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Gene Expression Microarray Analysis Reveals YKL-40 to Be a Potential Serum Marker for Malignant Character in Human Glioma¹

Departments of Surgery (Neurosurgery), Neurology, and Cell Biology, Memorial Sloan-Kettering Cancer Center, New York, New York 10021 [M. K. T., E. C. H.], and Department of Neuro-Oncology, University of Texas, M.D. Anderson Cancer Center, Houston, Texas 77030 [M. R. G.]

	ABSTRACT

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We have identified a potential serum marker for glioblastoma multiforme (GBM) usingmicroarray analysis from samples of GBM. We compared the gene expression profile of 19 gliomas to pooled normal brain by competitive hybridization of RNA from each tumor sample to a pooled sample of RNA isolated from normal brain tissue using the Incyte 10,000 gene expression array. The most differentially expressed gene in this analysis encodes a secreted glycoprotein and is referred to as YKL-40. YKL-40 mRNA was detected in the GBM samples with a range of 3- to 62-fold elevation over normal brain. It has been reported previously that this protein is expressed in pathologic conditions of extracellular matrix degradation and angiogenesis, such as rheumatoid arthritis, severe osteoarthritis, hepatic fibrosis, primary colorectal cancer, and metastatic breast cancer. These data suggest YKL-40 may be involved in extracellular matrix degradation and/or angiogenesis. Western blot analysis of glioma samples for YKL-40 protein levels revealed substantial elevation in 65% of GBMs and undetectable levels in lower-grade gliomas (grade II and III) or normal brain tissue. We performed ELISA analysis on serum samples of glioma patients to determine whether this protein would correlate with the presence of tumor and tumor grade or burden. YKL-40 serum levels were substantially elevated in many of the GBM patients. Statistical analysis of these data indicates that in patients with glioma, serum YKL-40 levels correlate with tumor grade and potentially tumor burden in GBM.

	INTRODUCTION

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GBM³ is the most common and most malignant primary brain tumor in adults (1) . Primary GBMs arise de novo with no evidence of previous lower-grade glioma. Secondary GBMs arise from pre-existing anaplastic astrocytomas, grade III glioma, or diffuse astrocytoma, grade II. Of the gliomas, grade IV GBM has the worst prognosis with a median survival of 12 months, even after surgical resection, radiation therapy, and chemotherapy. Patients with anaplastic astrocytomas have an average survival of 3 years, whereas patients with grade II gliomas have the best prognosis, with >5 years median survival (2) . Histologically, GBMs are characterized by high mitotic activity, nuclear atypia, microvascular proliferation, and necrosis. However, in the future, molecular subgrouping of the gliomas could aid in the classification of these tumors and may eventually help to better predict survival (3) .

Several distinct prognostic subgroups exist within each of these clinical grades, and consequently the survival of glioma patients can be quite variable (4 , 5) . Currently, the determination of treatment response and tumor progression is monitored using imaging techniques such as molecular resonance imaging or computed tomography. Often extensive tumor progression occurs in the interval between different imaging studies and/or goes undetected from lack of contrast enhancement. An alternative measure or marker of tumor burden may potentially permit early detection of treatment failure and allow for more rapid changes in therapeutic strategy.

Development of serum markers that are specific for a particular tumor type (6) or that correlate with biological properties of the tumor could be used for diagnosis and as a measure of response to treatment, and would greatly enhance patient care. If serum markers were identified that correlate with the activity of certain signaling pathways within the tumor, patients could be directed to clinical trials using specific agents aimed at that particular tumor biology. With such a set of markers that could predict and monitor response to therapy, patients would be better advised of the likely benefits of aggressive treatment. One method for identification of candidate markers is using gene expression microarray analysis (7 , 8) . Although many studies have been done on gene expression profiling of specific tumor types, and differentially expressed genes in these tumors have been reported, few of these studies have resulted in clinical application.

