Characterization of the mouse Men1 gene and its expression during development.

The gene responsible for multiple endocrine neoplasia type 1 (MEN1), a heritable predisposition to endocrine tumours in man, has recently been identified. Here we have characterized the murine homologue with regard to cDNA sequence, genomic structure, expression pattern and chromosomal localisation. The murine Men1 gene spans approximately 6.7 kb of genomic DNA and is comprised of 10 exons with similar genomic structure to the human locus. It was mapped to the pericentromeric region of mouse chromosome 19, which is conserved with the human 11q13 band where MEN1 is located. The predicted protein is 611 amino acids in length and overall is 97% homologous to the human orthologue. The 45 reported MEN1 mutations which alter or delete a single amino acid in human all occur at conserved residues, thereby supporting their functional significance. Two transcripts of approximately 3.2 and 2.8 kb were detected in both embryonal and adult murine tissues, resulting from alternative splicing of intron 1. By RNA in situ hybridization and Northern analysis the spatiotemporal expression pattern of Men1 was determined during mouse development. Men1 gene activity was detected already at gestational day 7. At embryonic day 14 expression was generally high throughout the embryo, while at day 17 the thymus, skeletal muscle, and CNS showed the strongest signal. In selected tissues from postnatal mouse Men1 was detected in all tissues analysed and was expressed at high levels in cerebral cortex, hippocampus, testis, and thymus. In brain the menin protein was detected mainly in nerve cell nuclei, whereas in testis it appeared perinuclear in spermatogonia. These results show that Men1 expression is not confined to organs affected in MEN1, suggesting that Men1 has a significant function in many different cell types including the CNS and testis.

A comparative study of the expression patterns for vegf, vegf-b/vrf and vegf-c in the developing and adult mouse.

With the goal of better understanding the function and regulation of the different members of the VEGF family this study reports mapping of vegf, vegf-b and vegf-c mRNA expression in developing and adult mice. On embryonic day 14 (E14) there is a high expression of vegf and vegf-b, vegf-b being exceptionally high in heart and CNS. The vegf-c expression is lower with distinct signals in CNS and heart. Prior to birth (E17), vegf and vegf-b expression is moderately downregulated. Overlapping expression is present in intrascapular fat and heart. vegf dominates in thyroid and lung, while vegf-b appears to be the only VEGF member expressed at detectable levels in the CNS. In young adult mouse vegf and vegf-b show partly overlapping expression patterns particularly in kidney, heart and in the thymus, vegf displays higher levels in lung and liver, vegf-b appears to be dominating in brain, heart, testis and kidney. In brain the highest levels of vegf-b is present in the hippocampus. No vegf-c mRNA expression could be detected in the adult. Taken together, these results illustrate, in detail, the different regulations of the members of the VEGF gene family. There are at present at least three specific effectors of vascular proliferation with clear differences in their expression.

Definition of the Minimal MEN1 Candidate Area Based on a 5-Mb Integrated Map of Proximal 11q13

Multiple endocrine neoplasia type 1 (MEN1) is an autosomal dominant disorder with a high penetrance characterized by tumors of the parathyroid glands, the endocrine pancreas, and the anterior pituitary. The MEN1 gene, a putative tumor suppressor gene, has been mapped to a 3- to 8-cM region in chromosome 11q13 but it remains elusive as yet. We have combined the efforts and resources from four laboratories to form the European Consortium on MEN1 with the aims of establishing the genetic and the physical maps of 11q13 and of further narrowing the MEN1 region. A 5-Mb integrated map of the region was established by fluorescence in situ hybridization on both metaphase chromosomes and DNA fibers, by hybridization to DNA from somatic cell hybrids containing various parts of human chromosome 11, by long-range restriction mapping, and by characterization of YACs and cosmids. Polymorphic markers were positioned and ordered by physical mapping and genetic linkage in 86 MEN1 families with 452 affected individuals. Two critical recombinants identified in two affected cases placed the MEN1 gene in an approximately 2-Mb region around PYGM, flanked by D11S1883 and D11S449.

Tumor-specific decreased expression of calcium sensing receptor messenger ribonucleic acid in sporadic primary hyperparathyroidism.

