Proteomic analysis of nuclei dissected from fixed rat brain tissue using expression microdissection

Expression microdissection (xMD) is a high-throughput, operator-independent technology that enables the procurement of specific cell populations from tissue specimens. In this method, histological sections are first stained for cellular markers via either chemical or immuno-guided methods, placed in close contact with an ethylene vinyl acetate (EVA) film, and exposed to a light source. The focal, transient heating of the stained cells or subcellular structures melts the EVA film selectively to the targets for procurement. In this report, we introduce a custom-designed flashcube system that permits consistent and reproducible microdissection of nuclei across an FFPE rat brain tissue section in milliseconds. In addition, we present a method to efficiently recover and combine captured proteins from multiple xMD films. Both light and scanning electron microscopy demonstrated captured nuclear structures. Shotgun proteomic analysis of the samples showed a significant enrichment in nuclear localized proteins, with an average 25% of recovered proteins localized to the nucleus, versus 15% for whole tissue controls (p < 0.001). Targeted mass spectrometry using multiple reaction monitoring (MRM) showed more impressive data, with a 3-fold enrichment in histones, and a concurrent depletion of proteins localized to the cytoplasm, cytoskeleton, and mitochondria. These data demonstrate that the flashcube-xMD technology is applicable to the proteomic study of a broad range of targets in molecular pathology.

Identification of a unique epigenetic sub-microenvironment in prostate cancer

The glutathione S-transferase P1 (GSTP1) gene promoter is methylated in tumour cells in more than 90% of prostate carcinomas. Recently, GSTP1 promoter methylation was identified in tumour-associated stromal cells in addition to the tumour epithelium. To define the extent and location of stromal methylation, epigenetic mapping using pyrosequencing quantification of GSTP1 promoter methylation and an anatomical three-dimensional reconstruction of an entire human prostate specimen with cancer were performed. Normal epithelium and stroma, tumour epithelium, and tumour-associated stromal cells were laser capture-microdissected from multiple locations throughout the gland. As expected, the GSTP1 promoter in both normal epithelium and normal stromal cells distant from the tumour was not methylated and the tumour epithelium showed consistently high levels of promoter methylation throughout. However, tumour-associated stromal cells were found to be methylated only in a localized and distinct anatomical sub-field of the tumour, revealing the presence of an epigenetically unique microenvironment within the cancer. Morphologically, the sub-field consisted of typical, non-reactive stroma, representing a genomic alteration in cells that appeared otherwise histologically normal. Similar epigenetic anatomical mapping of a control prostate gland without cancer showed low background methylation levels in all cell types throughout the specimen. These data suggest that stromal cell methylation can occur in a distinct sub-region of prostate cancer and may have implications for understanding tumour biology and clinical intervention.

Hypoxia effect on non-malignant prostatic urethra during prostatectomy

20048

Background: With changes in technology and surgical technique paving the way to improved prostectomies, attention must be paid to the effects of hypoxia during variable surgical times. Hypoxia has been reported to play various roles that are implicated in the development of spurious molecular mutagenesis and tumorogenesis. However, the specifics leading to alterations and downstream effects in non-malignant tissues are unknown. Further, the consequence of hypoxia on tissues for analysis of tumor markers may be confounded. The objective of our study is to evaluate the effects of iatrogenic ischemia on surrounding non-malignant tissue in patients undergoing prostatectomy. As potential tissue markers to assess putative hypoxia tissue damage, gene expression levels in microdissected cell populations were evaluated. Methods: Normal prostatic urethra tissue was procured from five patients with laparoscopic 5 mm biopsy forceps at three time points during surgery and was immediately imbedded in OCT and placed on dry ice. First biopsy was taken prior to loss of blood supply after anterior bladder neck dissection. Second biopsy was taken directly after prostate was isolated from the patient. Third biopsy was taken ex vivo after vesico-urethral anastomosis. Urethral epithelium samples were normalized using the gold standard cell counting (2,000 microdissected cells) and quantitation of total RNA was conducted using NanoDrop technique. Gene expression analysis was assessed using quantitative RT-PCR (qRT-PCR) of four historically high and low abundant housekeeping genes (18s, ACTB, CYPA, and TFRC). Results: Housekeeping genes were up-regulated with an average four fold increase in transcript RNA at each time point respectively. Conclusion: These data suggest that hypoxia plays a putative significant role in the expression of genes in non-malignant tissues. The additional gene sets for analysis include traditional hypoxia related genes (e.g. HIF-1a, VEGF, AKT, and VHL) and non-hypoxia related genes (e.g. LAMP2, MTR, and STAT5B) to further investigate the prospective global up-regulation of gene expression. The conclusions may elucidate the role of hypoxia in disease processes and potentially its role in confounding or influencing tumor marker gene expression between patient samples.

[Table: see text]

Common genetic variants of TP53 and BRCA2 in esophageal cancer patients and healthy individuals from low and high risk areas of northern China

TP53 and BRCA2 are frequently mutated in cancer and polymorphisms of these genes may modify cancer risk. We used SSCP and DNA sequencing to assess and compare frequencies of R72P (TP53) and 5'UTR203G>A, N372H, and K1132K (BRCA2) polymorphisms in healthy Chinese subjects at varying risk for esophageal squamous cell carcinoma (ESCC) and in ESCC patients. Suggestive overall differences in the distributions of genotypes by risk groups were seen for all genotypes except K1132K. Differences in R72P and N372H were most likely a reflection of lack of Hardy-Weinberg equilibrium (HWE), however, the difference in 203G>A was due to low prevalence of GG in ESCC patients (0.22 versus 0.36 in high risk group (P=0.047), and 0.22 versus 0.40 in low risk group (P=0.010)), consistent with a disease association. These data suggest that the 203G>A polymorphism in BRCA2 may be associated with risk of ESCC.

Gene discovery in oral squamous cell carcinoma through the Head and Neck Cancer Genome Anatomy Project: confirmation by microarray analysis

The near completion of the human genome project and the recent development of novel, highly sensitive high-throughput techniques have now afforded the unique opportunity to perform a comprehensive molecular characterization of normal, precancerous, and malignant cells, including those derived from squamous carcinomas of the head and neck (HNSCC). As part of these efforts, representative cDNA libraries from patient sets, comprising of normal and malignant squamous epithelium, were generated and contributed to the Head and Neck Cancer Genome Anatomy Project (HN-CGAP). Initial analysis of the sequence information indicated the existence of many novel genes in these libraries [Oral Oncol 36 (2000) 474]. In this study, we surveyed the available sequence information using bioinformatic tools and identified a number of known genes that were differentially expressed in normal and malignant epithelium. Furthermore, this effort resulted in the identification of 168 novel genes. Comparison of these clones to the human genome identified clusters in loci that were not previously recognized as being altered in HNSCC. To begin addressing which of these novel genes are frequently expressed in HNSCC, their DNA was used to construct an oral-cancer-specific microarray, which was used to hybridize alpha-(33)P dCTP labeled cDNA derived from five HNSCC patient sets. Initial assessment demonstrated 10 clones to be highly expressed (>2-fold) in the normal squamous epithelium, while 14 were highly represented in the malignant counterpart, in three of the five patient sets, thus suggesting that a subset of these newly discovered transcripts might be highly expressed in this tumor type. These efforts, together with other multi-institutional genomic and proteomic initiatives are expected to contribute to the complete understanding of the molecular pathogenesis of HNSCCs, thus helping to identify new markers for the early detection of preneoplastic lesions and novel targets for pharmacological intervention in this disease.

