Genome-wide single nucleotide polymorphism array analysis reveals recurrent genomic alterations associated with histopathologic features in intrahepatic cholangiocarcinoma

Recent studies indicate that genomic alterations (GAs) are associated with many human malignancies. Genome-wide analysis of GAs involved in intrahepatic cholangiocarcinoma (ICC) and association with histopathologic features are limited. To help characterize this relatively rare neoplasm, we collected 32 frozen tissue samples of ICC to study GAs and molecular karyotypes by using single-nucleotide polymorphism array. Recurrent GAs occurring in at least 40% of the patients were further correlated with histopathologic features. Gain of 1q21.3-q23.1 and losses of 1p36.33-p35.3 and 3p26.3-p13 were significantly associated with larger tumor size more than 5 cm in diameter; and loss of 4q13.2-q35.2 with tumor multiplicity. Moreover, losses of 1p36.32-p35.3, 3p26.3-p22.2, 4q13.1-q21.23, 4q31.3-q34.3 and 4q34.3-35.2 were inclined to be associated with high histological grade. As to tumor vascular invasion, gain of 1q21.3-q23.1 and losses of 3p22.1-p12.3 and 4q13.2-q35.2 were significantly associated with tumor vascular invasion. Some regions were concurrently associated with multiple histopathologic characteristics, including loss of 4q13.2-q35.2 associated with larger tumor size, high histological grade and vascular invasion; losses of 1p36.33-p35.3 and 3p26.3-p22.2 with larger tumor size and high histological grade; and gain of 1q21.3-q23.1 with larger tumor size and vascular invasion. Our study indicates that complex chromosomal instability is characteristic of ICC. Detecting crucial GAs will enable risk stratification and development of personalized therapies.     

中国六个群体Y染色体单核苷酸多态位点的遗传多态性研究

目的　分析中国 6个代表性群体中 Y染色体非重组区 15个单核苷酸多态位点 (single nu-cleotide polymorphism,SNP)的遗传多态性。方法　采用特异性等位基因聚合酶链反应 (allelic specificPCR,ASPCR)扩增技术和琼脂糖凝胶电泳、聚丙烯酰胺凝胶电泳检测方法 ,对来自中国南方、东北、西北 3个地区的福建汉族、四川汉族、蒙古族、赫哲族、锡伯族、回族 6个代表性群体 343份男性健康无血缘关系血样本的遗传多态性进行分析。结果　共定义出 30种 Y染色体单体群 ,其中 H15、H16、H18是所有 6个群体中共享的单体群。虽然赫哲族、蒙古族、锡伯族之间以及福建汉族、四川汉族、回族之间遗传异质性水平相似 ,但单体群的配对差异是显著的。遗传分子变异分析和单体群分布的主成分分析结果显示 ,赫哲族、蒙古族、锡伯族以及福建汉族、四川汉族、回族两大组群体之间等位基因多样性显著不同。结论　东北 /南方群体之间的遗传差异明显强于东北 /西北和南方 /西北 ,中国 6个群体呈现东北 /西北 /南方的地域性遗传关系。研究结果进一步证实了现代中国人群体遗传结构的复杂性 ,所积累的遗传数据对于构建现代人类基因库以及精确追溯中国人群的历史迁移足迹都具有重要意义。     

High-resolution analysis of allelic imbalance in neuroblastoma cell lines by single nucleotide polymorphism arrays

