Role of mitochondrial mutations in cancer

A role for mitochondria in cancer causation has been implicated through identification of mutations in the mitochondrial DNA (mtDNA) and in nuclear-encoded mitochondrial genes. Although many mtDNA mutations were detected in common tumors, an unequivocal causal link between heritable mitochondrial abnormalities and cancer is provided only by the germ line mutations in the nuclear-encoded genes for succinate dehydrogenase (mitochondrial complex II) and fumarate hydratase (fumarase). The absence of evidence for highly penetrant tumors caused by inherited mtDNA mutations contrasts with the frequent occurrence of mtDNA mutations in many different tumor types. Thus, either the majority of diverse mtDNA mutations observed in tumors are not important for the process of carcinogenesis or that they play a common oncogenic role.     

Mitochondrial DNA somatic mutations (point mutations and large deletions) and mitochondrial DNA variants in human thyroid pathology: a study with emphasis on Hürthle cell tumors

In an attempt to progress in the understanding of the relationship of mitochondrial DNA (mtDNA) alterations and thyroid tumorigenesis, we studied the mtDNA in 79 benign and malignant tumors (43 Hürthle and 36 non-Hürthle cell neoplasms) and respective normal parenchyma. The mtDNA common deletion (CD) was evaluated by semiquantitative polymerase chain reaction. Somatic point mutations and sequence variants of mtDNA were searched for in 66 tumors (59 patients) and adjacent parenchyma by direct sequencing of 70% of the mitochondrial genome (including all of the 13 OXPHOS system genes). We detected 57 somatic mutations, mostly transitions, in 34 tumors and 253 sequence variants in 59 patients. Follicular and papillary carcinomas carried a significantly higher prevalence of non-silent point mutations of complex I genes than adenomas. We also detected a significantly higher prevalence of complex I and complex IV sequence variants in the normal parenchyma adjacent to the malignant tumors. Every Hürthle cell tumor displayed a relatively high percentage (up to 16%) of mtDNA CD independently of the lesion's histotype. The percentage of deleted mtDNA molecules was significantly higher in tumors with D-loop mutations than in mtDNA stable tumors. Sequence variants of the ATPase 6 gene, one of the complex V genes thought to play a role in mtDNA maintenance and integrity in yeast, were significantly more prevalent in patients with Hürthle cell tumors than in patients with non-Hürthle cell neoplasms. We conclude that mtDNA variants and mtDNA somatic mutations of complex I and complex IV genes seem to be involved in thyroid tumorigenesis. Germline polymorphisms of the ATPase 6 gene are associated with the occurrence of mtDNA CD, the hallmark of Hürthle cell tumors.     

Respiratory chain complex I deficiency caused by mitochondrial DNA mutations

Defects of the mitochondrial respiratory chain are associated with a diverse spectrum of clinical phenotypes, and may be caused by mutations in either the nuclear or the mitochondrial genome (mitochondrial DNA (mtDNA)). Isolated complex I deficiency is the most common enzyme defect in mitochondrial disorders, particularly in children in whom family history is often consistent with sporadic or autosomal recessive inheritance, implicating a nuclear genetic cause. In contrast, although a number of recurrent, pathogenic mtDNA mutations have been described, historically, these have been perceived as rare causes of paediatric complex I deficiency. We reviewed the clinical and genetic findings in a large cohort of 109 paediatric patients with isolated complex I deficiency from 101 families. Pathogenic mtDNA mutations were found in 29 of 101 probands (29%), 21 in MTND subunit genes and 8 in mtDNA tRNA genes. Nuclear gene defects were inferred in 38 of 101 (38%) probands based on cell hybrid studies, mtDNA sequencing or mutation analysis (nuclear gene mutations were identified in 22 probands). Leigh or Leigh-like disease was the most common clinical presentation in both mtDNA and nuclear genetic defects. The median age at onset was higher in mtDNA patients (12 months) than in patients with a nuclear gene defect (3 months). However, considerable overlap existed, with onset varying from 0 to >60 months in both groups. Our findings confirm that pathogenic mtDNA mutations are a significant cause of complex I deficiency in children. In the absence of parental consanguinity, we recommend whole mitochondrial genome sequencing as a key approach to elucidate the underlying molecular genetic abnormality.     

