Parathyroid tumor suppressor on 1p: analysis of the p18 cyclin-dependent kinase inhibitor gene as a candidate

Molecular and Clinical Spectrum of Primary Hyperparathyroidism

Recent data suggest an increase in the overall incidence of parathyroid disorders, with primary hyperparathyroidism (PHPT) being the most prevalent parathyroid disorder. PHPT is associated with morbidities (fractures, kidney stones, chronic kidney disease) and increased risk of death. The symptoms of PHPT can be nonspecific, potentially delaying the diagnosis. Approximately 15% of patients with PHPT have an underlying heritable form of PHPT that may be associated with extraparathyroidal manifestations, requiring active surveillance for these manifestations as seen in multiple endocrine neoplasia type 1 and 2A. Genetic testing for heritable forms should be offered to patients with multiglandular disease, recurrent PHPT, young onset PHPT (age ≤40 years), and those with a family history of parathyroid tumors. However, the underlying genetic cause for the majority of patients with heritable forms of PHPT remains unknown. Distinction between sporadic and heritable forms of PHPT is useful in surgical planning for parathyroidectomy and has implications for the family. The genes currently known to be associated with heritable forms of PHPT account for approximately half of sporadic parathyroid tumors. But the genetic cause in approximately half of the sporadic parathyroid tumors remains unknown. Furthermore, there is no systemic therapy for parathyroid carcinoma, a rare but potentially fatal cause of PHPT. Improved understanding of the molecular characteristics of parathyroid tumors will allow us to identify biomarkers for diagnosis and novel targets for therapy.

Novel germline variants of CDKN1B and CDKN2C identified during screening for familial primary hyperparathyroidism

PURPOSE

CDKN1B mutations were established as a cause of multiple endocrine neoplasia 4 (MEN4) syndrome in patients with MEN1 phenotype without a mutation in the MEN1 gene. In addition, variants in other cyclin-dependent kinase inhibitors (CDKIs) were found in some MEN1-like cases without the MEN1 mutation. We aimed to describe novel germline mutations of these genes in patients with primary hyperparathyroidism (PHPT).

METHODS

During genetic screening for familial hyperparathyroidism, three novel CDKIs germline mutations in three unrelated cases between January 2019 and November 2021 were identified. In this report, we describe clinical features, DNA sequence analysis, and familial segregation studies based on these patients and their relatives. Genome-wide DNA study of loss of heterozygosity (LOH), copy number variation (CNV), and p27/kip immunohistochemistry was performed on tumour samples.

RESULTS

DNA screening was performed for atypical parathyroid adenomas in cases 1 and 2 and for cystic parathyroid adenoma and young age at diagnosis of PHPT in case 3. Genetic analysis identified likely pathogenic variants of CDKN1B in cases 1 and 2 and a variant of the uncertain significance of CDKN2C, with uniparental disomy in the tumour sample, in case 3. Neoplasm screening of probands showed other non-endocrine tumours in case 1 (colon adenoma with dysplasia and atypical lipomas) and case 2 (aberrant T-cell population) and a non-functional pituitary adenoma in case 3.

CONCLUSION

Germline mutations in CDKIs should be included in gene panels for genetic testing of primary hyperparathyroidism. New germline variants here described can be added to the current knowledge.

MEN4 and CDKN1B mutations: the latest of the MEN syndromes

Multiple endocrine neoplasia (MEN) refers to a group of autosomal dominant disorders with generally high penetrance that lead to the development of a wide spectrum of endocrine and non-endocrine manifestations. The most frequent among these conditions is MEN type 1 (MEN1), which is caused by germline heterozygous loss-of-function mutations in the tumor suppressor gene MEN1 MEN1 is characterized by primary hyperparathyroidism (PHPT) and functional or nonfunctional pancreatic neuroendocrine tumors and pituitary adenomas. Approximately 10% of patients with familial or sporadic MEN1-like phenotype do not have MEN1 mutations or deletions. A novel MEN syndrome was discovered, initially in rats (MENX), and later in humans (MEN4), which is caused by germline mutations in the putative tumor suppressor CDKN1B The most common phenotype of the 19 established cases of MEN4 that have been described to date is PHPT followed by pituitary adenomas. Recently, somatic or germline mutations in CDKN1B were also identified in patients with sporadic PHPT, small intestinal neuroendocrine tumors, lymphoma and breast cancer, demonstrating a novel role for CDKN1B as a tumor susceptibility gene for other neoplasms. In this review, we report on the genetic characterization and clinical features of MEN4.