Allelic loss on chromosome bands 13q11-q13 in esophageal squamous cell carcinoma

Allelic loss on chromosome 13 occurs frequently in esophageal squamous cell carcinoma. However, studies of the two known tumor suppressor genes located on 13q, RB1 and BRCA2, have shown few mutations, suggesting that other genes are likely to be involved in the development of this tumor type. To identify a minimal deletion interval, we first analyzed 42 microsatellite markers spanning chromosome bands 13q11-q13 in 56 esophageal squamous cell carcinoma patients, including 34 with a family history of upper gastrointestinal cancer and 22 without a family history of cancer. Lifestyle risk factors and clinical/pathologic characteristics were also collected. Two commonly deleted regions were identified: one was located on band 13q12.11, between markers D13S787 and D13S221; the other was located on bands 13q12.3-q13.1 from markers D13S267 to D13S219. We observed higher allelic loss frequencies for eight of the microsatellite markers in those patients with a family history of upper gastrointestinal cancer compared to patients without such a history. This study suggests that one or more unidentified tumor suppressor genes are located on chromosome arm 13q that play a role in the development of esophageal squamous cell carcinoma.

Reverse phase protein microarrays which capture disease progression show activation of pro-survival pathways at the cancer invasion front

Protein arrays are described for screening of molecular markers and pathway targets in patient matched human tissue during disease progression. In contrast to previous protein arrays that immobilize the probe, our reverse phase protein array immobilizes the whole repertoire of patient proteins that represent the state of individual tissue cell populations undergoing disease transitions. A high degree of sensitivity, precision and linearity was achieved, making it possible to quantify the phosphorylated status of signal proteins in human tissue cell subpopulations. Using this novel protein microarray we have longitudinally analysed the state of pro-survival checkpoint proteins at the microscopic transition stage from patient matched histologically normal prostate epithelium to prostate intraepithelial neoplasia (PIN) and then to invasive prostate cancer. Cancer progression was associated with increased phosphorylation of Akt (P<0.04), suppression of apoptosis pathways (P<0.03), as well as decreased phosphorylation of ERK (P<0.01). At the transition from histologically normal epithelium to PIN we observed a statistically significant surge in phosphorylated Akt (P<0.03) and a concomitant suppression of downstream apoptosis pathways which proceeds the transition into invasive carcinoma.

Genetic progression and heterogeneity associated with the development of esophageal squamous cell carcinoma

Esophageal squamous cell carcinoma is a common fatal cancer, and Shanxi province, a region in north-central China, has some of the highest esophageal cancer rates in the world. Chromosomal regions with frequent allelic loss may point to major susceptibility genes that will assist us in understanding the molecular events involved in esophageal carcinogenesis and may serve as the basis for the development of markers for genetic susceptibility and screening for early detection of this cancer. This study was designed to identify events in the molecular progression of precursor and invasive lesions of squamous esophageal cancer. Twelve marker loci identified during our previous studies as having some of the highest rates of loss of heterozygosity (LOH) in invasive esophageal cancer were evaluated in laser-microdissected DNA obtained from low- and high-grade dysplastic lesions and invasive tumor foci from 10 fully embedded esophageal resection specimens. Each resection specimen contained a spectrum of disease, from epithelium that appeared histologically normal to invasive cancer, including a single dominant tumor surrounded by a region of precursor lesions (low- and high-grade dysplasia) and occasional "remote," nonadjacent precancerous foci. Using the 12 polymorphic markers, LOH was found in all of the three stages of disease. The frequency of LOH for all of the markers together increased with increasing disease severity. Among the informative low-grade dysplasia samples, LOH was detected with markers D3S1766 (3p), D4S2632 (4p), D9S910 (9q), and D13S1493 (13q), suggesting that LOH at these loci may be associated with early stages of tumor initiation and/or progression. LOH was detected among the informative high-grade (but not low-grade) dysplasia samples for the other eight markers tested, suggesting that LOH at these loci may occur later in the neoplastic process. In addition to the association between disease progression and these genetic changes, considerable genetic heterogeneity was found in each fully embedded resection specimen both between and within geographically separate neoplastic lesions.

Molecular profiling of tissue samples using laser capture microdissection

The management of cancer and other genetically based diseases is far from optimal in even our most advanced medical centers. There is still uncertainty regarding how diseases will progress in certain patients, toxicity that must be tolerated with imprecise treatment regimens and significant potential for treatment failure. As our understanding of the complexity of these diseases has increased, it has become clear that we must move toward precisely tailored approaches to treating each individual patient. To that end, a major goal of current medical research is the rapid identification of the specific molecular alterations in each patient's disease. This will enable the design of optimal diagnosis, prognosis and treatment, significantly improving survival. This review describes one important approach to the genetic analysis of disease--molecular profiling--and the tenets and technologies necessary for its success.

Expression studies and mutational analysis of the androgen regulated homeobox gene NKX3.1 in benign and malignant prostate epithelium

PURPOSE

The NKX-3.1gene is an androgen regulated prostate specific homeobox gene that is believed to have a vital role in normal prostate development. In mice the homologue NKx3.1 is exclusively expressed in prostate epithelium. In humans NKX3.1 expression is also restricted to the prostate but to our knowledge the cellular location has not been described. Furthermore, since NKX3.1 maps to chromosomal band 8p21, a region with high loss of heterozygosity in prostate cancer, the gene has been proposed to have tumor suppressor function. In this study we demonstrate that in human prostates NKX3.1 is expressed exclusively in secretory epithelial cells and the level of NKX3.1 expression remains invariant in normal tissue and in tissue showing various grades of prostate cancer. In the 19 cases examined the DNA sequences of the NKX3.1 gene were identical and no mutation was detected.

MATERIALS AND METHODS

Frozen tissue from patients who underwent radical prostatectomy was used for this study. For in situ hybridization experiments a 377 bp fragment corresponding to a portion of the 3' untranslated region of the NKX3.1 gene was amplified by polymerase chain reaction and cloned into the pCRII plasmid vector Invitrogen. Antisense or sense [33P] uridine triphosphate labeled RNA probes were generated with SP6 or T7 RNA polymerase and hybridized to the tissue sections. Slides were exposed to photographic emulsion and visualized on autoradiography. Laser capture microdissection was performed to procure pure populations of malignant epithelium. DNA was isolated by digesting samples in proteinase K buffer. Polymerase chain reaction and direct sequencing was performed using standard protocols.

RESULTS

In vitro hybridization showed that NKX3.1 expression was restricted to secretory epithelial cells within benign prostate glands. No expression was detected in stroma or infiltrating lymphocytes. NKX3.1 was expressed in all grades of malignant epithelium in all 25 cases examined. Direct sequencing of the coding region of NKX3.1 revealed the wild-type sequence in all 18 microdissected cancers analyzed.

CONCLUSIONS

Based on our studies we propose that NKX3.1 gene expression is restricted to benign and malignant secretory epithelium within the prostate but NKX3.1 does not appear to be a classic tumor suppressor gene responsible for prostate cancer initiation. These findings are consistent with the role of NKX3.1 in the development of normal prostate epithelium and maintenance of normal secretory function. Thus, NKX3.1 may represent a useful molecular marker for benign and malignant prostate epithelium.

Frequent inactivation of the TP53 gene in esophageal squamous cell carcinoma from a high-risk population in China

Esophageal squamous cell carcinoma (ESCC) is one of the most common fatal cancers worldwide, and north central China has some of the highest rates in the world. Previous studies from tumors in this area of China have shown high frequencies of allelic loss on chromosome 17p13-11, which includes the region where the TP53 gene is found. We examined 56 ESCC patients using single-strand conformation polymorphism and DNA sequencing to assess the frequency and spectrum of TP53 mutation and the association between allelic loss at microsatellite marker TP53 and TP53 mutations. Ninety-six % of cases were found to have at least one genetic alteration, including TP53 mutation (77%), allelic loss within the TP53 gene (73%), and/or loss of heterozygosity at the TP53 microsatellite marker (80%); 75% had two or more such alterations, including 59% with both a point mutation and an intragenic allelic loss ("two hits"). The majority of mutations observed were in exon 5, where the most common type of nucleotide substitution was a G:C-->A:T or C:G-->T:A transition, including half that occurred at CpG sites. Allelic loss was most commonly found in exon 4 but was very common in exon 5 as well. Taken together, the multiple genetic alterations of TP53 in this population at high risk for ESCC indicate that there is a very high degree of genetic instability in these tumors, that TP53 is a primary target for inactivation, and that this tumor suppressor gene plays a critical role in the carcinogenesis process for ESCC.

