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Enzyme
Compound
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Query: EC:1.3.5.1 (
succinate dehydrogenase
)
8,177
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Experimental and observational evidence suggests that chronic hypoxic stimulation can induce parasympathetic paraganglioma. This is emphasized by the identification of germline mutations in genes of the mitochondrial
succinate dehydrogenase
enzyme
complex II
in hereditary paraganglioma. Because of inactivating mutations in the succinate dehydrogenase subunit B (SDHB), C (
SDHC
), or D (SDHD) gene, the paraganglia undergo a chronic hypoxic stimulus leading to proliferation of the paraganglionic cells. Hypoxia is a known inducer of p53 up-regulation, which triggers cell cycle arrest and apoptosis. Inactivation of the p53 pathway, by gene mutation or by MDM2 overexpression, would enable cells to escape from cell cycle arrest and apoptosis and could contribute to tumorigenesis. To determine whether p53 inactivation plays a role in paraganglioma tumorigenesis, we investigated a series of 43 paragangliomas from 41 patients (of whom 24 patients harbored a germline SDHD mutation) for mutations in p53 exons 5-8 by PCR-SSCP. In addition, these tumors were investigated for p53 and MDM2 protein expression by immunohistochemistry, and the results were compared with clinical data and the presence of SDHD mutations. No aberrations in p53 exons 5-8 were found. The immunohistochemical experiments showed nuclear p53 expression in 15 tumors. Three tumors were positive for MDM2 that were also positive for p53. There was no correlation between p53 and MDM2 expression and clinical data or SDHD status. Given the fact that hypoxia induces p53 expression and regarding the absence of p53 mutations, these results suggest that p53 inactivation does not play a major role in the tumorigenesis of hereditary and sporadic paragangliomas.
...
PMID:p53 alterations and their relationship to SDHD mutations in parasympathetic paragangliomas. 1367 47
Hereditary head and neck paragangliomas are tumours associated with the autonomic nervous system. Recently, mutations in genes coding for subunits of mitochondrial
complex II
, succinate-ubiquinone-oxidoreductase (SDHB,
SDHC
, and SDHD), have been identified in the majority of hereditary tumours and a number of isolated cases. In addition, a fourth locus, PGL2, has been mapped to chromosome 11q13 in an isolated family. In order to characterize phenotypic effects of these mutations, the present study investigated the immunohistochemical expression of the catalytic subunits of
complex II
(flavoprotein and iron protein), SDH enzyme activity, and mitochondrial morphology in a series of 22 head and neck paragangliomas. These included 11 SDHD-, one SDHB-, two PGL2-linked tumours, and eight sporadic tumours. In the majority of the tumours (approximately 90%), the enzyme-histochemical SDH reaction was negative and immunohistochemistry of catalytic subunits of
complex II
showed reduced expression of iron protein and enhanced expression of flavoprotein. Ultrastructural examination revealed elevated numbers of tightly packed mitochondria with abnormal morphology in SDHD-linked and sporadic tumours. Immuno-electron microscopy showed localization of the flavoprotein on the remnants of the mitochondrial inner membranes, whereas virtually no signal for the iron protein was detected. These results indicate that the function of mitochondrial
complex II
is compromised in the majority of head and neck paragangliomas.
...
PMID:SDHD mutations in head and neck paragangliomas result in destabilization of complex II in the mitochondrial respiratory chain with loss of enzymatic activity and abnormal mitochondrial morphology. 1459 61
Hereditary paraganglioma (PGL) is characterized by the development of slow-growing, highly vascularized tumors that can present either as hormonally silent head and neck tumors or as abdominal pheochromocytomas. PGL tumors are caused by germline inactivating heterozygous mutations in the SDHB,
SDHC
and SDHD genes, which encode three of the four subunits of
succinate dehydrogenase
(SDH;
succinate:ubiquinone oxidoreductase
; mitochondrial
complex II
). Here, potential mechanisms by which SDH mutations could lead to tumor development are discussed. Mechanisms that lead to variations in the prevalence, penetrance and expressivity of SDH subunit mutations remain to be clarified to improve the clinical management of PGL patients. Recently, germline mutations in the FH gene, the product of which (fumarate hydratase) catalyzes the conversion of fumarate to malate in the Krebs cycle, have been detected in a distinct hereditary tumor syndrome, which is characterized by uterine and skin leiomyomatosis and papillary renal cancer. Although the exact mechanisms of tumorigenesis in both disorders are unknown, SDH and FH could be involved in the control of cell proliferation under normal physiological conditions in the affected tissue types. Whereas SDH might be involved in hypoxic proliferation of paraganglia, FH might play an important role in the regulation of ammonium metabolism in smooth muscle cells.
...
