Regulation of migration of primary prostate epithelial cells by secreted factors from prostate stromal cells

Stromal-epithelial interactions, which regulate the migration of prostate epithelial cells, play an important role in prostate development, prostatic hyperplasia, and prostate cancer. The objective of this study was to determine how the prostate stroma stimulates the migration of primary prostate epithelial cells (PECs). In the Boyden chamber assay, PEC migration was strongly induced by the conditioned medium of primary prostate stromal cells (PSC-CM). Stimulation of PEC migration depended on the concerted action of adhesion and motility factors in the PSC-CM. Immobilized proteins from PSC-CM mediated adhesion, spreading, and head-to-tail polarization of PECs. Migration induced by immobilized PSC-CM proteins was significantly increased by hepatocyte growth factor/scatter factor (HGF/SF). Inhibition of P13-kinase or Src-family kinases, but not MEK or PLCchi, abolished migration in the Boyden chamber assay. Consistent with their concerted activity in migration assays, the combination of adhesion and motility factors was required for efficient activation of the P13-kinase/Akt pathway. HGF/SF in the PSC-CM was the principal stimulator of the P13-kinase/Akt pathway and an important mediator of PSC-CM-induced PEC migration. In conclusion, our data show that the migration of primary PECs is regulated by the P13-kinase and Src-family kinase signaling pathways and that the activation of the P13-kinase pathway requires adhesion and motility factors from the prostate stroma.     

Human prostate stromal cells stimulate increased PSA production in DHEA-treated prostate cancer epithelial cells

Dehydroepiandrosterone (DHEA) is commonly used as a dietary supplement and may affect prostate pathophysiology when metabolized to androgens and/or estrogens. Human prostate LAPC-4 cancer cells with a wild type androgen receptor (AR) were treated with DHEA, androgens dihydrotestosterone (DHT), T, or R1881), and E(2) and assayed for prostate specific antigen (PSA) protein and gene expression. In LAPC-4 monocultures, DHEA and E(2) induced little or no increase in PSA protein or mRNA expression compared to androgen-treated cells. When prostate cancer-associated (6S) stromal cells were added in coculture, DHEA stimulated LAPC-4 cell PSA protein secretion to levels approaching induction by DHT. Also, DHEA induced 15-fold more PSA mRNA in LAPC-4 cocultures than in monocultures. LAPC-4 proliferation was increased 2-3-fold when cocultured with 6S stromal cells regardless of hormone treatment. DHEA-treated 6S stromal cells exhibited a dose- and time-dependent increase in T secretion, demonstrating stromal cell metabolism of DHEA to T. Coculture with non-cancerous stroma did not induce LAPC-4 PSA production, suggesting a differential modulation of DHEA effect in a cancer-associated prostate stromal environment. This coculture model provides a research approach to reveal detailed endocrine, intracrine, and paracrine signaling between stromal and epithelial cells that regulate tissue homeostasis within the prostate, and the role of the tumor microenvironment in cancer progression.     

Suppressed prostate epithelial development with impaired branching morphogenesis in mice lacking stromal fibromuscular androgen receptor

Using the cre-loxP system, we generated a new mouse model [double stromal androgen receptor knockout (dARKO)] with selectively deleted androgen receptor (AR) in both stromal fibroblasts and smooth muscle cells, and found the size of the anterior prostate (AP) lobes was significantly reduced as compared with those from wild-type littermate controls. The reduction in prostate size of the dARKO mouse was accompanied by impaired branching morphogenesis and partial loss of the infolding glandular structure. Further dissection found decreased proliferation and increased apoptosis of the prostate epithelium in the dARKO mouse AP. These phenotype changes were further confirmed with newly established immortalized prostate stromal cells (PrSC) from wild-type and dARKO mice. Mechanistically, IGF-1, placental growth factor, and secreted phosphoprotein-1 controlled by stromal AR were differentially expressed in PrSC-wt and PrSC-ARKO. Moreover, the conditioned media (CM) from PrSC-wt promoted prostate epithelium growth significantly as compared with CM from PrSC-dARKO. Finally, adding IGF-1/placental growth factor recombinant proteins into PrSC-dARKO CM was able to partially rescue epithelium growth. Together, our data concluded that stromal fibromuscular AR could modulate epithelium growth and maintain cellular homeostasis through identified growth factors.     

cGMP enhances the sonic hedgehog response in neural plate cells.

