, significantly decreased Sema3A transcript was found after pulmonary misexpression of the epithelial specific Ets transcription factor, ELF5. ELF5 has been reported to repress distal epithelial specification and differentiation in the lung in a manner that is tightly developmentally regulated . More recently, reduced Sema3A gene expression was noted following genetic deletion of the transcriptional regulator, coactivator-associated arginine methyltransferase I (CARM1). The phenotype of late stage fetal lungs from CARM1 null mice was remarkably similar to what we observed in Sema3A null animals, with thickened alveolar walls, and attenuated differentiation of ATI cells . It is perhaps not surprising that the pulmonary phenotype of Sema3A-/- mice is less severe than what has been reported after disruption of factors that transcriptionally regulate the differentiation of lung epithelium , , , , . The finding that not all Sema3A-/- mice die immediately after birth suggests alternative pathways may compensate for the effects of Sema3A deletion on epithelial cell maturation and/or differentiation. This speculation is supported by the variable mortality reported for targeted deletions of Sema3A generated in differing genetic backgrounds , .
In mice, as in humans, the formation of alveolar septae occurs largely during postnatal life . Interestingly, the few Sema3A-/- mice surviving to P14 exhibited profound airspace enlargement, and MLI remained significantly increased in the rare animals surviving to adulthood. Signaling initiated by Sema3A requires the expression of its obligate co-receptor, neuropilin-1 (Nrp-1). Constitutive genetic deletion of Nrp-1 in mice results in embryonic lethality by E12.5, thus a definitive requirement for Nrp-1 in alveolar epithelial maturation and differentiation has not been determined. However, we previously reported that conditional deletion of Nrp-1 in the alveolar epithelium of one week old mice led to airspace enlargement in adulthood , supporting a potential role for epithelial Sema3A-Nrp-1 signaling in the processes controlling lung septation. We have not yet determined how disruption of Sema3A-induced distal epithelial cell maturation and/or differentiation might attenuate postnatal alveolar septation, although a recent report by Srisuma et al. suggested that primary abnormalities in ATII may impair epithelial-mesenchymal interactions coordinating elastogenesis and proper airspace formation .
Sema3A deletion could also impair postnatal alveolarization by pathways independent of those mediating epithelial differentiation. Nrp-1 expression is not restricted to epithelium, and prior reports demonstrate that Sema3A-Nrp-1 signals regulate angioblast migration and vascular patterning , , , as well as differentiation of vascular precursors to endothelial cells . It has long been recognized that alveolar septation is always associated with capillary invasion, and pulmonary vascular development must match epithelial morphogenesis to ensure optimal gas exchange in the lung. Endothelial Nrp-1 mediates signaling of both Sema3A and vascular endothelial growth factor (VEGF), and altered VEGF expression has been shown to profoundly influence both lung alveolarization and vascularization , . Loss of Sema3A could therefore impair distal lung homeostasis by disrupting the finely tuned balance between Sema3A- and VEGF-induced Nrp-1 signals in the developing vasculature. We did not detect significant differences in expression of mRNA for a panel of endothelial genes, including VEGFR2/flk-1, PECAM, flt4, ESAM-1, VEGF-A, or VEGF-C, in lung homogenate from E17.5 Sema3A-/- animals and wild-type littermate controls (data not shown). This suggests that endothelial cell number may not be altered in the absence of Sema3A, but additional experiments will be required to determine whether Sema3A plays a role in vascular patterning, or apposition of the vasculature and maturing alveolar epithelium.
Prior reports demonstrate that Sema3A and Nrp-1 signaling in extra-pulmonary tissues can influence multiple processes that may be critical for lung morphogenesis , , including cell viability and proliferation, fate specification, motility, and matrix adhesion , , , , . Our data are the first to suggest that loss of Sema3A signaling temporally regulates cell death during distal lung development. Because dysregulation of lung structural cell proliferation  and death , ,  have been shown to play an important role in the pathogenesis of emphysema in experimental models, Sema3A signals may therefore also be important determinants of plasticity following lung injury and alveolar remodeling. Consistent with this hypothesis, we recently demonstrated that conditional deletion of Nrp-1 in the distal lung epithelium of adult mice augmented both epithelial cell death and airspace enlargement in response to chronic cigarette smoke exposure .