To identify potential serum markers as genes overexpressed in GBMs relative to lower-grade gliomas and normal brain, we performed cDNA microarray gene expression profiling of a series of GBMs and lower-grade gliomas. In this analysis, we found that the most differentially expressed gene in the series of GBMs versus normal brain was YKL-40. YKL-40 encodes a secreted protein with sequence similarity to glycosyl hydrolases (9) and has been identified previously as being expressed in other cancer types such as breast and colon (10 , 11) . Little to no differential expression of YKL-40 was seen in lower-grade tumors relative to normal brain. The expression of YKL-40 protein, confirmed by Western blot analysis of tumor extracts, was also specific to GBMs and undetectable in lower-grade gliomas and normal brain. To ascertain whether YKL-40 could be an accurate marker for GBM presence and tumor burden, we measured YKL-40 serum levels in patients diagnosed with various types and grades of glioma, using a YKL-40-specific ELISA assay. Our data indicate a significant difference in YKL-40 serum concentrations between normal subjects and GBM patients, as well as between lower-grade glioma and GBM patients. Furthermore, there was a trend toward high YKL-40 levels and high tumor burden, although this did not reach statistical significance. These preliminary data suggest that YKL-40 levels may be an efficient and accurate indicator of glioma presence and grade.

	MATERIALS AND METHODS

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Tissue Collection.
Patient tumor and normal brain samples were collected from patients at M.D. Anderson Cancer Center at the time of surgical resection. Normal brain sample controls were obtained as overlying cortex during routine resection of deep intercerebral metastases. Specimens were snap frozen in liquid nitrogen and stored at -80°C until use. All of the patients signed consent for collection and analysis of samples.

Tissue Preparation and Microarray Analysis.
For RNA and protein extraction, the tissue was ground to powder using a mortar and pestle in the presence of liquid nitrogen. Nine grade IV GBMs, 5 grade III gliomas, and 5 grade II gliomas were used in the array analysis. RNA was isolated from 100 to 400 mg of tissue per sample. Standard TRIzol preparation protocol (Life Technologies, Inc., Rockville, MD) and reagents were used for total RNA isolation. To isolate polyadenylated RNA, the total RNA was twice passed over an Oligotex mRNA isolation column (Qiagen, Valencia, CA) following the manufacturer’s protocol. The RNA samples were quantified using a spectrophotometer and visualized on a Tris-borate EDTA gel for quality assurance. The mRNA samples were converted to cDNA and subsequently hybridized to the Human V cDNA microarray by Incyte Genomics (St. Louis, MO). The data were analyzed using GEM Tools 2.5 software.

Protein Extraction.
Sample collection and preparation was performed as described above. Protein extraction was performed using lysis buffer [100 mM NaCl, 30 mM Tris-HCl (pH 7.6), 1% NP40, 30 mM NaF, 1 mM sodium orthovanadate, 0.5 mM phenylmethylsulfonyl fluoride, protease inhibitor mixture tablets (Roche, Indianapolis, IN)], and the tissue was homogenized on ice using a sterile, plastic disposable pestle. The samples were allowed to incubate on ice for 30 min; then centrifuged at 14,000 x g for 10 min at 4°C. The supernatant was transferred to a fresh microfuge tube, and protein quantitation was performed using the BCA Protein Assay kit (Pierce, Rockford, IL) and a standard spectrophotometer.

Western Blot Analysis.
Fifty micrograms of each protein sample was separated on an SDS-PAGE gel. The protein samples were transferred overnight to nitrocellulose membrane (Osmonics Fischer-Scientific, Pittsburgh, PA). For protein detection, the membrane was incubated in 5% milk in TBS-T for 1 h at room temperature. The membrane was then incubated for 1 h with 4 mg of YKL-40 polyclonal antibody (Metra Biosystems, Mountain View, CA) in 5% dried milk-TBS-T. The membrane was then washed three times in TBS-T, 5 min each, and incubated with the secondary antirabbit antibody, 1:2000 dilution (Roche) for 1 h. Again the membrane was washed three times in TBS-T, and antibody-bound protein was detected by adding enhanced chemiluminescence reagent (Amersham Pharmacia Biotechnology, Piscataway, NJ) for 1 min and exposing the membrane to Kodak film.

Blood Collection and Serum Separation.
All of the blood samples were collected from patients at M.D. Anderson Cancer Center diagnosed with glioma through collaboration with the Neuro-Oncology Clinic. Normal blood samples were collected from volunteer subjects with no known malignancies. The blood samples were allowed to clot at room temperature for no more than 72 h, and were then centrifuged at 4°C for 5 min at 1000 rpm. The serum (upper phase) was aliquoted and stored at -20°C until use.

YKL-40 ELISA Assay.
YKL-40 levels were determined, in duplicate, for all of the serum samples, using the YKL-40 ELISA kit from Metra Biosystems according to the manufacturer’s protocol. Protein concentrations were determined as absorbances using the Bio-Rad Benchmark Microplate Reader.