A mouse model of multiple endocrine neoplasia, type 1, develops multiple endocrine tumors

Multiple endocrine neoplasia type 1 (MEN1) is an autosomal dominant cancer syndrome, characterized primarily by multiple tumors in the parathyroid glands, endocrine pancreas, and anterior pituitary. Other tumors, including gastrinoma, carcinoid, adrenal cortical tumors, angiofibroma, collagenoma, and lipoma, also occur in some patients. Individuals with MEN1 almost always have loss-of-function mutations in the MEN1 gene on chromosome 11, and endocrine tumors arising in these patients usually show somatic loss of the remaining wild-type allele. To examine the role of MEN1 in tumor formation, a mouse model was generated through homologous recombination of the mouse homolog Men1. Homozygous mice die in utero at embryonic days 11.5-12.5, whereas heterozygous mice develop features remarkably similar to those of the human disorder. As early as 9 months, pancreatic islets show a range of lesions from hyperplasia to insulin-producing islet cell tumors, and parathyroid adenomas are also frequently observed. Larger, more numerous tumors involving pancreatic islets, parathyroids, thyroid, adrenal cortex, and pituitary are seen by 16 months. All of the tumors tested to date show loss of the wild-type Men1 allele, further supporting its role as a tumor suppressor gene.

The role of tissue microdissection in cancer research

Tissue microdissection is a laboratory method that is used to procure specific cells or cell populations from a histology slide under direct microscopic visualization. The recovered cells can be studied with a variety of DNA, messenger RNA, and protein analysis methods, including new high-throughput gene expression and proteomics technologies. This approach is permitting investigators to comprehensivelyexamine the molecular anatomy of cells in tissue sections forthe first time. This article reviews the development and evolution of tissue microdissection techniques, summarizes examples of research studies, and discusses related challenges that the research community must address. Additional information and complete laboratory protocols are available on a website at http://cgap-mf.nih.gov/.

Loss of annexin 1 correlates with early onset of tumorigenesis in esophageal and prostate carcinoma

Annexin I protein expression was evaluated in patient-matched longitudinal study sets of laser capture microdissected normal, premalignant, and invasive epithelium from human esophageal squamous cell cancer and prostatic adenocarcinoma. In 25 esophageal cases (20 by Western blot and 5 by immunohistochemistry) and 17 prostate cases (3 by Western blot and 14 by immunohistochemistry), both tumor types showed either complete loss or a dramatic reduction in the level of annexin I protein expression compared with patient-matched normal epithelium (P < or = 0.05). Moreover, by using Western blot analysis of laser capture microdissected, patient-matched longitudinal study sets of both tumor types, the loss of protein expression occurred in premalignant lesions. Concordance of this result with immunohistochemical analysis suggests that annexin I may be an essential component for maintenance of the normal epithelial phenotype. Additional studies investigating the mechanism(s) and functional consequences of annexin I protein loss in tumor cells are warranted.

High frequency allelic loss on chromosome 17p13.3-p11.1 in esophageal squamous cell carcinomas from a high incidence area in northern China

Allelic loss on chromosome 17p has been reported frequently in esophageal squamous cell carcinoma (ESCC) and generally encompasses the p53 locus at 17p13.1. However, a good correlation between allelic loss on 17p and mutation of p53 has not been found. This suggests the possibility that unknown tumor suppressor genes near p53 may be involved in the development of ESCC. To evaluate this possibility, we analyzed 30 microsatellite markers covering the entire short arm of chromosome 17 in 56 ESCC patients from a high risk population in northern China, including 34 with a family history of upper gastrointestinal (UGI) cancer and 22 without a family history of any cancer. Cancer lifestyle risk factors and clinical/pathological characteristics were also collected. We found frequent allelic loss (>/=65%) at 28 of the 30 markers evaluated in these ESCC patients. The highest frequencies of allelic loss (> or =80%) were found in three smaller regions: deletion region I located at 17p13.3-p13.2 (between D17S849 and D17S1828); deletion region II located at 17p13.2-p13.1 (between D13S938 and TP53); deletion region III located at 17p13.1-p12 (between D17S804 and D17S799). A number of genes have already been identified in these deleted regions, including: OVCA1, OVCA2 and HIC-1 in deletion region I; p53 in deletion region II; ZNF18, ZNF29, ALDH3 and ALDH10 in deletion region III. These results will help us direct future testing of candidate genes and narrow the search region for major new tumor suppressor genes that may play a role in the pathogenesis of ESCC.

Gene expression profiles in squamous cell carcinomas of the oral cavity: use of laser capture microdissection for the construction and analysis of stage-specific cDNA libraries

Head and neck squamous cell carcinoma (HNSCC) is the sixth most common cancer among men in the developed world affecting the oral cavity, salivary glands, larynx and pharynx. Utilizing tissue from patients with HNSCC, we sought to systematically identify and catalog genes expressed in HNSCC progression. Here, we demonstrate the successful use of laser capture microdissection for procuring pure populations of cells from patient tissue sets comprised of oral squamous cell carcinomas (OSCCs) and matching normal tissue. From the estimated 5000 cells procured for each sample, we were able to extract total RNA (14.7-18.6 ng) of sufficient quality to transcribe GAPDH by reverse transcriptase-polymerase chain reaction (RT-PCR). The RNA was used for the synthesis of blunt-ended, double-strand complementary DNAs (cDNAs) by oligo (dT)-mediated reverse transcription, followed by addition of linkers. Primers specific for these linkers with uracil deglycosylase-compatible ends were used to amplify these cDNAs by PCR and the product was subcloned into the pAMP10 cloning vector. Ninety-six clones from each of six libraries were randomly sequenced and results indicated that 76-96% of the inserts represent either anonymous expressed sequence tags (ESTs) (25-48%), known genes (9-29%) or novel sequences (27-51%), respectively, with very little redundancy. These results demonstrate that high quality, representative cDNA libraries can be generated from microdissected OSCC tissue. Furthermore, these finding suggest the existence of at least 132 novel genes expressed in our cDNA libraries, which may have a role in the pathogenesis of HNSCC, and may represent novel markers for early detection as well as targets for pharmacological intervention in this disease.

Analysis of recurrent germline mutations in the MEN1 gene encountered in apparently unrelated families

Multiple endocrine neoplasia type 1 (MEN1) is an autosomal dominant disorder that manifests as varying combinations of tumors of endocrine and other tissues (parathyroids, pancreatic islets, duodenal endocrine cells, the anterior pituitary and others). The MEN1 gene is on chromosome 11q13; it was recently identified by positional cloning. We previously reported 32 different germline mutations in 47 of the 50 familial MEN1 probands studied at the NIH. Eight different germline MEN1 mutations were encountered repeatedly in two or more apparently unrelated families. We analyzed the haplotypes of families with recurrent MEN1 mutations with seven polymorphic markers in the 11q13 region surrounding the MEN1 gene (from D11S1883 to D11S4908). Disease haplotypes were inferred from germline DNA and also from tumors with 11ql3 loss of heterozygosity. Two different disease haplotype cores were shared by apparently unrelated families for two mutations in exon 2 (five families with 416delC and six families with 512delC). These two repeat mutations were associated with the two founder effects that we reported in a prior haplotype analysis. The disease haplotypes for each of the other six repeat mutations (seen twice each) were discordant, suggesting independent origins of these recurrent mutations. Most of the MEN1 germline mutations including all of those recurring independently occur in regions of CpG/CpNpG, short DNA repeats or single nucleotide repeat motifs. In conclusion, recurring germline mutations account for about half of the mutations in North American MEN1 families. They result from either founder effects or independent occurrence of one mutation more than one time.