两例补体第8成份β亚基缺陷家系患者的进一步分子遗传基础研究

目的　在白人群体中 ,导致人类补体第 8成份 β亚基缺陷的分子基础主要是在编码 β亚基基因的第 9外显子上发生碱基 C→ T的突变 ,从而形成终止密码 ,导致 C8β亚基不能完全合成。国外学者在两例 C8β亚基完全缺失的患者家系研究中 ,发现这两例β亚基缺失个体只是第 9外显子上碱基 C→ T突变的杂合子 ,现进一步寻找这两例 C8β亚基完全缺失的分子遗传学机理。方法　对两例 C8β亚基完全缺失患者的 C8β编码基因的全部 11个外显子的 PCR扩增产物进行 DNA测序分析并与正常人 DNA序列进行对比。结果　两例完全性 C8β亚基缺失患者的蛋白质编码基因中 ,分别在第 3外显子的 2 98和 388位置发现了 C→T突变 ,同时对这两个突变位点的家系分析也证实 ,位于第 3外显子上的这两个突变位点是独立于第 9外显子的突变而遗传。结论　所发现的两个突变位点均能形成终止密码而导致 C8β亚基合成提前终止 ,因此这两例患者 C8β亚基完全缺失的分子遗传学机理是由于编码 C8β亚基的基因在第 3和第 9外显子上同时发生了点突变 ,进而形成终止密码造成 C8β亚基合成终止所致。     

A study of 133 Chinese children with mitochondrial respiratory chain complex I deficiency

To investigate the clinical, enzymological and mitochondrial gene profiles of complex I deficiency in Chinese, clinical and laboratory data of the patients (79 boys, 54 girls) were retrospectively assessed. Activities of mitochondrial respiratory chain complexes in peripheral leucocytes were spectrophotometrically measured. The entire mitochondrial DNA (mtDNA) sequence was analyzed in 62 patients. Restriction fragment length polymorphism and gene sequencing analyses were performed in 15 families. Ninety‐one patients had isolated complex I deficiency; 42 had combined deficiencies of complex I and other complexes. The main clinical presentations were neuromuscular disorders (107 patients) and non‐neurological dysfunction (hepatopathy, renal damage and cardiomyopathy; 26 patients). In 32 of 62 patients who underwent mtDNA sequencing, 24 mutations were identified in 15 mitochondrial genes. The 12338T>C, 4833A>G and 14502T>C mutations were found in 12.9%, 11.3% and 4.8% patients, respectively. Seven patients had multiple mutations. Three novel mutations were identified. Chinese patients with complex I deficiency presented heterogeneous phenotypes and genotypes. Twenty‐four mutations were identified in 15 mitochondrial genes in 51.6% patients. mtDNA mutations were more common in isolated complex I deficiency than in combined complex deficiencies. The 12338T>C, 4833A>G and 14502T>C mutations were common.     

A novel NDUFA1 mutation leads to a progressive mitochondrial complex I-specific neurodegenerative disease

Mitochondrial diseases have been shown to result from mutations in mitochondrial genes located in either the nuclear DNA (nDNA) or mitochondrial DNA (mtDNA). Mitochondrial OXPHOS complex I has 45 subunits encoded by 38 nuclear and 7 mitochondrial genes. Two male patients in a putative X-linked pedigree exhibiting a progressive neurodegenerative disorder and a severe muscle complex I enzyme defect were analyzed for mutations in the 38 nDNA and seven mtDNA encoded complex I subunits. The nDNA X-linked NDUFA1 gene (MWFE polypeptide) was discovered to harbor a novel missense mutation which changed a highly conserved glycine at position 32 to an arginine, shown to segregate with the disease. When this mutation was introduced into a NDUFA1 null hamster cell line, a substantial decrease in the complex I assembly and activity was observed. When the mtDNA of the patient was analyzed, potentially relevant missense mutations were observed in the complex I genes. Transmitochondrial cybrids containing the patient’s mtDNA resulted in a mild complex I deficiency. Interestingly enough, the nDNA encoded MWFE polypeptide has been shown to interact with various mtDNA encoded complex I subunits. Therefore, we hypothesize that the novel G32R mutation in NDUFA1 is causing complex I deficiency either by itself or in synergy with additional mtDNA variants.     

