Adrenocortical carcinoma, an unusual extracolonic tumor associated with Lynch II syndrome.

Lynch syndrome (LS) is an autosomal dominant condition that predisposes to colorectal cancer and specific other tumors. Extracolonic tumors occur mainly in the endometrium, stomach, ovary, small intestine and urinary tract. The presence of rare tumors in patients belonging to families who have Lynch syndrome is always interesting, because the question arises whether these tumors should be considered as a coincidence or are related with the syndrome. In this last case, they are also the result of the defect in the mismatch repair system, opening the possibility of extending the tumor spectrum associated with the syndrome. Here we describe a patient from a Lynch syndrome family with a germline mutation c.2063T>G (p.M688R) in the MSH2 gene, who developed an adrenal cortical carcinoma, a tumor not usually associated with LS. We analyzed the adrenocortical tumour for microsatellite instability (MSI), LOH and the presence of the germline c.2063T>G (M688R) mutation. The adrenal cortical carcinoma showed the MSH2 mutation, loss of heterozygosity of the normal allele in the MSH2 gene and loss of immunohistochemical expression for MSH2 protein, but no microsatellite instability. Additionally, the adrenal cortical carcinoma did not harbour a TP53 mutation. The molecular study indicates that this adrenal cortical cancer is probably due to the mismatch repair defect.

Loss of heterozygosity of TP53 is not correlated with clinicopathological variables in sporadic colorectal carcinomas.

We have analyzed the loss of heterozygosity (LOH) of TP53 in a series of 96 sporadic colorectal carcinomas by means of PCR, using two microsatellite sequences (TP53 and Mfd152), to investigate its possible relationship with several clinicopathological variables in the Spanish population. Forty six of the 96 patients (48%) showed loss of one allele of the microsatellite TP53, Mfd152 or both, when compared with normal colorectal mucosae and blood samples of the same patient. This high percentage of LOH seems to corroborate the important role of p53 in sporadic colorectal cancer. However, we have found that LOH on this region is independent of histological grade and tumour location. With regard to tumour Dukes' stage, the fact that a substantial proportion of tumours show LOH on 17p from the first stages of the disease could imply that this alteration is not related with the invasiveness acquisition staging.

Digestion of human chromosomes by means of the isoschizomers MspI and HpaII.

The isoschizomers MspI and HpaII are four base cutter (C decrease CGG) restriction endonucleases, HpaII being sensitive to methylation of the internal cytosine. Human chromosomes treated with MspI have produced inconsistent results between laboratories, while HpaII has always been described as a nonbanding enzyme when used on human chromosomes. These results have been explained on the basis of both rarity of the CpG doublet in vertebrate genomes and high rate of CpG methylation (5mCpG). We demonstrated consistent banding patterns subsequent to digestions with MspI and HpaII. On euchromatin, MspI (but not HpaII) digests the DNA of R regions and thus R-bands apparently contain many more CCGG sites (mostly methylated) than G-bands. In heterochromatin, extensive digestion of the 9q12 region not only by MspI but also by HpaII reveals a heterochromatic domain with a high frequency of unmethylated CCGG sites, most probably within the satellite 3 DNA fraction. In addition, enzymatic digestions of the Yq12 heterochromatin, when this region is undercondensed by 5-azacytidine, contribute to deepen the insight into the mechanism of action of this cytidine analog and at the same time reinforce the idea of the heterogeneity of this chromosome region where domains with unmethylated CCGG sites may also exist.

Chromosomal localization of human satellites 2 and 3 by a FISH method using oligonucleotides as probes.

Classical satellites I, II and III are composed of a mixture of repeated sequences. However, each of them contains a simple family of repeated sequences as a major component. Satellites 2 and 3 are simple families of repeated sequences that form the bulk of human classical satellites II and III, respectively, and are composed of closely related sequences based on tandem repeats of the pentamer ATTCC. For this reason, extensive cross-hybridizations are probably responsible for the similar in situ hybridization patterns obtained for satellites II and III. We have used a fluorescent in situ hybridization method with highly specific oligonucleotides for satellites 2 and 3, respectively, as probes. Our results show that satellite 2 is mainly located on chromosomes 1, 2, 10 and 16, whereas the major domain of satellite 3 is on chromosome 9. Furthermore, minor sites of satellites 2 and 3 are shown. Two-colour in situ hybridizations have enabled us to define the spatial relationships existing between the major domains of both satellites and centromeric alpha satellite sequences. These experiments indicate that the heterochromatin regions of chromosomes 1, 9 and 16 have different molecular organizations.

Assignment of human satellite 1 DNA as revealed by fluorescent in situ hybridization with oligonucleotides.