Proteomic analysis of laser capture microdissected human prostate cancer and in vitro prostate cell lines

Specific populations of normal and malignant epithelium from three radical prostatectomy tissue specimens were procured by laser capture microdissection (LCM) and analyzed by two-dimensional polyacrylamide gel electrophoresis (2-D PAGE). Six proteins that were only seen in malignant cells and two proteins that were only seen in benign epithelium were reproducibly observed in two of two cases examined. Furthermore, these proteins were not observed in the 2-D PAGE profiles from the patient-matched microdissected stromal cell populations, but were seen in the protein profiles from the undissected whole cryostat sections. One of these proteins was determined to be prostate-specific antigen (PSA) by Western blot analysis, and intriguingly the remaining protein candidates were found to be at least as abundant as the PSA protein. Comparison of 2-D PAGE profiles of microdissected cell with matched in vitro cell lines from the same patient, and metastatic prostate cancer cell lines (LnCaP and PC3) showed striking differences between prostate cells in vivo and in vitro with less than 20% shared proteins. The data demonstrate that 2-D PAGE analysis of LCM-derived cells can reliably detect alterations in protein expression associated with prostate cancer, and that these differentially expressed proteins are produced in high enough levels which could allow for their clinical utility as new targets for therapeutic intervention, serum markers, and/or imaging markers.

MEN1 gene mutation analysis of high-grade neuroendocrine lung carcinoma

Neuroendocrine tumors of the lung consist of a spectrum of neoplasms, including typical carcinoids, atypical carcinoids, large-cell neuroendocrine carcinomas (LCNEC), and small-cell lung carcinomas (SCLC). We previously reported frequent inactivation of the gene responsible for multiple endocrine neoplasia type 1 (MEN1) in both typical and atypical carcinoid tumors. In the present study, we extend the analysis of human NE lung tumors to include 9 primary SCLCs, 36 SCLC cell lines, and 13 primary LCNECs for MEN1 gene inactivation. In SCLC, loss of heterozygosity (LOH) at the MEN1 gene on chromosome band 11q13 was detected in one primary tumor and two cell lines. The coding sequence and splice junctions of the MEN1 gene were screened for mutations in all 44 tumors and cell lines, and no mutations were detected. Northern blot analysis of 13 SCLC cell lines showed the MEN1 transcript to be present and of normal size. In LCNECs, a somatic frameshift in the MEN1 gene (1226delC) was found in one of 13 tumors, representing the first mutation observed outside the spectrum of neoplasms associated with MEN1. Interestingly, neither a deletion nor a mutation was detected in the other allele, and wild-type mRNA sequence was expressed in the tumor, suggesting that the MEN1 gene was not inactivated by a conventional two-hit mechanism. The data support the hypothesis that SCLC and lung carcinoids develop via distinct molecular pathways; however, further investigation is necessary to determine the significance of the MEN1 gene mutation observed in a single case of LCNEC. Published 2000 Wiley-Liss, Inc.

Development of a prostate cDNA microarray and statistical gene expression analysis package

A cDNA microarray comprising 5184 different cDNAs spotted onto nylon membrane filters was developed for prostate gene expression studies. The clones used for arraying were identified by cluster analysis of > 35 000 prostate cDNA library-derived expressed sequence tags (ESTs) present in the dbEST database maintained by the National Center for Biotechnology Information. Total RNA from two cell lines, prostate line 8.4 and melanoma line UACC903, was used to make radiolabeled probe for filter hybridizations. The absolute intensity of each individual cDNA spot was determined by phosphorimager scanning and evaluated by a bioinformatics package developed specifically for analysis of cDNA microarray experimentation. Results indicated 89% of the genes showed intensity levels above background in prostate cells compared with only 28% in melanoma cells. Replicate probe preparations yielded results with correlation values ranging from r = 0.90 to 0.93 and coefficient of variation ranging from 16 to 28%. Findings indicate that among others, the keratin 5 and vimentin genes were differentially expressed between these two divergent cell lines. Follow-up northern blot analysis verified these two expression changes, thereby demonstrating the reliability of this system. We report the development of a cDNA microarray system that is sensitive and reliable, demonstrates a low degree of variability, and is capable of determining verifiable gene expression differences between two distinct human cell lines. This system will prove useful for differential gene expression analysis in prostate-derived cells and tissue.

An approach to proteomic analysis of human tumors

A strategy for proteomic analysis of microdissected cells derived from human tumor specimens is described and demonstrated by using esophageal cancer as an example. Normal squamous epithelium and corresponding tumor cells from two patients were procured by laser-capture microdissection and studied by two-dimensional polyacrylamide gel electrophoresis (2D-PAGE). Fifty thousand cells resolved approximately 675 distinct proteins (or isoforms) with molecular weights ranging between 10 and 200 kDa and isoelectric points of pH 3-10. Comparison of the microdissected protein profiles showed a high degree of similarity between the matched normal-tumor samples (98% identical). However, 17 proteins showed tumor-specific alterations, including 10 that were uniquely present in the tumors and seven that were observed only in the normal epithelium. Two of the altered proteins were characterized by mass spectrometry and immunoblot analysis and were identified as cytokeratin 1 and annexin I. Acquisition of 2D-PAGE protein profiles, visualization of disregulated proteins, and subsequent determination of the identity of selected proteins through high-sensitivity MS-MS microsequencing are possible from microdissected cell populations. These separation and analytical techniques are uniquely capable of detecting tumor-specific alterations. Continued refinement of techniques and methodologies to determine the abundance and status of proteins in vivo holds great promise for future study of normal cells and associated neoplasms. Mol.

Layered expression scanning: rapid molecular profiling of tumor samples

Layered expression scanning is a new approach to comprehensive molecular analysis of tumor samples that uses a layered array of capture membranes coupled to antibodies or DNA sequences to perform multiplex protein or mRNA analysis. Cell or tissue samples are transferred through a series of individual capture layers, each linked to a separate antibody or DNA sequence. As the biomolecules traverse the membrane set, each targeted protein or mRNA is specifically captured by the layer containing its antibody or cDNA sequence. The two-dimensional relationship of the cell populations is maintained during the transfer process, thereby producing a molecular profile of each cell type present. Reduction-to-practice of the technique is demonstrated by analysis of prostate-specific antigen (PSA) protein, gelatinase A protein, and POV1 (PB39) cDNA. As layered expression scanning technology progresses, we envision a laboratory method that will have multiple applications for high-throughput molecular profiling of normal and tumor samples.

Identification of novel regions of allelic loss from a genomewide scan of esophageal squamous-cell carcinoma in a high-risk Chinese population

Esophageal cancer is one of the most common fatal cancers worldwide. Deletions of genomic regions are thought to be important in esophageal carcinogenesis. We conducted a genomewide scan for regions of allelic loss using microdissected DNA from 11 esophageal squamous-cell carcinoma patients with a family history of upper gastrointestinal tract cancer from a high-risk region in north central China. Allelic patterns of 366 fluorescently labeled microsatellite markers distributed at 10-cM intervals over the 22 autosomal chromosomes were examined. We identified 14 regions with very high frequency (>/= 75%) loss of heterozygosity (LOH), including broad regions encompassing whole chromosome arms (on 3p, 5q, 9p, 9q, and 13q), regions of intermediate size (on 2q, 4p, 11p, and 15q), and more discrete regions identified by very high frequency LOH for a single marker (on 4q, 6q, 8p, 14q, and 17p). Among these 14 regions were 7 not previously described in esophageal squamous-cell carcinoma as having very high frequency LOH (on 2q, 4p, 4q, 6q, 8p, 14q, and 15q). The very high frequency LOH regions identified here may point to major susceptibility genes, including potential tumor suppressor genes and inherited gene loci, which will assist in understanding the molecular events involved in esophageal carcinogenesis and may help in the development of markers for genetic susceptibility testing and screening for the early detection of this cancer. Genes Chromosomes Cancer 27:217-228, 2000. Published 2000 Wiley-Liss, Inc.