Changes in parathyroid proteome in patients with primary hyperparathyroidism due to sporadic parathyroid adenomas

PURPOSE

The pathogenesis of parathyroid tumours is only partially understood. A direct approach using proteomics could be a promising tool to increase our understanding of parathyroid tumorigenesis. The aim of the study was to investigate differentially expressed proteins to explore the underlying molecular basis of the disease and identify potential target proteins responsible for the genesis of adenoma.

METHODS

Proteins were extracted from adenomatous and normal parathyroid tissues. Differentially expressed proteins were separated by two-dimensional gel electrophoresis (2-D) and identified by matrix-assisted laser desorption/ionization-time of flight (MALDI-TOF) mass spectrometry. Statistical analysis was performed using spss 10.01 software.

RESULTS

Comparative analysis of the 2-D profiles of proteins isolated from adenomatous and normal parathyroid tissues showed 15 differentially expressed proteins, of which 11 were overexpressed. The characterized proteins were associated with diverse cellular functions including regulation of cell organization, programmed cell death, transcription and signal transduction.

CONCLUSION

The differentially expressed proteins in parathyroid adenomas may potentially serve as new targets to investigate the mechanisms of parathyroid adenoma transformation.

Complete genomic landscape of a recurring sporadic parathyroid carcinoma

Parathyroid carcinoma is a rare endocrine malignancy with an estimated incidence of less than 1 per million population. Excessive secretion of parathyroid hormone, extremely high serum calcium level, and the deleterious effects of hypercalcaemia are the clinical manifestations of the disease. Up to 60% of patients develop multiple disease recurrences and although long-term survival is possible with palliative surgery, permanent remission is rarely achieved. Molecular drivers of sporadic parathyroid carcinoma have remained largely unknown. Previous studies, mostly based on familial cases of the disease, suggested potential roles for the tumour suppressor MEN1 and proto-oncogene RET in benign parathyroid tumourigenesis, while the tumour suppressor HRPT2 and proto-oncogene CCND1 may also act as drivers in parathyroid cancer. Here, we report the complete genomic analysis of a sporadic and recurring parathyroid carcinoma. Mutational landscapes of the primary and recurrent tumour specimens were analysed using high-throughput sequencing technologies. Such molecular profiling allowed for identification of somatic mutations never previously identified in this malignancy. These included single nucleotide point mutations in well-characterized cancer genes such as mTOR, MLL2, CDKN2C, and PIK3CA. Comparison of acquired mutations in patient-matched primary and recurrent tumours revealed loss of PIK3CA activating mutation during the evolution of the tumour from the primary to the recurrence. Structural variations leading to gene fusions and regions of copy loss and gain were identified at a single-base resolution. Loss of the short arm of chromosome 1, along with somatic missense and truncating mutations in CDKN2C and THRAP3, respectively, provides new evidence for the potential role of these genes as tumour suppressors in parathyroid cancer. The key somatic mutations identified in this study can serve as novel diagnostic markers as well as therapeutic targets.

Germline and somatic mutations in cyclin-dependent kinase inhibitor genes CDKN1A, CDKN2B, and CDKN2C in sporadic parathyroid adenomas

The molecular pathogenesis of sporadic parathyroid adenomas is incompletely understood. The possible role of cyclin-dependent kinase inhibitor (CDKI) genes was raised by recognition of cyclin D1 as a parathyroid oncogene, identification of rare germline mutations in CDKI genes in patients with multiple endocrine neoplasia type 1; that in rodents, mutation in Cdkn1b caused parathyroid tumors; and subsequently through identification of rare predisposing germline sequence variants and somatic mutation of CDKN1B, encoding p27(kip1), in sporadic human parathyroid adenoma. We therefore sought to determine whether mutations/variants in the other six CDKI genes CDKN1A, CDKN1C, CDKN2A, CDKN2B, CDKN2C, and CDKN2D, encoding p21, p57, p14(ARF)/p16, p15, p18, and p19, respectively, contribute to the development of typical parathyroid adenomas. In a series of 85 sporadic parathyroid adenomas, direct DNA sequencing identified alterations in five adenomas (6 %): Two contained distinct heterozygous changes in CDKN1A, one germline and one of undetermined germline status; one had a CDKN2B germline alteration, accompanied by loss of the normal allele in the tumor (LOH); two had variants of CDKN2C, one somatic and one germline with LOH. Abnormalities of three of the mutant proteins were readily demonstrable in vitro. Thus, germline mutations/rare variants in CDKN1A, CDKN2B, and CDKN2C likely contribute to the development of a significant subgroup of common sporadic parathyroid adenomas, and somatic mutation in CDKN2C further suggests a direct role for CDKI alteration in conferring a selective growth advantage to parathyroid cells, providing novel support for the concept that multiple CDKIs can play primary roles in human neoplasia.