The elaboration of distinct cell types during development is dependent on a small number of inductive molecules. Among these inducers is Sonic hedgehog (Shh), which, in combination with other factors, patterns the dorsoventral (DV) axis of the nervous system. The response of a cell is dependent in part on its complement of cyclic nucleotides. cAMP antagonizes Shh signaling, and we examined the influence of cGMP on the Shh response. Cells in chick neural plate explants respond to Shh by differentiating into ventral neural-cell types. Exposure of intermediate-zone explants to cGMP analogs enhanced their response to Shh in a dose-dependent manner. The Shh response was also enhanced in dorsal-zone explants exposed to chick natriuretic peptide (chNP), which stimulates cGMP production by membrane-bound guanylate cyclase (mGC). Addition of chNP to intermediate-zone explants did not enhance the Shh response, consistent with a reported lack of mGC in this region of the neural tube. Finally, the presence of a nitric oxide (NO)-sensitive guanylate cyclase (GC) was established by demonstrating cGMP immunoreactivity in neural tissue following NO stimulation of whole chick embryos. Intracellular levels of cGMP and cAMP may thus provide a mechanism through which other factors modulate the Shh response during neural development.     

Estrogen metabolism by primary cultures of rat ventral prostate epithelial and stromal cells

Estrogen metabolism was examined in primary cultures of rat ventral prostate epithelial and stromal cells developed from young (approximately 3 weeks old) animals. Supraphysiologic concentrations (50 nM) of tritium-labelled estradiol (E2) and estrone (E1) were incubated separately with each cell type and the metabolites formed were measured at selected time points over a 24 h period. The metabolites were analyzed using high performance liquid chromatography. Epithelial cells exhibited an equal capability to interconvert E2 and E1 thus demonstrating the presence of similar oxidative and reductive activities for 17 beta-hydroxysteroid oxidoreductase (17 beta-HSOR) [0.45 and 0.40 pmol/3 h/microgram DNA respectively]. In contrast, stromal cells showed a 6-fold lower rate of oxidation of E2 to E1 (0.08 pmol/3 h/microgram DNA) but exhibited an approx 5-fold higher rate of reduction of E1 to E2 (1.81 pmol/3 h/microgram DNA). Estriol (E3) formation from either substrate was not detected in the two cell types. The results demonstrate that rat ventral prostate epithelial cells have similar capabilities to form or remove biologically active E2. In contrast, prostate stromal cells exhibited a preferential capability to form and possibly maintain high levels of biologically active E2. These findings are discussed with reference to the actions of estrogens on prostate epithelial-stromal cellular interactions.     

Inhibition of sonic hedgehog signaling in vivo results in craniofacial neural crest cell death

BACKGROUND: Sonic hedgehog (Shh) is well known for its role in patterning tissues, including structures of the head. Haploinsufficiency for SHH in humans results in holoprosencephaly, a syndrome characterized by facial and forebrain abnormalities. Shh null mice have cyclopia and loss of branchial arch structures. It is unclear, however, whether these phenotypes arise solely from the early function of Shh in patterning midline structures, or whether Shh plays other roles in head development. RESULTS: To address the role of Shh after floorplate induction, we inhibited Shh signaling by injecting hybridoma cells that secrete a function-blocking anti-Shh antibody into the chick cranial mesenchyme. The antibody subsequently bound to Shh in the floorplate, notochord, and the pharyngeal endoderm. Perturbation of Shh signaling at this stage resulted in a significant reduction in head size after 1 day, loss of branchial arch structures after 2 days, and embryos with smaller heads after 7 days. Cell death was significantly increased in the neural tube and neural crest after 1 day, and neural crest cell death was not secondary to the loss of neural tube cells. CONCLUSIONS: Reduction of Shh signaling after neural tube closure resulted in a transient decrease in neural tube cell proliferation and an extensive increase in cell death in the neural tube and neural crest, which in turn resulted in decreased head size. The phenotypes observed after reduction of Shh are similar to those observed after cranial neural crest ablation. Thus, our results demonstrate a role for Shh in coordinating the proliferation and survival of cells of the neural tube and cranial neural crest.     