Diagnosis of quantitative mitochondrial DNA defects by rapidly prepared whole mitochondrial DNA probe.

Analysis of disease-causing mutations in mitochondria genome requires rapid and reliable genetic approaches. However, the preparation of mitochondrial DNA (mtDNA) probe used for the determination of quantitative and qualitative mtDNA defects is time-consuming, cumbersome, and requires complicated instrumentation. To overcome the difficulties encountered during isolation and purification of mtDNA, the authors developed an alternative method based on polymerase chain reaction (PCR) amplification of whole mtDNA genome. In this study, they show that PCR-amplified and fluorescein-labeled mtDNA probe makes it possible, through Southern blot analysis, to identify quantitative defect of mtDNA. The results indicate that mtDNA probe can be prepared rapidly by PCR amplification and used to determine the level of mtDNA in the patients with mitochondrial diseases.     

Detection of DNA amplification in 17 primary breast carcinomas with homogeneously staining regions by a modified comparative genomic hybridization technique

A modified comparative genomic hybridization (mCGH) technique was applied to a series of 17 primary breast carcinomas in which cytogenetic study (CG) demonstrated the presence of homogeneously staining region(s), suggesting the occurrence of DNA amplification. mCGH demonstrated recurrent amplifications of the whole chromosome arms 8q (9 times) and I q (7 times) and of DNA loci in the following bands: 11 q 13 (6 times), 9p 13 and 17q21.1 (4 times), I q21.1 and 16p 11.2 (3 times), and 8q22, 8q24.1, 10q22, 15q26, 17q23, and 20q 13.3 (twice). Amplification of whole chromosome arms is likely to have resulted from unbalanced translocations or isochromosomes, whereas amplifications of smaller chromosomal segments probably arose through real DNA amplification processes. In all tumors but one, more than one amplified locus was detected. The fact that many chromosomal sites were involved suggests that the process of amplification is complex and that many genes are potential targets. Genes Chromosom Cancer 10:160–170 (1994). © 1994 Wiley-Liss, Inc.     

Isolated complex I deficiency in children: clinical, biochemical and genetic aspects

We retrospectively examined clinical and biochemical characteristics of 27 patients with isolated enzymatic complex I deficiency (established in cultured skin fibroblasts) in whom common pathogenic mtDNA point mutations and major rearrangements were absent. Clinical phenotypes present in this group are Leigh syndrome (n = 7), Leigh-like syndrome (n = 6), fatal infantile lactic acidosis (n = 3), neonatal cardiomyopathy with lactic acidosis (n = 3), macrocephaly with progressive leukodystrophy (n = 2), and a residual group of unspecified encephalomyopathy (n = 6) subdivided into progressive (n = 4) and stable (n = 2) variants. Isolated complex I deficiency is one of the most frequently observed disturbance of the OXPHOS system. Respiratory chain enzyme assays performed in cultured fibroblasts and skeletal muscle tissue in general reveal similar results, but for complete diagnostics we recommend enzyme measurements performed in at least two different tissues to minimize the possibility of overlooking the enzymatic diagnosis. Lactate levels in blood and CSF and cerebral CT/MRI studies are highly informative, although normal findings do not exclude complex I deficiency. With the discovery of mutations in nuclear encoded complex I subunits, adequate pre- and postnatal counseling becomes available. Finally, considering information currently available, isolated complex I deficiency in children seems to be caused in the majority by mutations in nuclear DNA.     

