Molecular Cloning and Characterization of spurt, a Human Novel Gene That Is Retinoic Acid-inducible and Encodes a Secretory Protein Specific in Upper Respiratory Tracts*

Yuan-Pu DiDagger §, Richart HarperDagger , Yuhua ZhaoDagger , Nima PahlavanDagger , Walter Finkbeiner, and Reen WuDagger

From the Dagger  Center for Comparative Respiratory Biology and Medicine, Division of Pulmonary & Critical Care Medicine, School of Medicine and the  Department of Pathology, Medical Center of the University of California, Davis, California 95616

Received for publication, October 15, 2002

    ABSTRACT
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Retinoids, such as all-trans-retinoic acid, play an essential role in the regulation of airway epithelial cell growth, differentiation, and gene expression. Using cDNA microarray, we identified a clone, DD4, that contains the cDNA of a novel gene, spurt (secretory protein in upper respiratory tracts) that was significantly induced by all-trans-retinoic acid in primary cultured human tracheobroncheal epithelia. Two alternatively spliced spurt transcripts of 1090 and 1035 base pairs exist that contain the same open reading frame expressing a 256-amino acid peptide. The full-length spurt cDNA sequence spans a genomic DNA fragment of 7,313 bp, and the gene is located on chromosome 20q11.21. spurt mRNA is notably expressed at high levels in human nasal, tracheal, and lung tissues. In situ hybridization demonstrated that spurt message is often present in secretory cell types. The human spurt gene product is a secretory protein that contains a distinct signal peptide sequence in its first 19 amino acids. Mono-specific antibodies were generated to characterize spurt expression. Our data demonstrate that spurt is secreted onto the apical side of primary human airway epithelial cultures and is present in clinical sputum samples. spurt gene expression is higher in sputum and tissue samples obtained from patients with chronic obstructive lung disease. Our results provide the cloning and characterization of this tissue-specific novel gene and its possible relationship with airway diseases.

    INTRODUCTION
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The mucociliary functions of conducting airway epithelia play an essential role in pulmonary defense against various inhaled pollutants. It has been reported that basal, ciliated, and secretory cells form a coordinated airway defense mechanism against inhaled air pollutants (1). Goblet cells in the airway epithelium and secretory cells in the submucosal glands are the major contributors to mucus secretion (2, 3). The secretory products contributed by each cell type are currently unknown. Therefore, identifying secretory products for each cell type provides a marker to either assess the functional role of a specific cell type in maintaining homeostasis of mucociliary function or evaluate its role in the pathogenesis of various airway diseases.

Airway epithelial secretory proteins are divided into two major classes: mucins and non-mucins. Mucins are major secretory components that play an essential role in protecting and lubricating the airway epithelial surface. Mucins constitute a very large molecular weight glycoprotein family that are poly-dispersed and heavily O-glycosylated (4, 5). Currently, there are at least 12 mucin genes identified. MUC1, MUC2, MUC4, MUC5AC, and MUC5B are expressed at relatively high levels in the human respiratory tracts compared with other mucin genes (6-10). Non-mucin secretory proteins include lysozyme, lactoferrin, peroxidase, and antileukoprotease. These proteins contribute directly or indirectly to the pulmonary defense mechanism against infectious pathogens (12, 13). The cell of origin for most of these non-mucin secretory proteins is the serous cell contained within submucosal glands (11-13). However, there is still a large gap of information about the nature of these secretory proteins and their role in pulmonary defense.

Vitamin A and its metabolites, retinoids, are critical to the maintenance of mucociliary functions and secretions in the airway epithelium. In vitamin A-depleted animals, the airway epithelial surface changes from a mucociliary cell layer to a protective, squamous cell surface. This alteration can be reversed upon the addition of retinoids, such as all-trans-retinoic acid (ATRA)1 (14). Similar changes can be demonstrated in vitro in primary cultures of airway epithelial cells derived from humans and other species (15-17). Despite efforts by researchers, effects of retinoids on airway epithelia are not completely understood. We propose that retinoids induce differentiation through sequential changes in gene expression. This is based on observations that retinoid administration coincides with airway cell differentiation.

To test this hypothesis, we employed a two-color-based differential hybridization on a high density cDNA microarray membrane, which contained 30,000 cDNA spots (18, 19). These cDNA clones were individually selected from a pool of cDNA libraries created from human tracheobroncheal epithelial (TBE) cells. The membrane was differentially hybridized with cDNA probes derived from ATRA-treated and -depleted cultures of primary human TBE cells. Several ATRA-responsive cDNA clones were identified, and one of them, the DD4 clone, encoded the cDNA sequence of a novel gene. In this report, we characterize the expression of this novel gene in airway epithelia. Results from our studies suggest that the DD4 clone encodes a novel gene product that corresponds to a secretory protein specifically produced by epithelial cells of the upper respiratory tract. Based on the characteristics of this gene, we subsequently named this gene spurt (secretory protein in upper respiratory tracts).

    MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Sources of Human Airway Tissues and Cells-- Human nasal, tracheobronchial, and lung tissues were obtained from the University of California at Davis Medical Center or from the Anatomic Gift Foundation (Laurel, MD) with consent. The Human Subject Review Committee of the University of California at Davis approved all procedures involved in tissue procurement. Excised tissues were transported to the laboratory in an ice-cold, minimal essential medium (Sigma). Primary human TBE cells were isolated from these tissues by a protease dissociation procedure and cultured in a serum-free hormone-supplemented medium as previously described (1, 17). Normally, the cells were grown in 6-well tissue culture plates either without additional substratum (TC) or with collagen gel substratum (CG) or in air-liquid biphasic culture insert chambers (TranswellTM chamber, Corning/Costar 3450, Corning, NY) without (BI) or with collagen gel substratum (BI-CG). The modified serum-free medium contained 1:1 of Ham's F-12/Dulbecco modified Eagle's medium and supplemented with insulin (5 µg/ml), transferrin (5 µg/ml), epidermal growth factor (10 ng/ml), dexamethasone (0.1 µM), cholera toxin (20 ng/ml), bovine hypothalamus extract (15 µg/ml), and ATRA (30 nM). This growth-optimized culture medium allows airway epithelial cells to express mucociliary differentiation in culture within 2-3 weeks of incubation (15, 20, 21), especially under BI-CG conditions. For both BI and BI-CG culture conditions, the cells were immersed in the culture medium for 7 days, and then the TranswellTM chambers were lifted up in between the air and liquid interface for the remaining days in culture. For dose response and time course experiments, the cultures were maintained for 7-10 days without ATRA supplementation followed by the addition of ATRA at various concentrations (1-1000 nM) as described in the experiments. For ATRA-depleted cultures, the cells were plated in the medium without ATRA.

The immortalized normal human TBE cell line HBE1 (22) was obtained from Dr. J. Yankaskas (University of North Carolina, Chapel Hill, NC). HBE1 cells were maintained in serum-free Ham's F-12 medium supplemented with six hormonal supplements as described previously (17). To induce mucous cell differentiation in this cell line, ATRA (30 nM) was added to the medium, the cells were plated on collagen gel-coated TranswellTM chamber and maintained in an air-liquid interface as described above.

RNA Isolation and Northern Blot Hybridization-- At varying times and treatments, the cells were harvested for total RNA isolation by a single-step acid guanidium thiocyanate extraction method (23). For Northern blot hybridization, equal amounts of total RNA (20 µg/lane) were subjected to electrophoresis on a 1.2% agarose gel in the presence of 2.2 mM formaldehyde and transferred overnight to a Nytran N+ nylon membrane. The transferred RNA was fixed and cross-linked to the membrane by UV cross-linking using UV Stratalinker 2400 (Stratagene, La Jolla, CA). The cDNA probes were labeled with [alpha -32P]dCTP (ICN, Costa Mesa, CA) to a specific activity of ~2 × 109 dpm/µg with a Ready-To-Go random primer labeling kit (Amersham Biosciences). The membranes were prehybridized in hybridization solution (6× SSC, 0.5% SDS, 0.01 M EDTA, 0.5% disodium pyrophosphate, 5× Denhardt's solution) at 68 °C for a minimum of 4 h followed by hybridization in the same solution plus specific probe at 68 °C for 16-20 h (overnight). Hybridized membranes were washed once with 2× SSC, 0.1% SDS for 10 min at room temperature and twice with 1× SSC, 0.1% SDS for 30 min at 68 °C. Following the second wash, the membranes were checked for excessive radioactivity, and, if necessary, washed in 0.1× SSC and 0.1% SDS for various times at 68 °C. PhosphorImager screens (Molecular Dynamics and Amersham Biosciences) and/or X-Omat film (Eastman Kodak Co.) were exposed to hybridized membranes for various times. ImageQuant analysis software was used for quantitation of Northern hybridization signals (Molecular Dynamics). To study the novel gene expression patterns in normal tissues, Northern blots containing 20 µg/lane of total RNA from various human tissues were prepared, and Northern analysis was carried out as described above.

Identification of ATRA-responsive Genes in Human TBE Cells-- Thirty thousand cDNA clones were derived from primary human TBE cells that had been cultured for more than 3 weeks under an air-liquid interface culture condition in the completed medium containing both the hormonal supplements and ATRA. Under this in vitro culture system, the human TBE cells differentiated into a mucociliary epithelium resembling that seen in vivo. The cDNA clones were packaged using a pBK CMV phagemid packaging system (Stratagene, La Jolla, CA).

From the 30,000 cDNA clones, we developed a high density microarray membrane (3.1 × 4.6 cm, Nytran N+ nylon membrane; Schleicher & Schuell). This 30,000 cDNA high density microarray membrane was hybridized simultaneously with two-color cDNA probes derived from ATRA-treated (magenta) and untreated (cyan) cultures of primary human TBE cells as described before (18). Based on a quantitative ratio of cyan/magenta either greater than 5 or less than 0.2, clones, including our novel gene, were selected for further characterization.

In Situ Hybridization-- cDNA clones obtained from the original phage library screening were converted to phagemids according to the manufacturer's protocol (Stratagene). The recombinant plasmid was linearized with EcoRI or XhoI to generate antisense and sense templates, respectively. The linearized templates were in vitro transcribed with T7 and T3 RNA polymerases using MAXIscriptTM according to the manufacturer's recommendations (Ambion Inc., Austin, TX) to produce 35S-UTP-labeled antisense and sense cRNA probes, respectively. In situ hybridization was carried out as described previously (24-26).

Cloning and Sequencing of spurt cDNA-- A human airway epithelial cell-specific cDNA library was screened to isolate spurt cDNA using a lambda ZAP cDNA library that was custom-made in our laboratory. The cDNA library was derived from human primary cultures of airway epithelial cells grown under BI-CG conditions in the presence of 30 nM ATRA for 3 weeks. DNA sequencing was carried out at the Institutional DNA Core Facility (Department of Plant Genetics, University of California at Davis) using the fluorescence-labeled automatic sequencing approach and separated by the ABI Prism model 377 automated DNA sequencer (Applied Biosystems, Foster City, CA). Four sequence primers (DD4 SEP 1-4) at different positions of DD4 were used as follows: DD4-SEP1, 5'-GACGTCAGTGATTCCTGGCC-3'; DD4-SEP2, 5'-TCCAGAAGACCTTGAATGGG-3'; DD4-SEP3, 5'CGTGTGCCCTCTGGTCAATG-3'; and DD4-SEP4, 5'-TAGGTGAGGCACATGGATG-3'.