Statistical Analysis.
The histological grade of each glioma according to the WHO criteria, as well as the patient disease status was determined for each sample collected. Disease status was stratified into a high tumor burden group and a low tumor burden group. Patients with newly diagnosed tumors awaiting initial surgery or who underwent only stereotactic biopsy were considered to have a high tumor burden. Patients with radiographic evidence of recurrent tumor growth were also included in this group. Patients who underwent a gross total or near total resection, had no active disease, or had evidence of response to treatment were placed in the low tumor burden group. Statistical analysis of data in each group was done using Student’s t test.

	RESULTS

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Experimental Design.
We were interested in studying gene expression changes that occur in malignant and nonmalignant gliomas compared with normal brain tissue to find potential clinical markers for this disease. Our approach was to start with a microarray analysis using the Incyte Genomics Human V cDNA microarray. Tumor mRNA samples were labeled with cy-5 and hybridized against the cy-3-labeled normal mRNA control. For this purpose, we chose to pool samples of normal brain mRNA, generating a constant control to be used on each chip analyzed (Fig. 1) . The normal brain samples were obtained from patients with deep metastatic brain tumors, cases in which removal of overlying normal cortex was required for safe resection of the metastatic tumor. mRNA was isolated from normal frontal, temporal, parietal, and occipital cortex samples, and combined to make one common control. To preserve the quality of the mRNA during tissue collection, all of the specimens were snap frozen in liquid nitrogen immediately after removal from the patient during surgery and subsequently stored at -80°C.

View larger version (19K): [in this window] [in a new window]   Fig. 1. Microarray strategy. All of the glioma mRNA samples were hybridized against RNA from pooled normal brain tissue obtained during resection of deep metastases. This strategy allows comparison of gene expression profiles between each tumor and normal brain as well as between tumors. NB, normal brain; G, GBM; L, lower-grade glioma.

View larger version (71K): [in this window] [in a new window]   Fig. 2. Microarray analysis of glioma versus normal brain. A, gene expression display of results from a given array hybridization. Shows that >95% of all genes were differentially expressed by < 2-fold difference. B, graph illustrating YKL-40 tumor mRNA levels as fold increase relative to normal brain. Expression elevation was not seen in lower-grade gliomas (LGR) versus normal control. C, comparison of differential mRNA levels encoding YKL-40 with transcripts encoding proteins involved in endoproteolytic and endoglycosidase degradation of the ECM. YKL-40 mRNA is significantly overexpressed compared with all endoproteases on the array. Order of genes graphed beginning from the back: YKL-40, Chitobiase, MMP-16 (matrix metalloproteinase-16), MMP-14, MMP-12, MMP-11, MMP-7, MMP-2, TIMP-1 (tissue inhibitor of metalloproteinase 1), TIMP-3, urokinase receptor plasminogen activator, tissue plasminogen activator, PAI-II (plasminogen activator inhibitor-II), PAI-I, and plasminogen. Numerical values for differential expression levels displayed in this graph are given in Table 1 . D, Western blot analysis of glioma and normal brain samples for YKL-40 protein showing that it is significantly elevated in 50% of the GBMs and undetectable in lower-grade gliomas (LGR) as well as a representative normal brain sample (N).

Review of the literature reveals that the gene for YKL-40 is located on chromosome 1q32 and is a mammalian member of family 18 glycosyl hydrolases, a gene family that includes bacterial and fungal chitinases (9 , 14) . YKL-40 has significant sequence similarity to the chitin-degrading enzyme, chitinase; it has been shown to bind chitin but retains no chitinase activity and has not been determined to have any other enzymatic activity or function (15) . The full spectrum of mammalian polysaccharide structures that bind to YKL-40 and the function of this protein in human glioma biology are unknown. YKL-40 is secreted by chondrocytes, synovial cells, neutrophils, and the osteosarcoma cell line MG-63 (9 , 16 , 17) .

Several lines of circumstantial evidence indicate that YKL-40 may promote degradation of the ECM or angiogenesis. YKL-40 is not present in normal adult cartilage but is detectable in human arthritic cartilage and during periods of cartilage generation, remodeling, and degradation. For example, patients with rheumatoid arthritis have high levels of serum-detectable YKL-40 (18) . In addition, elevated YKL-40 levels have been detected in patients with hepatic fibrosis and cirrhosis (19) , and in bovine breast tissue during mammary gland involution after cessation of lactation (20) , processes that involve tissue destruction and ECM remodeling.

