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.

Niemann-Pick C1 disease gene: homology to mediators of cholesterol homeostasis.

Niemann-Pick type C (NP-C) disease, a fatal neurovisceral disorder, is characterized by lysosomal accumulation of low density lipoprotein (LDL)-derived cholesterol. By positional cloning methods, a gene (NPC1) with insertion, deletion, and missense mutations has been identified in NP-C patients. Transfection of NP-C fibroblasts with wild-type NPC1 cDNA resulted in correction of their excessive lysosomal storage of LDL cholesterol, thereby defining the critical role of NPC1 in regulation of intracellular cholesterol trafficking. The 1278-amino acid NPC1 protein has sequence similarity to the morphogen receptor PATCHED and the putative sterol-sensing regions of SREBP cleavage-activating protein (SCAP) and 3-hydroxy-3-methyl-glutaryl coenzyme A (HMG-CoA) reductase.

Construction of a representative cDNA library from prostatic intraepithelial neoplasia.

We report the construction of a plasmid-based cDNA library made from microdissected cells derived from prostatic intraepithelial neoplasia. Total RNA was extracted and converted to blunt-ended, double-stranded cDNA by oligo(dT)-mediated reverse transcription followed by linker addition. A linker-specific primer with UDG-compatible ends was used to amplify the cDNA and the resulting PCR product was subcloned. A total of 154 clones were sequenced and results indicated that 81.5% of the clones derived from either known genes, anonymous expressed sequence tags, or novel transcripts with very little redundancy of screened clones. These results demonstrate the feasibility of constructing complex representative cDNA libraries from specific microdissected cell populations that represent microscopic precursor stages of cancer progression. This method should facilitate identification of transcripts specifically expressed in cells of a distinct histological origin and tumorigenic stage.

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.

Susceptibility to ras oncogene transformation is coregulated with signal transduction through growth factor receptors.

The human teratocarcinoma cell line PA-1 was derived from culturing ascites fluid cells from a patient with an ovarian germ line tumor. We previously described a non-neoplastic variant cloned from the PA-1 human teratocarcinoma cell line, clone 6, which at passage 40 was resistant to transformation by activated ras oncogenes. However, these cells could be transformed by a plasmid containing both myc and ras. Another PA-1 cell variant, clone 1, isolated at passage 63 and used 50 passages later becomes tumorigenic in nude mice after transfection with an activated ras oncogene (Tainsky et al., Anticancer Res., 8, 899-914, 1988). We report here that the progression from ras resistance to ras susceptibility occurs in both clone 1 and clone 6 cells during 25 passages in culture. In the presence of epidermal growth factor, transforming growth factor-alpha, and basic fibroblast growth factor, the ras-transformable cells exhibit anchorage independent growth, whereas the ras-resistant cells can not be growth stimulated by these growth factors. Similarly, ornithine decarboxylase (ODC) activity was inducible in ras susceptible and ras transformed cells by these growth factors, but not in the ras resistant cells. These differences are not due to the level and activity of epidermal growth factor receptor or to the level of expression of 25 proto-oncogenes.

Modulation of differentiation in PA-1 human teratocarcinoma cells after N-ras oncogene-induced tumorigenicity.