In summary, these data support a significant role for Sema3A in late fetal and early postnatal lung development. Perinatal lethality of Sema3A-/- mice was linked with reduced expression of ATI markers, and ATII cells exhibited some features characteristic of impaired maturation, although surfactant production was not grossly impaired in the days prior to birth. Additional studies will be required to determine whether these phenotypic epithelial cell changes are responsible for disruption of alveolar septation in Sema3A-/- animals. Defining how Sema3A influences structural and functional plasticity of the developing lung is a critical first step for determining if this pathway can be exploited to develop innovative strategies for repair after acute or chronic lung injury.
The authors are grateful to Alex Kolodkin and David Ginty for their generous support with reagents and scientific guidance, to Machiko Ikegami for graciously assisting with satPC measurements in lung tissue, and to Lawrence Nogee for his kind consultative advice.
Conceived and designed the experiments: PMB TST MJD CH JMS SM-M. Performed the experiments: PMB MJD CH JMS. Analyzed the data: PMB TST JMS. Contributed reagents/materials/analysis tools: PMB TST MJD JMS SM-M. Wrote the paper: PMB.
- 1. Hinck L (2004) The versatile roles of “axon guidance” cues in tissue morphogenesis. Dev Cell 7: 783–793.
- 2. Neufeld G, Shraga-Heled N, Lange T, Guttmann-Raviv N, Herzog Y, et al. (2005) Semaphorins in cancer. Front Biosci 10: 751–760.
- 3. Tran TS, Rubio ME, Clem RL, Johnson D, Case L, et al. (2009) Secreted semaphorins control spine distribution and morphogenesis in the postnatal CNS. Nature 462: 1065–1069.
- 4. Kaneko S, Iwanami A, Nakamura M, Kishino A, Kikuchi K, et al. (2006) A selective Sema3A inhibitor enhances regenerative responses and functional recovery of the injured spinal cord. Nat Med 12: 1380–1389.
- 5. Suzuki K, Kumanogoh A, Kikutani H (2008) Semaphorins and their receptors in immune cell interactions. Nat Immunol 9: 17–23.
- 6. Schwarz Q, Maden CH, Vieira JM, Ruhrberg C (2009) Neuropilin 1 signaling guides neural crest cells to coordinate pathway choice with cell specification. Proc Natl Acad Sci U S A 106: 6164–6169.
- 7. Tran TS, Kolodkin AL, Bharadwaj R (2007) Semaphorin regulation of cellular morphology. Annu Rev Cell Dev Biol 23: 263–292.
- 8. Kolodkin AL, Levengood DV, Rowe EG, Tai YT, Giger RJ, et al. (1997) Neuropilin is a semaphorin III receptor. Cell 90: 753–762.
- 9. Chen H, He Z, Tessier-Lavigne M (1998) Axon guidance mechanisms: semaphorins as simultaneous repellents and anti-repellents. Nat Neurosci 1: 436–439.
- 10. Neufeld G, Cohen T, Shraga N, Lange T, Kessler O, et al. (2002) The neuropilins: multifunctional semaphorin and VEGF receptors that modulate axon guidance and angiogenesis. Trends Cardiovasc Med 12: 13–19.
- 11. He Z, Tessier-Lavigne M (1997) Neuropilin is a receptor for the axonal chemorepellent Semaphorin III. Cell 90: 739–751.
- 12. Polleux F, Morrow T, Ghosh A (2000) Semaphorin 3A is a chemoattractant for cortical apical dendrites. Nature 404: 567–573.
- 13. Marin O, Yaron A, Bagri A, Tessier-Lavigne M, Rubenstein JL (2001) Sorting of striatal and cortical interneurons regulated by semaphorin-neuropilin interactions. Science 293: 872–875.
- 14. Bagnard D, Vaillant C, Khuth ST, Dufay N, Lohrum M, et al. (2001) Semaphorin 3A-vascular endothelial growth factor-165 balance mediates migration and apoptosis of neural progenitor cells by the recruitment of shared receptor. J Neurosci 21: 3332–3341.
- 15. Catalano A, Caprari P, Rodilossi S, Betta P, Castellucci M, et al. (2004) Cross-talk between vascular endothelial growth factor and semaphorin-3A pathway in the regulation of normal and malignant mesothelial cell proliferation. Faseb J 18: 358–360.