Because of the potential role of YKL-40 in ECM degradation, we compared its differential expression to that of other proteins involved in this process such as endoproteases and endoglycosidases present on the microarray, many of which have been shown to be important factors in glioma biology (Fig. 2C) . Although some of these genes demonstrated elevated mRNA levels in the tumor samples, when graphed together with YKL-40, their relative differential expression levels were barely detectable because of the substantial elevation of YKL-40 mRNA in the GBM samples. Differential expression values of YKL-40, endoglycosidases, endoproteases, and other ECM components on the array are shown in Table 1 .

YKL-40 Levels Are Stable in Collected Serum.
In a recent publication, YKL-40 serum values were found to increase significantly over time when blood samples (before serum collection) were stored at room temperature for >24 h or at 4°C for >72 h before serum isolation (21) . To determine whether our serum collection protocol introduced variable measurements because of collection techniques, we performed a time course experiment. We collected two vials of blood from each of two normal, healthy subjects. The blood samples were immediately centrifuged, and 150 µl of serum was collected from each vial and stored at -80°C. Next, one vial from each subject was kept at room temperature, and the other was kept at 4°C. Serum was collected from each vial at time points of 6 h, 24 h, 72 h, and 7 days, stored at -80°C, and subsequently analyzed by ELISA as described in "Materials and Methods." We found that YKL-40 levels did not show any significant increase or decrease through continuous storage at either room temperature or at 4°C (Fig. 3A) .

View larger version (13K): [in this window] [in a new window]   Fig. 3. YKL-40 in the serum of glioma patients and normal controls, and as a function of tumor burden. A, time course of YKL-40 levels in serum from two normal volunteers. YKL-40 levels appear stable in serum stored at room temperature () and at 4°C ( ) over time. B, categorical illustration of YKL-40 serum levels in normal controls, lower-grade gliomas, and GBMs. * designates the mean YKL-40 value of each subgroup. C, YKL-40 levels displayed as a measure of tumor burden in patients with grade IV GBM and compared with normal controls. Tumor burden was defined, at the time of serum collection, as presence of tumor based on pre- or postoperative patient status.

	DISCUSSION

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The role of YKL-40 in the biology of GBMs is unclear. Given the relative specificity of increased expression in GBMs relative to anaplastic gliomas, it is possible that YKL-40 protein is an integral component of GBM biology and/or may contribute to GBM-specific histological characteristics, which distinguish them from grade II and III gliomas. Alternatively, or potentially complementarily, YKL-40 expression may be the cause or effect of the signaling abnormalities that characterize GBMs such as elevated Akt or Ras pathway activity.

The fact that not all of the GBMs express YKL-40 also indicates that it is involved in the biology of only a subset of these tumors, potentially a molecular subdivision of GBMs. It is possible that for those tumors that do express large amounts of YKL-40, its levels could be a useful indicator of GBM subtype or disease status. Although YKL-40 levels showed a wide range of variability, statistical analysis of this data strongly suggests that in YKL-40 producing high-grade gliomas, serum levels may be a valuable indicator of disease activity. The utility of the YKL-40 levels as a surrogate marker of tumor burden, response to treatment, or relapse remains to be determined. This resolution will require a prospective trial in which serum samples are analyzed in patients with tumors demonstrating elevated expression of the YKL-40 gene at the time of diagnosis with subsequent measures during the course of the illness. Such a prospective study is planned, evaluating both gene expression in the tumor tissue along with serial measurement of YKL-40 protein concentrations in serum.

	ACKNOWLEDGMENTS

 
We thank Laura K. Schaefer for work on tumor sample preparation for the Microarray experiment and Western blot analysis. We also thank Michelle Hammond for help in collecting the serum samples, and Dr. Raymond Sawaya and the M.D. Anderson Department of Neurosurgery for their support.

	FOOTNOTES

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ Supported by The Bullock Foundation, NIH Grant UO1CA894314-1, the Searle Scholars, Bressler Scholars, and Tow Foundations.

² To whom requests for reprints should be addressed, at Department of Cell Biology, Memorial Sloan-Kettering Cancer Center, 1275 York Avenue, RRL 917B, New York, NY 10021. Phone: (212) 639-3017; Fax: (646) 422-2062; E-mail: hollande{at}mskcc.org

³ The abbreviations used are: GBM, glioblastoma multiforme; ECM, extracellular matrix; TBS-T, Tris-buffered saline with 1% Tween 20.

Received 2/ 4/02. Accepted 5/23/02.

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