Secretion of PTH is regulated by extracellular calcium via calcium receptors (CaR) on the parathyroid cell surface. Recent studies have shown a decreased expression of CaR messenger RNA (mRNA) and CaR protein in pathological parathyroids. We studied the expression of CaR mRNA in pairs of adenoma and adenoma-associated normal gland from the same patients (n = 17) and in biopsies of normal parathyroid glands of normocalcemic subjects (n = 4) using in situ hybridization with oligonucleotide probes on frozen sections. No down-regulation of CaR mRNA caused by hypercalcemia could be demonstrated in the normal adenoma-associated parathyroids when compared with the normal parathyroids of normocalcemic subjects. In contrast, CaR mRNA in the adenomas was significantly reduced to 64% (median; range 41-98) of the corresponding normal adenoma-associated glands. No correlation was seen between CaR mRNA in the adenoma and preoperative serum calcium, PTH, or weight of the adenoma. Loss of heterozygosity studies were performed on adenomas using markers for the locus of the CaR gene on chromosome 3q. No allelic loss was demonstrated, excluding allelic loss as the cause for decreased CaR mRNA expression in the adenomas. It is concluded that the lowered levels of CaR mRNA in parathyroid adenomas may contribute to the increased set point of PTH secretion. In large adenomas the increased cell mass seems to be more important for the increased secretion of PTH.

Autosomal dominant primary hyperparathyroidism and jaw tumor syndrome associated with renal hamartomas and cystic kidney disease: linkage to 1q21-q32 and loss of the wild type allele in renal hamartomas.

Hereditary hyperparathyroidism-jaw tumor syndrome (HPT-JT) is an autosomal dominant disease (OMIM 145001) that has recently been mapped to chromosomal region 1q21-q32 (HRPT2). Here we report two families with HPT-JT syndrome in which adult renal hamartomas or cystic kidney disease were prominent associated features, possibly representing a new phenotypic variant of the HPT-JT syndrome. In the first family, renal lesions were present in five out of six affected individuals, whereas HPT and JT were seen in four and two cases, respectively. In the second family, JT was found in three of the five affected individuals and two affected members also exhibited polycystic kidney disease. The possibility of the latter cosegregating as a separate autosomal dominant gene can not be ruled out. A sex-dependent penetrance of primary HPT, resulting in predominantly male-affected cases was evident in the two families. Twenty microsatellite markers in the HRPT2 region were typed, in addition to markers in the multiple endocrine neoplasia (MEN) types 1 and 2 regions at 11q13 and 10q11. The disease in these two kindreds was linked to five markers in the 1q21-q32 region (logarithm-of-odds scores: 3.2-4.2), whereas linkage to the MEN1 and MEN2 regions was excluded. Meiotic recombinations detected in affected individuals placed the locus telomeric of D1S215, thus narrowing the HRPT2 region from > 60 to approximately 34 centimorgans. Loss of heterozygosity was studied in seven renal hamartomas from two affected individuals in the first family, as well as in a jaw tumor and a parathyroid tumor from the second family. All renal hamartomas showed loss of heterozygosity at the 1q21-q32 region. The losses invariably involved the wild type allele derived from the unaffected parent, suggesting the inactivation of a tumor suppressor gene in this region.

Allelic loss of the retinoblastoma tumor suppressor gene: a marker for aggressive parathyroid tumors?

Allelic loss of the retinoblastoma tumor suppressor gene has recently been shown to be highly specific for parathyroid carcinoma. It has been proposed that this genetic abnormality may have diagnostic and prognostic implications for parathyroid carcinoma, but to date no further studies are available to substantiate these findings. In the present study, three cases of atypical recurrent hyperparathyroidism were examined: a patient with parathyroid carcinoma and an autotransplanted adenoma that progressed into carcinoma, a patient with recurrent juvenile hyperparathyroidism, and a patient with severe recurrent secondary hyperparathyroid disease due to rapidly growing autotransplant. Six pairs each of sporadic parathyroid adenoma and secondary parathyroid disease were also studied for comparison. Allelic losses of RB and D13S71 at 13q14 was found in the parathyroid carcinoma and the corresponding autotransplant that had previously been considered benign tissue and in the case of recurrent juvenile hyperparathyroidism, but not in any of the other tumors. Our findings support the findings of the previous study that RB or 13q loss is specific for parathyroid tumors with increased aggressiveness and might be of clinical significance.

