Abstract
Airway mucus responses to subclinical infections may explain variations in progression of chronic lung diseases and differences in clinical expression of respiratory infections across individuals. Pneumocystis associates to more severe Chronic Obstructive Pulmonary Disease (COPD), asthma, respiratory distress of premature newborns, and is a consistent subclinical infection between 2 and 5 months of age when hospitalizations for respiratory cause and infant mortality are higher. This atypical fungus associates to increased mucin 5AC (MUC5AC), a central effector of Th2-type allergic inflammation, in infant lungs. However, mucus progression, expression of MUC5B essential for airway defense, and potential for pharmacologic modulation of mucus during Pneumocystis infection remain unknown. We measured MUC5B and Pneumocystis in infant lungs, and progression of mucin levels and effect of inhibition of the STAT6/FoxA2 mucus pathway using Kaempferol, a JAK/STAT6 inhibitor, in immunocompetent rats during Pneumocystis primary infection. Pneumocystis associated to increased MUC5B in infant lungs. Muc5b increased earlier and more abundantly than Muc5ac during experimental primary infection suggesting an acute defensive response against Pneumocystis as described against bacteria, while increased Muc5ac levels supports an ongoing allergic, Th2 lymphocyte-type response during primary Pneumocystis infection. Kaempferol partly reversed Muc5b stimulation suggesting limited potential for pharmacological modulation via the STAT6-FoxA2 pathway.
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Introduction
Airway mucus is a biological hydrogel barrier that protects the airway against physical, chemical and biological insults. Healthy mucus is composed by water (>90%) and by polysaccharides and proteins whose relative proportions determine rheological properties and may vary in airway disease impairing mucociliary clearance1,2. Changes in mucus composition can importantly alter mucus transport and airway clearance contributing to mucous plugging as in asthma3,4. Upregulated mucus is characteristic of chronic diseases like asthma and COPD2,5,6.
Mucins are the main structural components of mucus. They consist of high molecular weight proteins classified into gel-forming and tethered mucins. MUC5AC and MUC5B are the main gel-forming mucins. They are secreted and heavily glycosylated1,2 contributing to form a very adhesive gel blanket that lies over periciliary fluid and is mechanically propelled by airway cilia to clean the airways. MUC5B is more secreted by submucosal glands and MUC5AC by superficial airway epithelial cells2,7,8. Additional mucins, classified as tethered mucins, are associated to the surface of the airway epithelium. Mucus production is tightly controlled via nonspecific mucogenic pathways such as IL13/JAK/STAT6 that controls mucin expression by binding inhibition of transcriptional repressor FoxA2 to mucin promoters9, TNFα/NFκβ, IL1β/COX-2, the Gabaergic system, EGFR mediated signaling, and others5,10,11,12. Mucus hypersecretion suggests stimulation of mucogenic pathways10,11,12. MUC5AC secreted by goblet cells in the airway epithelium, is a central effector of allergic inflammation and is required for airway hyperreactivity7,13. This mucin was considered for many years the most abundant mucin in the pediatric airways. MUC5B however, has been recognized more recently to be far more abundant than MUC5AC in healthy and asthmatic children4 and in adults with pulmonary fibrosis where regulation via FoxA2 promoter binding has been documented14. MUC5B has an essential role in defense against bacterial pneumonia, and lack of this mucin severely affected infection-related survival in animal models8,10.
Pneumocystis, a fungus well-known by the severe pneumonia of immunocompromised individuals, associates to increased severity of Chronic Obstructive Pulmonary Disease (COPD)15, to respiratory distress syndrome of newborns16, and is likely the most frequent and consistent infection of early infancy17. This primary Pneumocystis infection of immunocompetent infants goes undetected and peaks between two and five months of age18,19,20,21 providing a particular epidemiologic context that coincides with the highest prevalence of infant hospitalizations for respiratory cause22,23. We have reported increased MUC5AC and CLCA1 associated to Pneumocystis primary infection in lungs of infants dying in the community19,24. Understanding the effect of Pneumocystis on mucin production and its controlling pathways is underscored by the epidemiological context of this fungal infection18,19,20,21 and by the demonstration that Pneumocystis primary infection induces a Th2 environment in the healthy lung25,26. MUC5AC has been recently described as an essential effector of the epithelial response to allergic inflammation7. Increased MUC5AC is consistent with the intense Th2 (allergic type) airway immune response25,26 and STAT6 pathway activation27 plus induction of mucus-related genes such as Muc5ac and Clca328 associated to mucus hypersecretion documented in animal models of Pneumocystis infection26,27,29. Of interest, anti-Muc5ac immune staining is able to recognize only a minimal fraction of the mucus that stains with Alcian blue, suggesting additional mucins are involved during Pneumocystis infection26. No studies of MUC5B expression in infant lungs or of the murine homolog gene Muc5b during Pneumocystis infection are available.
