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Detection of Blood-borne Cells in Colorectal Cancer Patients by Nested Reverse Transcription-Polymerase Chain Reaction for Carcinoembryonic Antigen Messenger RNA

Longitudinal Analyses and Demonstration of Its Potential Importance as an Adjunct to Multiple Serum Markers¹

Laboratory of Clinical Pathology [F. G., S. A., M. D. C., A. S., R. D. A., M. R. A.], II Division of Surgical Oncology [M. C., F. G., F. C.], III Division of Surgical Oncology [S. C., P. P.], and Department of Pathology [F. S.], Regina Elena Cancer Institute, 00144 Rome, Italy; Laboratory of Tumor Immunology and Biology [J. K., J. W. G., S. V. S. K., J. S.], Biostatistics and Data Management Section [S. M. S.], National Cancer Institute, NIH, Bethesda, Maryland 20892; and Department of Surgery, University of Rome Tor Vergata, 00144 Rome, Italy [M. R.]

	ABSTRACT

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The use of reverse transcription-PCR (RT-PCR) to analyze cells in the blood of cancer patients for the detection of mRNA expressed in tumor cells has implications for both the prognosis and the monitoring of cancer patients for the efficacy of established or experimental therapies. Carcinoembryonic antigen (CEA) is expressed on 95% of colorectal, gastric, and pancreatic tumors, and on the majority of breast, non-small cell lung, and head and neck carcinomas. CEA shed in serum is useful as a marker in only 50% of colorectal cancer patients and rarely is shed by some other carcinoma types. RT-PCR has been used previously to detect CEA mRNA in cells in the blood and lymph nodes of cancer patients. Under the assay conditions validated in the studies reported here, 34 of 51 (67%) patients with different stages of colorectal cancer had blood cells that were positive by RT-PCR for CEA mRNA, whereas none of 18 patients with colonic polyps were positive; 2 of 60 apparently healthy individuals (who were age and sex matched with the carcinoma patients and were part of a colon cancer screening program as controls) were marginally positive. The results of CEA PCR in the blood of the carcinoma patients and the other groups showed strong statistical correlation with the disease (P2 < 0.0001). Analyses were carried out to detect both serum CEA protein levels and CEA mRNA in blood cells of colorectal carcinoma patients by RT-PCR. For all stages of disease, 18 of 51 patients (35%) were positive for serum CEA, whereas 35 of 51 (69%) were positive by RT-PCR. More importantly, only 5 of 23 (20%) of stage B and C colorectal cancer patients were positive for serum CEA, whereas 16 of 23 (70%) were positive by RT-PCR. The use of two other serum markers (CA19.9 and CA72-4) for colorectal cancer in combination with serum CEA scored two additional patients as positive; both were positive by RT-PCR for CEA mRNA. Pilot long-term longitudinal studies conducted before and after surgery identified some patients with CEA mRNA in blood cells that were negative for all serum markers, who eventually developed clinical metastatic disease. The studies reported here are the first to correlate RT-PCR results for CEA mRNA in blood cells with one or more serum markers for patients with different stages of colorectal cancer, and are the first long-term longitudinal studies to use RT-PCR to detect CEA mRNA in blood cells of cancer patients. Larger cohorts will be required in future studies to define the impact, if any, of this technology on prognosis and/or disease monitoring.

	INTRODUCTION

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One of the newer areas being explored in the management of cancer is the use of RT-PCR³ to analyze the blood of cancer patients for the detection of mRNA expressed in tumor cells (1, 2, 3, 4, 5, 6, 7) . This technology may aid in three major areas in the management of cancer: (a) predicting which patients will have a favorable outcome following removal/treatment of the primary lesion; (b) more efficiently analyzing ways to follow the efficacy of known therapies; and (c) defining ways to more rapidly determine the efficacy of a new experimental therapy.