Alterations of the MEN1 gene in sporadic parathyroid tumors.

Primary hyperparathyroidism is a common endocrine disease that also occurs in a number of inherited disorders, including multiple endocrine neoplasia type 1 (MEN1). Loss of heterozygosity (LOH) in the MEN1 region on chromosome 11q13 has been found in 30% of sporadic parathyroid tumors, making the recently cloned MEN1 gene a prime candidate for involvement in parathyroid tumorigenesis. Using LOH and single strand conformation analysis, we screened 45 sporadic tumors from 40 patients for alterations involving the MEN1 gene. Thirteen tumors showed LOH at 11q13, and in 6 of these cases, somatic mutation of the MEN1 gene was detected. In tumors without LOH, no mutations were detected. The mutations consisted of 3 small deletions, 1 insertion, and 2 missense mutations that had not been reported in MEN1 patients or parathyroid tumors previously. Using messenger ribonucleic acid in situ hybridization, the expression of the MEN1 gene was studied. There was no difference in expression between normal and tumor tissue. In conclusion, the findings of inactivating mutation in tumors with LOH at 11q13 confirm the role of the MEN1 tumor suppressor gene in a subset of sporadic parathyroid tumors.

Alternative genetic pathways in parathyroid tumorigenesis.

In this study 44 parathyroid tumors from 26 sporadic cases, 10 cases previously given irradiation to the neck, and 8 familial cases were screened for sequence copy number alterations by comparative genomic hybridization. In the sporadic adenomas, commonly occurring minimal regions of loss could be defined to chromosome 11 (38%), 15q15-qter (27%), and 1p34-pter (19%), whereas gains preferentially involved 19p13.2-pter (15%) and 7pter-qter (12%). Multiple aberrations were found in sporadic tumors with a somatic mutation and/or loss of heterozygosity of the MEN1 gene. The irradiation-associated tumors also showed multiple comparative genomic hybridization alterations and frequent losses of 11q (50%), and subsequent analysis of the MEN1 gene demonstrated mutations in 4 of 8 cases (50%). The adenomas from familial cases showed few alterations, and in 3 of these tumors a gain of 19p13.2-pter was seen as the only aberration. In this study numerical copy number alterations were frequently detected in sporadic and irradiation-associated parathyroid adenomas, although these tumors are benign. The majority of these alterations were found in tumors with confirmed involvement of the MEN1 gene locus in agreement with a role of the MEN1 gene in genomic stability. Furthermore, the frequent occurrence of MEN1 mutations (50%) in irradiation-associated parathyroid tumors suggests that inactivation of the MEN1 gene is an important genetic alteration involved in the development of parathyroid tumors in postirradiation patients.

Familial isolated hyperparathyroidism maps to the hyperparathyroidism-jaw tumor locus in 1q21-q32 in a subset of families.

Approximately 70 families with familial isolated hyperparathyroidism (FIHP) have been reported. Whether it is a separate entity or a variant of multiple endocrine neoplasia type 1 (MEN1 at 11q13) or hyperparathyroidism-jaw tumor (HPT-JT or HRPT2 at 1q21-32) syndrome is not known. We describe here 3 unreported families with familial primary hyperparathyroidism and evaluate their clinical, pathological, and genetic profiles. Biochemical and radiological screenings for MEN1 were negative for all families. In 2 families with a total of 10 affected cases and 3 female obligate carriers, there is no evidence of jaw or renal lesions despite careful radiological investigations. In both families the disease was linked to the 1q21-q32 region with the maximum logarithm of the odds (lod) scores of 3.10 and 3.43 for markers D1S222 and D1S249 respectively, at recombination fraction of 0. In 1 family 2 types of parathyroid pathology were found: 3 of chief cell type and 1 of oxyphil/oncocytic cell type. Two chief cell tumors and 1 oxyphil tumor were found to have loss of heterozygosity (LOH) involving loss of the wild-type alleles for chromosome 1q markers. In the third family, with 4 affected siblings, a parathyroid carcinoma and 2 cases of polycystic kidney disease were found. The parathyroid carcinoma also showed loss of heterozygosity in the 1q region. In conclusion, we found that the hyperparathyroidism traits in a subset of FIHP families are linked to the 1q21-32 markers in the HRPT2 region. We describe the spectrum of parathyroid disease in 1q-linked families involving 3 different types of pathology and demonstrate for the first time loss of wild-type alleles in these parathyroid tumors. Taken together, the results suggest that some of the FIHP are a variant of HPT-JT and that the gene involved is a tumor suppressor gene.