Animal models of hyperfunctioning parathyroid diseases for drug development

BACKGROUND

Disorders of mineral and bone metabolism have been implicated as a risk factor in the high mortality in patients with chronic kidney disease (CKD). Hyperphosphatemia, disorders of vitamin D metabolism and secondary hyperparathyroidism of uremia (SHPT) are therapeutic targets in these patients to improve the mortality. Animal models for CKD are indispensable and uremic rats produced by 5/6-nephrectomies are one of the most useful animal models for the development of new therapeutic agents. As there are limitations of uremic rats such as short lifespan and less severity of secondary hyperparathyroidism distinct from CKD patients on maintenance hemodialysis, the development of new model animals is expected.

OBJECTIVE

This review discusses the molecular pathogenesis of hyperfunctioning parathyroid diseases and the applications of animal models exhibiting hyperparathyroidisms in the aspect of the development of new therapeutics.

CONCLUSION

PTH-cyclin D1 transgenic mice, with parathyroid-targeted overexpression of cyclin D1 oncogene, not only developed abnormal parathyroid cell proliferation but, notably, also developed biochemical hyperparathyroidism with characteristic abnormalities in bone. The mice exhibit age-dependent development of biochemical hyperparathyroidism, which enables testing of the drug precisely. In addition, the mice develop parathyroid cell hyperplasia, followed by monoclonal expansion, which is observed in refractory SHPT patients.

Genetic characterization of large parathyroid adenomas

In this study, we genetically characterized parathyroid adenomas with large glandular weights, for which independent observations suggest pronounced clinical manifestations. Large parathyroid adenomas (LPTAs) were defined as the 5% largest sporadic parathyroid adenomas identified among the 590 cases operated in our institution during 2005-2009. The LPTA group showed a higher relative number of male cases and significantly higher levels of total plasma and ionized serum calcium (P<0.001). Further analysis of 21 LPTAs revealed low MIB1 proliferation index (0.1-1.5%), MEN1 mutations in five cases, and one HRPT2 (CDC73) mutation. Total or partial loss of parafibromin expression was observed in ten tumors, two of which also showed loss of APC expression. Using array CGH, we demonstrated recurrent copy number alterations most frequently involving loss in 1p (29%), gain in 5 (38%), and loss in 11q (33%). Totally, 21 minimal overlapping regions were defined for losses in 1p, 7q, 9p, 11, and 15q and gains in 3q, 5, 7p, 8p, 16q, 17p, and 19q. In addition, 12 tumors showed gross alterations of entire or almost entire chromosomes most frequently gain of 5 and loss of chromosome 11. While gain of 5 was the most frequent alteration observed in LPTAs, it was only detected in a small proportion (4/58 cases, 7%) of parathyroid adenomas. A significant positive correlation was observed between parathyroid hormone level and total copy number gain (r=0.48, P=0.031). These results support that LPTAs represent a group of patients with pronounced parathyroid hyperfunction and associated with specific genomic features.

MEN-4 and other multiple endocrine neoplasias due to cyclin-dependent kinase inhibitors (p27(Kip1) and p18(INK4C)) mutations

Cyclin-dependent kinase inhibitors (CDKIs) are known targets to become deregulated in various tumour types, including endocrine tumours. Typically, these cell cycle regulators are somatically inactivated in sporadic endocrine tumours. Recently, it became known that certain CDKI genes cause inherited susceptibility to endocrine neoplasia. Multiple endocrine neoplasia type 4 (MEN4) emerged as a novel form of multiple endocrine neoplasia, caused by mutations in the CDKI gene CDKN1B/p27(Kip1). The MEN4 phenotype remains unclear, but all MEN4 patients identified thus far present with parathyroid involvement, and less typically with pituitary adenomas and other endocrine features. Moreover, the CDKI gene CDKN2C/p18(INK4C) has been also implicated in endocrine neoplasia susceptibility. This review presents the recent advances in these novel MEN-related states and summarises the current knowledge of how these CDKIs may be implicated in endocrine neoplasia. In addition, it briefly presents data from Cdkn1b/p27(Kip1) and Cdkn2c/p18(INK4C) murine models, which strongly support the protective role of these inhibitors against endocrine tumourigenesis.