Genomic copy number changes are detectable in many malignancies, including neuroblastoma, using techniques such as comparative genomic hybridization (CGH), microsatellite analysis, conventional karyotyping, and fluorescence in situ hybridization (FISH). We report the use of 10K single nucleotide polymorphism (SNP) microarrays to detect copy number changes and allelic imbalance in six neuroblastoma cell lines (IMR32, SHEP, NBL-S, SJNB-1, LS, and SKNBE2c). SNP data were generated using the GeneChip DNA Analysis and GeneChip chromosome copy number software (Affymetrix). SNP arrays confirmed the presence of all previously reported cytogenetic abnormalities in the cell lines, including chromosome 1p deletion, MYCN amplification, gain of 17q and 11q, and 14q deletions. In addition, the SNP arrays revealed several chromosome gains and losses not detected by CGH or karyotyping; these included gain of 8q21.1 approximately 24.3 and gain of chromosome 12 in IMR-32 cells; loss at 4p15.3 approximately 16.1 and loss at 16p12.3 approximately 13.2, 11q loss with loss of heterozygosity (LOH) at 11q14.3 approximately 23.3 in SJNB-1 cells; and loss at 8p21.2 approximately 23.3 and 9p21.3 approximately 22.1 with corresponding LOH in SHEP cells. The SNP arrays refined the mapping of the 2p amplicons in LS, BE2c, and IMR-32 cell lines, the 12q amplicon in LS cells, and also identified an 11q13 amplicon in LS cells. There was good concordance among SNP arrays, CGH, and karyotyping. SNP array analysis is a powerful tool for the detection of allelic imbalance in neuroblastoma and also allows identification of LOH without changes in copy number (uniparental disomy).     

Genome-wide analysis of single nucleotide polymorphisms in Bordetella pertussis using comparative genomic sequencing

Bordetella pertussis is known to be a genotypically homogeneous pathogen but the extent of homogeneity at the genomic level is unknown. A currently circulating B. pertussis isolate from Australia was compared with the genome-sequenced Tohama I strain isolated in Japan in the 1950s from a distantly related lineage. Microarray-based comparative genome sequencing (CGS) was used to detect single nucleotide polymorphisms (SNPs) in a total of 1.4 Mb of the 4.09 Mb genome, including 1012 coding-regions, 217 pseudogenes and 268 intergenic regions. The CGS analysis, followed by validation using real-time PCR and DNA sequencing, identified 70 SNPs and five 1-3 bp indels, giving an overall frequency of base changes of 1 per 20 kb. Thirty-two of the 56 SNPs in coding regions were non-synonymous, including five located in virulence-associated genes. The data also allowed us to compare genomic diversity with other "clonal" human pathogens such as Mycobacterium tuberculosis and Yersinia pestis, showing that B. pertussis may be one of the least variable pathogenic bacterial species.     

Maffucci syndrome: a genome-wide analysis using high resolution single nucleotide polymorphism and expression arrays on four cases

Ollier disease and Maffucci syndrome are rare, nonhereditary skeletal disorders characterized by the presence of multiple enchondromas with (Maffucci) or without (Ollier) co-existing multiple hemangiomas of soft tissue. Enchondromas can progress toward central chondrosarcomas. PTH1R mutations are found in a small subset of Ollier patients. The genetic deficit in Maffucci syndrome is unknown. Here, we report the first genome-wide analysis using Affymetrix SNP 6.0 array on Maffucci enchondromas (n = 4) and chondrosarcomas (n = 2) from four cases. Results were compared to a previously studied cohort of Ollier patients (n = 37). We found no loss of heterozygosity (LOH) or common copy number alterations shared by all enchondromas, with the exception of some copy number variations. As expected, chondrosarcomas were found to have multiple genomic imbalances. This is similar to conventional solitary and Ollier-related enchondromas and chondrosarcomas and supports the multistep genetic progression model. Expression profiling using Illumina BeadArray-v3 chip revealed that cartilaginous tumors in Maffucci patients are more similar to such tumors in Ollier patients than to sporadic cartilage tumors. Point mutations in a single gene or other copy number neutral genomic changes might play a role in enchondromagenesis.     

Genome-wide analysis of loss of heterozygosity and copy number amplification in uterine leiomyomas using the 100K single nucleotide polymorphism array

Purpose

Uterine leiomyomas (fibroids) are benign smooth muscle tumors commonly found among reproductive-aged women. Though benign, these tumors are the leading indication for hysterectomies in the United States and cause significant morbidity. Despite the importance of this tumor in women's health, relatively little is known about the molecular etiology.

Methods

In this study, we used the Affymetrix 100K single nucleotide polymorphism (SNP) chip to assess whether the pattern and frequency of genome-wide loss of heterozygosity (LOH) and copy number amplifications is associated with clinical heterogeneity.