This work shows for the first time, that Pneumocystis associates to increased levels of MUC5B in infants, and replicates this finding in an experimental animal model of naturally acquired primary infection that resembles the mode of contagion and course of the primary infection in humans. We also show that pulmonary Muc5b occurs earlier and is more abundant that Muc5ac, that the mechanism of Muc5b hypersecretion partly depends on STAT6 stimulation by Pneumocystis -that inhibits FoxA2 repressor-, and that this mechanism can be reversed by pharmacological de-repression of FoxA2 using Kaempferol, a specific inhibitor of JAK3 that activates STAT630.
Results
MUC5B determinations in infant lungs
The clinical characteristics of infants whose autopsy lung biopsies were selected for this study were previously described19. Eight Pneumocystis-positive and eight control samples were randomly selected for analysis from a pool of 39 Pneumocystis-positive and 20 Pneumocystis-negative lung specimens. MUC5B protein levels increased in Pneumocystis-infected compared to non-infected infants (P < 0.001) (Fig. 1).
Muc5b and Muc5ac mRNA and protein levels in lungs of Pneumocystis primary infection experimental and control animals
mRNA levels of Muc5b were determined by qRT-PCR and compared with Muc5ac levels at each sacrifice point. mRNA levels of both mucins increased from day 60 and reached significance on day 75 (Fig. 2A,C). Of interest, the mRNA levels of Muc5b in the Pneumocystis-positive group increased over 10-fold than those of Muc5ac (Fig. 2E). Immunoblotting showed that protein expression levels of Muc5ac increased on day 75 (Fig. 2B), and Muc5b increased from day 60 reaching significance on days 60 and 75 (Fig. 2D). Muc5b protein levels were over 2-fold higher than those of Muc5ac in Pneumocystis-positive animals (Fig. 2F). Pneumocystis lung burden in these animals, estimated by qPCR of the Dihydrofolate Reductase (dhfr) gene of Pneumocystis, was characterized in previously published experiments26.
Immunohistochemistry for Muc5b and Muc5ac
Airways were classified according to diameter in bronchi (>250 μm) and bronchioles (<250 μm)31. Terminal bronchioles (<50 μm) were not observed in these microscopy slide sections. Muc5b was highly detected in bronchi of infected animals on days 45 and 75 of age compared to those of controls (Fig. 3A,B). Muc5b determinations on bronchioles of control and infected animals were not different (Fig. 3C). Signal for Muc5ac was not visualized in sections adjacent to those positive for Muc5b (Fig. 3D).
Effect of Kaempferol, a specific inhibitor of the JAK/STAT6 pathway, on Pneumocystis-induced STAT6 phosphorylation
The phosphorylation state of transcription factor STAT6 was evaluated in lung tissue using anti-Phospho STAT6 (P-STAT6) specific antibodies and Western Blot. P-STAT6 protein levels were increased in Pneumocystis-infected Kaempferol-untreated animals respect to control rats treated with saline. The Pneumocystis burden reached similar levels than in lungs where muc5ac26 and muc5b mucins were quantitated (Fig. 4A). The P-STAT6 stimulation effect of Pneumocystis was attenuated by Kaempferol as documented by the decrease in phosphorylation of STAT6 factor in Pneumocystis-infected animals receiving Kaempferol compared to those Pneumocystis-infected animals receiving saline (Fig. 4B,C).