Mutation analysis of the MEN1 gene in multiple endocrine neoplasia type 1, familial acromegaly and familial isolated hyperparathyroidism.

Multiple endocrine neoplasia type 1 (MEN 1) is an autosomal dominant disease characterized by neoplasia of the parathyroid glands, the endocrine pancreas, and the anterior pituitary gland. In addition, families with isolated endocrine neoplasia, notably familial isolated hyperparathyroidism (FIHP) and familial acromegaly, have also been reported. However, whether these families constitute MEN 1 variants or separate entities remains speculative as the genetic bases for these diseases are unclear. The gene for MEN 1 has recently been cloned and characterized. Using single strand conformation analysis (SSCA) and sequencing, we performed mutation analysis in: a) a total of 55 MEN 1 families from 7 countries, b) 13 isolated MEN 1 cases without family history of the disease, c) 8 acromegaly families, and d) 4 FIHP families. Mutations were identified in 27 MEN 1 families and 9 isolated cases. The 22 different mutations spread across most of the 9 translated exons and included frameshift (11), nonsense (6), splice (2), missense mutations (2), and in-frame deletions (1). Among the 19 Finnish MEN 1 probands, a 1466del12 mutation was identified in 6 families with identical 11q13 haplotypes and in 2 isolated cases indicating a common founder. One frameshift mutation caused by 359del4 (GTCT) was found in 1 isolated case and 4 kindreds of different origin and haplotypes; this mutation therefore represents a common "warm" spot in the MEN1 gene. By analyzing the DNA of the parents of an isolated case one mutation was confirmed to be de novo. No mutation was found in any of the acromegaly and small FIHP families, suggesting that genetic defects other than the MEN1 gene might be involved and that additional such families need to be analyzed.

Expression of RET and its ligand complexes, GDNF/GFRalpha-1 and NTN/GFRalpha-2, in medullary thyroid carcinomas.

OBJECTIVE: Mutations in the RET proto-oncogene are found in about one third of sporadic medullary thyroid carcinomas (MTCs), mostly affecting codon 918. Glial cell line derived neurotropic factor (GDNF) and its membrane-bound GDNF family receptor alpha (GFRalpha-1), as well as neurturin (NTN) and its membrane-bound receptor GFRalpha-2 form a complex with the RET product, a receptor tyrosine kinase, resulting in downstream signaling to the nucleus. DESIGN: To elucidate the role of these RET ligands in MTC tumorigenesis, their expression was determined in 15 MTC samples, one papillary thyroid carcinoma (PTC) and three normal thyroid tissue specimens. METHODS: The mRNA expression of RET, GDNF, GFRalpha-1, NTN and GFRalpha-2 was investigated by mRNA in situ hybridization, and confirmed by reverse transcription-PCR analysis. RESULTS: None of the five genes was expressed in the normal thyroids or in the PTC. All MTCs showed expression of RET, 13 expressed GDNF, 12 expressed GFRalpha-1 and 9 expressed NTN and GFRalpha-2. In 7 of the tumors RET, GDNF and GFRalpha-1 were expressed at high levels, and in five of these seven tumors NTN and GFRalpha-2 genes were also expressed at high levels. The high level of expression was preferentially seen in tumor cells adjacent to stroma and connective tissue. All MTCs without expression of the RET ligands harbored the RET codon 918 mutation. CONCLUSIONS: The results suggest that this signaling pathway is important for MTC development, and that it may be activated by expression of the RET ligand complexes by the tumor cells themselves.