Identification of novel regions of allelic loss from a genomewide scan of esophageal squamous-cell carcinoma in a high-risk Chinese population

Esophageal cancer is one of the most common fatal cancers worldwide. Deletions of genomic regions are thought to be important in esophageal carcinogenesis. We conducted a genomewide scan for regions of allelic loss using microdissected DNA from 11 esophageal squamous-cell carcinoma patients with a family history of upper gastrointestinal tract cancer from a high-risk region in north central China. Allelic patterns of 366 fluorescently labeled microsatellite markers distributed at 10-cM intervals over the 22 autosomal chromosomes were examined. We identified 14 regions with very high frequency (>/= 75%) loss of heterozygosity (LOH), including broad regions encompassing whole chromosome arms (on 3p, 5q, 9p, 9q, and 13q), regions of intermediate size (on 2q, 4p, 11p, and 15q), and more discrete regions identified by very high frequency LOH for a single marker (on 4q, 6q, 8p, 14q, and 17p). Among these 14 regions were 7 not previously described in esophageal squamous-cell carcinoma as having very high frequency LOH (on 2q, 4p, 4q, 6q, 8p, 14q, and 15q). The very high frequency LOH regions identified here may point to major susceptibility genes, including potential tumor suppressor genes and inherited gene loci, which will assist in understanding the molecular events involved in esophageal carcinogenesis and may help in the development of markers for genetic susceptibility testing and screening for the early detection of this cancer. Genes Chromosomes Cancer 27:217-228, 2000. Published 2000 Wiley-Liss, Inc.

Characterization of intracellular prostate-specific antigen from laser capture microdissected benign and malignant prostatic epithelium

The proportion of unbound serum prostate-specific antigen (PSA; percent-free PSA) is reported to be lower in men with prostate cancer compared to men with benign prostates (U. H. Stenman et al., Cancer Res., 51: 222-226, 1991; H. Lilja et al., Clin. Chem., 37: 1618-1625, 1991; D. L. Woodrum et al., J. Urol., 159: 5-12, 1998; W. J. Catalona et al., J. Am. Med. Assoc., 279: 1542-1547, 1998). The majority of immunoreactive PSA in serum is complexed to alpha-1-antichymotrypsin (ACT). Two major mechanistic questions have previously been unknown: (a) Does PSA in human prostate cancer cells in tissue exist in a free or bound form? and (b) Is PSA produced by malignant cells in the free form because it has lost the ability to form a complex with ACT? Laser capture microdissection (LCM) enables the acquisition of pure populations of defined cell types from tissue (M. R. Emmert-Buck et al., Science, 274: 998-1001, 1996; R. F. Bonner et al., Science, 278: 1481-1483, 1997). This technology provides a unique opportunity to study intracellular protein composition and structure from human cells. In this study, we used LCM to assess the bound versus free form of intracellular PSA in both benign and malignant epithelium procured from prostate tissue. One-dimensional and two-dimensional PAGE were performed on cellular lysates from LCM-procured benign and malignant prostate epithelium from frozen tissue specimens. Western blotting analysis of one-dimensional PAGE gels revealed a strong band at M(r) 30,000 (expected molecular weight of unbound PSA) in all cases demonstrating that the vast majority of intracellular tumor and normal PSA exists within cells in the "free" form. Binding studies showed that PSA recovered from LCM-procured cells retained the full ability to bind ACT, and two-dimensional PAGE Western analysis demonstrated that the PSA/ACT complex was stable under strong reducing conditions. We conclude that intracellular PSA exists in the "free" form and that binding to ACT occurs exclusively outside of the cell.

Sensitive immunoassay of tissue cell proteins procured by laser capture microdissection

Coupling laser capture microdissection (LCM) with sensitive quantitative chemiluminescent immunoassays has broad applicability in the field of proteomics applied to normal, diseased, or genetically modified tissue. Quantitation of the number of prostate-specific antigen (PSA) molecules/cell was conducted on human prostate tissue cells procured by LCM from fixed and stained frozen sections. Under direct microscopic visualization, laser shots 30 microm in diameter captured specific cells from the heterogeneous tissue section onto a polymer transfer surface. The cellular macromolecules from the captured cells were solubilized in a microvolume of extraction buffer and directly assayed using an automated (1.5 hour) sandwich chemiluminescent immunoassay. Calibration of the chemiluminescent assay was conducted by developing a standard curve using known concentrations of PSA. After the sensitivity, precision, and linearity of the chemiluminescent assay was verified for known numbers of solubilized microdissected tissue cells, it was then possible to calculate the number of PSA molecules per microdissected tissue cell for case samples. In a study set of 20 cases, using 10 replicate samples of 100 laser shots per sample, the within-run (intraassay) SD was approximately 10% of the mean or less for all cases. In this series the number of PSA molecules per microdissected tissue cell ranged from 2 x 10(4) to 6. 3 x 10(6) in normal epithelium, prostate intraepithelial neoplasia (PIN), and invasive carcinoma. Immunohistochemical staining of human prostate for PSA was compared with the results of the soluble immunoassay for the same prostate tissue section. Independent qualitative scoring of anti-PSA immunohistochemical staining intensity paralleled the LCM quantitative immunoassay for each tissue subpopulation and verified the heterogeneity of PSA content between tissue subpopulations in the same case. Extraction buffers were successfully adapted for both secreted and membrane-bound proteins. This technology has broad applicability for the quantitation of protein molecules in pure populations of tissue cells.

New approaches to molecular profiling of tissue samples

Figures on http://www.esacp.org/acp/2000/20-1/best.htm.

Molecular profiling of human cancer: new opportunities

The Human Genome Project will be completed in the near future, providing new opportunities for researchers to better understand human biology. In order to maximize the value of the genetic data, high-throughput molecular analyses will become an essential experimental methodology, allowing global views of gene expression to be produced and examined. As an example, this approach will permit investigators studying cancer to comprehensively examine the genes and gene products whose alterations underlie tumor development and progression. This information will be essential in determining the fundamental causes of human neoplasms as well as having immediate practical value in the development of clinically useful diagnostic markers and therapeutic targets.

Multiple endocrine neoplasia type 1: clinical and genetic features of the hereditary endocrine neoplasias

MEN1 is a syndrome of parathyroid adenomas, gastrinomas, prolactinomas, and other endocrine tumors. Collagenomas and facial angiofibromas are newly recognized but common skin expressions. Many tumors in MEN1 are benign; however, many entero-pancreatic neuroendocrine tumors and foregut carcinoid tumors are malignant. MEN1 is thus the expression of a cancer gene but without available prevention or cure for malignancy. Hereditary (as compared to sporadic) endocrine tumors show early onset age and multiplicity, because each cell of the body has "one hit" by inheritance. Multiple neoplasia syndromes with endocrine tumor(s) all include nonendocrine components; their known defective genes seem mainly to disturb cell accumulation. Hereditary neoplasia/hyperplasia of one endocrine tissue reflects a defect that is tissue selective and directed at cell secretion. Though the hereditary endocrine neoplasias are rare, most of their identified genes also contribute to common sporadic endocrine neoplasms. Hereditary tumors may be caused by activation of an oncogene (e.g., RET) or, more often, by inactivation of a tumor suppressor gene (e.g., P53, MEN1). Recently, MEN1 was identified by positional cloning. This strategy included narrowing the gene candidate interval, identifying many or all genes in that interval, and testing the newly identified candidate genes for mutation in MEN1 cases. MEN1 was identified because it showed mutation in 14 of 15 MEN1 cases. NIH testing showed germline MEN1 mutations in 47 of 50 MEN1 index cases and in seven of eight cases with sporadic MEN1. Despite proven capacity to find germline MEN1 mutation, NIH testing found no MEN1 mutation among five families with isolated hyperparathyroidism, suggesting that this often arises from mutation of other gene(s). Analogous studies in Japan found that familial isolated pituitary tumors also did not show MEN1 germline mutation. MEN1 mutation testing can now be considered for cases of MEN1 and its phenocopies and for asymptomatic members of families with known MEN1 mutation. Germline MEN1 testing does not have the urgency of RET testing in MEN2a and 2b, as MEN1 testing does not commonly lead to an important intervention. Somatic MEN1 mutation was found in sporadic tumors: parathyroid adenoma (21%), gastrinoma (33%), insulinoma (17%), and bronchial carcinoid (36%). For each of these, MEN1 was the known gene most frequently mutated. MEN1 has a widely expressed mRNA that encodes a protein (menin) of 610 amino acids. The protein sequence is not informative about domains or functions. The protein was mainly nuclear. Menin binds to JunD, an AP-1 transcription factor, inhibiting JunD's activation of transcription. Most of the germline and somatic MEN1 mutations predict truncation of menin, a likely destructive change. Inactivating MEN1 mutations in germline and in sporadic neoplasms support prior predictions that MEN1 is a tumor suppressor gene. Germline MEN1 mutation underlies all or most cases of MEN1 (familial or sporadic). Somatic MEN1 mutation is the most common gene mutation in many sporadic endocrine tumor types.