The gene for CEA is one of the most widely expressed genes in cancer cells. It is expressed in 95% of colorectal, gastric, and pancreatic cancers; on the majority of non-small cell lung cancers and other carcinoma types, such as squamous cell cancer of the head and neck; and in 50% of breast cancers (8) . Serum CEA protein currently is used to follow the course of therapy in the management of colorectal carcinoma (9) . Although CEA protein is expressed in tumors of other types, it rarely is shed into the serum in levels that can be detected. Furthermore, even in the case of colorectal cancer, it has been shown that only approximately half of colorectal cancers shed CEA in levels sufficient for their detection in monitoring therapy (10) . Moreover, it has been shown by statistical analysis that there is no correlation between the level of CEA expression in tumor biopsies and the presence of CEA protein in the serum (9) . Thus, for various aspects in the management of colorectal cancer and perhaps for other carcinoma types, detection in the blood of tumor cells that express CEA could conceivably help in the prognosis of patients, following the clinical course of patients, and analysis of standard therapies as well as new experimental therapies.

Numerous studies have reported the use of RT-PCR technology to detect CEA message in tumor cells from peripheral blood, lymph nodes, or peritoneal washes of cancer patients (2 , 11, 12, 13, 14, 15, 16, 17) . These methods have varied in terms of (a) primers used, (b) amount of RNA used, (c) amount of blood analyzed, (d) assay conditions, and (e) methodology to amplify the CEA message. As a result, the literature contains reports with conflicting findings as to the detection of CEA-containing cells in peripheral blood of "apparently healthy" donors as well as cancer patients. Some of the studies in which healthy donors were reported to have CEA-containing cells in their blood used primers that were not unique to CEA and indeed contained sequences shared between CEA and CEA-related proteins, such as NCA, which is expressed in skin and in granulocytes. There are several reports, however, in which primers specific for CEA were used and, to enhance the sensitivity, nested RT-PCR was performed (14 , 18) . With these methodologies, CEA-positive cells were not detected in the blood of healthy donors, but were found in approximately one-half to two-thirds of colon cancer patients. These studies analyzed peripheral blood samples by RT-PCR prior to surgery and 24 h after surgery (19) . In the studies reported here, we have essentially confirmed these previous findings, using minor modifications of previously published methods. Additionally, we report here, for the first time, long-term longitudinal analyses of blood cells from patients of different stages of colorectal cancer by nested RT-PCR for CEA mRNA. We have also compared, for the first time, these results with three known serum markers used in the management of colorectal cancer patients. The results demonstrate that the nested RT-PCR technology for CEA mRNA can, in some cases, detect CEA-expressing blood-borne cells in patients negative for the serum markers and can, in some cases, precede clinical detection of disease. We also show, in patients with early-stage disease, a lack of association between the detection of CEA mRNA in blood-borne cells and the detection of serum CEA, although there is some evidence of a relationship between these two measures in patients with more advanced disease. These studies thus form the basis for larger scale prospective studies toward the goal of using nested RT-PCR to detect CEA mRNA in blood-borne cells in the management of colorectal cancer and, perhaps, other CEA- expressing tumors.

	MATERIALS AND METHODS

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Patients and Samples
Patients’ Characteristics.
We evaluated 51 patients with histologically diagnosed primary colorectal adenocarcinoma (27 males, 24 females; mean, 60.1 years; range, 44–80 years). All patients with malignant disease underwent surgery for their primary tumor at the Regina Elena Cancer Institute or the University of Rome "Tor Vergata," Rome, Italy. Malignant colorectal disease was pathologically staged according to the Astler-Coller classification: stage A (n = 6), stage B1 (n = 7), stage B2 (n = 8), stage C1 (n = 3), stage C2 (n = 5), stage D (n = 17), and locoregional recurrences (n = 5). Tissue biopsies of histologically confirmed neoplastic tissues were obtained at surgery, immediately fixed in formalin, embedded in paraffin, and subsequently evaluated for CEA expression by immunohistochemistry. Carcinoma specimens were evaluated by histopathology and were shown to be free of necrotic areas and to consist of at least 50% malignant cells.