Homozygous inactivation of the MEN1 gene as a specific somatic event in a case of secondary hyperparathyroidism.

BACKGROUND: Most patients who have been surgically treated for secondary hyperparathyroidism (HPT) harbor at least one pathological parathyroid gland with a tumor of monoclonal origin. OBJECTIVE: To elucidate the underlying genetic mechanisms behind secondary HPT, by studying a panel of such tumors for numerical alterations. METHODS: Sixteen parathyroid glands from eight patients (median age 58 years, range 31-74 years), were screened for numerical chromosomal imbalances, using comparative genomic hybridization (CGH). Mutation analysis of the multiple endocrine neoplasia type 1 gene (MEN1) was also performed by sequencing of the coding region. RESULTS: The results show that gross chromosomal alterations occur rarely in secondary HPT. In one of the three glands analyzed from one patient, a complete loss of chromosome 11 was detected. This gland also had an inactivating nonsense mutation, E469X, of the MEN1 gene. The mutation was present neither in the other two glands, nor in the constitutional tissue of the same patient, thus confirming its somatic origin. CONCLUSIONS: The relative lack of numerical chromosomal alterations would suggest that more discrete genetic alterations are responsible for the monoclonal growth in the majority of cases of secondary HPT. Furthermore, somatic inactivation of the MEN1 tumor suppressor gene contributes to the tumorigenesis in a small proportion of the cases.

Detailed characterization of a complex karyotype in a patient with primary plasma cell leukaemia using multicolour spectral karyotyping and micro-FISH.

INTRODUCTION: Plasma cell leukaemia is a rare disorder that usually carries an aggressive course with a rapidly fatal outcome. A variety of chromosomal abnormalities have been reported in plasma cell leukaemia but the clinical significance of an abnormal karyotype is still unclear. MATERIALS AND METHODS: We have applied the molecular cytogenetic techniques multicolour spectral karyotyping and microdissection in combination with fluorescence in situ hybridization on metaphases from a patient with primary plasma cell leukaemia and a fatal outcome. RESULTS AND CONCLUSION: The chromosome analysis showed severe hypodiploidy and 12 marker chromosomes. Identification of the structural rearrangements was not possible using routine cytogenetic methods. Utilizing the methods above, all marker chromosomes could be identified in detail and the karyotype was shown to be very complex. Forty-three breakpoints were found, and 25 could be identified at the band level, among others 14q32 where the immunoglobulin heavy chain locus is situated. Thus, these techniques provide the opportunity to resolve very complex chromosomal changes in a way that has not been previously possible and will consequently be of great importance in the search for hot spots that may harbour new cancer genes.

Decreased expression of calcium-sensing receptor messenger ribonucleic acids in parathyroid adenomas.

BACKGROUND: The set point for parathyroid hormone (PTH) secretion is increased in patients with primary hyperparathyroidism, possibly because of receptor defect(s). A decreased expression of calcium receptor (CaR) messenger ribonucleic acid (mRNA) and protein and a decreased expression of the putative calcium-sensing CAS (gp330/megalin) protein have been demonstrated in parathyroid adenomas. METHODS: Expression of CAS mRNA was studied in matched pairs of adenomas and adenoma-associated biopsy specimens from normal parathyroid glands from 15 patients with sporadic primary hyperparathyroidism. Cryostat sections were hybridized with an oligonucleotide complementary to CAS mRNA, rinsed, air dried, and exposed to x-ray film for semiquantification of radioactivity. RESULTS: Expression of CAS mRNA in the adenomas was lowered significantly to 25% (median; range 9% to 80%) of that of the corresponding biopsy specimens of normal parathyroid glands. No correlation was seen between CAS mRNA in the adenoma and preoperative serum calcium levels, PTH level, or weight of the adenoma. The levels of CAS mRNA were significantly lower than those observed previously for CaR mRNA. There was no significant correlation between the levels of CAS and CaR mRNA. CONCLUSIONS: Lowered levels of receptors sensing extracellular calcium (CaR and CAS) probably contribute to the increased set point for PTH secretion in primary hyperparathyroidism.

