[Novel reference gene RPN1 for normalization of quantitative data in lung and kidney cancer].

Quantitative methods of gene expression analysis in tumors require accurate data normalization, which allows comparison of different mRNA/cDNA samples with unknown concentration. For this purpose reference genes with stable expression level (such as GAPDH, ACTB, HPRT1, TBP) are used. The choice of appropriate reference genes is still actual because well-known reference genes are not suitable for certain cancer types frequently and their unreasonable use without additional tests lead to wrong conclusions. We have developed the bioinformatic approach and selected a new potential reference gene RPN1 for lung and kidney tumors. This gene is located at the long arm of chromosome 3. Our method includes mining of the dbEST and Oncomine databases and functional analysis of genes. The RPN1 was selected from 1500 candidate housekeeping genes. Using comparative genomic hybridization with NotI-microarrays we found no methylation, deletions and/or amplifications at the RPN1-containing locus in 56 non-small cell lung and 42 clear cell renal cancer samples. Using RT-qPCR we showed low variability of RPN1 mRNA level comparable to those of reference genes GAPDH and GUSB in lung and kidney cancer. The mRNA levels of two target genes coding hyalouronidases--HYAL1 and HYAL2--were estimated and normalized relative to pair RPN1--GAPDH genes for lung cancer and RPN1--GUSB for kidney cancer. These combinations were shown to be optimal for obtaining accurate and reproducible data. All obtained results allow us to suggest RPN1 as novel reference gene for quantitative data normalization in gene expression studies for lung and kidney cancers.

[Technology of analysis of epigenetic and structural changes of epithelial tumors genome with NotI-microarrays by the example of human chromosome].

New comparative genome hybridization technology on NotI-microarrays is presented (Karolinska Institute International Patent WO02/086163). The method is based on comparative genome hybridization of NotI-probes from tumor and normal genomic DNA with the principle of new DNA NotI-microarrays. Using this method 181 NotI linking loci from human chromosome 3 were analyzed in 200 malignant tumor samples from different organs: kidney, lung, breast, ovary, cervical, prostate. Most frequently (more than in 30%) aberrations--deletions, methylation,--were identified in NotI-sites located in MINT24, BHLHB2, RPL15, RARbeta1, ITGA9, RBSP3, VHL, ZIC4 genes, that suggests they probably are involved in cancer development. Methylation of these genomic loci was confirmed by methylation-specific PCR and bisulfite sequencing. The results demonstrate perspective of using this method to solve some oncogenomic problems.

[Two CpG-islands of SEMA3B gene: methylation in clear cell renal cell carcinoma].

Earlier in some small cell lung (SCLC) and non-small cell lung carcinoma (NSCLC) cell lines, methylation of CpG-island was found in the SEMA3B region, which belongs to the first intron according to the NCBI data base (Build 36). The aim of this work was to study methylation of two SEMA3B CpG-islands: promoter and intronic in clear cell renal cell carcinoma (RCC). Using methyl specific PCR and bisulfite sequencing, it was shown for the first time that promoter CpG-island was methylated in RCC with high frequency 56% (34/61), and intronic CpG-island - with somewhat lower frequency 35% (17/48). Significant reverse correlation was estimated between mRNA level decrease and methylation of promoter CpG-island in RCC for the first time (P < or = 0.05 by Fisher's exact test), no correlation was determined for intronic CpG-island. This result suggested that methylation of promoter CpG-island contributed into inactivation of SEMA3B gene-suppressor in RCC.

[Down-regulation of RBSP3/CTDSPL, NPRL2/G21, RASSF1A, ITGA9, HYAL1 and HYAL2 genes in non-small cell lung cancer].