Forty apparently healthy donors and 18 patients with benign colorectal disease were also included in the study. Healthy donors were subjects enrolled in an institutional program of screening and surveillance for gastrointestinal cancer. Blood samples from patients with benign lesions were obtained just prior to digestive endoscopy. Diagnosis was confirmed by histological evaluation.

Blood Samples.
A 7-ml sample of venous blood was collected at the time of diagnosis by standard transcutaneous needle venipuncture into 7-ml Vacutainers containing lithium heparin from colorectal patients with either benign (n = 18) or malignant (n = 51) disease. Similarly, blood samples were obtained from apparently healthy donors (n = 40). Moreover, in 10 of the healthy donors, multiple Vacutainers (up to five), each containing 7 ml of peripheral blood, were obtained by the same needle transcutaneous venipuncture and numbered in sequence from 1 to 5, with 1 representing the first blood sample collected. Furthermore, in 13 of the 51 colorectal carcinoma patients, two to three Vacutainers containing 7 ml of peripheral blood (numbered in sequence from 1 to 3) were obtained on 2 different days no more than 1 week before surgery. Blood cells were isolated as peripheral blood mononuclear cells by Histopaque (Sigma Chemical Co., St. Louis, MO) and subjected to density gradient centrifugation at 2000 rpm for 30 min at room temperature. Cells were recovered from the plasma-Histopaque interface and washed twice with sterile phosphate buffer solution (GIBCO BRL, Life Technologies, Gaithersburg, MD). Cell pellets were snap frozen and stored at -80°C until RNA extraction.

Immunohistochemical Analyses
Immunohistochemical analyses were performed on paraffin-embedded sections that were cut at 5 µm using a modification of the avidin-biotin-peroxidase complex immunohistochemical method (20) . To evaluate the expression of CEA in tissue-tumor biopsies, the anti-CEA mouse MAb COL-1 was used at a concentration of 20 µg/ml (20) . The negative control antibody MOPC-21 (Sigma) was used at the same concentration.

All tumors were independently evaluated by two pathologists. For each slide, three to five different fields were scored for the presence of tumor cells and the cell-associated diaminobenzidene precipitate staining pattern. Staining intensity was scored as weak (+) for pale brown reactivity, moderate (++) for intermediate brown intensity, and strong (+++) for intensive, dark brown precipitate. The percentage of MAb-positive cells for each slide represented an analysis of the three to five fields for each tissue specimen. In an attempt to unify the two parameters (i.e., percentage of MAb-positive cells and staining intensity) used to define CEA expression, an arbitrary AI was used as reported by Roselli et al. (21) . Briefly, the AI is the product of the percentage of MAb-positive tumor cells and the staining intensity (+ = 1, ++ = 2, +++ = 3). For example, a sample in which 15% of the tumor cells were MAb positive with a relative staining intensity of ++ would have an AI of 30.

Determination of CEA, CA19.9, and CA72-4 in Serum Samples
Serum samples from 51 colorectal cancer patients were drawn no more than 1 week before surgery. Patients were monitored during the perioperative period and postoperatively (i.e., every 3 months at the time of scheduled clinical follow-up). All samples were coded and stored at -20°C until the assays were performed. Serum CEA levels were determined by an enzyme immunoassay test kit (AMDL, Inc., Tustin, CA), using a value of 5 ng/ml as positive (7) . CA19.9, an indicator of mucin TAG-72, was determined using the CA19.9 kit (Fujirebio, Malvern, PA), with the suggested value 37 units/ml as positive (22) . Serum CA72-4 antigen levels, another measure of mucin TAG-72, were determined using the CA72-4 kit (Fujirebio), with the suggested value 6 units/ml as positive (23) .