Effect of Kaempferol in Pneumocystis-induced Muc5b expression
Mucus documented by AB/PAS staining and by immunohistochemistry with anti-Muc5b antibody in Pneumocystis infected rats receiving saline (Pc+) coincide in airway epithelium location (Fig. 5A & arrow in inset) and was attenuated by administration of Kaempferol (Fig. 5A). Muc5b mRNA levels increased in Pneumocystis-infected animals receiving saline and this increase was 6-fold higher when compared with Pneumocystis non-infected rats (Fig. 5B). Treatment with Kaempferol completely reversed this effect to the level of Pneumocystis non-infected rats receiving saline (Pc−, Fig. 5B). Muc5b protein expression increased 2-fold in the Pneumocystis infected group when compared with the non-infected controls (Fig. 5C). The changes induced by Kaempferol in Muc5b protein levels replicated at a lesser scale the Kaempferol effect in mRNA levels.
Effect of Pneumocystis in transcriptional regulation of Muc5b promoter
JAK/STAT6 pathway normally regulates mucin transcription through the repressor FoxA2 which binds to the respective mucin promoter to control transcription and consequently mucin mRNA levels. A highly conserved FoxA2 binding site was identified by comparison of DNA sequences of the human, mouse and rat Muc5b promoter regions. The presence of FoxA2 in this Muc5b promoter region was first confirmed using chromatin immunoprecipitation (ChIP). Binding of FoxA2 decreased in 0,5-fold in Pneumocystis-infected animals compared to controls (Pc− v/s Pc+) (Fig. 6A). Kaempferol partly reversed the effect of Pneumocystis (Pc+v/s Pc + K). No differences were detected in FoxA2 mRNA and protein levels analyzed from total RNA and protein extracts, after Kaempferol treatment (Fig. 6B,C). However, a significant decrease in FoxA2 nuclear protein levels was detected in animals infected with Pneumocystis receiving saline only (Fig. 6D,E). This effect of Pneumocystis in lowering nuclei FoxA2 levels was attenuated completely by Kaempferol (Fig. 6D,E).
Discussion
This work documents increased expression of MUC5B associated to Pneumocystis primary infection in autopsy lung samples from immunocompetent infants dying in the community (Fig. 1), and the progression of gel-forming mucins (Muc5b and Muc5ac), and potential for pharmacological reduction of mucus through the STAT6/FoxA2 pathway, in an animal model of primary infection by Pneumocystis.
We have previously documented increased MUC5AC associated to Pneumocystis in infant lung autopsy samples and that this increase was unrelated to common respiratory viruses19,24. This association has proven consistent19,24. This work ads to show that Pneumocystis strongly stimulates both main gel-forming mucins suggesting an altered mucus physiology during the primary infection1,19. Overproduction of MUC5B has also been associated with chronic obstructive pulmonary disease (COPD), and to the development of interstitial pulmonary fibrosis (IPF) in adults, and overproduction of MUC5AC with asthma2. The role and duration of Pneumocystis associated mucus changes in these medical conditions associated to Pneumocystis, remain to be determined.
Muc5b levels increased 10 to 15 times, and this increase occurred earlier than that of Muc5ac in animals in this study suggesting a faster Muc5b than Muc5ac response during Pneumocystis primary infection (Fig. 2A–D), and that Muc5b may play a defensive role against Pneumocystis as recently described for bacterial pathogens8. Of interest, secreted MUC5AC increased later in the infection course (Fig. 2A,B). This progression is consistent with the findings that the primary infection by Pneumocystis can drive the development and progression of asymptomatic asthmatic-type airway pathology as described25,26, and is also consistent with the role of Muc5ac in the development of airway hyperreactivity7 adding to the possibility of altered airway responses during the course of this primary infection19,26. Muc5B was documented histologically in bronchi but not in bronchioles (Fig. 3). Goblet, mucus producing, cells are abundant in bronchi and rare in bronchioles and findings suggest stimulation of existing goblet cells rather than metaplasia during the time course of Pneumocystis infection evaluated in these experiments. This animal model reproduces the natural route of contagion and progression of this fungal infection in humans32, and documents an ongoing immune response throughout the course of the Pneumocystis primary infection26. Translating these findings to the human situation suggests that Pneumocystis may prime the lung to altered responses to co-infecting respiratory pathogens and support the hypothesis that subclinical, unnoticed, Pneumocystis may contribute to the higher incidence of respiratory morbidity and increased rate of hospitalizations for respiratory cause that occurs in infants between 2 and 5 months of age22,23. Respiratory viruses affect infants at any age. Pneumocystis however, is highly frequent between 2 and 5 months of age and is rare after the age of 6 months18,19,20,21. This possible, yet-unproven, role as a sub-clinical fungal co-pathogen is suggested by the extremely high prevalence of Pneumocystis in infants19,21, that peaks coincidently at this age window18,19,20,21 and by the pulmonary pathology documented in animal models25,26,27,28.