We have used a fluorescent in situ hybridization procedure to detect human satellite 1 DNA, the simple sequence family that constitutes the non-male-specific fraction of classical satellite 1 DNA. Satellite 1 appears to be located on pericentromeric regions of chromosomes 3, 4 and 13, and on satellites of each acrocentric chromosome. These results suggest a possible relationship between quinacrine fluorescence of heterochromatin and DNA composition. Furthermore, by means of multicolour in situ hybridization, we have spatially resolved satellite 1 sequences and centromeric alpha-satellite within heterochromatic blocks.

Digestion of centromeric DNA from each human metaphase chromosome by the 6 bp-restriction enzyme StuI.

Although 6 bp-restriction endonucleases infrequently cut DNA, we describe in this paper the banding pattern induced by one of them, StuI (AGGCCT), on fixed human chromosomes. This enzyme is the first 6 bp-restriction endonuclease demonstrated to be able to digest human heterochromatin. It causes the extraction of two families of repeated DNA, the alpha satellite DNA and the 3.4 kb HaeIII family (DYZ1). On the other hand, digestions with StuI and with another two enzymes, HinfI and RsaI, have established the distribution of sequences within the heterochromatic block of chromosome 3.

Distribution of TaqI sites along human chromosomes revealed by in situ enzyme-nick translation.

We have studied the relative richness of TaqI sites along human chromosomes by means of a nonradioactive in situ enzyme-nick translation procedure. Regions with a higher content of these sequences are shown to be the noncentromeric heterochromatin blocks, whereas within euchromatin, terminal R-bands are the domains more enriched in these sites. Results obtained suggest that the method of performing enzyme digestions using time as a variable, and then in situ nick translation, provides much more complete information about the distribution of enzyme sequences along chromosomes than standard enzyme digestions.

Distribution of satellite DNA fractions within major heterochromatic regions of human chromosomes as revealed by PleI and TfiI digestion.

Banding patterns induced by selective DNA extraction with the restriction endonucleases PleI and TfiI reveal the distribution of human satellite DNAs within the major heterochromatic blocks on human metaphase chromosomes. PleI and TfiI are able to discriminate HinfI target sites, depending on the nature of the central base. PleI digestion specifically reveals regions, within major C-bands, that include the major sites of satellite II DNA and permits more precise localization of satellite II domains than does radioactive in situ hybridization. The close correspondence between the cytogenetic results presented here and previously reported molecular data seems to support the idea that the frequency of enzyme target sequences is the main factor in determining the action produced by restriction endonucleases on fixed human chromosomes and that chromatin conformation is not an important factor in limiting enzyme accessibility.

Induction of R-bands on human chromosomes by TfiI as the consequence of local differences in target richness.

We present a new restriction enzyme-banding pattern on fixed human chromosomes. R-bands are induced by TfiI, an enzyme that cuts DNA at GA(A/T)TC, that is, at HinfI sites having A or T in the central position. Results suggest that regional differences in the frequency of targets are responsible for the effect caused by this enzyme, whereas conformational differences between G- and R-bands would not affect the enzyme action.

TaqI digestion reveals fractions of satellite DNAs on human chromosomes.

Restriction endonuclease TaqI has been known as a nonbanding restriction endonuclease when it is used on fixed human chromosomes. However, a specific TaqI digestion can be obtained after varying experimental conditions such as concentration of enzyme, time of incubation, and volume of the final reaction mixture. This digestion consists of an extensive DNA loss in heterochromatin subregions of chromosomes 1, 9, 15, 16, and Y. These regions essentially coincide with those corresponding to the main chromosome locations of satellite II DNA, whose tandem repeated units contain many TaqI target sequences, and some satellite III DNA domains enriched in TaqI sites.

Time-dependent AluI action on human chromosomes.

We have analyzed the pattern of AluI digestion over time on human chromosomes in order to monitor the evolution of the in situ enzyme action. Short treatments followed by Giemsa staining produce a G-like banding effect, whereas longer treatments produce a C-like banding pattern. However, when Propidium iodide staining is used, it reveals a uniform bright fluorescence after short AluI digestions and C bands when longer treatments are developed. We propose that C banding is the result of a uniform DNA removal in non centromeric regions taking place after a critical time point, the initial G like banding being produced by changes in the DNA-proteins interactions.

New distinctions between regions of centromeric heterochromatin in human chromosomes by treatments with the isoschizomers NdeII-Sau3AI.

The isoschizomers NdeII-Sau3AI (decreases GATC) have been used to characterize heterochromatic regions in human chromosomes. The findings with NdeII are identical with those previously published with MboI, but the results with Sau3AI provide evidence for new distinctions of centromeric heterochromatin in chromosomes 5 and 6. The results are discussed in relation to the chromatin organization at these regions an the mechanisms of the action of restriction endonucleases.