Expression of p18(INK4C) is down-regulated in human pituitary adenomas

Cyclin-dependent kinase inhibitors represented by the INK4 family comprising p16(INK4A), p15(INK4B), p18(INK4C), and p19(INK4D) are regulators of the cell cycle shown to be aberrant in many types of cancer. Mice lacking p18(Ink4c) exhibit a series of phenotypes including the development of widespread organomegaly and pituitary adenomas. The objective of our study is to examine the role of p18(INK4C) in the pathogenesis of human pituitary tumors. The protein and mRNA levels of p18(INK4C) were examined by immunohistochemistry and real-time reverse transcription-polymerase chain reaction, respectively. The methylation status of the p18(INK4C) gene promoter and somatic mutations of the p18(INK4C) gene were also investigated. p18(INK4C) protein expression was lost or significantly reduced in 64% of pituitary adenomas compared with levels in normal pituitary glands. p18(INK4C) mRNA levels were low in all ACTH adenomas and non-functioning (NF)-FSH and in 42%, 70% and 66% of GH, PRL, and subtype 3 adenomas, respectively. p18(INK4C) mRNA levels were significantly associated with p18(INK4C) protein levels. Neither methylated promoters in pituitary adenomas, except in one NF-FSH adenoma, nor somatic mutations of the p18(INK4C) gene in any pituitary adenomas were detected. The down-regulation of p18(INK4C) expression may contribute to the tumorigenesis of pituitary adenomas.

Reduced p18INK4c, p21CIP1/WAF1 and p27KIP1 mRNA levels in tumours of primary and secondary hyperparathyroidism

OBJECTIVE

Hyperparathyroidism (HPT) refers to states of excessive production of parathyroid hormone (PTH). The eukaryotic cell cycle is driven forward by cyclins and their cyclin-dependent kinase (CDK) partners. Cyclin-dependent kinase inhibitors (CKIs), which generally inhibit cell cycle progression, modulate the activity of cyclin-CDK complexes.

DESIGN

In order to quantify the expression of the CKI genes p18, p21, and p27 semiquantitative RT-PCR with mRNA specific-primers was performed on four normal parathyroid biopsies, 31 parathyroid adenomas of primary HPT and 13 hyperplastic glands from uraemic patients with secondary HPT.

PATIENTS

Parathyroid adenomas and secondary hyperplastic glands were obtained from 31 and 13 randomly selected patients undergoing parathyroidectomy in the clinical routine, respectively. Four normal parathyroid gland biopsies were obtained at surgery for pHPT or from normocalcemic patients undergoing thyroidectomy for goitre.

RESULTS

The relative p27 expression (p27/GAPDH) was significantly reduced in parathyroid adenomas compared to normal parathyroid gland biopsies. Furthermore, 42% and 53% of the parathyroid adenomas displayed undetectable p18 and p21 expression levels, respectively. All 13 adenomas that lacked p18 expression showed undetectable p21 expression. The p18 expression was significantly lower in tumours of uraemic sHPT as compared to normal parathyroids and an undetectable expression level was observed for p21 and p27 in 61% and 53%, respectively.

CONCLUSION

Parathyroid adenomas and secondary hyperplastic glands exhibit aberrant reduced expression of the CKIs p18, p21, and p27. This suggests that deranged collaboration of different CKIs may contribute to the development of both primary and secondary HPT.

Multiple endocrine neoplasia type 1 polymorphism D418D is associated with sporadic primary hyperparathyroidism

BACKGROUND

Sporadic primary hyperparathyroidism (pHPT) occurs separately and in several hereditary disorders including multiple endocrine neoplasia type 1. Irradiation to the neck, female gender, and age are well-identified risk factors that predispose to pHPT. The multiple endocrine neoplasia type 1 gene is the most commonly deranged gene in parathyroid adenomas and contains several polymorphisms including D418D with a prevalence of roughly 50%.

METHODS

We genotyped 162 pHPT patients and control participants to evaluate if the D418D polymorphism is related to development of pHPT. One hundred fourteen of the pHPT patients and control participants were recruited from a health screening and were subjected to measurement of bone mineral density (BMD) at the lumbar spine, femoral neck, and total body.