The sequence data were analyzed with both Geneworks (IntelliGenetics, Inc., Mountain View, CA) and Lasergene (DNASTAR Inc., Madison, WI) software programs as well as with the online GCG software package SeqWeb (GCG, Madison, WI). Sequence homology to published sequences in public data bases was analyzed and determined by the BLASTn or BLASTp programs at the National Center for Biotechnology Information through internet services.

5'-Primer Extension and 5'-Rapid Amplification of cDNA Ends-- The sequence of the full-length cDNA was determined by 5' extension of RNA from human TBE cells cultured under the BI-CG condition with 30 nM ATRA, using an end-labeled antisense primer (5'-GGCTAACAGCCCGTAGAAGAC-3') and the dideoxynucleotide chain termination method according to the manufacturer's recommendations (Promega, Madison, WI). A base pair ladder was sequenced in parallel with the 5' extension product TaqtrackTM sequencing kit (Promega).

For 5'-rapid amplification of cDNA ends, the marathon kit (Clontech) was used to synthesize the first strand cDNA from mRNA (1 µg) isolated from primary cultures of human TBE cells, which were cultured under air-liquid interface culture conditions and 30 nM ATRA supplement for 21 days (17). Oligo(dT) primers were used to initiate first strand cDNA synthesis. This was followed up by second strand cDNA synthesis and adaptor ligation to terminal ends. PCR with nested primers was performed for product amplification. The PCR products were subcloned into the TA vector (Invitrogen, San Diego, CA) for cloning and DNA sequencing.

In Vitro Transcription-Translation of spurt Protein-- spurt protein was transcribed and translated in vitro by combining the MAXIscriptTM T7/T3 kit and Retic Lysate IVT kit (Ambion). Template DNA was obtained by subcloning the ORF fragment of spurt cDNA into a pcDNA3 expression vector (Invitrogen). 1 µg of DD4 (spurt) DNA template was then mixed with the corresponding RNA polymerase, rNTPs, and transcription buffer, and the 20-µl reaction mixture was incubated for 45 min at 37 °C.

In vitro transcribed RNA (0.5 µg/reaction) was then labeled with 4 µl (1200 Ci/mmol) of [35S]methionine (ICN), reticulocyte lysate, and master mix containing 200 mM creatine phosphate, 3 M potassium acetate, 10 mM MgCl2, and an amino acid mixture (2 mM) (Ambion) for 60 min at 30 °C. Adding 1/10 volume of 1 mg/ml RNase A and continuing the incubation at 30 °C for 10 min more terminated the translation reaction. Four volumes of Laemmli SDS sample buffer (2.5% SDS, 0.1 M Tris, pH 6.8, 10% glycerol, 350 mM 0.025% beta -mercaptoethanol, 0.1% bromphenol blue) were added (27). The translated products were separated by electrophoresis in a 12% SDS-polyacrylamide gel. For imaging, dried gels were exposed to x-ray film.

Construction and Transfection of a spurt FLAG-tagged Fusion Protein-- A fusion protein with FLAG attached to the N terminus of spurt protein was made to identify the size of spurt protein. For FLAG tagging, the entire coding region of the novel cDNA was fused in frame 3' to a FLAG tag in the vector pFLAG CMV2 (Sigma). To prepare the FLAG-spurt expression vector, the ORF fragment of spurt was amplified by PCR using appropriate primers (forward Primer DD4FLAG-1F, 5'-ACGAATTCGTTTCAAACTGGGGGCCTC-3'; reverse primer DD4FLAG-2R, 5'-TGCTCTAGAGGCACATGGGATGTTACAC-3') containing EcoRI and BglII sites at the 5'- and 3'-ends, respectively. The PCR products were inserted into EcoRI/BglII sites of the pFLAG vector (Sigma). Modification was made to place a perfect Kozak sequence (5'-CCACC-3') (28) immediately upstream of the presumed translational start codon of the ORF of spurt. The vector-insert junction was verified by nucleotide sequencing. For transient transfection studies, 0.5 µg of FLAG-spurt plasmid was transfected into 5 × 104 HBE cells in a 35 mM Petri dish with LipofectAMINE (Invitrogen). Two days post-transfection, one dish from each transfection group was harvested for protein isolation and Western blot analysis.

Polyclonal Antibody Production and Western Blot Analysis-- A 16-mer oligopeptide antigen was synthesized (Research Genetics, Inc., Huntsville, AL) using the deduced amino acid sequence from Arg165 to Cys180 of spurt. The peptide was conjugated to multiple antigen peptide to increase its antigenicity, and rabbit-based polyclonal antibodies were generated as described before (29). The specificity of the polyclonal antiserum was determined by enzyme-linked immunosorbent assay and Western blot analysis.

For Western blot analysis, cultured cells were harvested as described (30, 31). Supernatant protein concentrations were determined by the method of Lowry using the Bio-Rad Dc assay. Equal protein amounts were subjected to discontinuous SDS-polyacrylamide gel electrophoresis according to Laemmli (27). The proteins were blotted onto polyvinylidene difluoride or Nytran membranes according to the manufacturer's recommendations with a semi-dry blotting apparatus (Schleicher & Schuell) at 120 mA/45 min/10-cm2 gel surface area. Western hybridization was done using a Vectastain ABC kit (Vector Laboratories, Inc., Burlingame, CA) and the appropriate primary and secondary antibodies.