Clinical, genetic, and biochemical characterization of a Leber hereditary optic neuropathy family containing both the 11778 and 14484 primary mutations.

Four mitochondrial DNA (mtDNA) mutations at nps 3460, 11778, 14484, and 14459 account for roughly 90% of cases of Leber hereditary optic neuropathy (LHON) and are designated as "primary" LHON mutations since they act as major predisposition factors for LHON. Although each primary mutation can arise independently on different mtDNA backgrounds during human evolution, they characteristically do not co-occur in LHON patients. We report here a family with the simultaneous occurrence of the 11778A and 14484C mutations. Neuro-ophthalmological examination of the proband, a nine-year-old Caucasian female, revealed the bilateral optic atrophy, central scotomas, and reduced visual acuity typical of LHON. Her mother had normal appearing optic discs and is today visually asymptomatic. Analysis of the proband blood mtDNA revealed that she harbored both the 11778A (heteroplasmic, 94% mutant) and the 14484C (homoplasmic mutant) mutation. This genotype was maintained in proband lymphoblasts and transmitochondrial cybrids. The mother also had both mutations, with the 14484C mutation homoplasmic in all cell types examined. However, only 31% of her blood mtDNAs carried the 11778 mutation, which segregated to essentially 100% wild-type in lymphoblast and cybrid mtDNA. Complex I-linked respiration and specific enzyme activity were consistently lowest in proband lymphoblast and cybrid mitochondria compared to those from the mother, 11778A patients, 14484C patients, or controls, thus demonstrating both a deleterious synergistic interaction between the 11778A and 14484C mutations and the magnitude of 11778A-associated complex I dysfunction. Remarkably, spontaneous vision recovery occurred in the proband, highlighting the complexities encountered when associating mtDNA genotype and complex I function with LHON expression.     

Respiratory chain supercomplexes set the threshold for respiration defects in human mtDNA mutant cybrids

Mitochondrial DNA (mtDNA) mutations cause heterogeneous disorders in humans. MtDNA exists in multiple copies per cell, and mutations need to accumulate beyond a critical threshold to cause disease, because coexisting wild-type mtDNA can complement the genetic defect. A better understanding of the molecular determinants of functional complementation among mtDNA molecules could help us shedding some light on the mechanisms modulating the phenotypic expression of mtDNA mutations in mitochondrial diseases. We studied mtDNA complementation in human cells by fusing two cell lines, one containing a homoplasmic mutation in a subunit of respiratory chain complex IV, COX I, and the other a distinct homoplasmic mutation in a subunit of complex III, cytochrome b. Upon cell fusion, respiration is recovered in hybrids cells, indicating that mitochondria fuse and exchange genetic and protein materials. Mitochondrial functional complementation occurs frequently, but with variable efficiency. We have investigated by native gel electrophoresis the molecular organization of the mitochondrial respiratory chain in complementing hybrid cells. We show that the recovery of mitochondrial respiration correlates with the presence of supramolecular structures (supercomplexes) containing complexes I, III and IV. We suggest that critical amounts of complexes III or IV are required in order for supercomplexes to form and provide mitochondrial functional complementation. From these findings, supercomplex assembly emerges as a necessary step for respiration, and its defect sets the threshold for respiratory impairment in mtDNA mutant cells.     

Clinical,genetic, and biochemical characterization of a Leber hereditary optic neuropathy family containing both the 11778 and 14484 primary mutations