RESULTS

The prevalence of each genotype (ie, MM, Mm, and mm) was for all pHPT patients: 62%, 29%, and 9%; and for all control participants: 32%, 43%, and 25% (P <.0004). For the screening-detected pHPT patients and control participants, the genotype distribution for MM, Mm, and mm was 60%, 30%, and 10%; and 31%, 44%, and 25%, respectively (P =.009). In the screening-recruited control participants, but not in pHPT patients, the MM genotype was also associated with higher total body BMD (P =.01) and BMD at the femoral neck (P =.02), whereas it failed to be significant for BMD at the lumbar spine (P =.08).

CONCLUSIONS

We report that the MM genotype was overrepresented in pHPT patients compared with control participants, suggesting a novel marker for pHPT. Furthermore, the MM genotype was associated with higher BMD at the femoral neck and in the total body in the screening-recruited control participants.

Genetic and clinical characterization of sporadic cystic parathyroid tumours

OBJECTIVE

The hyperparathyroidism--jaw tumour (HPT--JT) syndrome is one of the familial disorders characterized by primary hyperparathyroidism and has been linked to the chromosomal region of 1q32--q21. The parathyroid tumours related to this syndrome have shown loss of wild-type alleles at this locus suggesting that inactivation of a tumour suppressor gene might be responsible for the disease. In the majority of these tumours cysts are a prominent feature. By loss of heterozygosity (LOH) studies, we investigated the region of interest in an attempt to clarify its possible role in a series of cystic sporadic parathyroid adenomas.

DESIGN AND SUBJECTS

A total of 30 patients diagnosed with sporadic hyperparathyroidism were included in the study, genotyped with 17 polymorphic microsatellite markers at chromosome 1q, and additional markers from 1p and 11q13 which are commonly involved in sporadic parathyroid tumours. The cystic parathyroid tumours were characterized clinically, and immunohistochemistry against PTH was carried out to confirm the parathyroid origin of the cysts.

RESULTS

LOH was found in six of 30 tumours (20%) on 1q, six of 30 tumours (20%) on 1p and five of 30 tumours (17%) on 11q13. We found a significant correlation between allelic alterations and the clinical parameters, tumour weight and PTH. Furthermore, we found a significant difference between tumour weight and PTH in cases of cystic parathyroid tumours compared with unselected sporadic cases.

CONCLUSIONS

These results suggest that cystic parathyroid tumours might represent a new subgroup among parathyroid tumours based on the genetic and clinical findings. Loss of heterozygosity at 1q further supports the presence of a tumour suppressor gene at this locus.

Frequent inactivation of the cyclin-dependent kinase inhibitor p18 by homozygous deletion in multiple myeloma cell lines: ectopic p18 expression inhibits growth and induces apoptosis

Multiple myeloma (MM) is a clonal neoplasm of plasma cells which offers an excellent model to study multistep molecular oncogenesis. In 20-25% of primary tumors and cell lines examined, cyclin D1 is overexpressed due to the translocation t(11;14)(q13;q32). We have characterized cyclin-dependent kinase inhibitor p15 (CDKN2B), p16 (CDKN2A) and p18 (CDKN2C) deletions in cyclin D1-expressing and non-expressing MM cell lines. p18 was found to be frequently deleted (38%); in some cases p18 deletions coexisted with hemizygous p16 deletion. To examine the function of p18 as a putative tumor suppressor in myeloma cells, a zinc-inducible p18 construct was stably transfected into KMS12, a MM cell line with biallelic p18 and monoallelic p16 deletions as well as cyclin D1 overexpression. Ectopic expression of p18 caused 40-45% growth suppression as determined by trypan blue exclusion and MTS assays. p18 induction also resulted in apoptosis, suggesting that inhibition of the cyclin D1/CDK/pRb pathway in these tumor cells could be a crucial step toward the induction of tumor regression via apoptotic cell death. This cell cycle pathway is thus frequently mutated and provides a potentially novel target for gene therapeutic or pharmacologic approaches to human myeloma.

Allelic loss in clinically and screening-detected primary hyperparathyroidism

OBJECTIVE

Parathyroid adenomas frequently harbour deletions of genomic DNA at chromosome regions 1p, 6q and 11q. In this study we related clinical characteristics in 56 patients with primary hyperparathyroidism (pHPT) to loss of heterozygosity (LOH) in these chromosome regions.

DESIGN

LOH analysis was performed on 56 sporadic parathyroid tumours using a total of 18 microsatellite markers for chromosome regions 1p, 6q and 11q. LOH was identified, for either radioactive or fluorescent labelled markers, as total absence or reduction of > or = 50% of the signal intensity of an allele in the tumour DNA vs. constitutional DNA.