Results

Thirty-seven tumors with varying sizes and histology from eleven patients were analyzed. LOH was observed in 4/37 tumors (10.8%) and significantly associated with large-sized tumors (p < 0.0014). Two tumors revealed hemizygosity on chromosome 7q, a region that has been consistently reported to have LOH. Additionally, we detected one novel region of LOH, 16p13.11 in one tumor (2.7%). Copy number amplifications were observed on all chromosomes; however, most were low-level amplifications and only detected in a single tumor. One region of amplification at 3p26.3 was detected in four tumors.

Conclusions

Despite the use of a high-density SNP platform, our results suggest that genome-wide LOH and copy number amplifications are infrequent events and generally do not determine clinical and histologic characteristics of this disease.     

Typing of canine parvovirus isolates using mini-sequencing based single nucleotide polymorphism analysis

The antigenic types of canine parvovirus (CPV) are defined based on differences in the amino acids of the major capsid protein VP2. Type specificity is conferred by a limited number of amino acid changes and in particular by few nucleotide substitutions. PCR based methods are not particularly suitable for typing circulating variants which differ in a few specific nucleotide substitutions. Assays for determining SNPs can detect efficiently nucleotide substitutions and can thus be adapted to identify CPV types. In the present study, CPV typing was performed by single nucleotide extension using the mini-sequencing technique. A mini-sequencing signature was established for all the four CPV types (CPV2, 2a, 2b and 2c) and feline panleukopenia virus. The CPV typing using the mini-sequencing reaction was performed for 13 CPV field isolates and the two vaccine strains available in our repository. All the isolates had been typed earlier by full-length sequencing of the VP2 gene. The typing results obtained from mini-sequencing matched completely with that of sequencing. Typing could be achieved with less than 100 copies of standard plasmid DNA constructs or ≤101 FAID?? of virus by mini-sequencing technique. The technique was also efficient for detecting multiple types in mixed infections.     

A microsphere-based assay for multiplexed single nucleotide polymorphism analysis using single base chain extension

A rapid, high throughput readout for single-nucleotide polymorphism (SNP) analysis was developed employing single base chain extension and cytometric analysis of an array of fluorescent microspheres. An array of fluorescent microspheres was coupled with uniquely identifying sequences, termed complementary ZipCodes (cZipCodes), which allowed for multiplexing possibilities. For a given assay, querying a polymorphic base involved extending an oligonucleotide containing both a ZipCode and a SNP-specific sequence with a DNA polymerase and a pair of fluoresceinated dideoxynucleotides. To capture the reaction products for analysis, the ZipCode portion of the oligonucleotide was hybridized with its cZipCodes on the microsphere. Flow cytometry was used for microsphere decoding and SNP typing by detecting the fluorescein label captured on the microspheres. In addition to multiplexing capability, the ZipCode system allows multiple sets of SNPs to be analyzed by a limited set of cZipCode-attached microspheres. A standard set of non-cross reactive ZipCodes was established experimentally and the accuracy of the system was validated by comparison with genotypes determined by other technologies. From a total of 58 SNPs, 55 SNPs were successfully analyzed in the first pass using this assay format and all 181 genotypes across the 55 SNPs were correct. These data demonstrate that the microsphere-based single base chain extension (SBCE) method is a sensitive and reliable assay. It can be readily adapted to an automated, high-throughput genotyping system. [Primer sequences used in this study are available as online supplementary materials at www.genome.org.]     

Progress in concurrent analysis of loss of heterozygosity and comparative genomic hybridization utilizing high density single nucleotide polymorphism arrays

Genetic aberrations, such as deletions and amplifications are among the major pathogenetic mechanisms underlying many medical disorders. Analysis of chromosomal aberrations is particularly important in cancer research, where amplifications of oncogenes and deletions of tumor suppressor genes are major steps in the "multi-hit" process of tumorigenesis. Genome-wide molecular biological analyses, such as loss of heterozygosity (LOH) profiling and comparative genomic hybridization (CGH) have significantly enhanced our ability to detect chromosomal aberrations in cancer cells and assess their role in tumorigenesis. The recent introduction of high-density oligonucleotide arrays for measuring single nucleotide polymorphisms (SNP) has sparked a new wave of high-resolution genetic mapping studies, including LOH and CGH applications on various cancer types. This review highlights recent progress on concurrent LOH and CGH analyses utilizing high density SNP arrays and their application in cancer research.     