Anoikis resistance in mammary epithelial cells is mediated by semaphorin 7a

Semaphorin-7a (SEMA7A), best known as a neuroimmune molecule, plays a diverse role in many cellular processes and pathologies. Here, we show that SEMA7A promotes anoikis resistance in cultured mammary epithelial cells through integrins and activation of pro-survival kinase AKT, which led us to investigate a role for SEMA7A during postpartum mammary gland involution—a normal developmental process where cells die by anoikis. Our results reveal that SEMA7A is expressed on live mammary epithelial cells during involution, that SEMA7A expression is primarily observed in α6-integrin expressing cells, and that luminal progenitor cells, specifically, are decreased in mammary glands of SEMA7A−/− mice during involution. We further identify a SEMA7A-α6/β1-integrin dependent mechanism of mammosphere formation and chemoresistance in mammary epithelial cells and suggest that this mechanism is relevant for recurrence in breast cancer patients.Subject terms: Breast cancer, Cancer stem cells, Apoptosis, Mammary stem cells     

Discovery of sonic hedgehog expression in postnatal growth plate chondrocytes: differential regulation of sonic and Indian hedgehog by retinoic acid

Sonic hedgehog (Shh) is a key signal protein in early embryological patterning of limb bud development. Its analog, Indian hedgehog (Ihh), primarily expressed during early cartilage development in prehypertrophic chondrocytes, regulates proliferation and suppresses terminal differentiation of postnatal growth plate (GP) chondrocytes. We report here for the first time that both Shh and Ihh mRNA are expressed in the GP of rapidly growing 6-week-old broiler-strain chickens. They are also expressed in other tissues such as articular chondrocytes, kidney, and bone. In situ hybridization and RT-PCR analyses reveal Shh in all zones of the GP, with peak expression in late hypertrophy. Using primary cultures of GP chondrocytes in serum-containing medium, we followed the patterns of Shh and Ihh mRNA expression as the cultures matured and mineralized. We find a cyclical expression of both hedgehog genes during the early period of culture development between day 10 and 14; when one is elevated, the other tended to be suppressed, suggesting that the two hedgehogs may play complementary roles during GP development. Retinoic acid (RA), a powerful modulator of gene expression in cell differentiation, stimulates GP chondrocytes toward terminal differentiation, enhancing mineral formation. We find that RA strongly suppresses Ihh, but enhances expression of Shh in this system. While Ihh suppresses maturation of GP chondrocytes to hypertrophy, we hypothesize that Shh acts to push these cells toward hypertrophy.     

Sonic hedgehog is indirectly required for intraretinal axon pathfinding by regulating chemokine expression in the optic stalk

Successful axon pathfinding requires both correct patterning of tissues, which will later harbor axonal tracts, and precise localization of axon guidance cues along these tracts at the time of axon outgrowth. Retinal ganglion cell (RGC) axons grow towards the optic disc in the central retina, where they turn to exit the eye through the optic nerve. Normal patterning of the optic disc and stalk and the expression of guidance cues at this choice point are necessary for the exit of RGC axons out of the eye. Sonic hedgehog (Shh) has been implicated in both patterning of ocular tissue and direct guidance of RGC axons. Here, we examine the precise spatial and temporal requirement for Hedgehog (Hh) signaling for intraretinal axon pathfinding and show that Shh acts to pattern the optic stalk in zebrafish but does not guide RGC axons inside the eye directly. We further reveal an interaction between the Hh and chemokine pathways for axon guidance and show that cxcl12a functions downstream of Shh and depends on Shh for its expression at the optic disc. Together, our results support a model in which Shh acts in RGC axon pathfinding indirectly by regulating axon guidance cues at the optic disc through patterning of the optic stalk.     

