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Department of Molecular Medicine, Endocrine Tumor Unit (F.F., B.T.T., A.S., C.P., C.L.), Department of Molecular Medicine, Clinical Genetics Unit (G.W.), Department of Clinical Pathology (A.H.) and Department of Surgery (F.F., A.S., K.S., L.-O.F.), Karolinska Hospital, S-171 76 Stockholm, Sweden; the Department of Clinical Genetics, Oulu University Hospital (S.K.), Kajaanintie 50, 90220 Oulu, Finland; and the Department of Surgery, University of Michigan Hospital (N.T.), TC 2920-D, Ann Arbor, Michigan 48109
Address all correspondence and requests for reprints to: Dr. Filip Farnebo, Department of Molecular Medicine, Endocrine Tumor Unit, Karolinska Hospital CMM L8:01, S-171 76 Stockholm, Sweden. E-mail: filip.farnebo{at}cmm.ki.se
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Introduction |
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Using LOH analysis, single strand conformation analysis (SSCA), direct sequencing, and messenger ribonucleic acid (mRNA) in situ hybridization, we have analyzed a panel of tumors to evaluate the role of the MEN1 gene in sporadic primary HPT.
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Materials and Methods |
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Parathyroid tissue from 31 patients with uniglandular
disease, operated on for sporadic primary HPT at the Karolinska
Hospital in 1996, and tissue from 9 patients (14 glands) with
multiglandular disease, operated on between 1993 and 1996, were
snap-frozen in liquid nitrogen after removal and stored at -70 C until
analysis. The clinical data for these tumors are summarized in Table 1
. The patients (32 women and 8 men) had
a median age of 64.5 yr at operation (range, 29–83 yr). The
preoperative median concentration of serum calcium was 2.85 mmol/L
(11.4 mg/dL; reference range, 2.20–2.60 mmol/L), and that of intact
PTH was 88 ng/L (reference range, 12–55 ng/L). None of the patients in
the multiglandular disease group had a positive family history for any
other endocrine disease, nor did they show any clinical sign of other
endocrine disorder. The surgical approach was to identify all 4 glands
in each patient. The median tumor weight in the uniglandular group was
618 mg (range, 152–2900), and the median weight of the largest gland
in patients with multiglandular disease was 1030 mg (range, 250–2710).
All patients were normocalcemic postoperatively. High mol wt DNA was
prepared from fresh-frozen tumor tissue and peripheral blood leukocytes
using standard methods. To prove the representativity of the tumor
material, pieces were cut from all specimens for histopathological
examination. By semiquantitative evaluation all tumor samples included
in the study were shown to contain more than 70% tumor cells.
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SSCA
The 9 coding exons of the gene were amplified using
15 different fragments of 200–300 bp each, as previously described
(5). Genomic DNA (50 ng) was amplified using the standard PCR
conditions in 50 mmol/L KCl; 10 mmol/L Tris-HCl (pH 9.0); 1.5 mmol/L
MgCl2 (Promega, Madison, WI); 0.2 mmol/L deoxy (d)-TTP,
dCTP, and dGTP; 0.05 mmol/L dATP; and [
-32P]dATP
(Amersham) at 1 µCi/reaction and 2 U Taq DNA polymerase
(Promega) in a final volume of 15 µL. Thermocycling conditions
consisted of 30 cycles of 1 min at 94 C, 1 min at 62 C, and 1 min at 72
C, followed by 1 cycle of 5-min extension at 72 C. The PCR products
were then electrophoresed in 25% MDE (FMC, Rockland, ME) gels at room
temperature for 12 h at 6–8 watts. Gels were dried before
autoradiography was carried out. Positive controls were available for
all exons except 2 (exons 6 and 8).
Direct DNA sequencing
All SSCA-shifted bands were excised from the MDE gel and placed in 50 µL ddH2O at 37 C for 1 h. A 5-µL aliquot of this solution was then amplified in a 50-µL reaction with the following components: 50 mmol/L KCl; 10 mmol/L Tris-HCl (pH 9.0); 1.5 mmol/L MgCl2 (Promega); 0.2 mmol/L dTTP, dCTP, dGTP, and dATP; and 15 U Taq DNA polymerase (Promega). The purified PCR products were sequenced from both strands. For sequence reactions, one of the PCR primers was biotinylated at the 5'-end. Solid phase sequence reactions with 35S-labeled dATP were performed using Dynabeads (Dynal, Chantilly, VA) and Sequenase (U.S. Biochemical Corp., Cleveland, OH) according to the manufacturers’ manuals, followed by terminal deoxynucleotidyl transferase (Boehringer Mannheim, Indianapolis, IN) treatment for 15 min with the addition of 0.2 mmol/L dNTPs. Sequence reactions were then run on 6% denaturing polyacrylamide gels and autoradiographed overnight. Mutations were confirmed to be somatic using direct sequencing of the constitutional DNA.
LOH analysis
Two microsatellite markers located close to and flanking the MEN1 gene on chromosome 11q13 were selected: D11S449 and PYGM (14). PCR were performed according to standard procedures, and the PCR products were electrophoresed on polyacrylamide gel followed by autoradiography. LOH was defined as a complete absence or reduced signal intensity for one of the constitutional alleles in the tumor tissue that could be detected visually.
mRNA in situ hybridization
Preparation of probes. Two oligonucleotide probes
with sequences complementary to mRNAs encoding for menin
(nucleotides 2324–2364 and 7686–7726; GenBank/EMBL Data Bank
accession no. U93237) (4) and one for glycerol aldehyde phosphate
dehydrogenase (GAPDH; nucleotides 1149–1193; GenBank/EMBL Data Bank
accession no. M33197) (15) were synthesized (Geneset, Paris, France).