PMID:On the association of succinate dehydrogenase mutations with hereditary paraganglioma. 1464 60
Succinate dehydrogenases and fumarate reductases are complex mitochondrial or bacterial respiratory chain proteins with remarkably similar structures and functions. Succinate dehydrogenase oxidizes succinate and reduces ubiquinone using a flavin adenine dinucleotide cofactor and iron-sulfur clusters to transport electrons. A model of the quaternary structure of the tetrameric Saccharomyces cerevisiae
succinate dehydrogenase
was constructed based on the crystal structures of the Escherichia coli
succinate dehydrogenase
, the E. coli fumarate reductase, and the Wolinella succinogenes fumarate reductase. One FAD and three iron-sulfur clusters were docked into the Sdh1p and Sdh2p catalytic dimer. One b-type heme and two ubiquinone or inhibitor analog molecules were docked into the Sdh3p and Sdh4p membrane dimer. The model is consistent with numerous experimental observations. The calculated free energies of inhibitor binding are in excellent agreement with the experimentally determined inhibitory constants. Functionally important residues identified by mutagenesis of the
SDH3
and SDH4 genes are located near the two proposed quinone-binding sites, which are separated by the heme. The proximal quinone-binding site, located nearest the catalytic dimer, has a considerably more polar environment than the distal site. Alternative low energy conformations of the membrane subunits were explored in a molecular dynamics simulation of the dimer embedded in a phospholipid bilayer. The simulation offers insight into why Sdh4p Cys-78 may be serving as the second axial ligand for the heme instead of a histidine residue. We discuss the possible roles of heme and of the two quinone-binding sites in electron transport.
...
PMID:The quaternary structure of the Saccharomyces cerevisiae succinate dehydrogenase. Homology modeling, cofactor docking, and molecular dynamics simulation studies. 1467 29
Until very recently, the majority of hereditary pheochromocytomas were related to the MEN 2 and the VHL. In rare instances, hereditary pheochromocytoma was reported in patients with NF1. In addition, nonsyndromic hereditary pheochromocytomas have been reported. Recently, three more genes (SDHD, SDHB, and
SDHC
) which are all related subunits of the mitochondrial
complex II
have been identified to cause susceptibility to pheochromocytoma and/or paraganglioma. Hence, mutation analysis of VHL, RET, SDHB, and SDHD is generally recommended in patients with pheochromocytoma regardless of their family history or other features suggestive for a hereditary form. Mutation analysis should start with VHL and RET. However, in the presence of extra-adrenal pheochromocytoma, it may be more useful to screen for VHL, SDHD and SDHB mutations. It is of interest that various different genes can lead to one type of tumor formation. A common pathway (i.e. oxygen sensing) has been shown for VHL and SDHX. However, although several genes that are involved in the pathogenesis of hereditary pheochromocytoma are known, the precise molecular steps in tumorigenesis are widely unknown. In addition, recent data in MEN 2 pheochromocytomas point to a 'second hit' mechanism as a trigger for tumor formation. The molecular pathogenesis of sporadic pheochromocytomas remains obscure [114].
...
PMID:The genetic basis of pheochromocytoma. 1467 4
Hereditary paraganglioma syndrome has recently been shown to be caused by germline heterozygous mutations in three (SDHB,
SDHC
, and SDHD) of the four genes that encode mitochondrial
succinate dehydrogenase
. Extraparaganglial component neoplasias have never been previously documented. In a population-based registry of symptomatic presentations of phaeochromocytoma/paraganglioma comprising 352 registrants, among whom 16 unrelated registrants were SDHB mutation positive, one family with germline SDHB mutation c.847-50delTCTC had two members with renal cell carcinoma (RCC), of solid histology, at ages 24 and 26 years. Both also had paraganglioma. A registry of early-onset RCCs revealed a family comprising a son with clear-cell RCC and his mother with a cardiac tumor, both with the germline SDHB R27X mutation. The cardiac tumor proved to be a paraganglioma. All RCCs showed loss of the remaining wild-type allele. Our observations suggest that germline SDHB mutations can predispose to early-onset kidney cancers in addition to paragangliomas and carry implications for medical surveillance.
...