Four mitochondrial DNA (mtDNA) mutations at nps 3460, 11778, 14484, and 14459 account for roughly 90% of cases of Leber hereditary optic neuropathy (LHON) and are designated as “primary” LHON mutations since they act as major predisposition factors for LHON. Although each primary mutation can arise independently on different mtDNA backgrounds during human evolution, they characteristically do not co‐occur in LHON patients. We report here a family with the simultaneous occurrence of the 11778A and 14484C mutations. Neuro‐ophthalmological examination of the proband, a nine‐year‐old Caucasian female, revealed the bilateral optic atrophy, central scotomas, and reduced visual acuity typical of LHON. Her mother had normal appearing optic discs and is today visually asymptomatic. Analysis of the proband blood mtDNA revealed that she harbored both the 11778A (heteroplasmic, 94% mutant) and the 14484C (homoplasmic mutant) mutation. This genotype was maintained in proband lymphoblasts and transmitochondrial cybrids. The mother also had both mutations, with the 14484C mutation homoplasmic in all cell types examined. However, only 31% of her blood mtDNAs carried the 11778 mutation, which segregated to essentially 100% wild‐type in lymphoblast and cybrid mtDNA. Complex I‐linked respiration and specific enzyme activity were consistently lowest in proband lymphoblast and cybrid mitochondria compared to those from the mother, 11778A patients, 14484C patients, or controls, thus demonstrating both a deleterious synergistic interaction between the 11778A and 14484C mutations and the magnitude of 11778A‐associated complex I dysfunction. Remarkably, spontaneous vision recovery occurred in the proband, highlighting the complexities encountered when associating mtDNA genotype and complex I function with LHON expression. © 2001 Wiley‐Liss, Inc.     

Novel non‐neutral mitochondrial DNA mutations found in childhood acute lymphoblastic leukemia

Mitochondria produce adenosine triphosphate (ATP) for energy requirements via the mitochondrial oxidative phosphorylation (OXPHOS) system. One of the hallmarks of cancer is the energy shift toward glycolysis. Low OXPHOS activity and increased glycolysis are associated with aggressive types of cancer. Mitochondria have their own genome (mitochondrial DNA [mtDNA]) encoding for 13 essential subunits of the OXPHOS enzyme complexes. We studied mtDNA in childhood acute lymphoblastic leukemia (ALL) to detect potential pathogenic mutations in OXPHOS complexes. The whole mtDNA from blood and bone marrow samples at diagnosis and follow‐up from 36 ALL patients were analyzed. Novel or previously described pathogenic mtDNA mutations were identified in 8 out of 36 patients. Six out of these 8 patients had died from ALL. Five out of 36 patients had an identified poor prognosis genetic marker, and 4 of these patients had mtDNA mutations. Missense or nonsense mtDNA mutations were detected in the genes encoding subunits of OXPHOS complexes, as follows: MT‐ND1, MT‐ND2, MT‐ND4L and MT‐ND6 of complex I; MT‐CO3 of complex IV; and MT‐ATP6 and MT‐ATP8 of complex V. We discovered mtDNA mutations in childhood ALL supporting the hypothesis that non‐neutral variants in mtDNA affecting the OXPHOS function may be related to leukemic clones.     

The mitochondrial DNA G13513A MELAS mutation in the NADH dehydrogenase 5 gene is a frequent cause of Leigh-like syndrome with isolated complex I deficiency

Leigh syndrome is a subacute necrotising encephalomyopathy frequently ascribed to mitochondrial respiratory chain deficiency. This condition is genetically heterogeneous, as mutations in both mitochondrial (mt) and nuclear genes have been reported. Here, we report the G13513A transition in the ND5 mtDNA gene in three unrelated children with complex I deficiency and a peculiar MRI aspect distinct from typical Leigh syndrome. Brain MRI consistently showed a specific involvement of the substantia nigra and medulla oblongata sparing the basal ganglia. Variable degrees of heteroplasmy were found in all tissues tested and a high percentage of mutant mtDNA was observed in muscle. The asymptomatic mothers presented low levels of mutant mtDNA in blood leucocytes. This mutation, which affects an evolutionary conserved amino acid (D393N), has been previously reported in adult patients with MELAS or LHON/MELAS syndromes, emphasising the clinical heterogeneity of mitochondrial DNA mutations. Since the G13513A mutation was found in 21% of our patients with Leigh syndrome and complex I deficiency (3/14), it appears that this mutation represents a frequent cause of Leigh-like syndrome, which should be systematically tested for molecular diagnosis in affected children and for genetic counselling in their maternal relatives.     