Statistical Analyses
The association between RT-PCR classification (positive, borderline, or negative) and type of subject (healthy donor, patient with benign colorectal disease, and patient with colorectal cancer) was determined by the Jonckheere-Terpstra test for trend (24) , the Cochran-Armitage trend test (25) , and Fisher’s exact test, as appropriate.

The difference in actual CEA, CA19.9, CA72-4, or AI values between RT-PCR dichotomized as positive (+) versus negative (-) was tested using the Wilcoxon rank-sum test. The same parameters [whether actual values or dichotomized as (-) or (+)] were compared between four levels of RT-PCR (-, +, ++, and +++) using the Jonckheere-Terpstra test for trend. Any results from analyses of 2 x 2 tables were obtained using either the ² test or Fisher’s exact test, as appropriate. All Ps are two-tailed and denoted P2.

Cell Lines
The murine colon adenocarcinoma MC38 and MC38(CEA2) cell lines have been described and characterized (26) . The MC38(CEA2) cell line, developed by transduction of the MC38 cell line with a retroviral construct containing cDNA encoding the human CEA gene, is designated as MC38(CEA) here (26) . The MC38(NCA) line is the result of transduction of MC38 with the human NCA gene and has been characterized (26) . These three cell lines were used as positive and negative controls to establish the CEA-specific RT-PCR methodology. All cell lines were maintained in DMEM supplemented with 2 mM L-glutamine, 0.1 mM nonessential amino acids, 0.1 mM sodium pyruvate, and 10% heat-inactivated fetal bovine serum (Life Technologies).

RNA Extraction
Total RNA from cell lines and blood cells was extracted using TRIZOL (Life Technologies) according to the manufacturer’s protocol. The concentration, purity, and amount of total RNA were determined by UV spectrophotometry. The integrity and quality of the patients’ RNA were assessed by electrophoresis in Tris-acetate-EDTA buffer on 1% agarose gel (FMC Bioproducts, Rockland, ME), with the DNA bands visualized by ethidium bromide staining.

Primers
CEA and ß-actin primers were designed according to published sequence information (18 , 27) , synthesized, and cartridge-purified by ANNOVIS (Aston, PA). These primers were as follows:

ß-actin forward primer: 5'-GCTCACCATGGATGATGATATCGC-3'

ß-actin reverse primer: 5'-GGAGGAGCAATGATCTTGATCTTC-3'

CEA A primer: 5'-TCTGGAACTTCTCCTGGTCTCTCAGCTGG-3'

CEA B primer: 5'-TGTAGCTGTTGCAAATGCTTTAAGGAAGAAGC-3'

CEA C primer: 5'-GGGCCACTGCTGGCATCATGATTG-3'

cDNA Synthesis
cDNA was synthesized using the GIBCO BRL SuperScript Preamplification System (Life Technologies) with 1–5 µg of total RNA, 20 pM of random hexamers, and Moloney murine leukemia virus reverse transcriptase, according to the manufacturer’s instructions.

The integrity of patients’ RNA samples and the fidelity of cDNA synthesis were verified using 2 µl of cDNA to amplify ß-actin in a standard RT-PCR reaction. Each 50-µl reaction contained 20 mM Tris (pH 8.4), 50 mM KCl, 1 mM MgCl₂, 2 mM deoxynucleotide triphosphate; 1 unit of Hot Tub (Amersham Pharmacia Biotech, Piscataway, NJ), and diethyl pyrocarbonate-treated water to 48 µl, and 200 ng each of ß-actin forward and reverse primers. ß-Actin was amplified at 94°C for 2 min, and for 25 cycles at 94°C (30 s), 55°C (30 s), and 72°C (30 s), with a final extension step at 72°C (7 min), using the Perkin-Elmer GeneAmp PCR System 9600 (Applied Biosystems Division, Perkin-Elmer, Foster City, CA). The ß-actin PCR product, a DNA fragment of 1 kb, was resolved for each patient’s sample by electrophoresis on 1% agarose in Tris-acetate-EDTA buffer and visualized by ethidium bromide staining of the gel.