An important mechanistic result of this work is the documentation that Muc5b production is to certain extent dependent on STAT6/FoxA2 pathway and that pharmacological intervention of the STAT6/FOXA2 pathway, as has been previously proposed33, can serve as a mechanism for modulation of mucus during Pneumocystis infection. STAT6 is an important pathway in the innate immune response to Pneumocystis as suggested in our previous studies related to the association of Pneumocystis and MUC5AC increase in infant lungs and documented in STAT6 knockout mice24,27. STAT6 is activated by IL13 that favors mucin expression through binding inhibition of transcriptional repressor FoxA2 to the mucin promoters9,34. FoxA2 reduces the expression of mucins and, therefore, binding-inhibition of FOXA2 is necessary to induce enhanced expression of MUC5B35. Paradoxically, increased methylation of FoxA2 binding site in the mucin promoter has been shown to enhance overexpression of MUC5B14, indicating that regulation mucins expression is complex. Kaempferol, was selected as a drug to reverse the FoxA2 binding-inhibition of Pneumocystis because kaempferol is a specific inhibitor of JAK3, which phosphorylates and activates STAT65,10,30. We first documented increasing P-STAT6 levels by Pneumocystis activation and reversal by Kaempferol (Fig. 4), and then, the stimulatory effect of Pneumocystis in Muc5b secretion and reversal by Kaempferol (Fig. 5). However, the limited potential for Muc5b pharmacological modulation via the STAT6/FoxA2 pathway was confirmed in these animals by the partial reversal of the binding of FoxA2 to Muc5b promoter associated to Pneumocystis by the addition of Kaempferol (Fig. 6). Therefore, documenting that Pneumocystis stimulation of Muc5b via the STAT6/FoxA2 pathway, occurs by inhibition of the FoxA2 repressor and, can be partly reverted by Kaempferol. Other potential pharmacological intervention that has been suggested to modulate the mucus hypersecretion associated to Pneumocystis in infants and patients with COPD, is to increase methylation of histone 3 which is known to suppress STAT635 suggesting epigenetic modifications also deserve exploration35,36. Modulation of mucus is complex and additional mucogenic pathways like EGFR and NFkB may be involved. For example, STAT6 and NFkB pathways that may interact via transcription factors P-STAT6 and NFkB subunits p50 and p6537 or through a non-canonical pathway where IL13 stimulation has been documented to activate NFkB38.
In summary, this work documents a relevant mucus response to Pneumocystis primary infection in the immunocompetent host. The progression of individual gel forming mucins over time showed an earlier and higher increase of Muc5b as part of the innate defensive response, and a slower increase of Muc5ac that suggests an ongoing Th2-type immune response that is more related to airway sensitization against this fungus occurring during the primary infection. Pneumocystis sensitizes the airway to strikingly potent constrictive responses39. Results show also, that the STAT6/FOXA2 pathway is involved in the positive regulation of mucus during Pneumocystis primary infection, and that pharmacologic modulation of this pathway may be a suitable strategy to limit Pneumocystis-induced mucus overproduction.