Mitochondrial DNA integrity is essential for mitochondrial maturation during differentiation of neural stem cells

Differentiation of neural stem cells (NSCs) involves the activation of aerobic metabolism, which is dependent on mitochondrial function. Here, we show that the differentiation of NSCs involves robust increases in mitochondrial mass, mitochondrial DNA (mtDNA) copy number, and respiration capacity. The increased respiration activity renders mtDNA vulnerable to oxidative damage, and NSCs defective for the mitochondrial 8-oxoguanine DNA glycosylase (OGG1) function accumulate mtDNA damage during the differentiation. The accumulated mtDNA damages in ogg1(-/-) cells inhibit the normal maturation of mitochondria that is manifested by reduced cellular levels of mitochondrial encoded complex proteins (complex I [cI], cIII, and cIV) with normal levels of the nuclear encoded cII present. The specific cI activity and inner membrane organization of respiratory complexes are similar in wt and ogg1(-/-) cells, inferring that mtDNA damage manifests itself as diminished mitochondrial biogenesis rather than the generation of dysfunctional mitochondria. Aerobic metabolism increases during differentiation in wild-type cells and to a lesser extent in ogg1(-/-) cells, whereas anaerobic rates of metabolism are constant and similar in both cell types. Our results demonstrate that mtDNA integrity is essential for effective mitochondrial maturation during NSC differentiation.     

唐氏综合征患儿线粒体基因组突变的分析

目的 研究唐氏综合征中线粒体DNA突变情况.方法 采用高通量测序和焦磷酸测序检测7个唐氏综合征(Down's syndrome,DS)家系中的患儿和母亲的线粒体基因组序列,分析线粒体基因组序列的变化情况.结果 ①DS患儿中检测到36个与其母亲中不同的线粒体DNA突变,其中14个位点是首次在唐氏综合征样本中发现;②36个线粒体DNA突变主要发生于D-Loop区和线粒体复合物Ⅰ中;③ 线粒体基因组13个编码基因中,有11个基因检测到线粒体DNA的突变;④ 焦磷酸测序对线粒体基因组杂合突变频率的检测结果和高通量测序结果吻合.结论 DS患儿中广泛存在线粒体DNA的突变,这些突变可能与唐氏综合征的线粒体功能异常相关.     

Detection of mitochondrial DNA mutations in gestational trophoblastic disease

Mitochondrial DNA (mtDNA) mutations have been implicated in a wide range of human disease. However, its role in gestational trophoblastic disease remains unclear. In this study, the entire mitochondrial genome of 10 hydatidiform moles (HM) and one choriocarcinoma were examined by automated DNA sequencing after amplification by polymerase chain reaction. MtDNA sequences obtained separately from disease tissues (HM and choriocarcinoma) and patients' tissues were compared. Of the 133 neutral sequence variants identified, 41 have not been reported to date. Large or small-scale deletion or insertion was not detected in any of the samples studied. A total of six (five in the D-loop and one in the 16S rRNA gene) somatic point mutations were detected in the choriocarcinoma sample, in contrast to none being detected in the HM samples. Somatic mtDNA instability was detected in the D-loop region in three cases of HM as well as in the choriocarcinoma sample. Somatic mtDNA instability appeared in the same nucleotide position, from 303 to 309, within the Conserved Sequence Block II resulting in alteration in length of the homopolymorphic C-tract, reflecting microsatellite instability. The results suggest that mtDNA instability may be an early event occurring at a premalignant stage. Occurrence of multiple somatic mtDNA mutations in choriocarcinoma suggests that mtDNA mutations might play an important role in the molecular pathogenesis of invasive gestational trophoblastic disease.     

