Different basic fibroblast growth factor and fibroblast growth factor-antisense expression in eutopic endometrial stromal cells derived from women with and without endometriosis.

In all species studied, the basic fibroblast growth factor (bFGF) gene is transcribed into multiple mRNAs, one of which is an antisense RNA (1B FGF-AS) probably involved in regulating the stability of the sense transcript. In this study we investigated whether the regulatory mechanisms of bFGF expression might be altered in endometrial stromal cells derived from women with endometriosis. bFGF and 1B FGF-AS mRNA levels were quantified in primary cultures of eutopic endometrial stromal cells derived from 29 women without endometriosis and 24 patients affected by the disease. When the data were analyzed according to the phase of the menstrual cycle, endometrial stromal cells derived from patients in the late proliferative phase showed significantly higher bFGF mRNA values and significantly lower 1B FGF-AS mRNA levels compared with control samples. Furthermore, the mean bFGF/1B FGF-AS mRNA ratio was significantly higher in endometrial stromal cells derived from patients compared with that in controls (mean +/- SEM, 2.31 +/- 0,55 and 0.77 +/- 0.14, respectively; P = 0.009). Moreover, for bFGF expression the differences existing at the mRNA level were maintained at the protein level. These findings support the hypothesis that 1B FGF-AS mRNA could regulate the expression of the sense transcript and suggest that in endometrial cells derived from patients, the presence of higher bFGF levels could improve their ability to proliferate at the ectopic site.

Physical map of the D6S149-D6S193 region on chromosome 6Q27 and its involvement in benign surface epithelial ovarian tumours.

A detailed long range restriction map of the region defined by markers D6S149 and D6S193 on chromosome 6q27 has been constructed. This was achieved by YAC cloning and contig assembling of the same region. Seven YAC clones were found to span the almost 1000 Kb region flanked by the two markers which on the genetic map resulted to be 1.9 cM apart. With some of the characterized YAC clones we undertook a molecular cytogenetic analysis of 20 benign ovarian tumors. The rationale for this was the recent mapping to a region of chromosome 6q27, flanked by markers D6281 and D6S133, of a locus for the SV40-mediated immortalization of human cells (SEN6 gene). Noteworthy we found that the the D6S149-D6S193 region (comprised in the larger D6S281-D6S133 physical interval) was altered in all samples analysed adding support to the occurrence of a immortalization step in this type of tumors.

Characterization of multiple enhancer regions upstream of the apolipoprotein(a) gene.

Plasma concentrations of the atherogenic lipoprotein(a) (Lp(a)) are predominantly determined by inherited sequences within or closely linked to the apolipoprotein(a) gene locus. Much of the interindividual variability in Lp(a) levels is likely to originate at the level of apo(a) gene transcription. However, the liver-specific apo(a) basal promoter is extremely weak and does not exhibit common functional variations that affect plasma Lp(a) concentrations. In a search for additional apo(a) gene control elements, we have identified two fragments with enhancer activity within the 40-kilobase pair apo(a)-plasminogen intergenic region that coincide with DNase I-hypersensitive sites (DHII and DHIII) observed in liver chromatin of mice expressing a human apo(a) transgene. Neither enhancer exhibits tissue specificity. DHIII activity was mapped to a 600-base pair fragment containing nine DNase I-protected elements (footprints) that stimulates luciferase expression from the apo(a) promoter 10-15-fold in HepG2 cells. Binding of the ubiquitous transcription factor Sp1 plays a major role in the function of this enhancer, but no single site was indispensable for activity. DHIII comprises part of the regulatory region of an inactive long interspersed nucleotide element 1 retrotransposon, raising the possibility that retrotransposon insertion can influence the regulation of adjacent genes. DHII enhancer activity was localized to a 180-base pair fragment that stimulates transcription from the apo(a) promoter 4-8-fold in HepG2 cells. Mutations within an Sp1 site or either of two elements composed of direct repeats of the nuclear hormone receptor half-site AGGTCA in this sequence completely abolished enhancer function. Both nuclear hormone receptor elements were shown to bind peroxisome proliferator-activated receptors and other members of the nuclear receptor family, suggesting that this enhancer may mediate drug and hormone responsiveness.

Genomic structure and organization of kringles type 3 to 10 of the apolipoprotein(a) gene in 6q26-27.

Apolipoprotein(a) [apo(a)] is a highly polymorphic glycoprotein covalently linked to the apolipoprotein B-100 of LDL in a particle called lipoprotein(a) [Lp(a)]. High plasma levels of Lp(a) are associated with coronary as well as peripheral atherosclerosis. Plasma levels of Lp(a) show a remarkable variation ranging from 0.1 mg/dl to over 100 mg/dl. The apo(a) gene shows a size polymorphism which resides in the variable number of kringle domains which resemble plasminogen kringle IV. Ten different types of kringle IV repeats have been described, nine of which (kringle IV type 1 and type 3-10) are each supposed to be present in a single copy. The other kringles, namely kringle IV type 2 repeats, vary in number from 3 to 42 between apo(a) alleles and form the basis for the apo(a) size polymorphism. Although an inverse relationship has been observed between the number of kringle type 2 repeats and plasma levels of Lp(a), there are exceptions to this general finding. Indeed, several individuals have been described with similar apo(a) size alleles but very different plasma levels of Lp(a). Genetic studies have linked these differences to the apo(a) locus on 6q26-27, outlining the importance, besides the kringle type 2 repeats, of other regions of the apo(a) gene in contributing to the interindividual differences in the plasma concentration of Lp(a). One of the candidate regions is represented by the non-repeated type-3 to type-10 kringles which are invariably present in each apo(a) allele and whose structural integrity is playing a critical role in the correct assembly of the Lp(a) particle. Biochemical studies with recombinant wild type and mutagenized apo(a) cDNAs with several alterations of the non-repeated kringles have well documented this latter point. As a starting point to search for genetic variations in these kringles associated with different levels of Lp(a), we are presenting the genome organization of type-3 to 10 kringle along with specific PCR primers for easy analysis from genomic DNA. Restriction as well as partial sequencing analyses of the type-3 to 10 kringles region has also provided interesting clues as to the different evolutionary origin of these types of kringle with respect to the polymorphic type-2 kringles.

Several liver specific DNAse hypersensitive sites are present in the intergenic region separating human plasminogen and apoprotein(A) genes.

The genes coding for plasminogen and apoprotein(a) are clustered, together with two related genes, on the telomeric region of chromosome 6 at band 6q26-27. Moreover, the two genes are 40 Kb apart and transcriptionally pointing to opposite directions. Plasminogen and apoprotein(a) share a high degree of homology in the promoter and 5' flanking regions and their expression is mainly confined to liver. To assess whether common controlling elements mediate the tissue specific expression of these two genes, the region between them was investigated for DNase hypersensitive sites in hepatic cell nuclei.