Methods
Infant lung samples
Infant autopsies were legally required as per Chilean law for all infants dying in the community, and conducted at the Servicio Médico Legal de Santiago, which is the coroner’s office institution for the Metropolitan Area of Chile. Autopsy lung samples from infants without an ascertainable cause of death and categorized as Sudden Unexpected Infant Deaths (SUID) were selected using a randomization protocol available at www.randomizer.org from a pool of 39 Pneumocystis-positive and 20 Pneumocystis-negative samples stored at -80 °C in our laboratory without possible identifiers to link their identity19. Samples were numbered 1 to 39 in Pneumocystis-positive group and 1 to 20 in Pneumocystis-negative group and eight positive and eight negative samples were selected.
Rat model of Pneumocystis Primary Infection
Sprague Dawley rats from same colony were used for each individual experiment. Timed-pregnant rats were randomly assigned to be exposed or non-exposed to Pneumocystis as described26 and received tylosin tartrate (93 mg/l) during 3 weeks prior to delivery to prevent bacterial infections. Control pregnant rats received cotrimoxazole (TMS) in addition to secure prevention of Pneumocystis. Dams and pups of the exposed groups were co-housed at birth with seeding rats with Pneumocystis pneumonia as described26. Female pups were selected at weaning. However, the effect of gender in Pneumocystis primary infection has not been studied. They were sacrificed at 45, 60 and 75 days from birth under deep anesthesia with Xylazine 10 mg/kg and Ketamine 100 mg/kg. Half of animals at each sacrifice were exsanguinated and their lungs kept at -80 °C until processed to extract RNA and proteins. The other half were perfused via cava vein with 3.7% PBS-buffered formalin and removed after 24 hours as described26.
Administration and evaluation of Kaempferol effect
The same model26 was reproduced to evaluate pharmacologic modulation of STAT6/FoxA2 pathway with Kaempferol at day 70. Pneumocystis-positive and Pneumocystis-negative rat groups were each separated in two groups to start Kaempferol 7 mg/Kg or saline daily intra-peritoneal injections for two weeks from days 55–70. All animals were sacrificed at day 70 for mucus and STAT6/FoxA2 pathway markers determinations.
Detection and quantification of Pneumocystis
Total genomic DNA was isolated from fresh-frozen homogenized lung tissue 0.3 g aliquots using QIAmp DNA mini kit (Qiagen). Pneumocystis was identified by nPCR using P. carinii specific oligonucleotide primers as described40. Pneumocystis burden was determined by quantification dhfr gene using qPCR with primers as described26. Copies of the dhfr gene were determined by interpolation in a calibration curve. PCR reactions conditions utilized an initial denaturation step of 5 minutes at 94 °C, 45 cycles of 20 seconds at 94 °C, 20 seconds at 57 °C, and 20 seconds at 72 °C.
Mucus determinations
Paraffin embedded lungs sections (3 μm) were stained with Alcian Blue (1% AB in 3% glacial acetic acid, pH = 2.5) and periodic acid-Schiff’s reagent (AB/PAS) using standard protocols. All images were acquired using an Olympus BX60 microscope connected to a Q-IMAGING Micropublisher 3.3 RTV camera (QImaging, Burnaby, BC, Canada). Immunohistochemical staining was done as per manufacturer protocols sc-2018 using anti-MUC5B primary antibody sc-135508 (Santa Cruz Biotechnology, USA) and anti-Muc5ac ab 64259 kit (Abcam, UK). Muc5ac and Muc5b immunohistochemical quantifications were done by estimating the percentage of airway epithelium area stained by each respective mucin antibody using Image Pro Plus software version 5.1.0 (Media Cybernetics Inc., Rockville, MD, USA) in an average of 16 optical fields (3–35 range) per animal using a 10x objective (100x magnification). Each mucin stained area per animal represents the mean percent airway epithelial stained area value of the individual airways measured in that animal. Means per animal were then used to calculate the group mean. Airways were classified according to diameter in bronchi (>250 μm), bronchioles (50 to 250 μm) and terminal bronchioles (<50 μm)31.