Sputum Sample Preparation-- Sputum samples were collected from subjects using a protocol approved by the University of California at Davis Institutional Human Subjects Review Board. Subjects were randomly asked to generate sputum during a routine visit to a general pulmonary clinic. Sputum generation was directly observed to ensure collection of an adequate specimen. The samples were discarded if the fluid viscosity was more consistent with saliva compared with sputum. All expectorated sputum samples were immediately stored on ice. During preparation, sputum samples were placed in a shaking water bath at 37 °C for 20 min to ensure complete homogenization and in the presence of a protease inhibitor mixture that included 1 µM iodoacetamine, 25 µg/ml aprotinin, 10 µM leupeptin, 5 mM phenylmethylsulfonyl fluoride, and 10 mM dithiothreitol to reduce protein degradation and disulfide cross-links (Sigma). The samples were spun to separate gel/mucin/cells from the soluble phase (32, 33). The protein concentration of the soluble portion of the sputum sample was determined by Lowry's method (Bio-Rad). From the soluble portion of the sputum samples, 30 µg of total protein was used for SDS-PAGE and Western blotting.

    RESULTS
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Isolation of an ATRA-responsive Gene-- A high density DNA microarray membrane containing 30,000 cDNA clones derived from cDNA libraries of human TBE cells was used to differentially screen for ATRA-responsive genes (18, 19). One of the ATRA-inducible novel genes, DD4, was selected for further studies. Northern blot hybridization with RNA isolated from primary human airway epithelial cultures treated with or without ATRA (30 nM) confirmed that the expression of DD4 is strongly induced by ATRA (Fig. 1A). The RNA staining gel (Fig. 1B) confirmed equal loading of the RNA samples and lack of any RNA degradation. To further confirm the ATRA-responsive nature of DD4, we examined DD4 induction at a variety of ATRA concentrations and times. Northern blot hybridization revealed that the DD4 message was strongly induced by ATRA in a dose-dependent manner (Fig. 2A). The induction could be seen at concentrations higher than 30 nM. DD4 gene expression was detected 7 days after starting retinoid treatment, which indicates that induction by retinoids is a late event (Fig. 2B). Other ATRA derivatives, such as all-trans-retinol and 9-cis-retinoic acid, also stimulate the expression of this novel gene (data not shown).


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Fig. 1.   DD4 gene expression is increased by ATRA in primary human TBE cell cultures. Northern blots of RNA from cultured human TBE cells were hybridized to probes specific to DD4. A, primary human TBE cells were cultured under four different culture conditions (TC, CG, BI, and BI-CG) for 14 days with (lanes 2, 4, 6, and 8) and without (lanes 1, 3, 5, and 7) supplementary 3 × 10-8 M ATRA as described above. B, the staining gel of the transferred membrane that was used in A showing the 28 and 18 S bands, which confirms equal RNA loading. C, quantitative results that represent DD4 gene expression levels after normalization with18 S.


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Fig. 2.   The ATRA-induced increase in DD4 gene expression is dose- and time-dependent. Northern blots of RNA from cultured human TBE cells were hybridized to probes specific either to human DD4 or, as an internal control (Con), 18 S rRNA. A, primary human TBE cells were cultured under BI-CG conditions for 14 days with increasing concentrations of ATRA as shown. B, primary human TBE cells were cultured under BI-CG conditions with 3 × 10-8 M ATRA for the indicated periods. The lower panels of A and B are the same membranes rehybridized with 18 S ribosomal cDNA probe to normalize RNA loading.

In addition, cell culture conditions had an effect on DD4 mRNA expression levels. The highest induction of DD4 message was observed when cultured cells were maintained on collagen gel under air-liquid interface culture conditions (BI-CG). Other culture conditions, such as plating on CG substratum alone or with an air-liquid interface alone (BI), resulted in lower levels of DD4 gene expression. Expression was the lowest in cells plated on a TC plastic surface. Despite these changes in DD4 gene expression, quantitative results demonstrated that ATRA enhanced DD4 mRNA expression at least 10-fold in all culture conditions (Fig. 1C).

Expression Pattern of spurt mRNA in Normal Tissues-- To identify the expression pattern of the DD4 gene in normal tissues, we employed a multiple-tissue Northern blot hybridization. Using a human tissue distribution membrane consisting of total RNA derived from various normal human tissues, Northern blot analysis revealed significant DD4 message levels in the trachea, bronchi, and lung. No hybridization signal was observed in RNA samples harvested from other tissues (Fig. 3). Similar results were obtained using the human DD4 probe against a murine multiple tissue distribution membrane, which included 14 different mouse tissues. DD4 expression in the mouse was observed only in the nasal septum, trachea, and lung (data not shown). In addition, nasal epithelial cells freshly obtained from human nasal turbinates and nasal polyps exhibited relative high DD4 expression levels by Northern blot analysis. These observations suggest that DD4 expression is specific to the conducting airways.


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Fig. 3.   DD4 gene expression in humans is specific to the upper airways. Northern blot analysis was performed for DD4 gene expression with total RNA isolated from various human tissues. Total RNA (20 µg/lane) from human tissues was separated by formaldehyde, 1.2% agarose gel electrophoresis. Hybridization was performed as described above, followed by autoradiography. DD4 gene expression was observed in RNA isolated from the lung (lane 2), bronchi (lane 4), trachea (lane 5), nasal turbinates (lane 11), and nasal polyps (lane 12). There was no DD4 gene expression seen in the heart (lane 1), kidney (lane 3), liver (lane 6), brain (lane 7), stomach (lane 8), small intestine (lane 9), or colon (lane 10).

In situ hybridization demonstrated that DD4 mRNA is specifically expressed in the secretory ducts and submucosal glands of normal human tracheobronchial tissue sections (Fig. 4). For comparison, in situ hybridization with a sense cRNA probe did not display an observable signal when compared with background (data not shown). In situ hybridization of tissue sections from "normal" patients showed low abundance DD4 message in the surface epithelium. Furthermore, the expression level of DD4 is highest in the trachea and decreases progressively from the proximal (bronchial region) to distal (bronchiolar region) airways in the human lung (Fig. 5). This pattern closely correlates with previous reports on serous cell distribution patterns in the respiratory tract (12, 34).