We have been studying the effect of oncogenes on differentiation using the human ovarian teratoma-derived cell line PA-1. From this study we have characterized variants representing four stages relevant to multistage carcinogenesis, two non-tumorigenic and two tumorigenic. The two non-tumorigenic cell variants differ in that one is resistant to transformation by ras oncogenes whereas the other can be transformed to tumorigenicity. When these non-tumorigenic PA-1 variants are treated with retinoic acid (RA), a morphogen, they stop dividing, begin to express homeobox genes, and change in morphology. Transfection of an activated N-ras oncogene into ras-resistant non-tumorigenic PA-1 cells does not alter the RA responsiveness of the cells, indicating that expression of the activated oncogene is not sufficient for blocking RA-induced differentiation. Spontaneous activation of an N-ras oncogene leading to tumorigenic transformants and gene transfer-induced N-ras transformants are resistant to these effects of RA. However, another spontaneous transformant of PA-1 cells that does not contain an activated N-ras is responsive to RA. We prepared somatic cell hybrids of the RA-non-responsive, N-ras-transformed and tumorigenic PA-1 cell and the RA-responsive, ras-resistant non-tumorigenic PA-1 cell; the hybrid cell lines continue to express the oncogene but are non-tumorigenic. These non-tumorigenic hybrids are responsive to RA with regard to morphological changes, growth arrest and induction of homeobox gene expression. Tumorigenic revertants of these hybrids arise as a result of the loss of some chromosomes; these hybrid cells express the oncogene but have lost RA responsiveness. These results indicate that tumorigenic transformation in general is not sufficient to induce RA resistance, and resistance to differentiation may be oncogene-specific. In addition, the expression of an activated N-ras oncogene alone is insufficient to induce resistance to RA and ras-induced tumorigenicity is necessary. Therefore, some feature of cellular metabolism that is altered by and discordantly segregates with tumorigenic transformation controls responsiveness to RA. This controlling element is presumably a tumor suppressor.

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.

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.

Multiple phenotypic divergence of mammary adenocarcinoma cell clones. I. In vitro and in vivo properties.

The properties of cell clones derived from locally growing and spontaneous metastases of 13762NF mammary adenocarcinoma change during in vitro growth. This has been termed phenotypic drift and is reproducible in independent experiments using different cryoprotected cell stocks. To determine whether phenotypic drift in 13762NF cell clones is the result of an en bloc shift in the properties of all tumor cells, or independent phenotypic divergence of tumor cells to produce a mixed cell population, local tumor-derived clone MTF7 was subcloned at low and high culture passage numbers in vitro. Each subclone was analyzed in vitro for cell morphology, growth rate, saturation density, karyotype and ploidy, and in vivo for experimental metastatic behavior. Subclones derived from low passage clone MTF7 (T11; tissue culture passage number 11) were relatively homogeneous in their growth rates (doubling times of 16.8-17.4 h) and saturation densities (approximately 2 X 10(5) cells/cm2); yet, these same subclones were heterogeneous in their in vitro cell morphologies, experimental metastatic potentials (means range from 0 to greater than 100 tumor nodules per lung), size distributions of lung tumor nodules, marker chromosomes and modal chromosome numbers. High passage MTF7 (T35; tissue culture passage number 35) subclones had similar growth rates and saturation densities, except for subclone 2, which had a doubling time of approximately 26 h. Cell morphologies, experimental metastatic potentials (means range from 3 to greater than 600 tumor nodules per lung), size distribution of lung tumor nodules, marker chromosomes and modal chromosome numbers varied between MTF7 (T35) subclones. The results suggest that simultaneous, independent divergence of several phenotypes from a single cloned cell occurred to form a mixed cell population containing cells with independently segregated, unrelated phenotypes. Thus, the reproducibility of phenotypic drift in clonal cell populations was probably the result of tumor cell divergence and was not an en bloc shift in phenotypic properties of all cells.

9p monosomy in a patient with Gilles de la Tourette's syndrome.

Gilles de la Tourette's syndrome (GTS) is a genetic disorder characterized by multiple motor and vocal tics, obsessive-compulsive disorder, and attention-deficit disorder. Family studies support the presence of an autosomal dominant gene; however, to date, an assignment for the GTS locus has not been made. We present the case of a boy with GTS and a deletion of the terminal portion of the short arm of chromosome 9, del(9)(qter----p2304:).

Double minutes in the HeLa cell line.

Metaphase preparations of three sublines of the HeLa line showed the presence of double minutes (DM) in varying frequencies. In two sublines (S3 and TCH-3753), the size of the DM was variable, whereas in the Fe-1000 subline, they were uniform. Giemsa banding preparations revealed typical HeLa marker chromosomes in all sublines.

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.

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.

Picoliter-scale protein microarrays by laser direct write.