Muc5ac and Muc5b qRT-PCR determinations in rat lungs
Lungs were placed in RNA later (QIAGEN, USA) immediately after sacrifice, kept for one night at 4 °C and then frozen at -80 °C until total RNA extraction. Total RNA extraction was performed according QIAGEN RNeasy mini spin columns method, starting with 30 mg of tissue. Total RNA (2 μg) was reversely transcribed into cDNA using random hexamer primers and SuperScript IV (Invitrogen, USA). The resulting one-stranded cDNA was diluted 1:2 and 1 μl used for PCR reactions. Amplification of Muc5b and Muc5ac was performed using the SensiMix SYBR Hi-ROX Kit (Bioline, UK) using a RotorGene 6000 Series equipment (Corbett Research, Canada). Primer sets used for amplification were: Muc5b F: 5′ CCTGAAGTCTTCCCCAGCAG 3′; Muc5b R: 5′ GCATAGAATTGGCAGCCAGC 3′; Muc5ac F 5′ ACCACGGATATCAGAACCAGC 3′; Muc5ac R 5′ TGTCAAGCCACTTGGTCCAG 3′. PCR reactions were performed with the following conditions: Initial denaturation of 5 minutes at 94 °C, 45 cycles of 30 seconds at 94 °C, 20 seconds at 60 °C, 20 seconds at 72 °C. Actin was used as internal amplification control26. mRNA quantifications were normalized by actin. Results were compared using the corresponding control determination at each sacrifice point as the reference value.
Western blotting determinations in human and rat lungs
30 mg samples from each lung were homogenized in 1 ml of standard RIPA (50 mM Tris pH 7.4, 1% NP-40, 0.5% sodium deoxycholate, 150 mM NaCl, 1 mM EDTA) buffer supplemented with protease inhibitor cocktail (Roche, Germany) and sodium dodecyl sulfate (0.01% final concentration). Samples were centrifuged twice to eliminate cellular debris and lipids after 30 minutes of ice incubation. 30 μg per sample were analyzed for MUC5B, total STAT6, phosphorylated STAT6 (P-STAT6) and FoxA2 by immunoblotting. Proteins were separated by 8% polyacrylamide denaturing gel and transferred to PVDF membrane (ThermoScientific, USA). Membranes were blocked with 5% non-fat milk in TBS for one hour at room temperature and then probed with anti-MUC5B (sc-135508, Santa Cruz Biotechnology, USA), anti-STAT6 (sc-621, Santa Cruz Biotechnology, USA), anti-P-STAT6 (sc-11762, Santa Cruz Biotechnology, USA), anti-FoxA2 (sc-6554, Santa Cruz Biotechnology, USA) or anti-actin (sc-1616, Santa Cruz Biotechnology, USA) diluted 1/2000 in 1% non-fat milk in TBS during one night at 4 °C. Complexes were visualized by chemiluminescence using the ECL Detection System and X-ray films (ThermoScientific, USA). Bands were quantified using ImageJ software and normalized against actin (NIH, USA). (All original gels are provided as supplementary material). Results were compared using the corresponding control animal determination as the reference value.
Nuclear protein extractions in rat lungs
200 mg of fresh lungs were homogenized in 1,5 ml of Buffer A (10 mM HEPES pH 7.9, 10 mM KCl, 1.5 mM MgCl2, 0.6% NP-40, complete protease inhibitor cocktail) and centrifuged at 350 g, 30 seconds at 4 °C, to eliminate debris. Supernatants were put in ice for 5 minutes and then centrifuged during 5 minutes at 6000 g. Pelleted materials were suspended in 200 μl of Buffer B (10 mM HEPES pH 7.9, 10 mM KCl, 1.5 mM MgCl2, 1.2 M Sucrose, 0.5 mM DTT, complete protease inhibitor cocktail) and then centrifuged at 13000 g during 30 minutes at 4 °C. Supernatants were discarded, and pellets resuspended in 100 μl of Buffer C (20 mM HEPES pH 7.9, 420 mM NaCl, 1.5 mM MgCl2, 0.2 mM EDTA, 0.5 mM DTT, 25% glycerol, complete protease inhibitor cocktail). Samples were incubated in ice for 20 minutes. Nuclear debris were eliminated by 2 minutes centrifugation at 6000 g at 4 °C. Nuclear proteins were quantified in supernatants and stored at -80 °C. 10 μg of each sample were analyzed to detect FoxA2 and H1 as internal control (sc-393358, Santa Cruz Biotechnology, USA)41.