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Fig. 4.   DD4 message is localized to the tracheal submucosal glands and secretory ducts. Radiolabeled antisense DD4 RNA probes were prepared as described above and hybridized to human tracheal tissue sections. DD4 message is localized to the secretory ducts (A and B) or submucosal glands (C and D) of the trachea. Original optical magnification, 400×.


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Fig. 5.   DD4 message in vivo is specific to the human upper airways. In situ hybridization of human airway surface epithelia was performed using radiolabeled antisense DD4 RNA probes as described above. The intensity of DD4 signal in airway surface epithelia progressively decreased from the upper airways (A and D) to the lower airways (C and F) as shown. Original optical magnification, 400×.

Expression Pattern of spurt mRNA in COPD Tissues-- Importantly, although the gene expression of DD4 was generally confined to the submucosal gland region of normal human tracheobronchial tissues, we were able to detect elevated DD4 message in the airway surface epithelia in all tissue sections obtained from four patients with chronic obstructive pulmonary disease (COPD). For in situ hybridization, we labeled DD4 riboprobes by an enzymatic method, obtaining concurrent views of both staining pattern and histological structure. The observed positive staining using antisense probe (Fig. 6A) indicated specific DD4 gene expression when compared with the negative staining of the sense probe (Fig. 6B). DD4 message was elevated in both the surface epithelium and the submucosal glands as shown in Fig. 6 (C and D). These results suggest that an increase in DD4 mRNA expression is associated with COPD.


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Fig. 6.   Increased expression of DD4 mRNA occurs in the epithelium of a diseased airway. In situ hybridization of human trachea tissue sections from a patient with COPD. A, positive hybridization with DD4 antisense probe was seen in both the surface epithelium and the submucosal gland region in the trachea of a COPD patient (100×). B, the same serial tissue sections as in A were hybridized with DD4 sense probe and did not show observable signal in either the surface epithelium or the submucosal glands (100×). Higher magnification clearly demonstrates the positive staining of DD4 message in the surface epithelium (C) and submucosal glands (D) (200×). DD4 message was elevated in both the surface epithelium and the submucosal glands compared with normal tissue sections (Fig. 5).

Molecular Characterization of Full-length spurt cDNA-- Our original search in the GenBankTM data base found three expressed sequence tag (EST) clones, (GenBankTM accession numbers AA315985, N27741, and N23239) with nucleotide sequences homologous to the preliminary DD4 sequence (954 bp) (Fig. 7A). To further characterize the full-length cDNA sequence of DD4, several different approaches were used. These approaches included further cDNA library screening, rapid amplification of cDNA ends, and 5'-end primer extension.


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Fig. 7.   Two DD4 cDNA sequences exist with alternative splicing at the 3'-untranslated end. A, cartoon representation of the full-length human DD4 cDNA. The proposed open reading frame (bold arrow) and the position of the primer used for 5'-extension are shown. The positions of our four independently isolated cDNA clones and three GenBankTM EST clones are shown relative to the human DD4 (spurt) cDNA. B, results of 5'-end primer extension experiments using a 22-mer primer sequence antisense to the 95-116-bp region of the DD4 cDNA. Single base ladder markers (lanes 1-4) were compared with the DD4 extended products, spurt and spurta (lane 5). C, reverse transcription-PCR confirmed two alternatively spliced forms of DD4 (spurt) at the 3'-untranslated region. PCR primers were designed to correspond to the DD4 3'-untranslated region upstream (5'-CATGCTGATCCACGGACTAC-3') and downstream (5'-ACGCCTGGTGGGAAAGGAG-3') of the proposed alternative splicing site. Amplified PCR products were separated by electrophoresis on a 2% agarose gel and visualized by an UV/light gel documentation system from Amersham Biosciences. Molecular markers at 250-bp (lane 1) and 100-bp (lane 2) intervals served as size references for our PCR products. PCR amplification was performed with 0.2 µg of total RNA template from primary TBE cells under BI-CG and 30 nM ATRA culture conditions (lanes 3 and 4). For positive control, we used full-length (lane 5, clone DD4-C1) and alternatively spliced (lane 6, clone DD4-C3) DD4 cDNA clones. These results indicate that both the long (spurt) and short (spurta) forms of DD4 cDNA exist simultaneously in airway tissues.

Through cDNA library screening, we isolated four DD4-like clones (clone DD4-C1 to DD4-C4). Sequence information of these cDNA clones revealed the consensus cDNA sequence of the DD4 gene. Various products of rapid amplification of cDNA ends were carried out to further confirm the sequence information of this gene.

To identify the transcription start site, 5'-end primer extension was performed (Fig. 7B). These results indicate that the transcription start site is at least 12 bp upstream of the longest cDNA clone, DD4-C4. We obtained similar results using Eukaryotic Neural Network Promoter Prediction (NNPP/Eukaryotic) software to theoretically predict the promoter region and transcription start site (data not shown). However, the smear pattern seen with our primer extension results suggested incomplete primer extension. We found that there were several consecutive guanidine residues in the region of the transcription start site. This potentially will interfere with the capability of reverse transcriptase to fully extend to the upstream 5'-end of the actual starting site. In support of this, additional data from recently released EST clones (BG546713, BG570614, BG538707, and BG537983) suggest that the actual transcriptional starting site is five base pairs upstream of our original results.