The oligonucleotides were labeled at the 3'-end with
[-35S]dATP (New England Nuclear, Boston, MA) using
terminal deoxynucleotidyl transferase (Amersham Life Science,
Cleveland, OH). The labeled probes were purified using the QIAquick
nucleotide removal kit (Qiagen, Germany).
In situ hybridization. Cryostat sections, 14 µm thick, were cut at -20 C and thaw-mounted onto SuperFrost Plus slides (Menzel-Gläser). Hybridization was essentially performed as previously described (13). Negative control experiments using a sense probe were performed.
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). The
clinical information regarding the tumors is summarized in Table 1
, and
the results for the 13 cases in which alterations were detected are
detailed in Table 2. LOH analysis was
performed using markers located within a 600-kb region and flanking the
MEN1 gene (cen-[PYGM-MEN1-D11S449]-tel). All
cases were informative for at least 1 marker, and in 13 of the 45
tumors (29%), LOH was detected. SSCA screening detected variants in 8
of the 45 tumors analyzed. Two of these were due to a polymorphism in
exon 3, codon 171 (4), and were also present in the corresponding
constitutional DNA. In the remaining 6 cases, the normal nucleotide
sequence was found in the constitutional DNA, thus confirming the
mutation as somatic. The types of mutation detected included small
deletions (n = 3) and insertions (n = 1), resulting in frame
shifts or deletion of one amino acid, and missense mutations (n =
2) causing incorporation of a different amino acid.
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). In four of the nine
cases with multiglandular disease, more than one pathological gland was
analyzed. One of the tumors from patient 61 showed both LOH and a
missense mutation, whereas in the other tumor from the same patient, no
alterations were detected (Table 2).
Using mRNA in situ hybridization, the expression of
the MEN1 gene was determined in normal and tumor tissue. A
total of 54 tumors and 4 normal parathyroid glands were analyzed,
including 37 of the tumors from the mutation analysis and an additional
set of 17 tumors with matched normal biopsies. The expression of GAPDH
was analyzed to exclude significant reduction of mRNA due to
ribonuclease activity in the tumors, and in addition, human testis was
included as a positive control in the experiments. The level of
expression was generally low in the parathyroid samples, and equal
results were obtained with the 2 oligonucleotide probes, located in
different parts of the gene. Furthermore, the expression was similar in
normal and tumor tissue and in tumors with and without alteration of
the MEN1 gene (Fig. 2).
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Discussion |
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TopAbstractIntroductionMaterials and MethodsResultsDiscussionReferences |
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The frequency of mutations and LOH was equal in tumors from patients with uniglandular and multiglandular diseases. In the multiglandular group, no constitutional MEN1 mutations were identified, and one patient was shown to have a somatic MEN1 gene mutation in only one of two pathological glands. In the other gland, other genetic alterations might be responsible. No histopathological difference was noted between these two tumors, except that the tumor showing LOH and mutation was significantly larger (618 vs. 175 mg). The clinical course of this patient has been uneventful. This finding further strengthens the view that multiglandular parathyroid disease is not always MEN1, but may involve other genetic pathways, where the MEN1 gene may or may not participate. Alternatively, tumorigenesis in multiglandular disease may be caused by independent genetic events.
Normally, the expression pattern for a mutated tumor suppressor gene would be decreased in tumors that lacked one or two alleles due to mutation or LOH (1). In both situations, the difference in expression is visible between matching normal and tumor tissues. In the present study, however, there was no difference in expression between normal and tumor tissues, including tumors with and without LOH, and those with both LOH and mutation. Therefore, we expanded the study to include an additional set of sporadic primary parathyroid tumors with matching normal biopsies from the same patient (13). The level of expression remained uniform, and no difference between the tumors and the biopsies could be shown. In cases with LOH, one might speculate that the loss of one allele causes up-regulation of the other. For example, in basal cell carcinoma, inactivating mutations are associated with overexpression of the involved tumor suppressor gene PTCH (16). Alternatively, it might suggest the existence of an alternately spliced form that plays a more important role in the tumorigenesis of the parathyroid but was not detected by the two probes we used. For example, an alternatively spliced form of the FHIT gene, recently cloned from the t(3;8) breakpoint of a familial renal cell carcinoma family, was found to be expressed in normal kidney tissues and cell lines, but have loss of expression in familial and metastatic renal cell carcinoma (17). A better interpretation and correlation of our results might be possible when the function(s) of the MEN1 gene in normal and tumor tissues is known.
In summary, we have characterized 6 mutations in 45 investigated tumors, all of which were confined to tumors that had lost the other chromosome 11q13 allele. These data confirm the role of the MEN1 gene in a subgroup of sporadic parathyroid tumors. As most sporadic parathyroid tumors do not show LOH at 11q13, mutations in genes other than MEN1 have to be sought to explain the development of the majority of parathyroid tumors.
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Footnotes |
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Received December 19, 1997.
Revised February 12, 1998.
Accepted February 26, 1998.
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T, giving rise to a missense mutation. b, LOH analysis of
the same tumor with marker D11S449, showing LOH.