Allelic loss in esophageal squamous cell carcinoma patients with and without family history of upper gastrointestinal tract cancer

Chromosomal regions with frequent allelic loss may point to major susceptibility genes that will assist in understanding molecular events involved in esophageal carcinogenesis. Esophageal squamous cell carcinoma samples and blood from 46 patients, including 23 patients with and 23 patients without a family history of upper gastrointestinal cancer, were screened using laser microdissected DNA and tested for loss of heterozygosity (LOH) at 18 marker loci representing 14 chromosomal regions (on 2q, 3p, 4p, 4p, 5q, 6q, 8p, 9p, 9q, 11p, 13q, 14q, 15q, and 17p) identified in an earlier genome-wide scan to have frequent LOH. Clinical/pathological and lifestyle risk factor data were also collected. For all 46 tumors combined, the lowest frequency LOH for any of the 18 markers was 37%, and 8 markers showed LOH in > or =75% of informative tumors. One marker (D13S894 on 13q) showed greater LOH in patients with a positive family history (93% versus 50%; P = 0.04), whereas two markers (D6S1027 on 6q and D9S910 on 9q) had significantly more LOH in patients with metastasis, and one marker (D4S2361 on 4p) showed significantly higher LOH in patients with a lower pathological tumor grade. No relation was seen between LOH and lifestyle risk factors. This study confirms the previously observed high frequency LOH for these 14 chromosomal regions, including a locus on 13q where LOH is more common in patients with a family history of upper gastrointestinal cancer than in those without such history, suggesting that a gene in this area may be involved in genetic susceptibility to esophageal cancer.

Loss of heterozygosity on chromosome 13 is associated with advanced stage prostate cancer

PURPOSE

In order to investigate the possible involvement of a tumor suppressor gene(s) on chromosome 13 in prostatic neoplasms, we performed loss of heterozygosity (LOH) analysis on normal and tumor pairs from 36 prostate cancer patients.

MATERIALS AND METHODS

Pure DNA was obtained from carcinoma cells and normal epithelium by tissue microdissection. The DNA had previously been analyzed for LOH on chromosomes 8 and 16. After an initial pilot experiment to determine the region(s) of significant LOH from 9 loci on chromosome 13q, 3 loci at and near the Rb1 locus (D13S153, D13S1319, and D13S1303) were chosen for further study.

RESULTS

The overall rate of LOH on chromosome 13 was 27.3%. Four tumors exhibited LOH at all 3 loci. Two tumors exhibited LOH at D13S153 but not at the other, more telomeric loci; two additional tumors had loss at D13S1303 or D13S1319 but not D13S153. These data suggest that a tumor suppressor gene involved in prostate cancer may be located just telomeric to Rb1. Analysis of clinical and pathological data from carcinomas with and without loss shows that chromosome 13q LOH is correlated with advanced stage prostate cancer.

CONCLUSIONS

Our LOH data suggests that there may be a tumor suppressor gene telomeric to Rb1 that is potentially involved in prostate cancer progression. Identification of this gene may be valuable in providing diagnostic and prognostic information for prostate cancer patients.

Analysis of mRNA quality in freshly prepared and archival Papanicolaou samples

OBJECTIVE

To study the feasibility of utilizing mRNA recovered from cytologic Papanicolaou (Pap) specimens as a resource for gene expression studies of normal and diseased cells.

STUDY DESIGN

To assess the effects of fixation on mRNA recovery and analysis, fresh Pap samples were processed by three separate methods: (1) routine cytologic fixation (2) 70% ethanol fixation, and (3) air drying without fixation. One-week-old, 1-month-old, 1-year-old and 10-year-old samples were studied to determine the quality of mRNA in archival samples. mRNA quality was analyzed by RT-PCR for the HPRT gene, and by complete transcript amplification. Both heterogeneous (whole slide scrapes) and microdissected cell populations were studied.

RESULTS

Reverse transcriptase-polymerase chain reaction (RT-PCR) for the hypoxanthine guanine phosphoribosil transferase gene was positive in all fresh and archival samples and was not affected by fixative, processing methodology or microdissection. Complete transcript amplification followed by gel electrophoresis showed cDNA smears in all fresh samples with a maximum intensity between 1 and 2 kilobases (kb). Amplification of mRNA was not affected by fixation. Smaller cDNA smears were seen in archival specimens with a maximum intensity between 0.5 and 1.5 kb in both one-week-old and one-month-old samples. Smears of approximately 500 base pairs were observed in the 1-year-old and 10-year-old samples. Successful mRNA amplification was possible from microdissected cell populations.

CONCLUSION

Messenger RNA recovery and analysis is possible from archival cytologic specimens, suggesting that they can serve as a useful template for RT-PCR analysis of individual genes as well as newly developing high-throughput gene expression methodologies, such as microarrays. Cytologic samples may be particularly useful for study of archival samples as well as diseases from which tissue samples amenable to mRNA-based studies are not available.

Chromosome 16 allelic loss analysis of a large set of microdissected prostate carcinomas

PURPOSE

To perform loss of heterozygosity (LOH) analysis on chromosome 16 in 102 highly purified DNA samples isolated from one or more adenocarcinomas, prostatic intraepithelial neoplasia (PIN), and matched benign prostatic epithelium from 95 radical prostatectomy patients.

MATERIALS AND METHODS

Specimens were procured by microdissection of frozen tissue samples, thus ensuring that highly select pure populations of cells were obtained for DNA extraction and LOH analysis. Multiple microsatellite markers were used to determine allelic loss on chromosome 16q.

RESULTS

Overall loss on 16q was seen in 31% of the cancers, and occurred more frequently in high stage cancers than low stage cancers. In contrast, allelic loss in PIN failed to exceed 6% at any of the loci that were examined.

CONCLUSIONS

These results suggest that inactivation of a putative tumor suppressor gene on 16q may be involved in the progression of some prostate cancers.

The gene for multiple endocrine neoplasia type 1: recent findings

Multiple endocrine neoplasia type 1 (MENI) is a promising model to understand endocrine and other tumors. Its most common endocrine expressions are tumors of parathyroids, entero-pancreatic neuro-endocrine tissue, and anterior pituitary. Recently, collagenomas and multiple angiofibromas of the dermis also have been recognized as very common. MEN1 can be characterized from different perspectives: (a) as a hormone (parathyroid hormone, gastrin, prolactin, etc.) excess syndrome with excellent therapeutic options; (b) as a syndrome with sometimes lethal outcomes from malignancy of entero-pancreatic neuro-endocrine or foregut carcinoid tissues; or (c) as a disorder than can give insight about cell regulation in the endocrine, the dermal, and perhaps other tissue systems. The MEN1 gene was identified recently by positional cloning, a comprehensive strategy of narrowing the candidate interval and evaluating all or most genes in that interval. This discovery has opened new approaches to basic and clinical issues. Germline MEN1 mutations have been identified in most MEN1 families. Germline MENI mutations were generally not found in families with isolated hyperparathyroidism or with isolated pituitary tumor. Thus, studies with the MENI gene helped establish that mutation of other gene(s) is likely causative of these two MEN1 phenocopies. MEN1 proved to be the gene most frequent L4 mutated in common-variety, nonhereditary parathyroid tumor, gastrinoma, insulinoma, or bronchial carcinoid. For example, in common-variety parathyroid tumors, mutation of several other genes (such as cyclin D1 and P53) has been found, but much less frequently than MEN1 mutation. The majority of germline and somatic MEN1 mutations predicted truncation of the encoded protein (menin). Such inactivating mutations strongly supported prior predictions that MEN1 is a tumor suppressor gene insofar as stepwise mutational inactivation of both copies can release a cell from normal growth suppression. Menin is principally a nuclear protein; menin interacts with junD. Future studies, such as discovery of menin's metabolic pathway, could lead to new opportunities in cell biology and in tumor therapy.