Chromatin immunoprecipitation in rat lungs
30 mg aliquots of fresh lungs were homogenized in 300 μl of iced-PBS in 1% formaldehyde final concentration as described42. Chromatins were incubated with 2 μg of anti-FoxA2 (sc-6554, Santa Cruz Biotechnology, USA) or of IgG (sc-2027, Santa Cruz Biotechnology, USA). Precipitated DNA was collected using QIAquick® PCR purification kit (QIAGEN, USA). DNA was suspended to a final volume of 50 μl. Aliquots of 3 μl were analyzed by qPCR to amplify FoxA2-site in the rat Muc5b promoter. Primers used were: PMuc5bF: 5′ CTTCCTTCTCCATGGCCTC 3′, PMuc5bR: 5′ CCATCCCTCCAATTCCTGC 3′. PCR reactions were performed with the following conditions: Initial denaturation of 5 minutes at 94 °C, 45 cycles of 30 seconds at 94 °C, 20 seconds at 60 °C, 20 seconds at 72 °C. Amplification product included the FoxA2 binding site, TATA-box, transcription start and the first 11 codons of the protein.
Statistics
Sample size for animal experiments was estimated considering a minimum of 60% difference in means per group with 95% potency for all comparisons using online tool available at http://oep.umh.es/calculo-del-tamano-muestral/. GraphPad Prism 6.0 software (San Diego, CA, USA) was used to analyze the means ± Standard Deviations (SD) of qRT-PCR and immunoblotting determinations by non-parametric Mann-Whitney test, assuming non-normal distribution and give sample size < 10 individual determinations. Two-way ANOVA was used for comparisons in sequential determinations of mucins by qPCR and protein levels by western blot, with multiple comparisons using Bonferroni analysis. Differences were considered significant when P < 0.05. Original data is provided as supplementary material.
Ethics approvals
The Ethics Commission for Studies in Human Subjects of the University of Chile School of Medicine approved this study under protocol CEISH #092-2013. Informed consent was not obtained because this was a retrospective study of stored samples without identifiers as to the subject of origin, which is in line with national laws and regulations. All methods were performed in accordance with the principles of the Declaration of Helsinki for medical research involving human subjects and with the relevant local guidelines and regulations.
The Bioethics Committee University of Chile School of Medicine approved the animal studies under protocol CBA0606 and experiments conducted in accordance with the Animal Protection Law of Chile (Law 20.380), and the Guide for the Care and Use of Laboratory Animals (8th Edition, National Academies Press, Washington DC).
Data Availability
The data that support the findings of this study are available from the corresponding author upon request.
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Acknowledgements
Presented in part at the 17th Annual St. Jude Pediatric Infectious Diseases Research Conference, held at St Jude Children’s Research Hospital, Memphis TN. USA. March 8–9, 2018. This work was supported by The Fondo Nacional de Desarrollo Científico y Tecnológico (FONDECYT) Chile Grant 1140412 to SLV, by Posdoctoral fellowship grant 3140391 to DAR, and by The European Commission (ERANet-LAC) and The Corporación Nacional de Desarrollo Científico y Tecnológico de Chile (CONICYT) joint project ELAC2014/HID0254 to SLV.
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D.A.R. and S.L.V. conceived the experiments, analyzed results, and wrote the paper. M.G. and P.B. performed infant necropsies and analyzed results, D.A.R. performed molecular determinations. A.M., C.P., P.I., and R.B. performed animal experiments and analyzed results. D.A.R. and A.M. performed I.H.C. determinations and analyzed I.H.C. results. S.L.V. assumes full responsibility for the integrity of the submission and had final responsibility for the decision to submit for publication. All authors read and approved the final manuscript.
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Rojas, D.A., Iturra, P.A., Méndez, A. et al. Increase in secreted airway mucins and partial Muc5b STAT6/FoxA2 regulation during Pneumocystis primary infection. Sci Rep 9, 2078 (2019). https://doi.org/10.1038/s41598-019-39079-4
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DOI: https://doi.org/10.1038/s41598-019-39079-4
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