Based on PCR data, we confirmed two alternatively spliced products of the DD4 gene (Fig. 7C). Using the same set of primers, we were able to amplify two products, 1090 and 1035 bp long, that differ by 55 bp at the 3'-untranslated end. Both amplified clones contain an open reading frame of 256 amino acid residues. For both products, the region adjacent to the translational initiation codon contains a favorable Kozak sequence (28). Both cDNA products contain the same polyadenylation signal, AAUAAA, located 19 bp upstream of the polyadenylation site. Although the 55-bp size difference of the two transcripts is distinguishable using reverse transcription-PCR amplification methods, we are unable to resolve the two transcripts with Northern blot analysis.

Characterization of Protein Expression-- The peptide sequence analyses suggested that both DD4 cDNAs encode a protein with 256 amino acid residues. The predicted isolectric point of DD4 is 5.497, and the calculated molecular mass is 26,711 daltons. To confirm the accuracy of the deduced amino acid sequence, we used in vitro transcription-coupling translation. This approach demonstrated a major translation product at 25 kDa in SDS-PAGE (Fig. 8A, lane 3). The slight discrepancy between the in vitro translated product and the predicted molecular mass of 26.7 kDa is probably due to the migration behavior of DD4 protein in gel. In addition, we performed transient transfection studies using a chimeric construct of pFLAG fused in frame to the coding sequence of the DD4 gene under the direction of a CMV promoter. Western blot analysis using anti-FLAG M5 antibody demonstrated a single protein product at the 27-kDa position. Mock (no transfection) and control transfections (control pFLAG vector with no cDNA insert) yielded no detectable signal (Fig. 8B).


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Fig. 8.   Successful DD4 in vitro transcription/translation and FLAG-tagged human DD4 protein expression. A, the complete DD4 cDNA was cloned into a pcDNA3 expression vector and translated in a reticulocyte cell lysate in the presence of [35S]methionine. The reaction products were analyzed by 12% (w/v) SDS-polyacrylamide gel electrophoresis, followed by autoradiography. The reaction was performed in the presence of capped XeF-1 RNA (lane 1, positive control) and in the absence of RNA (lane 2, negative control). The DD4 translated gene product was observed with an approximate molecular mass of 25 kDa as indicated (lane 3). B, human HBE1 cells were transiently transfected with either no DNA (lane 1), pFLAG CMV2 empty expression vector (lane 2), or pFLAG CMV2 expression vector inserted with the DD4 ORF (lane 3), and protein extracts were analyzed by Western hybridization as described above. The proteins were transferred to a polyvinylidene difluoride membrane and were incubated with the anti-FLAG antibody M5 at a 1:800 dilution. The arrow corresponds to a FLAG-tagged DD4 fusion protein.

The DD4 Gene Product Is a spurt Protein-- To analyze the protein structure of DD4, several web-based protein structure analysis software programs were used. SignalP identifies secretory signal peptides and predicts the possible cleavage site of putative signal peptide sequences (35). Based on the analysis by this program of the deduced amino acid sequence, the human DD4 gene contains a distinct signal peptide sequence in its first 19 amino acids (data not shown). In addition, SignalP analysis predicted Ala19 to Gln20 as the most likely cleavage site. Another software program, PSORT, detects the sorting signals of proteins and predicts their subcellular locations (36). The results obtained from PSORT suggested a 33.3% probability that spurt is extracellularly secreted (data not shown). Both of these analyses strongly suggest that DD4 is a secretory protein.

Hydrophobicity analysis, based on the method of Kyte and Doolittle (59), predicted the hydrophilic/hydrophobic regions of DD4 (Fig. 9A). Based on this analysis, an oligopeptide that corresponds to a highly hydrophilic, highly antigenic region of 16 amino acids with high surface probability (Arg165-Cys180) was synthesized and used as an immunogen to generate polyclonal antibodies in rabbit. Using anti-DD4 antibody, DD4 protein was detected from cell culture supernatants collected from the apical region of the culture chamber in both human bronchial epithelial HBE1 cell lines and primary cultured airway epithelial cells maintained in 30 nM ATRA. Sputum samples also demonstrated the presence of DD4 protein (Fig. 10). Similar Western blot analyses were performed using preimmune serum or antibody neutralization with DD4-specific antigen. The observed staining patterns confirmed not only anti-DD4 antibody specificity but also the secretory characteristics of DD4 because its gene product could be detected in naturally secreted human airway sputum. A nonspecific upper band exists in both preimmune and anti-DD4 antisera. Based on these results, we named DD4 gene the secretory protein in upper respiratory tracts: spurt.


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Fig. 9.   Secretory nature of human DD4 is recognized by a polyclonal anti-DD4 antibody to DD4 protein expression in culture supernatants. A, schematic representation of the human DD4 (spurt) protein that includes a hydrophilicity plot (Kyte-Doolittle), an antigenic index (Jameson-Wolf), and a surface probability plot (Emini). Lasergene software was used to generate the analyses. The horizontal axis represents the corresponding amino acid position of DD4 (spurt), and the vertical axis of each plot represents arbitrary units. The amino acid residues that we used to generate anti-DD4 (spurt) polyclonal antibodies are marked in a shaded rectangular box, which corresponds to a region of high hydrophilicity and high surface probability (Arg165-Cys180). B, HBE1 cells and human primary TBE cells were treated with and without 3 × 10-8 M ATRA in air-liquid interface culture conditions. Supernatants from the apical region were collected and analyzed by Western hybridization using anti-DD4 (spurt) antibody. As indicated by a hybridization band at ~25 kDa (arrow), increased protein expression was observed in cell culture conditions that included ATRA.