Mitochondrial DNA mutations in Leigh syndrome and their phylogenetic implications

Of 100 patients with the clinical diagnosis of Leigh syndrome, 21 were found to have specific enzyme defects: 15 involving cytochrome c oxidase (COX); 4, pyruvate dehydrogenase complex (PDHC); one, complex I (reduced nicotinamide adenine dinucleotide [NADH]-coenzyme Q reductase) and one, complex II (succinate-ubiquinone reductase) deficiencies. In addition to the most common form of COX deficiency, mtDNA mutations in the adenosine triphosphatase (ATPase) 6 coding region were also commonly seen. Eighteen patients (18%) had mtDNA mutations at nucleotide position (np) 8993 or 9176. The mutated DNAs were present in a heteroplasmic state, comprising more than 90% of the DNA in muscle and/or blood samples from all patients. Patients with the T-to-G mutation at np 8993 usually had early onset of the disease with rapid progression, showing the typical clinical features of Leigh syndrome. On the other hand, those with the T-to-C 8993 mutation showed a milder and more chronic course. Patients with the mutation at np 9176 showed variable courses. Phylogenetic analysis of mtDNA D-loop sequences for the patients with the ATPase 6 mutations and normal Japanese subjects revealed that a T-to-G/C mutation at np 8993 and a T-to-C mutation at np 9176 occurred many times independently in the Japanese population. Received: September 21, 1999 / Accepted: November 24, 1999     

Frequent chromosomal DNA unbalance in thyroid oncocytic (Hürthle cell) neoplasms detected by comparative genomic hybridization.

Thyroid oncocytic (Hürthle cell) neoplasms represent a distinct subset of follicular thyroid tumors characterized by abnormal accumulation of mitochondria, whose chromosomal abnormalities have never been systematically analyzed. We have used comparative genomic hybridization to investigate chromosomal DNA alterations in 11 thyroid oncocytic tumors (7 adenomas and 4 carcinomas). Unbalanced chromosomal DNA profiles were detected in 6 of 7 adenomas and 3 of 4 carcinomas, numerical chromosomal aberrations being the dominant feature. Comparative genomic hybridization findings are compatible with two separate groups of tumors with karyotypic abnormalities, one characterized by multiple chromosomal gains with polysomy of chromosomes 5 and 7, the other by loss of chromosome 2. Pathologic and clinical features were similar in the two groups with no difference observed between adenomas and carcinomas. Activating H-, K-, or N-Ras mutations are commonly detected in follicular adenomas and carcinomas of the thyroid gland. However, Ras mutational analysis demonstrated that only one of the tumors in this series, an oncocytic carcinoma with a balanced karyotype, had activating Ras mutations (at codon 13 of K-Ras). The lack of Ras mutations in the 9 oncocytic neoplasms exhibiting chromosomal aneuploidy indicates that numerical chromosomal abnormalities are independent of activating Ras mutations in oncocytic tumors.     

Protein S gene analysis reveals the presence of a cosegregating mutation in most pedigrees with type I but not type III PS deficiency

DNA sequence analysis of the protein S gene (PROS1) in 22 Spanish probands with type I or III PS deficiency, has allowed the identification of 10 different mutations and 2 new sequence variants in 15 probands. Nine of the mutations, 8 of which are novel, cosegregate with type I or quantitative PS deficiency in 12 of the 13 pedigrees analyzed. One of these mutations (Q238X) also cosegregates with both type I and III PS‐deficient phenotypes coexisting in a type I/III pedigree. Another mutation identified in a pedigree with these two PS phenotypes is the missense mutation R520G, present in the homozygous form in the type I propositus and in the heterozygous form in his type III relatives. By contrast, no cosegregating PROS1 mutation has been found in any of the six families with only type III phenotypes. Three of these families, as well as the two families with type I and I/III phenotypes where no other PROS1 mutation has been identified, segregate the P allele of the S460P variant, although this allele does not always cosegregate with the deficient phenotype. From these results we conclude that while mutations in PROS1 are the main cause of type I PS deficiency, the molecular basis of the type III phenotype is probably more complex, with many cases not being explained by a PROS1 mutation. Hum Mutat 14:30–39, 1999. © 1999 Wiley‐Liss, Inc.