PATIENTS

Twenty-one of the patients were recruited by a population-based screening for pHPT and the remaining pHPT patients were gathered from routine clinical practice.

RESULTS

In total, 27%, 23% and 23% of the tumours showed LOH at 1p, 6q and 11q, respectively. LOH at both 1p and 11q was more common in the screening-detected pHPT patients compared to those recruited from clinical practice (38% vs. 20%; P = 0.02 and 43% vs. 11%; P = 0.001, respectively), while allelic loss at 6q was more prevalent in the latter group (11% vs. 31%; P = 0.001). No apparent relationships between LOH at 1p, 6q, and 11q and clinical characteristics, such as glandular weight, serum levels of PTH or calcium, were demonstrated. Moreover, additional LOH analysis of chromosome 1p suggested a putative parathyroid tumour suppressor gene(s) in the region between markers DS214 and D1S503, spanning approximately 6 cM.

CONCLUSION

A high frequency of LOH at 1p and 11q in tumours of screening-detected pHPT patients is intriguing, and may suggest that inactivation of known (the MEN1 gene) and putative tumour suppressor genes at these chromosomal regions is associated with a more benign disease.

Putative parathyroid tumor suppressor on 1p: independent molecular mechanisms of tumorigenesis from 11q allelic loss

Multiple endocrine neoplasia type 1 (MEN1) gene was identified to be a tumor suppressor that encodes menin, playing an important role in the development of MEN1-associated tumors. Somatic MEN1 gene mutations also were detected in sporadic non-MEN1 endocrine tumors. Frequent loss of chromosomal arm 1p has been reported in parathyroid adenomas, suggesting the existence of putative tumor-suppressor genes on 1p. In this study, we performed allelotyping of chromosomes 1p and 11q on 60 sporadic parathyroid adenomas. Thirteen of 48 (27%) informative tumors had allelic loss on 1p, and 18 of 50 (36%) had allelic loss on 11q. Ten of 18 tumors with 11q allelic loss successfully completed the sequence of the MEN1 gene coding region and splice junctions, and 3 of 10 (30%) tumors had no somatic mutation, indicating that other putative tumor-suppressor genes on 11q may contribute to their tumorigenesis. Frequency of allelic losses on 1p was significantly higher in tumors without 11q allelic losses (7 of 11 informative tumors [64%]) than in tumors with 11q allelic losses (3 of 17 informative tumors [18%]) by chi-square test (P = 0.0131; chi-square = 6.152). These observations suggested that putative tumor-suppressor genes locate on 1p, and pathways of their tumorigenesis are independent from inactivation of tumor-suppressor genes on 11q.

Accumulation of allelic changes at chromosomes 7p, 18q, and 2 in parathyroid lesions of uremic patients

We examined by microsatellite allelotyping 69 hyperplastic lesions of the parathyroid glands from 23 patients with refractory, uremic hyperparathyroidism. Allelic changes, at least at one chromosomal arm, were found in 31 of the 69 lesions (43%). Alteration at a single chromosome was seen in 14 lesions and at two to four chromosomes in 11 lesions, and there were five to eight alterations in 5 nodules. Allelic imbalance occurred most frequently at chromosome 7p between the EGFR gene and locus D7S817 (16%), at 18q between loci D18S61 and D18S70 (14%), and at chromosome 2 between D2S380 and D2S1391 (9%). X-inactivation study showed a monoclonal growth in 18 of 29 nodules in females, and a loss of the Y chromosome was seen in 8 of the 39 nodules obtained from males. Our results suggest that the uremic "hyperplastic" nodules have a molecular pathway distinct from those known for sporadic primary parathyroid adenomas.

Frequent loss of heterozygosity at 1p36.3 and p73 abnormality in parathyroid adenomas