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Fig. 10.   DD4 (spurt) protein secretion is increased in patients with COPD. A, the secretion of spurt protein could be detected in clinical sputum samples from a normal patient (lanes 1, 3, and 5) and a patient with COPD (lanes 2, 4, and 6). Preimmune serum (lanes 3 and 4) was obtained from the same rabbit that generated the anti-DD4 antibody (lanes 1 and 2). Antigen block (lanes 5 and 6) was achieved using anti-DD4 (spurt) antibody that was prehybridized with DD4-specific oligopeptide antigen. B, the secretion of spurt protein is elevated in clinical sputum samples from COPD patients. Sputum samples were obtained from two normal subjects (lanes 1 and 2) and six COPD patients (lanes 3-8). Anti-DD4 (spurt) antibody was used at a 1:1,000 dilution for Western blot analyses.

spurt Protein Expression Is Elevated in COPD Patients-- Our initial analysis of sputum samples revealed that spurt expression was higher in the sputum of patients with COPD. To further characterize this observation, we examined sputum samples from additional normal subjects and COPD patients for the presence of spurt. Using the anti-spurt specific (anti-DD4 specific) antibody, we consistently observed higher amounts of spurt in sputum samples obtained from COPD patients compared with normal subjects (Fig. 10B). These results were consistent with our in situ hybridization results (Fig. 6), which demonstrated higher levels of spurt mRNA in COPD patients.

Functional Analysis of spurt Protein-- To elucidate the function of spurt protein, various bioinformatics search methods were performed, including InterPro Scan, ScanProsite, ProfileScan, pfam HMM search, and PATTINPROT. Using a Smith-Waterman algorithm, the putative spurt amino acid sequence has 27.3% homology to the C-terminal domain of the bactericidal/permeability increasing protein (BPI) that is located at chromosome 20q11.23 (37, 38) (Fig. 11A). Furthermore, when reverse position-specific BLAST (39) was performed to search against the Conserved Domain Data Base, spurt aligns to a conserved domain named BPI 1 that is derived from the N-terminal domain of BPI (SMART accession number SM0328) (40-42) (Fig. 11B). In addition, preliminary findings demonstrated a conserved phosphorylation site for casein kinase II from Ser190 to Asp193.


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Fig. 11.   Significant alignment of the spurt and BPI amino acid sequences. A, using a Smith-Waterman algorithm, our analysis revealed the spurt amino acid sequence is homologous to the C-terminal domain of rabbit BPI. B, the peptide sequence alignment of spurt to the N-terminal domain of human BPI (BPI 1, CD:smart00328) using a reverse position-specific BLAST search. The exact alignment of amino acids between spurt and BPI is indicated as a solid line, and the dots represent the alignment of two substitutable amino acids.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In this study, we utilized a microarray assay to identify an ATRA-inducible, novel secretory protein, spurt, which is secreted by conducting airway epithelia. Our results indicate retinoids regulate spurt mRNA and protein levels in cultured airway epithelial (TBE) cells. We observed that ATRA significantly increases spurt gene expression. Increased expression occurs after several days of ATRA treatment and with higher doses of retinoids.

Furthermore, we demonstrated that specific cell culture manipulations enhance spurt expression. Expression of spurt increased in a progressive fashion as the culture conditions were changed from tissue culture plates alone (TC) to biphasic conditions without and with collagen gel substrata. Optimized expression of spurt message occurred when airway epithelial cells were plated on a collagen gel substratum with air-liquid interface culture conditions (BI-CG). These data suggest that expression of spurt occurs as the airway epithelial cell layer develops toward the more mature stages of differentiation.

In support of this idea, it has been observed that the most suitable culture conditions to promote airway mucociliary differentiation in vitro include the combination of an air-liquid interface, a collagen gel substratum, and retinoid supplementation (1). Under these culture conditions, human airway epithelial cells develop into a fully differentiated cell layer with multiple mucociliary functions. In the absence of one or more of these conditions, the differentiated features are not as extensive. In addition, spurt gene expression in vivo appears to be limited to specialized cells in the human airway. In situ hybridization of lung tissue and Northern blot analyses of RNA samples from various human tissues demonstrated an abundance of spurt message in the upper respiratory tract. Gene expression was particularly high in serous cells within the submucosal glands.

Based on the sequence information obtained from our genomic cloning effort and information in the public data base, full-length spurt sequence consists of nine exons and eight introns that spans a genomic DNA region of 7,313 bp (spurt genomic clone GenBankTM accession number AF421369). Because the matched BAC clone, bA49G10, is designated to contig 158 of chromosome 20, the corresponding cytogenetic chromosome position of the spurt gene is assigned to 20q11.21. In addition, we have found that two spurt transcripts, a short and a long form, exist in EST data bases and our airway epithelial cell specific cDNA library. These two transcripts differ at the 3'-untranslated region. This observation supports the proposal that there is alternative splicing of spurt in the 9th exon that generates two transcripts with the same ORF. How this alternative splicing affects the function and expression of the spurt gene is currently unknown.

It is necessary to point out that several human EST clones identified in GenBankTM and other sequence data bases show high sequence alignments with our spurt clone, but all of them have shorter inserts than ours and contain only partial sequence information. Importantly, although several different researchers independently identified spurt-like EST clones, all of the EST clones were identified in cDNA libraries from human lung or olfactory epithelium. These observations further support our finding that spurt is a human airway-specific gene.

To elucidate the putative function of spurt, protein structural analyses were performed using several software packages including Geneworks, Lasergene, GCG, and web-based search sites. These analyses predicted spurt to be a globular protein with slightly hydrophobic properties. Furthermore, protein analyses by SignalP predicted a 19-amino acid secretory signal peptide at the N-terminal region of spurt. This signal peptide sequence is homologous to other secretory proteins such as the von Ebner minor salivary gland protein (46, 47), and the parotid secretory protein precursor (48, 49). Based on this information, we generated a specific polyclonal antibody, spurtAb2, to detect the protein expression of spurt. Examination of sputum samples confirmed the secretory nature of the protein. We easily detected spurt protein in sputum samples by Western blot analyses using spurtAb2 antibody.