CEA Nested RT-PCR
The nested RT-PCR was performed as described previously (18) , with some modifications. For the first round of PCR, 80 µl of PCR Buffer (Applied Biosystems Division, Perkin-Elmer), containing 1.5 mM MgCl₂, 0.8 µM CEA primers A and B, 200 µM deoxynucleotide triphosphate, 2 µl of cDNA, and 2 units of AmpliTaq Gold (Applied Biosystems Division, Perkin-Elmer) were added to the tubes. CEA amplification was performed by heating at 95°C (10 min), followed by 20 rounds of denaturation at 95°C (1 min), annealing and polymerase extension at 72°C (2 min), and a final extension step at 72°C for 10 min. Amplified product (5 µl) was transferred to a second tube with the above buffer containing 0.4 µM primers C and B and 2 units of AmpliTaq Gold; the tubes were heated to 95°C for 10 min to activate the Taq polymerase, followed by 30 cycles of denaturation at 95°C (1 min), annealing at 69°C (1 min), polymerase extension at 72°C (1 min), and a final extension step for 10 min at 72°C. The 131-bp CEA PCR product was identified by electrophoresis of 10 µl through 4% NuSieve 3:1 plus agarose (FMC Bioproducts) in Tris-borate-EDTA buffer and ethidium bromide staining.

Each RT-PCR run included a positive control synthesized from the transduced MC38(CEA) cell line (CEA positive), the negative cell line MC38, and cells from a negative blood donor. Each PCR run also included a sample containing PCR buffer but no cDNA. The RT-PCR method was standardized by loading equal volumes of PCR product on agarose gels to ensure that the intensity of the ß-actin bands reflected an equivalent amount of ethidium bromide-detectable products.

The 131-bp products from blood cells and the MC38(CEA) line were sequenced and found to be identical to the CEA sequence published by Schrewe et al. (27) .

	RESULTS

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Studies were first conducted to determine the optimal amount of RNA necessary for the detection of CEA-positive cells in blood samples by nested RT-PCR using the primers described in "Materials and Methods." As seen in Table 1 (series I), total RNA was extracted from peripheral blood mononuclear cell preparations of 20 apparently healthy donors (age- and sex-matched with colorectal cancer patients as part of a cancer surveillance study) and 20 patients with metastatic colorectal cancer; 1, 2, and 5 µg of total RNA were used to synthesize cDNA. cDNA was then analyzed by nested RT-PCR using the CEA-specific primers. With these methods, none of the 20 healthy donors were positive for CEA expression at any of the three RNA levels. The percentage of positive colorectal cancer patients with advanced disease clearly went up with increasing amounts of RNA to a detection level of 75% when 5 µg of RNA were used. This is exemplified in Fig. 1A , where total RNA extracted from three different patients with advanced colorectal cancer was analyzed using 5 and 1 µg of RNA. As seen in Fig. 1A , the 1 µg samples (Lanes 4–6) were negative, whereas the 5 µg samples (Lanes 1–3) gave detectable signals by ethidium bromide staining.