PMID:Early-onset renal cell carcinoma as a novel extraparaganglial component of SDHB-associated heritable paraganglioma. 1468 38
Germline mutations in
succinate dehydrogenase
subunits B, C and D (SDHB,
SDHC
and SDHD), genes encoding subunits of mitochondrial
complex II
, cause hereditary paragangliomas and phaeochromocytomas. In SDHB (1p36)- and
SDHC
(1q21)-linked families, disease inheritance is autosomal dominant. In SDHD (11q23)-linked families, the disease phenotype is expressed only upon paternal transmission of the mutation, consistent with maternal imprinting. However, SDHD shows biallelic expression in brain, kidney and lymphoid tissues (Baysal et al., 2000). Moreover, consistent loss of the wild-type (wt) maternal allele in SDHD-linked tumours suggests expression of the maternal SDHD allele in normal paraganglia. Here we demonstrate exclusive loss of the entire maternal chromosome 11 in SDHD-linked paragangliomas and phaeochromocytomas, suggesting that combined loss of the wt SDHD allele and maternal 11p region is essential for tumorigenesis. We hypothesize that this is driven by selective loss of one or more imprinted genes in the 11p15 region. In paternally, but not in maternally derived SDHD mutation carriers, this can be achieved by a single event, that is, non-disjunctional loss of the maternal chromosome 11. Thus, the exclusive paternal transmission of the disease can be explained by a somatic genetic mechanism targeting both the SDHD gene on 11q23 and a paternally imprinted gene on 11p15.5, rather than imprinting of SDHD.
...
PMID:Somatic loss of maternal chromosome 11 causes parent-of-origin-dependent inheritance in SDHD-linked paraganglioma and phaeochromocytoma families. 1506 8
Hereditary paraganglioma (PGL) is characterized by the development of slow-growing and vascularized tumors in the paraganglionic system. PGL is caused by germ line heterozygous inactivating mutations in the SDHB (PGL4),
SDHC
(
PGL3
), or SDHD (PGL1) genes, which encode three of the four subunits of mitochondrial
complex II
(
succinate dehydrogenase
; SDH). Common tumor sites include the carotid body in the neck and paraganglia in the abdomen. The risk of tumor development associated with SDHD mutations is determined by the sex of the transmitting parent, because only a paternal transmission leads to tumorigenesis in the progeny. This transmission pattern suggests operation of genomic imprinting on the SDHD gene. There is also evidence that the risk of tumor development increases at higher altitudes among SDHD mutation carriers. Accordingly, the increased prevalence of SDHD mutations in the Netherlands, attributable to multiple founder mutations, has been explained in part by the low altitudes in this country, which presumably reduce gene penetrance and relax the natural selection. Thus, PGL caused by SDHD mutations represents an unusual example of an inherited monogenic tumor syndrome because the risk of tumorigenesis shows an absolute dependence on the sex of the transmitting parent and may be modified by a ubiquitous environmental factor.
...
PMID:Genomic imprinting and environment in hereditary paraganglioma. 1526 76
Mutations within three genes, SDHB,
SDHC
, and SDHD, encoding distinct subunits of a hetero-oligomeric protein known as the mitochondrial
complex II
, a component of the mitochondrial electron transport chain and the Krebs cycle have been implicated in the pathogenesis of hereditary paraganglioma (PGL). This study describes a mutation screen of SDHB,
SDHC
, and SDHD in blood and tumor samples of 14 sporadic and three familial cases of head and neck PGL (HNP). Germline mutations in SDHB and SDHD were identified in two of the three affected individuals with familial HNP. The SDHB mutation was a novel 3 base pair, in-frame deletion of AGC at nucleotide 583-585 encoding serine (delS195). The SDHD mutation was a C to T transition within codon 81 causing substitution of proline with leucine (P81L). In contrast to familial cases, no germline or somatic mutations were identified in the 14 sporadic cases of HNP. The presence of mutations within SDHB and SDHD in two of the three samples of familial PGLs and absence of mutations in sporadic cases is consistent with the significant contribution of these genes to familial but not sporadic PGL. The etiology of sporadic PGL remains to be elucidated.
...
PMID:SDHB, SDHC, and SDHD mutation screen in sporadic and familial head and neck paragangliomas. 1547 92
Intracellular oxidative stress from mitochondria is thought to be important in carcinogenesis and tumorigenesis, but direct experimental proof is limited. In this study, a transgenic mouse cell line (
SDHC
E69) with a mutated
SDHC
gene (a subunit of
complex II
in the electron transport chain) was constructed to test this question. The
SDHC
E69 cells overproduced superoxide anion (O(2)(-)) from mitochondria, had elevated cytoplasmic carbonyl proteins and 8-OH-deoxyguanine in their DNA as well as significantly higher mutation frequencies than wild type. There were many apoptotic cells in this cell line, as predicted by the observed increase in caspase 3 activity, decrease in mitochondrial membrane potential, and structural changes in their mitochondria. In addition, some cells that escaped from apoptosis underwent transformation, as evidenced by the fact that
SDHC
E69 cells caused benign tumors when injected under the epithelium of nude mice. These results underscore the notion that mitochondrially generated oxidative stress can contribute to nuclear DNA damage, mutagenesis, and ultimately, tumorigenesis.
...
PMID:A mutation in the SDHC gene of complex II increases oxidative stress, resulting in apoptosis and tumorigenesis. 1566 96
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