Although we have identified spurt to be an upper airway-specific secretory protein, the function of spurt is still unknown. Despite an extensive blast search, no human protein with known function shows more than 40% homology to the deduced amino acid sequence of spurt. A separate group identified a "mouse unknown protein," plunc (palate, lung, and nasal epithelium clone) (43) with 74% homology to the human spurt deduced amino acid sequence. Mouse plunc was identified through mRNA differential display methods as a gene up-regulated during palate closure of the developing mouse embryo. Similarly, Iwao et al. (44) identified a novel human lung-specific gene, LUNX (lung-specific X protein), to be a potential molecular marker for detection of micro-metastasis in non-small cell lung cancer. However, the protein properties and function of plunc were not described in these papers.

Recently, a human sequence homologous to mouse plunc and human spurt was reported in a brief communication by Bingle and Bingle (45). Similar to LUNX, the human plunc sequence is highly homologous to the short form of spurt with some sequence discrepancies in both the coding and noncoding regions. One important difference regarding the expression of human spurt and the expression of human plunc was the induction by retinoids. spurt was originally identified in our microarray study as an ATRA-responsive gene. This induction was further confirmed by Northern blot analyses as shown in our data. However, Bingle's research group described high levels of plunc RNA expression in cultured airway epithelial cells without any retinoid treatment and showed that this expression was not altered by retinoid treatment as indicated in the manuscript. Although we observed higher expression levels of spurt mRNA in human nasal turbinates and trachea, we did not identify a significant amount of spurt RNA expression in primary cultures of normal nasal epithelial or tracheobronchial epithelial cells under retinoid-depleted culture conditions. In addition, we did not demonstrate the expression of spurt or plunc-like message in NCI-H647 cell lines obtained from the ATCC. This cell line was shown by Bingle's group to be the only cell line constitutively expressing plunc message. The reason for these discrepancies is currently unclear.

Based on our protein structural analyses of spurt, two functional motifs have been identified. One of them is a conserved phosphorylation site from Ser190 to Asp193 for casein kinase II, which is known to regulate cellular responses through phosphorylation and is associated with a number of substrates, including topoisomerase I, p53, and protein phosphatase 2A (50-52). Currently, we have not determined whether spurt is phosphorylated. However, based on the similarity of the molecular weight obtained from amino acid sequence estimations and the mobility of spurt in SDS-PAGE, we concluded that phosphorylation is less likely.

The second "putative" domain identified in spurt shows amino acid sequence homology to both the N-terminal and C-terminal domains of BPI. BPI has been implicated in bactericidal processes (53-57). The presence of a BPI-like domain in spurt protein suggests an antibacterial role for this novel protein. Consistent with this idea, our in situ hybridization studies demonstrated that spurt is frequently expressed in the serous cells of secretory ducts and submucosal glands. Some serous cell secretions, such as lysozyme, are known to have antibacterial activity. It is interested to note that plunc, a spurt-like mouse gene, has been shown to be expressed in mouse thymus, a tissue that harbors antimicrobial gene products (58). These observations suggest that spurt and plunc represent members of a new bactericidal gene family.

To better understand the role of spurt in human disease, we compared the level of spurt expression between normal subjects and subjects with chronic lung diseases. Based on in situ hybridization, we observed a higher level of spurt mRNA expression in submucosal gland serous cells of patients with COPD. In addition, the submucosal gland ducts and airway epithelial surface of lung tissue from COPD patients also displayed expression of spurt mRNA. We were unable to demonstrate spurt mRNA expression in the airway epithelial surface of lung tissue obtained from normal patients. Similarly, Western blot analysis demonstrated that spurt protein expression is significantly elevated in all sputum samples obtained from COPD patients compared with normal subjects. We postulate that the recurrent infections seen in patients with chronic lung diseases such as emphysema and chronic bronchitis results in the up-regulation of airway bactericidal proteins such as spurt. This higher expression of spurt involves both increased induction of the gene in submucosal gland serous cells that normally express the gene as well as the induction of cells in the submucosal gland ducts and airway surface epithelia that normally do not express spurt.

In conclusion, we have shown that spurt is a novel upper airway-specific secretory protein that is induced by retinoids. Two alternatively spliced forms of spurt exist. spurt has putative antibacterial functions, and the expression of this protein is increased in lung diseases such as chronic bronchitis and emphysema. The mechanisms and purpose of this up-regulation are actively being investigated in our laboratory.

    FOOTNOTES

* This work was supported in part by National Institutes of Health Grants HL35635, ES09701, ES06230 5F32HL09573, and HL04404), American Lung Association Grant RG-025L, and California Tobacco-related Disease Research Program Grants 7RT-0145, 10KT-0262, and 8KT-0092.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EBI Data Bank with accession number(s) AF417257, AF417256, and AF421369.

§ To whom correspondence should be addressed: Dept. of Environmental and Occupational Health, University of Pittsburgh, 3343 Forbes Ave., Pittsburgh, PA 15260. Tel.: 412-383-2157; Fax: 412-383-2123; E-mail: peterdi@pitt.edu.

Published, JBC Papers in Press, October 29, 2002, DOI 10.1074/jbc.M210523200

    ABBREVIATIONS

The abbreviations used are: ATRA, all-trans-retinoic acid; TBE, tracheobroncheal epithelial; TC, tissue culture; CG, collagen gel; ORF, open reading frame; COPD, chronic obstructive pulmonary disease; EST, expressed sequence tag; CMV, cytomegalovirus; BPI, bactericidal/permeability increasing protein; contig, group of overlapping clones.

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