High-resolution analysis of 9p loss in human cancer cells using single nucleotide polymorphism-based mapping arrays

Single nucleotide polymorphism (SNP) mapping arrays were used to perform DNA copy number analysis of five human cancer cell lines (four malignant mesotheliomas; one non-small cell lung carcinoma) to identify and map the end-points of deletions of 9p. All five cell lines exhibited homozygous deletions encompassing the CDKN2A (alias INK4A/ARF) and CDKN2B loci. The DNA analysis profiles demarcated precisely two different, but overlapping, deletions in each mesothelioma cell line, but the lung cancer cells showed two copies of a single deletion. In the latter cell line, allele analysis revealed that virtually all SNPs for chromosome 9 were homozygous, suggestive of uniparental disomy. These findings demonstrate the utility of SNP-based mapping arrays for high-resolution analysis of genomic imbalances in cancer cells.     

髓母细胞瘤全基因组的等位基因型分析

目的研究髓母细胞瘤全基因组的遗传学异常,寻找与该肿瘤发病有关的等位基因失衡的特异性染色体位点。方法应用包括384个微卫星灶标记物的高分辨全基因组等位基因型分析法研究12例髓母细胞瘤的遗传学改变。结果我们在所有39条常染色体臂上发现了238个(62．3％)失衡的等位基因。在染色体7q(58．3％),8p(66．7％),16q(58．3％),17p(58．3％)和17q(66．7％)上存在非随机的等位基因丢失或获得。另外,在平均值以上的等位基因失衡出现在染色体3p(33．3％),3q(33．3％),4q(41．7％),7p(33．3％),8q(41．7％),10q(41．7％),13q(33．3％),14q(33．3％)和20q(33．3％)。染色体上等位基因失衡的比率与患者的预后无明显关联。结论发生在染色体7q,8p,16q,17p和17q上的等位基因失衡可能在髓母细胞瘤的发病机制中起着重要的作用。     

Delineation of commonly deleted chromosomal regions in meningiomas by high-density single nucleotide polymorphism genotyping arrays

Despite recent advances in the identification of the cytogenetic profiles of meningiomas, a significant group of tumors still show normal karyotypes or few chromosomal changes. The authors analyzed the cytogenetic profile of 50 meningiomas using fluorescence in situ hybridization and high-density (500 K) single nucleotide polymorphism (SNP) arrays. Our results confirm that del(22q) (52%) and del(1p) (16%) (common deleted regions: 22q11.21-22q13.3. and 1p31.2-p36.33) are the most frequent alterations. Additionally, recurrent monosomy 14 (8%), del(6q) (10%), del(7p) (10%), and del(19q) (4%) were observed, while copy number patterns consistent with recurrent chromosomal gains, gene amplification, and copy number neutral loss of heterozygosity (cnLOH) were either absent or rare. Based on their overall SNP profiles, meningiomas could be classified into: (i) diploid cases, (ii) meningiomas with a single chromosomal change [e.g., monosomy 22/del(22q)] and (iii) tumors with ≥2 altered chromosomes. In summary, our results confirm and extend on previous observations showing that the most recurrent chromosomal abnormalities in meningiomas correspond to chromosome losses localized in chromosomes 1, 22 and less frequently in chromosomes 6, 7, 14, and 19, while chromosomal gains and cnLOH are restricted to a small proportion of cases. Finally, a set of cancer-associated candidate genes associated with the TP53, MYC, CASP3, HDAC1, and TERT signaling pathways was identified, in cases with coexisting monosomy 14 and del(1p).     

A nanobiotechnology roadmap for high-throughput single nucleotide polymorphism analysis