View larger version (49K): [in this window] [in a new window] [Download PPT slide]   Fig. 1. Optimization of the sensitivity and specificity of the RT-PCR assay for CEA mRNA. A, improvement in RT-PCR sensitivity using different amounts of total RNA. Agarose gel electrophoresis of CEA RT-PCR amplification products from peripheral blood cells of three different metastatic colorectal carcinoma patients when cDNA was synthesized using either 5 µg (Lanes 1–3) or 1 µg (Lanes 4–6) of total RNA. Lane 7, cDNA negative control. Arrow, 131-bp CEA band. M, 100-bp DNA ladder (also seen in B–D). B, evaluation of two different blood samples obtained at days 7 and 1 prior to surgery, using two different blood volumes from the same colorectal cancer patient. Lane 1, MC38(CEA) cell line. Lane 2, MC38 cell line. Lanes 3 and 4, 15 and 7 ml of blood, respectively, from a colorectal cancer patient 7 days prior to surgery. Lanes 5 and 6, 15 and 7 ml of blood, respectively, from the same patient 1 day prior to surgery. Lane 7, cDNA negative control. C, evaluation of the specificity of the RT-PCR reaction. Lane 1, MC38(CEA) cells expressing CEA. Lanes 2 and 3, MC38 and MC38(NCA), respectively. Lanes 4–11 (and Lanes 1–11 in D), blood samples from 19 different, apparently healthy donors.

RNA was then extracted from blood cells from an additional 40 apparently healthy donors who were enrolled in an institutional gastrointestinal cancer screening program (Table 1 , series II). These subjects were age and sex matched with the colorectal cancer patients analyzed in this study. RNA was also extracted from blood cells obtained prior to colonoscopy from 18 patients in whom adenomatous polyps had been detected via colonoscopy. RNA was also extracted from blood cells of 51 patients with various stages of colorectal carcinoma, as will be detailed below. As can be seen in Table 1 (series II), 95% of the donors in the surveillance program were negative by CEA RT-PCR, whereas 2 of the 40 demonstrated a marginal positivity. It should be pointed out that the 20 donors initially tested in the RNA titration experiments (Table 1 , series I) were again negative when retested using 5 µg of total RNA. It should also be pointed out that the RNA from these 20 patient samples has subsequently been tested by RT-PCR five additional times, always with negative results. Thus, a total of 60 apparently healthy individuals were tested at the 5 µg of RNA level; of these individuals, 2 (3.3%) were marginally positive (Table 1 , series I and II). All 18 patients with polyps tested in an identical manner were negative (Table 1) ; 34 of 51 (67%) patients with different stages of colorectal cancer were positive, and 1 additional patient was marginally positive (Table 1) . When we compared these three groups and included the marginally positive result as a separate, intermediate category, there was a strong statistically significant association between the RT-PCR result and type of subject evaluated (P2 < 0.0001). When donors and patients with benign colorectal disease were pooled, the difference remained strongly significant (P2 < 0.0001). Finally, when we used a dichotomized RT-PCR result (-) versus (+, ±) and compared the combination of donors and patients with benign disease versus those with malignant disease, we found an extremely strong relationship between RT-PCR result and the presence or absence of malignant disease (P2 < 7.5 x 10^-17). Thus, regardless of the categorization, there is a strong association between the RT-PCR result and type of specimen evaluated.

CEA mRNA from blood cells of patients with different stages of colorectal carcinoma was then analyzed by RT-PCR prior to surgery (Table 2) . Surprisingly, two of six patients with stage A colorectal cancer were positive by RT-PCR. All six of these patients were negative for serum CEA protein (Table 2) . Follow-up studies of the two positive patients are detailed below. Four of seven patients with stage B1 colorectal cancer were also positive by RT-PCR prior to surgery, whereas only one of these seven patients was positive for serum CEA. Five of eight stage B2 patients were positive by RT-PCR, whereas only one of these patients was positive for serum CEA (Table 2) . Analysis of blood cells by RT-PCR revealed that seven of eight patients with stage C1 and C2 colorectal carcinoma were positive by RT-PCR prior to surgery (Table 2) . Three of these patients were positive for serum CEA, and one of these patients was also negative by RT-PCR. This patient (patient 25) will be discussed below. As seen in Table 2 , 13 of 17 patients with stage D colorectal cancer with metastases at various sites were positive by RT-PCR prior to surgery; moreover, four of five patients with locoregional recurrence were positive by RT-PCR prior to surgery. Many of these patients with stage D and locoregional recurrence were also positive for serum CEA (Table 2) .

