Showing papers by "Richard N. Clayton published in 1997"

Allelic deletion in pituitary adenomas reflects aggressive biological activity and has potential value as a prognostic marker.

Abstract: Tumors of the pituitary gland are usually benign adenomas and account for 10% of all intracranial neoplasms. Five pituitary tumors have previously been reported to harbor multiple allelic deletions. Of these, three displayed particularly aggressive biological behavior, whereas there were no clinical details provided for the others. This study was designed to test the hypothesis that genetic deletions are a marker of invasive behavior and to identify the loci most commonly involved. Accordingly, we studied two cohorts of pituitary tumors, classified radiologically as invasive or noninvasive, for loss of heterozygosity (LOH). There is a significantly higher frequency of LOH in invasive tumors (10.8% of all loci examined) compared to noninvasive tumors (2.4%; P < 0.001). Of the 11 loci investigated, 75% of the allelic deletions identified in invasive tumors were found at 4 loci: 11q13, 13q12–14, 10q, and 1p. Twenty of 47 invasive tumors had evidence of at least 1 allelic deletion, whereas 14 of 20 had more t...

Chromosome 9p deletions in invasive and noninvasive nonfunctional pituitary adenomas : The deleted region involves markers outside of the MTS1 and MTS2 genes

Abstract: We have screened 57 cases of primary, nonfunctional, pituitary adenomas for loss of heterozygosity of markers on chromosome 9p. Using a panel of 11 microsatellite markers, we found hemizygous deletion with at least one of the markers in 18 tumors (31.5%). The frequency of loss was similar in both noninvasive (8 of 26; 31%) and invasive tumors (10 of 31; 32%), suggesting that loss on this chromosome might be an early event in pituitary tumorigenesis. Two discrete areas of loss were punctuated by a region of retention of heterozygosity between the markers D9S171 and IFNA, indicative of homozygous deletion. However, multiplex PCR analysis (MTS1 and MTS2) and the presence of a 3' untranslated region polymorphism in MTS1 suggested that neither of these tumor suppressor genes was homozygously deleted. In 6 of the 18 tumors showing LOH, sufficient DNA was also available for Southern blot analysis and, in all cases, showed retention of MTS1. Cell mixing experiments of tumor cell DNA homozygously deleted for MTS1 with DNA in which neither copy of the gene was deleted only gave rise to a signal at contamination levels greater than 30% and could discriminate homozygous and hemizygous loss. These studies support the recent findings that mechanisms other than hemi- and homozygous deletion are most likely responsible for the loss of MTS1 gene product in pituitary tumors (M. Woloschak et al., Cancer Res., 56: 2493-2486, 1996.). These data show that losses on either side of 9p21-22, both or either of which may be deleted, are involved in pituitary tumorigenesis and provide evidence for distinct suppressor gene loci, in addition to MTS1, on chromosome 9p.

Altered composition of high density lipoproteins in women with the polycystic ovary syndrome.

Abstract: Women with polycystic ovary syndrome (PCOS) appear at increased cardiovascular risk due in part to a dyslipidemia characterized by increased plasma triglyceride and reduced high density lipoprotein (HDL) cholesterol levels. This is a detailed exploratory study of HDL composition in 35 obese [body mass index (BMI), > 27] and 22 nonobese subjects with PCOS and in 14 healthy obese and 18 nonobese women. Although we found reduced levels of total and HDL2 cholesterol in obese women with PCOS, HDL composition was modified by depletion of lipid relative to protein, with reduced ratios of HDL total cholesterol and HDL phospholipids to apolipoprotein A-I (apoA-I) compared to those in obese controls (P = 0.008 and P = 0.012, respectively). This was explained by reduced cholesterol (P = 0.004) and phospholipid (although not significant, P = 0.07) in HDL with no change in the content of apoA-I, its major protein. Obesity, insulin resistance, and hyperandrogenemia are features of PCOS and potentially affect lipid metabolism. Insulin sensitivity was assessed by the reduction in endogenous glucose concentration after exogenous insulin; the insulin, glucose, and fatty acid responses to oral glucose; and the fasting insulin concentration. When age, BMI, free androgen index, insulin sensitivity determined by all methods, and the presence of PCOS were subjected to stepwise multivariate regression analysis, the presence of PCOS was the most consistent predictor of lipid-depleted HDL (HDL total cholesterol/apoA-I and HDL phospholipids/apoA-I). We speculate that altered activity of hepatic lipase or lipid transfer protein could explain this aspect of the dyslipidemia. Obesity has an important influence on the lipid profile. Obese PCOS and control subjects had higher levels of cholesterol, triglyceride, apoB, and fatty acids than their lean counterparts, and BMI proved the best predictor of blood levels on multiple regression analysis. In contrast, lean PCOS patients had normal sensitivity to insulin and lipid profiles similar to those of the lean controls and did not manifest the HDL abnormalities. Although in PCOS, correlations were obtained between the free androgen index and cholesterol, triglyceride, and apoB levels and between the integrated glucose and insulin responses after oral glucose and fasting fatty acid and triglyceride levels, when age and adiposity were included as covariates only fatty acids and the integrated glucose response remained significantly correlated. Among the controls, total, low density lipoprotein cholesterol, triglycerides, and apoB were related to aspects of insulin sensitivity independent of age and BMI. Lipid metabolism in PCOS is dependent on several related factors, but subjects with PCOS who are obese show a specific reduction in HDL lipid, suggesting a reduced capacity for cholesterol removal from tissues with diminished antiatherogenic potential. Efforts should be directed toward reducing obesity in PCOS to improve the metabolic disturbance in addition to ameliorating the presenting symptoms.