- 16. Gagliardini V, Fankhauser C (1999) Semaphorin III can induce death in sensory neurons. Mol Cell Neurosci 14: 301–316.
- 17. Guttmann-Raviv N, Shraga-Heled N, Varshavsky A, Guimaraes-Sternberg C, Kessler O, et al. (2007) Semaphorin-3A and semaphorin-3F work together to repel endothelial cells and to inhibit their survival by induction of apoptosis. J Biol Chem 282: 26294–26305.
- 18. Ito T, Kagoshima M, Sasaki Y, Li C, Udaka N, et al. (2000) Repulsive axon guidance molecule Sema3A inhibits branching morphogenesis of fetal mouse lung. Mech Dev 97: 35–45.
- 19. Le A, Zielinski R, He C, Crow MT, Biswal S, et al. (2009) Pulmonary epithelial neuropilin-1 deletion enhances development of cigarette smoke-induced emphysema. Am J Respir Crit Care Med 180: 396–406.
- 20. Taniguchi M, Yuasa S, Fujisawa H, Naruse I, Saga S, et al. (1997) Disruption of semaphorin III/D gene causes severe abnormality in peripheral nerve projection. Neuron 19: 519–530.
- 21. Behar O, Golden JA, Mashimo H, Schoen FJ, Fishman MC (1996) Semaphorin III is needed for normal patterning and growth of nerves, bones and heart. Nature 383: 525–528.
- 22. McGrath-Morrow S, Lauer T, Yee M, Neptune E, Podowski M, et al. (2009) Nrf2 increases survival and attenuates alveolar growth inhibition in neonatal mice exposed to hyperoxia. Am J Physiol Lung Cell Mol Physiol 296: L565–573.
- 23. Feiner L, Koppel AM, Kobayashi H, Raper JA (1997) Secreted chick semaphorins bind recombinant neuropilin with similar affinities but bind different subsets of neurons in situ. Neuron 19: 539–545.
- 24. Metzger DE, Stahlman MT, Shannon JM (2008) Misexpression of ELF5 disrupts lung branching and inhibits epithelial differentiation. Dev Biol 320: 149–160.
- 25. Mason RJ, Nellenbogen J, Clements JA (1976) Isolation of disaturated phosphatidylcholine with osmium tetroxide. J Lipid Res 17: 281–284.
- 26. Chung L, Yang TL, Huang HR, Hsu SM, Cheng HJ, et al. (2007) Semaphorin signaling facilitates cleft formation in the developing salivary gland. Development 134: 2935–2945.
- 27. Reidy KJ, Villegas G, Teichman J, Veron D, Shen W, et al. (2009) Semaphorin3a regulates endothelial cell number and podocyte differentiation during glomerular development. Development 136: 3979–3989.
- 28. Tufro A, Teichman J, Woda C, Villegas G (2008) Semaphorin3a inhibits ureteric bud branching morphogenesis. Mech Dev 125: 558–568.
- 29. Kagoshima M, Ito T, Kitamura H, Goshima Y (2001) Deverse gene expression and function of semaphorins in developing lung: positive and negative regulatory roles of semaphorins in lung branching morphogenesis. Genes to Cells 6: 559–571.
- 30. Dang TP, Eichenberger S, Gonzalez A, Olson S, Carbone DP (2003) Constitutive activation of Notch3 inhibits terminal epithelial differentiation in lungs of transgenic mice. Oncogene 22: 1988–1997.
- 31. Martis PC, Whitsett JA, Xu Y, Perl AK, Wan H, et al. (2006) C/EBPalpha is required for lung maturation at birth. Development 133: 1155–1164.
- 32. O'Brien KB, Alberich-Jorda M, Yadav N, Kocher O, Diruscio A, et al. (2010) CARM1 is required for proper control of proliferation and differentiation of pulmonary epithelial cells. Development 137: 2147–2156.
- 33. Wan H, Kaestner KH, Ang SL, Ikegami M, Finkelman FD, et al. (2004) Foxa2 regulates alveolarization and goblet cell hyperplasia. Development 131: 953–964.