Allelic loss on chromosome arm 8p: analysis of sporadic epithelial ovarian tumors

OBJECTIVE

Our objective was to determine the frequency of allelic loss at 8p21 in sporadic epithelial ovarian cancer. We recently described allelic loss at this locus in 7/9 ovarian cancers from patients with BRCA1 gene mutations.

METHODS

We anonymously obtained and examined 40 unselected invasive epithelial ovarian cancers and 5 low-malignant-potential (LMP) ovarian tumors for loss of heterozygosity (LOH) at 8p12-22. Pure epithelial and stromal cell populations were procured selectively by laser capture microdissection and extracted DNA was amplified with polymorphic microsatellite markers spanning the region of interest.

RESULTS

LOH was highest (50%) at marker D8S136 located at 8p21 with 15 of 30 informative cases exhibiting an allelic deletion. None of the LMP tumors evaluated showed LOH at 8p12-22. A trend toward more frequent LOH at 8p12-22 was identified with increasing disease aggressiveness from LMP to early stage invasive ovarian cancer to advanced stage invasive ovarian cancer (Lehman's test, P2 < 0.024).

CONCLUSIONS

Fifty percent allelic loss at the distal portion of 8p21 has not been reported to date for sporadic epithelial ovarian carcinomas. The higher rate of loss in our cohort, in contrast to previous allelotyping studies, is due likely to analysis from homogenous cell populations. These results, in concert with our previous study of BRCA1 mutation-positive patients, suggest a tumor suppressor gene locus at 8p21 for epithelial ovarian cancer.

The Cancer Genome Anatomy Project: EST sequencing and the genetics of cancer progression

As the process of tumor progression proceeds from the normal cellular state to a preneoplastic condition and finally to the fully invasive form, the molecular characteristics of the cell change as well. These characteristics can be considered a molecular fingerprint of the cell at each stage of progression and, analogous to fingerprinting a criminal, can be used as markers of the progression process. Based on this premise, the Cancer Genome Anatomy Project was initiated with the broad goal of determining the comprehensive molecular characterization of normal, premalignant, and malignant tumor cells, thus making a reality the identification of all major cellular mechanisms leading to tumor initiation and progression ([Strausberg, R.L., Dahl, C.A., and Klausner, R.D. (1997). "New opportunities for uncovering the molecular basis of cancer." Nat. Genet., 16: 415-516.], www.ncbi.nlm.nih.gov/ncicgap/). The expectation of determining the genetic fingerprints of cancer progression will allow for 1) correlation of disease progression with therapeutic outcome; 2) improved evaluation of disease treatment; 3) stimulation of novel approaches to prevention, detection, and therapy; and 4) enhanced diagnostic tools for clinical applications. Whereas acquiring the comprehensive molecular analysis of cancer progression may take years, results from initial, short-term goals are currently being realized and are proving very fruitful.

Immuno-LCM: laser capture microdissection of immunostained frozen sections for mRNA analysis

Microdissection of routinely stained or unstained frozen sections has been used successfully to obtain purified cell populations for the analysis of cell-specific gene expression patterns in primary tissues with a complex mixture of cell types. However, the precision and usefulness of microdissection is frequently limited by the difficulty to identify different cell types and structures by morphology alone. We therefore developed a rapid immunostaining procedure for frozen sections followed by laser capture microdissection (LCM) and RNA extraction, which allows targeted mRNA analysis of immunophenotypically defined cell populations. After fixation, frozen sections are immunostained under RNAse-free conditions using a rapid three-step streptavidin-biotin technique, dehydrated and immediately subjected to LCM. RNA is extracted from captured tissue, DNAse I treated, and reverse transcribed. Acetone-, methanol-, or ethanol/acetone-fixed sections give excellent immunostaining after 12 to 25 minutes total processing time. Specificity, precision, and speed of microdissection is markedly increased due to improved identification of desired (or undesired) cell types. The mRNA recovered from immunostained tissue is of high quality. Single-step PCR is able to amplify fragments of more than 600 bp from both housekeeping genes such as beta-actin as well as cell-specific messages such as CD4 or CD19, using cDNA derived from less than 500 immunostained, microdissected cells. Immuno-LCM allows specific mRNA analysis of cell populations isolated according to their immunophenotype or expression of function-related antigens and significantly expands our ability to investigate gene expression in heterogeneous tissues.

Molecular regulation, membrane association and secretion of tumor cathepsin B

Upregulation, membrane association and secretion of cathepsin B have been shown to occur in many types of tumors and to correlate positively with their invasive and metastatic capabilities. To further understand changes in cathepsin B activity and localization, we have been examining its regulation at many levels including transcription and trafficking. Our studies indicate that there may be three promoter regions in the cathepsin B gene. Of these, continued examination of the promoter upstream of exon 1 has indicated possible control by several regulatory factors including E-box and Sp-1 binding elements. Upregulation of cathepsin B at this level may account for some of the secretion of cathepsin B found in tumors. We have also gathered evidence that endo- and exocytosis of cathepsin B may be regulated by ras and ras-related proteins in addition to previously described trafficking systems. There is also evidence that several populations of lysosomes may exist and that trafficking to different populations may determine whether cathepsin B is secreted from the tumor cell or remains intracellular. Our results indicate that membrane association and secretion of cathepsin B is not a random process in the tumor cell, but rather part of a tightly controlled system.

The genetics of cancer--a 3D model

Gene expression microarrays hold great promise for studies of human disease states. There are significant technical issues specific to utilizing clinical tissue samples which have yet to be rigorously addressed and completely overcome. Precise, quantitative measurement of gene expression profiles from specific cell populations is at hand, offering the scientific community the first comprehensive view of the in vivo molecular anatomy of normal cells and their diseased counterparts. Here, we propose a model for integrating-in three dimensions-expression data obtained using the microarray.

Differential cytokine mRNA expression in human labial minor salivary glands in primary Sjögren's syndrome

Cytokines are known to be involved in a number of autoimmune conditions and are increasingly viewed as key components in numerous aspects of normal and abnormal cell functions. The purpose of the present study was to investigate possible immunopathogenic mechanisms within the labial minor salivary glands of patients with primary Sjögren's syndrome (pSS) by examining differential cytokine gene expression in individual cell populations (acini, ducts, or lymphoid cells). A cell-specific microdissection technique in combination with reverse transcription-polymerase chain reaction (RT-PCR) and Southern hybridization using 32P-labeled cytokine gene-specific probes was utilized to measure cytokine messenger RNA expression in individual cell populations of patients and healthy controls. mRNAs for interleukin 2 (IL-2), interleukin 6 (IL-6), interleukin 10 (IL-10), tumor necrosis factor alpha (TNF-alpha), interferon gamma (IFN-gamma) and transforming growth factor beta 1 (TGF-beta1) were detected in the epithelial cells (acini and ducts) and lymphoid cells of the labial minor salivary glands of pSS patients. The expression levels of these mRNAs in the epithelial cells were either up- or down-regulated by adjacent focal infiltrating lymphoid cells. mRNAs for all of the above cytokines, with the exception of IFN-gamma, were detected in salivary tissues of healthy volunteers. The epithelial cells in the salivary glands are active participants in the autoimmune-mediated process of pSS, as evidenced by their ability to express a high frequency and wide variety of cytokines. The presence of an infiltrating lymphoid focus within the gland appeared to modulate cytokine gene expression by the salivary epithelial cells.