Expression of matrix metalloproteinase gelatinase A messenger ribonucleic acid in parathyroid carcinomas.

BACKGROUND: The incidence of parathyroid cancer in patients with hyperparathyroidism is less than 1%. However, these few cases cause diagnostic problems in the absence of clear-cut invasion of adjacent organs or metastasis. New markers are needed to increase diagnostic accuracy. METHODS: Thirty-one parathyroid tumors from patients with primary hyperparathyroidism were collected worldwide. Eighteen tumors were classified as unequivocal cancers, whereas 13 tumors were considered equivocal because of a lack of infiltrative growth or evidence of recurrence. Paraffin sections were hybridized with a 35S-labeled riboprobe complementary to gelatinase A mRNA, dipped in photographic emulsion, developed, counterstained, and then evaluated by light- and dark-field microscopy. RESULTS: Fourteen of the 18 unequivocal parathyroid cancers expressed gelatinase A, as compared with the equivocal tumors, of which only 4 of 13 showed expression. The strongest hybridization signal was seen in stromal cells at the tumor border, most likely fibroblasts and macrophages. No expression was detected in tumor cells. CONCLUSIONS: Invasive growth of many tumors is facilitated by proteolytic enzymes, such as gelatinase A. The presence of gelatinase A mRNA in parathyroid tumors strengthens the suspicion of malignancy but cannot be used as a definitive marker of malignancy.

Aberrations of chromosome 8 in 16 breast cancer cell lines by comparative genomic hybridization, fluorescence in situ hybridization, and spectral karyotyping.

Comparative genomic hybridization (CGH) studies have shown that chromosome 8 is a frequent target for chromosomal aberrations in breast cancer. We characterized these aberrations of chromosome 8 in 16 breast cancer cell lines (BT-474, BT-549, CAMA-1, DU-4475, MCF-7, MDA-MB-134, MDA-MB-157, MDA-MB-361, MDA-MB-415, MDA-MB-436, MPE600, SK-BR-3, T-47D, UACC-812, UACC-893 and ZR-75-1) by CGH, fluorescence in situ hybridization (FISH) with arm- and locus-specific probes, and spectral karyotyping (SKY). Chromosome 8 was structurally abnormal in 13 of 16 cell lines. Loss of 8p was detected in nine cell lines, gain of entire 8q in six cell lines, 8q21-qter in three, 8q23-qter in two, and 8q12-qter and 8p21-q21 in one cell line. Extra copies of the C-MYC oncogene were found in 11 cell lines, but high-level amplification only in SK-BR-3. Derivative chromosomes including material from chromosomes 8 were complex, and the breakpoints were strikingly dissimilar. Chromosome 11 was the most frequent translocation partner with chromosome 8 (in 7 cell lines). Isochromosomes and/or isoderivative 8q were found in four cell lines. The high frequency and complexity of alterations at 8q indicate a significant pathogenetic role in breast cancer. The high-level amplification of c-myc is less common than previously thought.

Molecular genetics of primary and secondary hyperparathyroidism.

Hyperparathyroidism (HPT) can be caused by solitary parathyroid adenomas and carcinomas, and primary and secondary multiglandular parathyroid disease. Primary HPT is also a feature of several hereditary diseases e.g. multiple endocrine neoplasia type 1 and type 2A (MEN1 and 2A), familial hypocalciuric hyperparathyroidism (FHH), the HPT-jaw tumor syndrome (HPT-JT), and familial isolated HPT. Summarizing data from the literature and our own observations, various genetic abnormalities are observed in the pathogenesis of HPT. These include chromosomal deletions of the MEN1 locus on 11q in sporadic and MEN1 associated primary HPT, of RB1 on 13q in carcinomas, and of the FHH gene located on 3q in sporadic primary and secondary HPT. Genetic material is also lost from chromosomes 1p, 6q, 15q and X suggesting loss of yet unidentified tumor suppressor genes in these regions. In addition the HRPT2 gene on 1q, as well as the proto-oncogenes RET on 10q and PRAD1 on 11q are associated with a subset of parathyroid tumors.

Expression analysis of RET and the GDNF/GFRalpha-1 and NTN/GFRalpha-2 ligand complexes in pheochromocytomas and paragangliomas.