Although 1p is one of the most common loci showing loss of heterozygosity (LOH) in primary parathyroid adenoma, fine mapping has not been previously examined. In this study, we analyzed LOH in 32 primary parathyroid adenomas using five microsatellite markers at 1p36 (proximal-D1S507-D1S450-D1S2893-D1S468-D1S243-distal). All cases were heterozygous for at least one marker. The frequency of LOH varied from 41.2% (D1S468) to 7.1% (D1S507) among the different markers. LOH was detected consistently in a group of nine adenomas (28.1%, 9/32). A single region (7 cM) showing a consistent LOH at 1p36.3 was obtained that was flanked distally by D1S468 and proximally by D1S2893. Because the p73 gene is localized within this region and acts as a tumor suppressor gene, we examined the possible involvement of p73 in the development of parathyroid tumor. Allelic loss of p73 was identified in four adenomas (25%, 4/16 informative cases) that were all from the group of the nine adenomas with LOH, but somatic mutation was not detected in the remaining allele. At the StyI polymorphism of Exon 2, four of the six adenomas with LOH at 1p36 were heterozygous and expressed the GC allele. Of the six heterozygous adenomas without LOH, 4 showed biallelic and 2 monoallelic expressions (GC allele). All adenomas mainly expressed the p73alpha isoform. p73 protein was observed in five of the six adenomas with LOH and in two of the six adenomas without LOH. There were no differences in p73 protein levels between the samples with and without LOH. In conclusion, a candidate gene for parathyroid tumorigenesis is present within a 7-cM region at 1p36.3, however p73 is unlikely to be the target of the LOH at 1p36.3.

Molecular pathology of parathyroid tumors

Primary hyperparathyroidism (pHPT), generally caused by a monoclonal parathyroid adenoma, is a common endocrinopathy. Until recently, the genesis of the disease was poorly understood but during the past decade the molecular pathology of parathyroid tumor development has begun to be unveiled. This review summarizes recent advances in our understanding of genetic predisposition to pHPT, and the role of vitamin D receptor gene (VDR) variants in development of the disease. It has been shown that the multiple endocrine neoplasia tumor suppressor gene (MEN1) is mutated in parathyroid adenomas, and overexpression of the cyclin D1 oncogene [PRAD1 (parathyroid adenoma 1)] seems to contribute to parathyroid tumorigenesis. Several familial hyperparathyroid disorders have been studied, and the identification and characterization of the disease-causing genes have contributed to our understanding of parathyroid physiology and pathophysiology.

Molecular mechanisms of primary hyperparathyroidism

Several advances have been achieved toward the goal of understanding the molecular basis of parathyroid tumorigenesis. The cyclin D1/PRAD1 oncogene has been identified, and is involved in the development of several different tumor types besides those of the parathyroid. The tumor suppressor RB gene has been linked to the pathogenesis of parathyroid carcinoma. The MEN-1 gene product has been identified and mutations in MENIN shown to contribute to sporadic tumors. An understanding of the functions of MENIN will provide further insights into parathyroid disease. Mutations in the RET gene have been identified as the causal agent in MEN-2 but this gene contributes rarely to development of sporadic parathyroid tumors. Ultimately, a description of parathyroid tumorigenesis will need to account for such features as the rarity of parathyroid carcinoma, the increased incidence of tumors after neck irradiation, and the increased frequency of hyperparathyroidism in postmenopausal women. In addition, the relationship between excessive cellular proliferation and an altered set-point in the mechanism linking extracellular calcium concentration to PTH secretion requires explanation. While mutations in the CASR gene itself play a critical role in familial disease, they do not appear to be involved in sporadic parathyroid tumorigenesis, and investigation of genes important for its expression is clearly warranted.

Analysis of the RAD54 gene on chromosome 1p as a potential tumor-suppressor gene in parathyroid adenomas

Parathyroid adenomas causing primary hyperparathyroidism (pHPT) frequently exhibit allelic loss of DNA markers on the short arm of chromosome 1, indicating the presence of one or more tumor-suppressor genes on 1p. Since the development of pHPT is enhanced in individuals exposed to ionizing radiation to the neck, it could be anticipated that genes involved in DNA repair and recombination may be special targets for mutation in parathyroid tumorigenesis, whether irradiation-associated or not. RAD54 is a member of a family of genes involved in such functions, and RAD54 knockout mice show increased sensitivity to ionizing radiation. The localization of the RAD54 gene to 1p32 has therefore elevated it to a most compelling candidate parathyroid tumor-suppressor gene. Twelve parathyroid adenomas demonstrating allelic loss at chromosome 1p were selected from 55 parathyroid adenomas previously analyzed for loss of heterozygosity using polymorphic microsatellite markers. All 18 exons of the RAD54 gene were fully analyzed by automated sequencing for detection of point mutations or micro-deletions in each parathyroid adenoma. No mutational aberrations were detected in the RAD54 gene, strongly suggesting that complete somatic inactivation of RAD54 is infrequently, if ever, associated with the development of parathyroid adenomas. Whether genes controlling DNA repair and recombination are involved in parathyroid neoplasia remains to be determined.