An improved method for construction of directionally cloned cDNA libraries from microdissected cells

Here, we developed an improved method for constructing microdissected cDNA libraries, based on strand-switching properties of reverse transcriptase, followed by PCR amplification with primers to mediate unidirectional insert cloning. Using RNA from microdissected ovarian carcinoma cells, we constructed a cDNA library consisting of 1.3 x 10(6) unidirectional recombinants with an average insert size of 500 bp. Single-pass sequencing of 100 clones with the T7 primer revealed 89 inserts derived from known genes, anonymous expressed sequence tags (ESTs), or novel sequences. Among these clones were known genes and ESTs previously found in cDNA libraries from bulk ovarian tissue RNA, sequences seen for the first time in an ovarian-derived library, and novel sequences not previously seen in any cDNA library. These results demonstrate a methodology for constructing quality cDNA libraries that are cloned in a unidirectional fashion, are complex and diverse, and reflect the tissue of origin.

cDNA sequencing and analysis of POV1 (PB39): a novel gene up-regulated in prostate cancer

We recently identified a novel gene (PB39) (HGMW-approved symbol POV1) whose expression is up-regulated in human prostate cancer using tissue microdissection-based differential display analysis. In the present study we report the full-length sequencing of PB39 cDNA, genomic localization of the PB39 gene, and genomic sequence of the mouse homologue. The full-length human cDNA is 2317 nucleotides in length and contains an open reading frame of 559 amino acids which does not show homology with any reported human genes. The N-terminus contains charged amino acids and a helical loop pattern suggestive of an srp leader sequence for a secreted protein. Fluorescence in situ hybridization using PB39 cDNA as probe mapped the gene to chromosome 11p11.1-p11.2. Comparison of PB39 cDNA sequence with murine sequence available in the public database identified a region of previously sequenced mouse genomic DNA showing 67% amino acid sequence homology with human PB39. Based on alignment and comparison to the human cDNA the mouse genomic sequence suggests there are at least 14 exons in the mouse gene spread over approximately 100 kb of genomic sequence. Further analysis of PB39 expression in human tissues shows the presence of a unique splice variant mRNA that appears to be primarily associated with fetal tissues and tumors. Interestingly, the unique splice variant appears in prostatic intraepithelial neoplasia, a microscopic precursor lesion of prostate cancer. The current data support the hypothesis that PB39 plays a role in the development of human prostate cancer and will be useful in the analysis of the gene product in further human and murine studies.

Laser-capture microdissection: opening the microscopic frontier to molecular analysis

As the list of expressed human genes expands, a major scientific challenge is to understand the molecular events that drive normal tissue morphogenesis and the evolution of pathological lesions in actual tissue. Laser capture microdissection (LCM) has been developed to provide a reliable method to procure pure populations of cells from specific microscopic regions of tissue sections, in one step, under direct visualization. The cells of interest are transferred to a polymer film that is activated by laser pulses. The exact morphology of the procured cells (with intact DNA, RNA and proteins) is retained and held on the transfer film. With the advent of LCM, cDNA libraries can be developed from pure cells obtained directly from stained tissue, and microhybridization arrays of thousands of genes can now be used to examine gene expression in microdissected human tissue biopsies. The fluctuation of expressed genes or alterations in the cellular DNA that correlate with a particular disease stage can ultimately be compared within or between individual patients. Such a fingerprint of gene-expression patterns can provide crucial clues for etiology and might, ultimately, contribute to diagnostic decisions and therapies tailored to the individual patient. Molecules found to be associated with a defined pathological lesion might serve as imaging ot therapeutic targets.

Microdissection, microchip arrays, and molecular analysis of tumor cells (primary and metastases)

Advances in biotechnology and bioinformatics are offering promise for new breakthroughs in gene discovery and elucidation of gene function. At present, many candidate genes related to cancer pathogenesis have been identified in several types of human cancer, yet frequently their function remains elusive. This is particularly true as it relates to the progression of human cancer. This landscape could change dramatically, however, as technological innovations and improvements continue to revolutionize these fields. High-throughput molecular approaches are emerging, which may become accurate, automated, and cost-effective. For example, DNA arrays on microchips are under development with numerous applications, including the ability to screen genes rapidly for mutations and to study patterns of gene expression on a large scale. Automated systems for microdissection and sequencing are also in their implementation stages. Commensurate with their integration and evolution, these information and technological tools have the potential to offer a more comprehensive understanding of multiple genetic and cellular alterations occurring during cancer initiation, development, and progression. Ultimately, this fundamental knowledge can provide strategies for intervention, prevention, and early diagnosis. This is a US government work. There are no restrictions on its use.

Germline and somatic mutation of the gene for multiple endocrine neoplasia type 1 (MEN1)

Dideoxyfingerprinting was used to screen for germline and somatic MEN1 mutations. This method, applied to a panel of germline DNA from 15 probands with multiple endocrine neoplasia type 1 (MEN-1), allowed confident discovery of the MEN1 gene. Germline MEN1 mutation has been found in 47 out of 50 probands with familial MEN-1, in 7 out of 8 cases with sporadic MEN-1, and in 1 out of 3 cases with atypical sporadic MEN-1. Germline MEN1 mutation was not found in any of five probands with familial hyperparathyroidism. Somatic MEN1 mutations were found in 7 out of 33 parathyroid tumours not associated with MEN-1. Allowing for repeating mutations, a total of 47 different germline or somatic MEN1 mutations have been identified. Most predict inactivation of the encoded 'menin' protein. supporting expectations that MEN1 is a tumour suppressor gene. The 16 observed missense mutations were distributed across the gene, suggesting that many domains are important to its as yet unknown functions.

Histopathology and molecular biology of ovarian epithelial tumors

Carcinogenesis in the ovary presents special features related to that organ. First, the preinvasive or even invasive lesions are difficult to detect, which explains why most cases are diagnosed at an advanced stage. Second, the group of tumors of low malignant potential (borderline tumors) are still a controversial category of ovarian lesions. Finally, familial ovarian tumors represent an interesting hereditary model of carcinogenesis at the molecular level. Flow cytometry and immunohistochemistry for proliferative markers or oncogenes provide important prognostic information in patients with ovarian tumors. Molecular data, such as loss of heterozygosity at specific genetic loci, also have been correlated with prognosis. Clonality studies in patients with multiple ovarian/pelvian lesions analyzing chromosome X inactivation patterns and genetic deletions or mutations have contributed to the understanding of the origin of these lesions. New technologies to study gene expression patterns, such as cDNA library construction and DNA microarray technologies, are being applied to study histologic phases of tumor progression, such as normal, preinvasive, and tumor tissues. It is hoped that these studies will contribute important information not only for a better understanding of the process of carcinogenesis, but also for assessing the biology and behavior of individual tumors, determining patient prognosis, and eventually influencing therapy.

Evidence of independent origin of multiple tumors from patients with prostate cancer

BACKGROUND

In men with prostate cancer, the gland usually contains two or more widely separate tumors. A critical issue of prostatic carcinogenesis is whether these multiple tumors are independent in origin. Molecular analysis of microsatellite (i.e., highly repeated, short nucleotide sequences) alterations in the DNA from separate tumors in the same prostate can be used to determine whether or not these separate tumors arise independently.

METHODS

Four microsatellite polymorphic markers (D8S133, D8S136, and D8S137, for a putative tumor suppressor gene on chromosome 8p, and D17S855, for the BRCA1 gene on chromosome 17q) were used to examine the pattern of allelic loss in prostate cancer from 19 patients who had two or more distantly separate tumors (i.e., located on contralateral sides or separated by at least half the anterior-posterior diameter of the prostate). Forty distantly separate tumors were microdissected, DNA samples were prepared from formalin-fixed, paraffin-embedded wholemount prostate tissue section, and the overall frequencies of loss of heterozygosity at the four loci were determined.

RESULTS

The pattern of allelic loss was compatible with independent tumor origin in 15 of 18 informative cases. A random discordant pattern of allelic deletion was observed in distantly separate tumors, whereas the same allele was consistently lost in cells from different regions of the same tumor. For three patients, the results were compatible with either intraglandular dissemination or independent origin of prostate cancer.

CONCLUSIONS

Our data suggest that multiple tumors in some patients with prostate cancer have independent origin.