We demonstrate the accurate picoliter-scale dispensing of active proteins using a novel laser transfer technique. Droplets of protein solution are dispensed onto functionalized glass slides and into plastic microwells, activating as small as 50-microm diameter areas on these surfaces. Protein microarrays fabricated by laser transfer were assayed using standard fluorescent labeling techniques to demonstrate successful protein and antigen binding. These results indicate that laser transfer does not damage the active site of the dispensed protein and that this technique can be used to successfully fabricate a functioning protein microarray. Also, as a result of the efficient nature of the process, material usage is reduced by two to four orders of magnitude compared to conventional pin dispensing methods for protein spotting.

Quantitative study of a proposed interstitial del (20p 12.2) in multiple endocrine neoplasia (MEN-II).

A quantitative measurement of the prophase Giemsa banding patterns in chromosome 20 of the peripheral blood samples obtained from seven patients with medullary carcinoma of the thyroid (MCT), three nonsymptomatic family members of MCT patients, and three normal controls has revealed no differences in the short arms of the two homologs. More specifically, measurements of band from 20p 12.1 to 20p 12.3 and statistical analysis of the mean ratio between these bands have given no indication of intersitial deletion in chromosome 20p of MCT patients.

PA-1, a human cell model for multistage carcinogenesis: oncogenes and other factors.

We have developed a cell system which utilizes the human teratocarcinoma cell line PA-1, from which we have characterized four stages of tumor progression. Soon after establishment in culture PA-1 cells revert and are no longer tumorigenic in athymic nude mice. Later, PA-1 cells as they are passaged in culture, become tumorigenic at passage 100. The transition from nontumorigenic to tumorigenic is the result of the biological effects of an activated N-ras oncogene and can be reproduced by transfection of the cloned oncogene into preneoplastic PA-1 cells. Certain preneoplastic cells (prior to passage 100) in this series are susceptible to transformation by single oncogenes while others are not. In studying the basis of this susceptibility to single oncogene induced transformation we have found that somatic cell hybrids between preneoplastic cells which can suppress ras-induced transformation and ras-transformed cells are non-tumorigenic. Therefore, we believe that the progression from ras suppressing to ras susceptibility may be due to the inactivation of a trans-dominant suppressor gene. Our system has identified at least three steps which lead to tumorigenicity; establishment of growth past senesence, activation of a ras oncogene, and inactivation of an oncogene suppressor function. Further genetic alterations are necessary for tumor dissemination and metastasis.

Gene identification by 3' terminal exon trapping.

3' terminal exon trapping offers a powerful and efficient technology for rendering fragments of transcribed genes from large stretches of unsequenced, vertebrate, genomic DNA. The products from this methodology are the starting point for further studies of gene discovery and analysis. Future considerations for this technology include answering questions about the degree of efficiency from various trapping substrates and whether or not this approach can be scaled up for large-scale gene discovery such as individual chromosome or whole genomic approaches. With the onset of EST database searching, the final analysis becomes a computer assay that is consistent with the future of genetics as this field continues to move towards informational experimentation based on DNA sequence.

Printing of protein microarrays via a capillary-free fluid jetting mechanism.

Current proteomics experiments rely upon printing techniques such as ink jet, pin, or quill arrayers that were developed for the creation of cDNA microarrays. These techniques often do not meet the requirements needed for successful spotting of proteins to perform high-throughput, array-based proteomic profiling. Biological laser printing (BioLP) is a spotting technology that does not rely on solid pins, quill pins, or capillary-based fluidics. The non-contact mechanism of BioLP utilizes a focused laser pulse to transfer protein solutions, thereby eliminating the potential for orifice clogging, air bubbles, and unnecessary volume loss potentially encountered in commercially available spotting technologies. The speed and spot-to-spot reproducibility of BioLP is comparable to other techniques, while the minimum spot diameter and volume per printed droplet is significantly less at 30 microm and approximately 500 fL, respectively. The transfer of fluid by BioLP occurs through a fluid jetting mechanism, as observed by high-speed images of the printing process. Arraying a solution of BSA with subsequent immunodetection demonstrates the reproducible spotting of protein in an array format with CVs of <3%. Printing of the enzyme alkaline phosphatase followed by a positive reaction with a colorimetric substrate demonstrates that functional protein can be spotted using this laser-based printer.