- 34. Wan H, Luo F, Wert SE, Zhang L, Xu Y, et al. (2008) Kruppel-like factor 5 is required for perinatal lung morphogenesis and function. Development 135: 2563–2572.
- 35. Ramirez MI, Millien G, Hinds A, Cao Y, Seldin DC, et al. (2003) T1alpha, a lung type I cell differentiation gene, is required for normal lung cell proliferation and alveolus formation at birth. Dev Biol 256: 61–72.
- 36. Basseres DS, Levantini E, Ji H, Monti S, Elf S, et al. (2006) Respiratory failure due to differentiation arrest and expansion of alveolar cells following lung-specific loss of the transcription factor C/EBPalpha in mice. Mol Cell Biol 26: 1109–1123.
- 37. Wan H, Xu Y, Ikegami M, Stahlman MT, Kaestner KH, et al. (2004) Foxa2 is required for transition to air breathing at birth. Proc Natl Acad Sci U S A 101: 14449–14454.
- 38. Yadav N, Lee J, Kim J, Shen J, Hu MC, et al. (2003) Specific protein methylation defects and gene expression perturbations in coactivator-associated arginine methyltransferase 1-deficient mice. Proc Natl Acad Sci U S A 100: 6464–6468.
- 39. Warburton D, El-Hashash A, Carraro G, Tiozzo C, Sala F, et al. (2010) Lung organogenesis. Curr Top Dev Biol 90: 73–158.
- 40. Srisuma S, Bhattacharya S, Simon DM, Solleti SK, Tyagi S, et al. (2010) Fibroblast growth factor receptors control epithelial-mesenchymal interactions necessary for alveolar elastogenesis. Am J Respir Crit Care Med 181: 838–850.
- 41. Bates D, Taylor GI, Minichiello J, Farlie P, Cichowitz A, et al. (2003) Neurovascular congruence results from a shared patterning mechanism that utilizes Semaphorin3A and Neuropilin-1. Dev Biol 255: 77–98.
- 42. Shoji W, Isogai S, Sato-Maeda M, Obinata M, Kuwada JY (2003) Semaphorin3a1 regulates angioblast migration and vascular development in zebrafish embryos. Development 130: 3227–3236.
- 43. Torres-Vazquez J, Gitler AD, Fraser SD, Berk JD, Van NP, et al. (2004) Semaphorin-plexin signaling guides patterning of the developing vasculature. Dev Cell 7: 117–123.
- 44. Cimato T, Beers J, Ding S, Ma M, McCoy JP, et al. (2009) Neuropilin-1 identifies endothelial precursors in human and murine embryonic stem cells before CD34 expression. Circulation 119: 2170–2178.
- 45. Gerber HP, Hillan KJ, Ryan AM, Kowalski J, Keller GA, et al. (1999) VEGF is required for growth and survival in neonatal mice. Development 126: 1149–1159.
- 46. Jakkula M, Le Cras TD, Gebb S, Hirth KP, Tuder RM, et al. (2000) Inhibition of angiogenesis decreases alveolarization in the developing rat lung. Am J Physiol Lung Cell Mol Physiol 279: L600–607.
- 47. Morrisey EE, Hogan BL (2010) Preparing for the first breath: genetic and cellular mechanisms in lung development. Dev Cell 18: 8–23.
- 48. Yao H, Yang SR, Edirisinghe I, Rajendrasozhan S, Caito S, et al. (2008) Disruption of p21 attenuates lung inflammation induced by cigarette smoke, LPS, and fMLP in mice. Am J Respir Cell Mol Biol 39: 7–18.
- 49. Giordano RJ, Lahdenranta J, Zhen L, Chukwueke U, Petrache I, et al. (2008) Targeted induction of lung endothelial cell apoptosis causes emphysema-like changes in the mouse. J Biol Chem 283: 29447–29460.
- 50. Taraseviciene-Stewart L, Scerbavicius R, Choe KH, Moore M, Sullivan A, et al. (2005) An animal model of autoimmune emphysema. Am J Respir Crit Care Med 171: 734–742.
- 51. Tuder RM, Zhen L, Cho CY, Taraseviciene-Stewart L, Kasahara Y, et al. (2003) Oxidative stress and apoptosis interact and cause emphysema due to vascular endothelial growth factor receptor blockade. Am J Respir Cell Mol Biol 29: 88–97.