Chromosomal and genome abnormalities of 3p are frequent events in many epithelial tumours, including lung cancer. Several critical regions with high frequency of hemi--and homozygous deletions in tumours were detected on 3p and more then 20 different cancer-related genes were identified in 3p21.3 locus. Real-time PCR was used to measure mRNA level of tumour-suppressor genes and candidates in 3p21.3 (RBSP3/CTDSPL, NPRL2/G21, RASSF1A, ITGA9, HYAL1 and HYAL2 in basic types of non-small cell lung cancer (NSCLC)--squamous cell lung cancer (SCC) and lung adenocarcinoma (AC). Significant (from 2 to 100 times) and frequent (from 44 to 100%) mRNA level decrease was shown in NSCLC. Level and frequency of mRNA decrease for all genes depended on histological type of NSCLC. Down-regulation of RASSF1A and ITGA9 was associated significantly with AC progression, the same tendency was found for genes RBSP3/CTDSPL, NPRL2/G21, HYAL1 and HYAL2. On the contrary, down-regulation of all genes in SCC was not associated with clinical stages, tumor cells differentiation and metastases in lymph nodes. Significant decrease of RBSP3/CTDSPL, NPRL2/G21, ITGA9, HYAL1 and HYAL2 mRNA levels (on average, 5-13 times) with high frequency (83-100%) was already shown at the first stage of SCC. Simultaneous decrease of all six genes mRNA level was found in the same tumor samples and was not depended on their localization on 3p21.3 and functions of the proteins. Spearman's correlation coefficient r(s) was from 0.63 to 0.91, P < 0.001. Co-regulation of gene pairs ITGA9 and HYAL2, HYAL1 and HYAL2, which mediate cell-cell adhesion and cell-matrix interaction, was suggested based on the obtained data. It was shown that genetic and epigenetic mechanisms were important for down-regulation of RBSP3/CTDSPL and ITGA9 genes. These results supported the hypothesis on simultaneous inactivation of cluster cancer-related genes in extended 3p21.3 locus during development and progression of lung cancer and other epithelial tumors. Significant and frequent decrease of mRNA level of six genes in SCC could be important for development of specific biomarker sets for early SCC diagnosis and new therapeutic approaches/strategies for NSCLC.

[Tumor suppressor gene RBSP3 in cervical carcinoma: copy number and transcriptional level].

In this work for the first time copy number and expression changes of the tumor suppressor gene RBSP3 (3p21.3) were investigated. The study was performed on HPV-positive squamous cervical carcinoma (SCC) using real-time PCR. Deletions were detected in 42% of cases (19 of 45 studied biopsies). Frequency of deletions was significantly higher in SCC samples with metastases (64%) than in tumors without metastases (32%, P < 0.05). In a few cases amplification of RBSP3 was also found. Altogether copy number changes of RBSP3 were detected in 51% of cases (23 of 45). Expression of RBSP3 was decreased in 64% of SCC samples (21 of 33). Again decreased expression of RBSP3 was detected significantly more frequently (83%) in tumors with metastases compared with SCC without metastases (52%, P < 0.05). In several cases however increased expression was observed. Altogether changes in expression of RBSP3 were detected in 79% (26 of 33) of SCC biopsies. Comparison of copy number and expression changes showed that in 23% of SCC cases decreased expression of RBSP3 was detected in samples with deletions and in 36% cases such decrease was not associated with copy number changes. Rarely more complicated SCC cases were found. For example in some tumors increased expression of RBSP3 was detected in samples with deletions or without changes in copy number. Results of the study suggested that RBSP3 is involved in the progression of SCC and complex mechanisms for inactivation of RBSP3. We also hypothesize that these data indicate that RBSP3 in addition to dephosphorylation of pRb has other functions important for malignant transformation because pRb is almost absent in HPV-positive SCC.

[Identification of changes in gene loci potentially associated with cervical cancer using NotI microarrays].

The investigation of the cancer-associated structural and epigenetic changes in cell genome is a major approach for understanding mechanisms of cancerogenesis. To investigate these genome changes, novel technique of microarrays comprising NotI-linking genome clones was developed. Twenty eight samples from patients with cervical cancer were analyzed using NotI microarrays of human chromosome 3. Deletions, amplifications and methylation were detected for 109 out of 182 NotI clones with different frequency. Notably, 17 NotI-linking clones showed genomic changes in more than 35% of tumor samples investigated, which suggests involvement of genes associated with these clones in development of cervical cancer.

[NotI-STS markers for human chromosome 3 are gene markers].