View larger version (20K): [in this window] [in a new window] [Download PPT slide]   Fig. 2. Relationship between CEA RT-PCR results and CEA serum levels and CEA expression in tumor tissue. A, modest overall association between serum CEA levels and RT-PCR analysis for CEA in the blood of colorectal cancer patients. [P2 = 0.11, comparing four groups as shown; P2 = 0.02 comparing (+) versus (-)]. B, strong relationship between CEA expression in tumor tissue by immunohistochemistry and RT-PCR analysis for CEA in the blood of colorectal cancer patients (P2 = 0.0041). NEG, negative.

Four patients with stage A colorectal carcinoma were followed by RT-PCR and serum markers for 122–675 days postsurgery (Table 5) . Prior to surgery, patient 2 was positive for CEA by RT-PCR, positive for serum markers CA19.9 and CA72-4, but negative for serum CEA. As shown in Table 5 , five longitudinal samples postsurgery were negative for CEA by RT-PCR as well as for all three serum markers. Patient 4, on the other hand, was positive by RT-PCR analysis prior to surgery, as well as at days 47 and 122 postsurgery, but remained negative for all three serum markers throughout the 122-day observation period. Approximately 1 month after the day 122 RT-PCR analysis, this patient was diagnosed with peritoneal recurrence of colorectal carcinoma. The two other stage A patients with colorectal carcinoma were negative for CEA by RT-PCR and for all three serum markers, both prior to surgery and at the several time intervals analyzed postsurgery (Table 5) .

Four stage D patients with metastatic colorectal carcinoma and one stage C2 patient who received chemotherapy immediately after surgery were also analyzed by RT-PCR for CEA-positive cells in the blood and by three serum markers (Table 6) . Two of these patients (patients 26 and 38) were positive prior to surgery and when analyzed postsurgery by both CEA RT-PCR and serum CEA. The stage C2 patient (patient 26) underwent a course of adjuvant chemotherapy after removal of the primary tumor; during the 6 months of treatment, CEA RT-PCR remained positive. Subsequently, the patient developed lung metastases, which were diagnosed on day 420. Two additional patients (patients 31 and 37) were positive by RT-PCR prior to surgery, became negative during chemotherapy, and subsequently became positive. Both of these patients were initially characterized as "responsive" to chemotherapy but were diagnosed with progressive disease. Patient 46, on the other hand, was negative for all three serum makers prior to surgery and at all subsequent samples to day 219 postsurgery. This patient, however, was positive for CEA by RT-PCR prior to surgery and remained positive through the 219-day observation period (Table 6) . At this time, however, this patient is defined clinically as a "complete response."

	DISCUSSION

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These comparisons were extended to include three serum markers (i.e., CEA, CA19.9, and CA72-4) that are used to follow colorectal cancer disease progression (Table 2) . Of the 51 patients analyzed, 20 were positive for at least one of three serum markers and by RT-PCR, and 12 were negative for all serum markers and negative by RT-PCR. Four of the 51 patients were negative by RT-PCR and positive for at least one serum marker. However, 15 of the 51 patients (29.4%) were negative for all three serum markers and positive for CEA mRNA in blood-borne cells by RT-PCR. These studies in toto indicate that the detection of CEA-expressing blood-borne cells by RT-PCR is potentially different from all three serum markers and, at times, can be advantageous when used in combination with serum markers. The lack of general correlation between the detection of blood-borne cells expressing CEA by RT-PCR and CEA protein in the blood, although varying to some degree by stage of disease, is not surprising in light of the fact that previous studies (9) demonstrated a lack of correlation between serum CEA levels and CEA expression in tumor biopsies from the same patient. Indeed, two phenomena are likely occurring here: the CEA RT-PCR analysis is most likely detecting the presence of tumor cells in peripheral blood, whereas levels of serum CEA have been shown to generally correlate with tumor mass. The studies reported here confirm and extend the observations of Mori et al. (1) , who demonstrated a correlation between the stage of disease and the detection of CEA-positive cells by RT-PCR in the blood.