Regulation of cavernous nerve injury-induced apoptosis by sonic hedgehog

Thirty to eighty-seven percent of patients treated by radical prostatectomy experience erectile dysfunction (ED). The reduced efficacy of treatments in this population makes novel therapeutic approaches to treat ED essential. We propose that abundant apoptosis observed in penile smooth muscle when the cavernous nerve (CN) is cut (mimicking the neural injury which can result from prostatectomy) is a major contributing factor to ED development. We hypothesize that decreased Sonic hedgehog (SHH) signaling is a cause of ED in neurological models of impotence by increasing apoptosis in penile smooth muscle. We examined this hypothesis in a bilateral CN injury model of ED. We found that the active form of SHH protein was significantly decreased 1.2-fold following CN injury, that SHH inhibition causes a 12-fold increase in smooth muscle apoptosis in the penis, and that SHH treatment at the time of CN injury was able to decrease CN injury-induced apoptosis (1-3-fold) in a dose-dependent manner. These results show that SHH stabilizes the alterations of the corpora cavernosal smooth muscle following nerve injury.     

Activation of fgf4 gene expression in the myotomes is regulated by myogenic bHLH factors and by sonic hedgehog

The Fgf4 gene encodes an important signaling molecule which is expressed in specific developmental stages, including the inner cell mass of the blastocyst, the myotomes, and the limb bud apical ectodermal ridge (AER). Using a transgenic approach, we previously identified overlapping but distinct enhancer elements in the Fgf4 3' untranslated region necessary and sufficient for myotome and AER expression. Here we have investigated the hypothesis that Fgf4 is a target of myogenic bHLH factors. We show by mutational analysis that a conserved E box located in the Fgf4 myotome enhancer is required for Fgf4-lacZ expression in the myotomes. A DNA probe containing the E box binds MYF5, MYOD, and bHLH-like activities from nuclear extracts of differentiating C2-7 myoblast cells, and both MYF5 and MYOD can activate gene expression of reporter plasmids containing the E-box element. Analyses of Myf5 and MyoD knockout mice harboring Fgf4-lacZ transgenes show that Myf5 is required for Fgf4 expression in the myotomes, while MyoD is not, but MyoD can sustain Fgf4 expression in the ventral myotomes in the absence of Myf5. Sonic hedgehog (Shh) signaling has been shown to have an essential inductive function in the expression of Myf5 and MyoD in the epaxial myotomes, but not in the hypaxial myotomes. We show here that expression of an Fgf4-lacZ transgene in Shh-/- embryos is suppressed not only in the epaxial but also in the hypaxial myotomes, while it is maintained in the AER. This suggests that Shh mediates Fgf4 activation in the myotomes through mechanisms independent of its role in the activation of myogenic factors. Thus, a cascade of events, involving Shh and bHLH factors, is responsible for activating Fgf4 expression in the myotomes in a spatial- and temporal-specific manner.     

Inhibition of histone deacetylases is the major pathway mediated by astaxanthin to antagonize LPS‐induced inflammatory responses in mammary epithelial cells