Ninety four NotI-STS markers to seventy two individual NotI clones were developed basing on DNA nucleotide sequences from NotI-"jumping" and "linking" NotI-libraries of human chromosome 3. The localization of NotI-STS markers and their ordering on chromosome was established by combined data of RH-mapping (our data), contig-mapping, cytogenetic mapping and in silico mapping. Performed comparison of NotI-STS DNAs with human genome sequences revealed two gaps in the regions, 3p21.33 (marker NLI-256) and 3p21.31 (NL3-005), and segmental duplication. Identical DNA fragments are localized in the regions 12q and 3p22-21.33 (marker NL3-007). In the region 3q28-q29 (marker NLM-084) a fragment was detected with its identical copies present also on chromosomes 1, 2, 15 and 19. For 69 NotI-STSs, significant homologies with nucleotide sequences of 70 genes and two cDNAs were detected taking in consideration homologies to NotI-STS 5'- and 3'-terminal sequences. Association of NotI-STSs with genes is confirmed by high correlation of gene density distribution with the density of NotI-STS markers on the map of human chromosome 3. Obtained data evidence possibility of NotI-STS marker application as gene markers and allow considering constructed NotI-map as gene map of human chromosome 3.

[Methylation of the promoter region of the RASSF1A gene, a candidate tumor suppressor, in primary epithelial tumors]. / Uroven' metilirovaniia promotornoi oblasti gena RASSF1A v pervichnykh épitelial'nykh opukholikh.

Methylation of the promoter CpG-islands of the candidate tumor suppressor gene RASSF1A (3p21.31) was studied in primary tumors of kidney, breast and ovary (172 cases). Methylation-specific PCR (MSP) and methyl-sensitive restriction endonuclease digestion followed by PCR (MSRA) were applied. Statistically significant correlation (P << 10(-6)) was shown for the results of the MSP and MSRA, and the data of bisulfite sequencing reported earlier. The frequency of RASSF1A methylation according to MSP and MSRA was 86% (25/29) and 94% (50/53) in renal cell carcinoma (RCC) and 64% (18/28) and 78% (32/41)--in breast carcinoma (BC) samples, and 59% (17/29) and 73% (33/45) in ovarian epithelial tumors (OET), respectively. The use of several methyl-sensitive restriction enzymes (HpaII, HhaI, Bsh12361, AciI) enhanced the sensitivity of MSRA and allowed to analyze methylation status of 18 CpG-pairs in the RASSF1A CpG-island. Density of methylation of the RASSF1A CpG-island was 72% (644/900) in RCC, 63% (361/576) in BC, and 58% (346/594) in OET samples (18 CpG-pairs multiplied to the number of samples shown methylation were assumed as 100%). The RASSF1A gene methylation was also observed in samples of morphologically normal tissues adjacent to corresponding tumors (11-35%), but it was not detected in blood DNAs of healthy donors (0/15). The RASSF1A methylation frequency did not show significant correlation to tumor stage, grade and metastases (P = 0.3-1.0). The RASSF1A gene methylation was observed more frequently than other investigated aberrations--hemi- and homozygous deletions inside or around this gene. These observations are consistent with the hypothesis that the RASSF1A gene methylation is an early event in the carcinogenesis and one of the dominant ways of its inactivation.

[From identification of genomic polymorphism to diagnostic and prognostic markers of human epithelial tumors]. / Ot identifikatsii genomnogo polimorfizma k diagnosticheskim i prognosticheskim markeram épitelial'nykh opukholei cheloveka.