The studies reported here also demonstrate a positive relationship between the detection of CEA-positive blood-borne cells by RT-PCR and CEA expression in tumor biopsy from the same patient by immunohistochemistry (Table 4) . It is of interest to note that two of nine patients with metastatic disease were negative by RT-PCR. Analysis of tumor biopsies of both of these patients demonstrated that they were indeed also negative for CEA expression in the tumor. These studies thus indicate that an optimal analysis of blood for the detection of cells may ultimately involve the use of primers for two or more tumor-associated genes. Other studies have used the detection of mRNA of cytokeratin 19 or 20 (28 , 29) , or MUC-1 (6) toward this goal. Future studies for the detection of these and other genes, in combination with the use of probes for the detection of CEA, will perhaps bear out this point.

The studies reported here also demonstrate that minor changes in methodology can manifest substantial alterations in results. As seen in Table 1 , the use of 5 µg of RNA was better than using the smaller amounts that were used in several previous reports (1 , 15, 16, 17, 18) . These findings, as well as a review of the literature, underscore the need for eventual standardization of methodologies and reagents to detect antigen-expressing cells in blood by RT-PCR.

The studies reported here are the first to analyze blood samples longitudinally by RT-PCR for colorectal patients at various stages of disease. Our results indicate that analysis of blood samples within 1 month of surgery is not reliable in adequately reflecting the long-term prospect for detection or lack of detection of CEA-expressing cells by RT-PCR. This may be attributable to the fact that after surgery, patients receive numerous transfusions that can dilute and mask the detection of CEA-positive cells in the blood. Other factors not understood at this time may also be responsible for this phenomenon. Of interest, however, were the results obtained here from longer term follow-up of patients at different stages of colorectal cancer by both CEA RT-PCR and three serum markers. One of four stage A colorectal cancer patients remained positive for CEA-expressing cells in the blood by RT-PCR up to 122 days postsurgery, but remained negative for all three serum markers (Table 5) . This patient was subsequently diagnosed with peritoneal metastases. Also of interest is the analysis of one of five patients with stage B2 colon carcinoma (Table 5 , patient 21). Prior to surgery, this patient was negative for CEA by RT-PCR and all three serum markers. At 108 days postsurgery, the patient remained negative for all of the serum markers but was strongly positive for RT-PCR. At day 677 postsurgery, the patient remained strongly positive for CEA-expressing cells in the blood by RT-PCR and negative for serum CEA, but became slightly positive for the CA72-4 serum marker. This patient was also subsequently diagnosed with recurrent pelvic carcinoma; here, the presence of CEA-positive cells in the blood was detected 629 days prior to recurrence of disease. Large randomized prospective studies will be required to define the role of CEA RT-PCR in the management of colorectal cancer. The studies reported here do demonstrate, however, the possibility that longitudinal analyses of blood-borne cells expressing CEA by RT-PCR may be useful for the management of colorectal cancer and other CEA-expressing tumors in terms of prognosis, in the analysis of the response to existing therapies, and perhaps in the analysis of new therapies.

	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 in part by a grant from the Italian Ministry of Health, Progetto Finalizzato Ministero della Sanità.

² To whom requests for reprints should be addressed, at Laboratory of Tumor Immunology and Biology, National Cancer Institute, NIH, 10 Center Drive, Building 10, Room 8B09, Bethesda, MD 20892. Phone: (301) 496-4343; Fax: (301) 496-2756; E-mail: js141c{at}nih.gov

³ The abbreviations used are: RT-PCR, reverse transcription-PCR; CEA, carcinoembryonic antigen; NCA, normal cross-reacting antigen; MAb, monoclonal antibody; AI, antigen index.

Received 11/ 1/00. Accepted 1/11/01.

	REFERENCES

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 

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