Pheochromocytoma and its extra-adrenal counterpart paraganglioma are rare catecholamine producing tumors which usually occur sporadically but may also be a part of neuroendocrine tumor syndromes such as multiple endocrine neoplasia type 2A (MEN 2A). Activating mutations of the RET proto-oncogene which is the underlying cause of MEN 2A, is also seen in approximately 10% of sporadic pheochromocytomas. Glial cell line derived neurotrophic factor (GDNF) and neurturin (NTN) have been shown to function as independent ligands to RET, binding in a complex with the membrane-bound receptors GFRalpha-1 and GFRalpha-2 respectively. Here we have investigated the mRNA expression of RET and its ligand complexes, GDNF/GFRalpha-1 and NTN/GFRalpha-2, in a panel of pheochromocytomas and paragangliomas using mRNA in situ hybridization. RET expression was evident in normal adrenal medulla, and in 13/15 pheochromocytomas, including 5/5 MEN 2A associated tumors, but only in 1/10 paragangliomas. The frequent expression of RET in the pheochromocytomas suggest that this gene might be involved in the tumorigenesis. However, no expression of GDNF/GFRalpha-1 or NTN/GFRalpha-2 could be detected in any of the 25 tumors analyzed, suggesting that these ligand complexes are not important in the development of pheochromocytoma or paraganglioma.

Timing of radiotherapy in head and neck free flap reconstruction--a study of postoperative complications.

The local treatment protocol of preoperative radiotherapy in head and neck cancer treatment at the Karolinska University Hospital has resulted in a unique cohort of preoperatively high dose-irradiated patients. In total 216 consecutive patients were reviewed, of whom 221 free flaps, for head and neck cancer reconstruction, were operated between 1984 and 2002. In 194 cases radiotherapy was administered preoperatively and 27 operations were performed without prior radiation. The radiation dose was 64 Gy in 147 cases, 54 Gy or less in 45 cases and uncertain in two cases. In order to study whether the time elapsed between the end of radiotherapy and surgery had any significance regarding postoperative events, the cohort was subsequently divided into three groups: patients operated on within 4 weeks (n=27), between 4 and 6 weeks (n=88) and more than 6 weeks (n=78) after the last radiotherapy session. Postoperative complications were analysed in relation to preoperative dose and timing of radiotherapy. Preoperative radiotherapy was related to an increased risk of free flap necrosis as 22 complete and eight partial flap necroses occurred in the group that had received preoperative radiotherapy and none were observed in the non-irradiated group (P<0.05). Furthermore, a linear trend of increased flap loss (P<0.001), infections (P<0.001) and delayed wound healing (P<0.001) was seen when time increased between the last radiotherapy session and surgery. The largest increase in all complication rates was seen when more than 6 weeks elapsed between last radiotherapy session and surgery. Postoperative complications were independent of the radiation dose given. Our data show an increased morbidity in free flap surgery in the head and neck region after preoperative radiotherapy. Furthermore, time elapsed between the last radiotherapy session and surgery is associated with the risk of developing postoperative complications. We strongly suggest that free flap reconstruction should be performed within 6 weeks of the last radiotherapy session.

Restricted expression pattern of vegf-d in the adult and fetal mouse: high expression in the embryonic lung.

Endothelial growth factors have become the target of intense research since the initial discovery of vascular endothelial growth factor (VEGF/VPF). At present, VEGF is established as a major inducer of angiogenesis in normal and pathological conditions. Recently several new members in the VEGF family have been described; VEGF-B/VRF, VEGF-C and VEGF-D. VEGF-D is most closely related to VEGF-C by virtue of the presence of N- and C-terminal extensions that are not found in other VEGF family members. We have here examined the expression pattern of vegf-d mRNA with in situ hybridization in developing and adult mice. This shows a restricted expression pattern, with high levels mainly in lung tissue. The expression in embryonic lung is upregulated prior to birth. Expression of vegf-d in other tissues, as well as in lung tissue of the E14 embryo, was either low or absent. This suggests that VEGF-D may be of special relevance for the vascularization of lung tissue during the last trimester of fetal development.