The review considers the results obtained by several groups in the fields of identification of polymorphic loci in the human genome, localization and analysis of genes associated with epithelial tumors of various origins, and generation of molecular markers of socially important oncological diseases. In the first two cases, work was initiated and supported by the Russian program Human Genome. To find new polymorphic loci in the human genome, di-, tri-, and tetranucleotide repeats were searched for in an ordered cosmid library of chromosome 13, NotI and cosmid clones of chromosome 3, and in brain EST. In total, nine polymorphisms and almost 200 STS were identified. Markers of NotI clones of chromosome 3 were associated with particular genes. Polymorphic loci NL1-024, NL2-007, and EST04896 were employed in analysis of deletions from chromosome 3p in tumor DNA. Deletion mapping of 3p in epithelial tumors of five types revealed six critical regions containing potential tumor suppressor genes. Of these, two were in the distal region of chromosome 3p and four, in region 3p21.3. A significant correlation was observed for the frequency of allelic deletions and the stage and the grade of tumors (P < 0.05). On the strength of these findings, genes of region 3p were associated with both tumor development and progression, and proposed as prognostic markers. Regions LUCA and AP20 (3p21.3) showed a high (90%) frequency of aberrations, including homozygous deletions in almost 20% cases. The peak of allelic deletions from region D3S2409-D3S3667 (600 kb) was statistically valid (P = 10(-3)). Regions AP20 and D3S2409-D3S3667 (3p21.3) were for the first time associated with tumorigenesis. Clusters of tumor suppressor genes were identified in regions LUCA, AP20, and D3S2409-D3S3667. Methylation of RASSF1A and RARbeta2 (3p) was associated with early carcinogenesis, and that of SEMA3B, with tumor progression. These findings are useful for early diagnostics and post-surgery prognosis of tumors.

[New tumor suppressor genes in hot spots of human chromosome 3: new methods of identification]. / Novye geny-supressory opukholevogo rosta v goriachikh tochkakh khromosomy 3 cheloveka: novye metody identifikatsii.

Studies of the recent decade, including sequencing of numerous human genome regions, allowed a great progress in detection of new tumor suppressor genes (TSG) and development of new means of their identification and analysis. Effective methods of genome scanning and TSG identification combine DNA array techniques and subtraction hybridization. Alternative ways take advantage of new extrachromosomal vector systems (pETE, pETR) and the functional gene inactivation test. A breakthrough was made in localizing new TSG on the human chromosome 3 short arm, which harbors tumor-suppressing regions and is often rearranged in various tumors and in early carcinogenesis. On 3p, only three putative TSG were known five years ago, and at least ten were identified by the end of 2002. The role of new TSG in carcinogenesis is commonly inferred from a decrease in their transcription in tumor cell lines or primary tumors and from their ability to suppress the growth of these. Protein products of 3p TGS play an important part, constraining cell malignization. Some are directly involved in regulating the cell cycle and inducing apoptosis (RASSFIA), others suppress angiogenesis (Sema3B) or metastasis (Hyal-1). Numerous attempts to find mutations in exons of silent genes failed, and at least half of the new candidate genes (RASSFIA, CACNA2D2, BLU, HYAL1, SEMA3B, RAR-beta) proved to be inactivated by promoter methylation.

[Mapping allelic deletions on the short arm of human chromosome 3 in kidney neoplasms]. / Kartirovanie allel'nykh deletsii na korotkom pleche khromosomy 3 cheloveka v opukholiakh pochki.

Allelic deletions along the short arm of human chromosome 3 were mapped in 57 pairs of DNA samples from tumor and normal tissue of renal carcinoma patients in order to locate potential tumor suppressor genes. Twenty highly polymorphic microsatellite markers were used for deletion mapping. Allelic deletions were found in most of the samples (91%). Extended terminal deletions (56%) prevailed over shorter internal and multiple deletions and dominated (65%) in the most aggressive histopathological kidney cancer subtype, clear-cell carcinoma. Frequency analysis of loss of heterozygosity allowed detection of the human chromosome 3 regions most essential for renal carcinomas: the region adjacent to the gene VHL (3p26-p25), the region of homozygous deletions AP20 (3p22-p21.33), and a new region between markers D3S2420 and D3S2409 (3p21.31, 2.2 Mbp).

[Alternative approaches to genome mapping and sequencing]. / Al'ternativnye podkhody k kartirovaniiu i sekvenirovaniiu genoma.

The main methods used for large-scale mapping of the human and other genomes are reviewed. These methods comprise two procedures of random mapping/sequencing and an approach using linking and jumping libraries. Importantly, no method used up to now has proved efficient in comparative genome analysis. A new method is presented basing on slalom libraries. These libraries provide 10-100 times higher efficiency and may be used for mapping and sequencing whole genomes by small research groups.