Mastitis is a major inflammatory response of the mammary gland due to various pathogenic invasions and is a serious disease that affects the production yield and health status of cows. Astaxanthin (AST), a xanthophyll carotenoid, is a secondary metabolite synthesized by microalgae and yeasts that has been reported to suppress various inflammatory responses. However, the protective effect of AST on lipopolysaccharide (LPS)‐induced mammary epithelial cells has not yet been reported. The present study results indicated that AST treatment markedly attenuated the oxidative stress markers and nitric oxide (NO) while improving the anti‐oxidant enzymes in LPS exposed cells. On the other hand, LPS‐exposed cells showed nuclear translocation of nuclear factor‐κB (NF‐κB) with the activation of inflammatory cytokines such as monocyte chemoattractant protein‐1, tumor necrosis factor‐α, interferon‐γ, and interleukin‐6 (IL‐6). In addition, mRNA expression analysis revealed that the histone deacetylase (HDAC) ‐1, ‐2, ‐3, ‐6, ‐7 and pentraxin 3 (PTX3) expressions were increased in the LPS group. Furthermore, the activity of HDAC was increased to 2‐fold with a significant reduction in the histone acetyltransferase activity in cells exposed to LPS. However, AST was able to inhibit the nuclear translocation of NF‐κB with attenuated HDAC activity. Intriguingly, HDAC inhibition studies demonstrated that the cytokines such as IL‐4, IL‐8, granulocyte‐mcrophage colony stimulating factor, C‐reactive protein, IL‐17A, and IL‐22 were significantly suppressed which were upregulated in LPS treatment; while AST was found acting by improving the anti‐inflammatory cytokine IL‐10, and thioredoxin reductase levels. Collectively, these findings provide novel insights into the role of HDACs in regulating cellular processes involved in the pathogenesis of LPS‐induced mastitis as well as the potential use of AST as a therapeutic in treatment for controlling disease progression.     

Ongoing sonic hedgehog signaling is required for dorsal midline formation in the developing forebrain

The division of the mammalian forebrain into distinct left and right hemispheres represents a critical step in neural development. Several signaling molecules including sonic hedgehog (SHH), fibroblast growth factor 8 (FGF8), and bone morphogenetic proteins (BMPs) have been implicated in dorsal midline development, and prior work suggests that the organizing centers from which these proteins are secreted mutually regulate one another during development. To explore the role of the ventral organizing center in the formation of two hemispheres, we assessed dorsal midline development in Shh mutant embryos and in wildtype embryos treated with the SHH signaling inhibitor HhAntag. Collectively, our findings demonstrate that SHH signaling plays an important role in maintaining the normal expression patterns of Fgf8 and Bmp4 in the developing forebrain. We further show that FGF8 can induce the expression of Zic2, which is normally expressed at the midline and is required in vivo for hemispheric cleavage, suggesting that FGF signaling may stimulate dorsal midline development by inducing Zic2 expression.     

Cystic fibrosis transmembrane conductance regulator trafficking is mediated by the COPI coat in epithelial cells

Cystic fibrosis (CF) is caused by defects in the CF transmembrane conductance regulator (CFTR) that functions as a chloride channel in epithelial cells. The most common cause of CF is the abnormal trafficking of CFTR mutants. Therefore, understanding the cellular machineries that transit CFTR from the endoplasmic reticulum to the plasma membrane (PM) is important. The coat protein complex I (COPI) has been implicated in the anterograde and retrograde transport of proteins and lipids between the endoplasmic reticulum and the Golgi. Here, we investigated the role of COPI in CFTR trafficking. Blocking COPI recruitment to membranes by expressing an inactive form of the GBF1 guanine nucleotide exchange factor for ADP-ribosylation factor inhibits CFTR trafficking to the PM. Similarly, inhibiting COPI dissociation from membranes by expressing a constitutively active ADP-ribosylation factor 1 mutant arrests CFTR within disrupted Golgi elements. To definitively explore the relationship between COPI and CFTR in epithelial cells, we depleted beta-COP from the human colonic epithelial cell HT-29Cl.19A using small interfering RNA. Beta-COP depletion did not affect CFTR synthesis but impaired its trafficking to the PM. The arrest occurred pre-Golgi as shown by reduced level of glycosylation. Importantly, decreased trafficking of CFTR had a functional consequence as cells depleted of beta-COP showed decreased cAMP-activated chloride currents. To explore the mechanism of COPI action in CFTR traffic we tested whether CFTR was COPI cargo. We discovered that the alpha-, beta-, and gamma-subunits of COPI co-immunoprecipitated with CFTR. Our results indicate that the COPI complex plays a critical role in CFTR trafficking to the PM.