Genetic analysis based on single nucleotide polymorphisms (SNPs) has the potential to enable identification of genes associated with disease susceptibility, to facilitate improved understanding and diagnosis of those diseases, and should ultimately contribute to the provision of new therapies. To achieve this end, new technology platforms are required that can increase genotyping throughput, while simultaneously reducing costs by as much as two orders of magnitude. Development of a variety of genotyping platforms with the potential to resolve this dilemma is already well advanced through research in the field of nanobiotechnology. Novel approaches to DNA extraction and amplification have reduced the times required for these processes to seconds. Microfluidic devices enable polymorphism detection through very rapid fragment separation using capillary electrophoresis and high-performance liquid chromatography, together with mixing and transport of reagents and biomolecules in integrated systems. The potential for application of established microelectronic fabrication processes to genetic analyses systems has been demonstrated (e.g. photolithography-based in situ synthesis of oligonucleotides on microarrays). Innovative application of state-of-the-art photonics and integrated circuitry are leading to improved detection capabilities. The diversity of genotyping applications envisaged in the future, ranging from the very high-throughput requirements for drug discovery through to rapid and cheap near-patient genotype analysis, suggests that several SNP genotyping platforms will be necessary to optimally address the different niches.     

Genomic profiling by whole-genome single nucleotide polymorphism arrays in Wilms tumor and association with relapse

Despite the excellent survival rate of Wilms tumor (WT) patients, only approximately one-half of children who suffer tumor recurrence reach second durable remission. This underlines the need for novel markers to optimize initial treatment. We investigated 77 tumors using Illumina 370CNV-QUAD genotyping BeadChip arrays and compared their genomic profiles to detect copy number (CN) abnormalities and allelic ratio anomalies associated with the following clinicopathological variables: relapse (yes vs. no), age at diagnosis (≤ 24 months vs. >24 months), and disease stage (low stage, I and II, vs. high stage, III and IV). We found that CN gains at chromosome region 1q21.1-q31.3 were significantly associated with relapse. Additional genetic events, including allelic imbalances at chromosome arms 1p, 1q, 3p, 3q, and 14q were also found to occur at higher frequency in relapsing tumors. Interestingly, allelic imbalances at 1p and 14q also showed a borderline association with higher tumor stages. No genetic events were found to be associated with age at diagnosis. This is the first genome wide analysis with single nucleotide polymorphism (SNP) arrays specifically investigating the role of genetic anomalies in predicting WT relapse on cases prospectively enrolled in the same clinical trial. Our study, besides confirming the role of 1q gains, identified a number of additional candidate genetic markers, warranting further molecular investigations.     

Genome-wide copy number alterations detection in fresh frozen and matched FFPE samples using SNP 6.0 arrays

SNP arrays offer the opportunity to get a genome-wide view on copy number alterations and are increasingly used in oncology. DNA from formalin-fixed paraffin-embedded material (FFPE) is partially degraded which limits the application of those technologies for retrospective studies. We present the use of Affymetrix GeneChip SNP6.0 for identification of copy number alterations in fresh frozen (FF) and matched FFPE samples. Fifteen pairs of adenocarcinomas with both frozen and FFPE embedded material were analyzed. We present an optimization of the sample preparation and show the importance of correcting the measured intensities for fragment length and GC-content when using FFPE samples. The absence of GC content correction results in a chromosome specific "wave pattern" which may lead to the misclassification of genomic regions as being altered. The highest concordance between FFPE and matched FF were found in samples with the highest call rates. Nineteen of the 23 high level amplifications (83%) seen using FF samples were also detected in the corresponding FFPE material. For limiting the rate of "false positive" alterations, we have chosen a conservative False Discovery Rate (FDR). We observed better results using SNP probes than CNV probes for copy number analysis of FFPE material. This is the first report on the detection of copy number alterations in FFPE samples using Affymetrix GeneChip SNP6.0.     

Role of epigenetic alterations in the pathogenesis of Barrett's esophagus and esophageal adenocarcinoma

Barrett's esophagus, a pre-malignant condition that can lead to esophageal adenocarcinoma, is characterized by histological changes in the normal squamous epithelium of the esophagus. Numerous molecular changes occur during the multistage conversion of Barrett's metaplasia to dysplasia and frank adenocarcinoma. Epigenetic changes, especially changes in DNA methylation are widespread during this process. Aberrant DNA methylation has been shown to occur at promoters of tumor suppressor genes, adhesion molecules and DNA repair genes during Barrett's esophagus. These epigenetic alterations can be used as molecular biomarkers for risk stratification and early detection of esophageal adenocarcinoma. We also show that genome wide analysis of methylation surprisingly reveals that global hypomethylation and not hypermethylation is the dominant change during Barrett's metaplasia. The transformation of Barrett's esophagus to frank adenocarcinoma is in turn characterized by much smaller wave of selective promoter hypermethylation. These studies reveal many novel, potential targets for new therapies and illustrate the utility of incorporating these epigenetic changes as biomarkers during endoscopic surveillance interval for patients with Barrett's esophagus.     