Apoptosis in neuroendocrine tumours

Acquired resistance to apoptosis in neuroendocrine tumours (NETs) may promote clonal expansion and enhance the likelihood that subsequent mutations lead to growth or persistence of the neoplastic clone. Recent studies have demonstrated that deregulation of programmed cell death may be a critical component in multistep tumourigenesis of NETs and that the frequent expression of the Bcl-2 oncoprotein in these tumours may contribute to their pathogenesis. The genetic complementation of simultaneously deregulated Bcl-2 and c-Myc may be implicated in the multistep tumourigenesis of human NETs. Furthermore, because the efficacy of cytotoxic chemotherapy relies on its ability to induce programmed cell death, resistance to apoptosis typically correlates with chemoresistance, a phenomenon that is typical in NETs. Consideration of how oncogenes affect rates of cell death, in addition to augmenting growth, has already provided valuable insights into the biology of cancer. Understanding the molecular and cellular features of this process may enable the development and application of more effective and potentially curative treatment strategies in which the induction of programmed cell death is an integral component.

Cytogenetic Profile of Lymphoma of Follicle Mantle Lineage: Correlation With Clinicobiologic Features

Conventional chromosome analysis (CCA) and interphase fluorescence in situ hybridization (FISH) was performed in 42 patients with mantle-cell lymphoma (MCL), with BCL1 rearrangement. The t(11;14)(q13;q32) or 11q abnormalities were detected by CCA in 34 cases, 20 of which had additional aberrations. A normal karyotype was observed in 8 cases. Probes detecting the chromosome aberrations that were observed in at least 3 cases by CCA, ie, +12, 13q14 deletion, and 17p deletion, were used for interphase FISH analysis. FISH detected total or partial +12, 13q14 deletion and 17p- in 28.5%, 52.4%, and 26% of the cases, respectively. The presence of these anomalies was not a function of karyotype complexity. Based on the results of CCA/FISH, three groups of increasing karyotype complexity were recognized: group 1, including 11 patients without detectable aberrations in addition to BCL1 rearrangement; group 2, including 14 patients with 1 to 2 additional anomalies; and group 3, including 17 patients with three or more additional anomalies. Clinical parameters associated with shorter survival were male sex (P= .006) and primary lymph-node involvement compared with primary bone marrow involvement (P = .015). Trisomy 12 was the only single cytogenetic parameter predictive of a poor prognosis (P = .006) and the best prognostic indicator was the derived measure of karyotype complexity (P < .0001), which maintained statistical significance in multivariate analysis (P< .0001). We arrived at the following conclusions: 13q14 deletion occurs at a high incidence in MCL; 17p deletion and total/partial +12 are relatively frequent events in MCL, the latter aberration being associated with a shorter survival; and the degree of karyotype complexity has a strong impact on prognosis in this neoplasia.

Cytogenetic Profile of Lymphoma of Follicle Mantle Lineage: Correlation With Clinicobiologic Features

Conventional chromosome analysis (CCA) and interphase fluorescence in situ hybridization (FISH) was performed in 42 patients with mantle-cell lymphoma (MCL), with BCL1 rearrangement. The t(11;14)(q13;q32) or 11q abnormalities were detected by CCA in 34 cases, 20 of which had additional aberrations. A normal karyotype was observed in 8 cases. Probes detecting the chromosome aberrations that were observed in at least 3 cases by CCA, ie, +12, 13q14 deletion, and 17p deletion, were used for interphase FISH analysis. FISH detected total or partial +12, 13q14 deletion and 17p- in 28.5%, 52.4%, and 26% of the cases, respectively. The presence of these anomalies was not a function of karyotype complexity. Based on the results of CCA/FISH, three groups of increasing karyotype complexity were recognized: group 1, including 11 patients without detectable aberrations in addition to BCL1 rearrangement; group 2, including 14 patients with 1 to 2 additional anomalies; and group 3, including 17 patients with three or more additional anomalies. Clinical parameters associated with shorter survival were male sex (P= .006) and primary lymph-node involvement compared with primary bone marrow involvement (P = .015). Trisomy 12 was the only single cytogenetic parameter predictive of a poor prognosis (P = .006) and the best prognostic indicator was the derived measure of karyotype complexity (P &lt; .0001), which maintained statistical significance in multivariate analysis (P&lt; .0001). We arrived at the following conclusions: 13q14 deletion occurs at a high incidence in MCL; 17p deletion and total/partial +12 are relatively frequent events in MCL, the latter aberration being associated with a shorter survival; and the degree of karyotype complexity has a strong impact on prognosis in this neoplasia.