Localisation of a gene causing endocrine neoplasia to a 4 cM region on chromosome 1p35-p36.

Abstract: The development of some endocrine tumours, such as medullary thyroid carcinomas, phaeochromocytomas, anterior pituitary adenomas, and parathyroid adenomas involve a putative tumour suppressor gene located on chromosome 1p32-pter, a region that represents 111 cM. In order to refine the location of this gene, 93 endocrine tumours (39 parathyroid adenomas, 40 anterior pituitary adenomas, seven pancreatic islet cell adenomas, and seven carcinoids) were investigated for loss of tumour heterozygosity (LOH) using the seven polymorphic loci 1pter-D1S228-D1S507-D1S234-D1S476-D1S22 0-D1S207-D1S206-1cen. LOH was detected in 27% of the parathyroid tumours and in 7.5% of the pituitary tumours, but in none of the pancreatic islet cell or carcinoid tumours. In addition, seven of the 10 parathyroid tumours that showed LOH of chromosome 1p facilitated a more precise mapping of this putative tumour suppressor gene; five tumours involved a loss only of the telomeric locus D1S228, whereas two other tumours showed LOH at the centromeric loci D1S507, D1S234, D1S476, and D1S220, but not D1S228. Thus, our results have mapped this tumour suppressor gene implicated in endocrine tumours to a 4 cM region flanked by D1S228 and D1S507 on chromosome 1p35-p36.

Tumour Suppressor Genes in the Pathogenesis of Human Pituitary Tumours

Abstract: Abnormal cell proliferation is controlled by opposing actions of oncogene products (stimulatory) and tumour suppressor gene (TSG) products (inhibitory). The former are dominantly acting, i.e. only one copy needed for tumorigenesis, whilst for TSG both copies of the gene must be inactivated so these are recessive at a cellular level. For anterior pituitary tumours only one oncogene (Gsp) has been identified in a variable proportion (4-40%) of a single tumour subtype (somatotrophinomas). Contrariwise, allelic deletion studies, using a PCR-based microsatellite polymorphism analysis of DNA extracted from archival specimens, have shown significant loss of heterozygosity in 20-40% of all tumour subtypes at the locus of the putative MEN-1 gene (chr. 11q13); the retinoblastoma gene (chr. 13q 12-14), and 10q26. Moreover, these DNA microdeletions were concentrated in radiologically invasive tumours compared to noninvasive tumours (modified Hardy gdes 3 and 4 vs. 1 + 2). In addition, 50% of Cushing's adenomas showed presence of p53 immunopositivity, though no point mutations in exons 4-9 were found, by SSCP analysis, to account for this. These studies show that analysis of TSGs in pituitary adenomas may provide clues to their pathogenesis, and more importantly relate to clinical behaviour of the tumour, and hence aid decisions regarding management.

Genomic sequence analysis of a key residue (Arg183) in human Gαq in invasive non‐functional pituitary adenomas

Abstract: OBJECTIVE With isolated exceptions the only oncogene significantly associated with pituitary tumours is a constitutively active Gs protein (G alpha s). The recent cloning of the cDNA of human G alpha q has facilitated the study of this activator of the phospholipase C beta/Ca2+/ protein kinase C pathway. Since, with isolated exceptions, non-functional tumours are responsive in vitro to TRH and GnRH which activate Gq, we have investigated the genomic sequence of G alpha q, in non-functional (NF) invasive pituitary adenomas, at a residue corresponding to the one most frequently mutated in G alpha s. PATIENTS AND MEASUREMENTS We studied 27 invasive NF pituitary tumours by direct sequencing of DNA derived from archival slide extracted tumour cells. Primers were designed to encompass Arg183 (corresponding to Arg201 of G alpha s) which when mutated has been shown to have oncogenic potential when transfected into cultural rat fibroblasts. In a previous study we have described allelic loss at tumour suppressor gene loci (TSG) in 7 of these 27 tumours. RESULTS We successfully amplified genomic DNA with primers designed from the cDNA sequence of G alpha q with specific exclusion of a processed pseudogene. No mutations were found at Arg183, in either the tumours showing allelic losses at specific TSG loci, or in the 20 remaining tumours in which we found no losses at the TSG loci investigated. CONCLUSIONS Mutations at this key residue in G alpha q occur infrequently, if at all, in invasive non-functional pituitary tumours. However we cannot exclude the possibility of mutation(s) at the other key residue of G alpha q, Gin209, implicated in GTP hydrolysis, or in other components of this pathway.