Molecular genetic changes in metastatic primary Barrett's adenocarcinoma and related lymph node metastases: comparison with nonmetastatic Barrett's adenocarcinoma.

Lymph node metastasis is one of the strongest negative prognostic factors for patients with Barrett's adenocarcinoma (BCA). However, despite the importance of the metastatic process in BCA, the molecular basis of it remains poorly understood. To search for cytogenetic events associated with metastasis in regional or distant lymph nodes in BCA, we investigated 8 primary BCA and their lymph node metastases and compared them with 18 nonmetastatic BCA. In metastatic primary BCA, we observed significantly more DNA gains on 3q (P = .013), 17q (P = .019), and 22q (P = .021) compared with nonmetastatic primary BCA. No statistically significant correlation could be observed between DNA copy number changes and the histopathologic stage, grade, or survival (P > .05). The most frequent alteration observed only in lymph node metastases but not in the related primary tumor was loss of 2q (5 of 8). Coamplification of 7p and chromosome 17 was found in 6 of 8 lymph node metastases. A comparison of DNA copy number changes between primary tumors and their corresponding metastases indicated a high degree of genetic heterogeneity. Fluorescence in situ hybridization analysis demonstrated the involvement of the Her-2/neu gene in primary BCA and its related lymph node metastases. Each of the investigated primary tumors and related lymph node metastases also showed striking heterogeneity with respect to Her-2/neu, with several areas displaying different levels of amplification. In summary, our data indicate that DNA copy number changes on 2q, 3q, 7p, 17q, and 22q may be involved in the metastatic process in BCA. Furthermore, the striking genetic heterogeneity that we found between primary BCA and its lymph node metastases may underlie BCA's poor responsiveness to therapy and could help explain why prognostic biomarkers measured exclusively in primary tumors give an incomplete view of the biologic potential of BCA.     

Intragenic single nucleotide polymorphism haplotype analysis of SUR1 mutations in familial hyperinsulinism

Familial hyperinsulinism (HI; MIM# 256450) is an autosomal recessive disorder of pancreatic β‐cell function, characterized by inadequate suppression of insulin secretion despite severe recurrent fasting hypoglycemia. Subtotal pancreatectomy is frequently required to prevent permanent neurologic sequelae. The incidence of HI in the Caucasian population is estimated at 1:50,000, however an apparent increased incidence among Ashkenazi Jews and Saudi Arabian Arabs has been reported. A locus for HI was assigned by linkage analyses to human chromosome 11p15.1. The sulfonylurea receptor (MIM# 600509, SUR1) and the potassium channel, inwardly rectifying, subfamily J member 11 (MIM# 600937, KIR6.2) genes, 2 components of the β‐cell K_ATP channel, are clustered in this chromosomal region, and mutations in these genes have been implicated in HI. We previously demonstrated that two mutations in the SUR1 gene are present on approximately 88% of HI‐associated chromosomes in Ashkenazi Jewish patients. Haplotype analysis with microsatellite markers flanking the gene revealed that one mutation (delF1388), reported only in Ashkenazi probands, occurred on two related extended haplotypes. By contrast, the second, more common mutation (3992‐9g→a) was associated with nine different intergenic haplotypes and has been reported in non‐Jewish HI patients as well. In this study, we evaluated disease‐associated chromosomes from 41 Ashkenazi Jewish and 2 non‐Jewish HI patients carrying the 3992‐9g→a mutation by assessing haplotypes defined by nine common single nucleotide polymorphisms (SNPs), six in the SUR1 gene, and three in the KIR6.2 gene. Our results indicate that all 54 chromosomes carrying the 3992‐9g→a mutation in the Jewish patients appear to have originated from one founder mutation, whereas the same mutation on chromosomes from non‐Jewish patients originated independently. Furthermore, our findings have implications concerning the HI‐associated chromosomes on which no mutation has been identified. Hum Mutat 14:23–29, 1999. © 1999 Wiley‐Liss, Inc.