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Query: UMLS:C0017638 (
glioma
)
30,880
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Microsatellite instability has been reported in
familial cancer
syndrome and in various kinds of human sporadic tumors. We investigated the replication error (RER) and mutation rate of the transforming growth factor-beta type II receptor (TGF-beta RII) gene to determine the frequency of the RER+ phenotype and elucidate the relation between the mutation of the TGF-beta RII gene and RER in the tumorigenesis of
glioma
. We screened genomic DNA from 40 gliomas, comprised from 24 glioblastomas (GB), 11 anaplastic astrocytomas (AA) and five astrocytomas (AS) and compared the results with DNA from corresponding leukocytes. Seven of the 40 (18%) gliomas had the RER+ phenotype: five (21%) of 24 GB and two (18%) of 11 AA. In six gliomas we detected mutation of the TGF-beta RII gene. Five (71%) of seven RER+ and one (3%) of 33 RER-tumors had one A deletion in the (A)10 repeat of the TGF-beta RII gene. No mutations were detected in the (GT)3 repeat area of the TGF-beta RII gene. As the normal cells of these
glioma
patients had no mutations, we concluded that the mutations were somatic. We posit that the observed mutations inactivate the receptor through a frameshift mutation resulting in protein truncation. Our data suggest that the TGF-beta RII (A)10 repeat may be one area of genomic instability in the early stages of malignant
glioma
tumorigenesis.
...
PMID:Microsatellite instability and mutated type II transforming growth factor-beta receptor gene in gliomas. 906 36
Epidemiological studies suggest that some familial aggregations of
glioma
may be due to inherited predisposition. Many genes involved in familial cancers are frequently altered in the corresponding sporadic forms. We have investigated several genes known to be altered in sporadic gliomas for their potential contribution to familial
glioma
. Fifteen
glioma
patients with a family history of brain tumors were identified through the Mayo Clinic Department of Neurology (nine diffuse astrocytomas, two oligodendrogliomas, two mixed oligoastrocytomas, one pilocytic astrocytoma, and one pineal
glioma
). Eleven of the propositi had one or more first degree relative with a
glioma
. Lymphocyte DNA was derived from each of the patients and analyzed by polymerase chain reaction (PCR) and direct sequencing of the PTEN, p53, p16(INK4A)/p14(ARF), and CDK4 genes. In addition, fluorescence in situ hybridization (FISH) was performed on EBV-transformed lymphocytes from each affected individual to detect germline copy number of the p16(INK4A)/p14(ARF) tumor suppressor region. A p53 germline point mutation was identified in one family with some findings of Li-Fraumeni syndrome, and a hemizygous germline deletion of the p16(INK4A)/p14(ARF) tumor suppressor region was demonstrated by FISH in a family with history of both astrocytoma and melanoma. Thus, whereas germ-line mutations of PTEN, p53, p16(INK4A)/p14(ARF), and CDK4 are not common events in familial
glioma
, outside of
familial cancer
syndromes, point mutations of p53 and hemizygous deletions and other rearrangements of the p16(INK4A)/p14(ARF) tumor suppressor region may account for a subset of familial
glioma
cases. Collectively, these data lend genetic support to the heritable nature of some cases of
glioma
.
...
PMID:Investigation of germline PTEN, p53, p16(INK4A)/p14(ARF), and CDK4 alterations in familial glioma. 1079 39
A small proportion of brain tumors are attributed to a genetic predisposition; however, the hereditary proportion is undetermined. This study evaluates the degree of familial aggregation of cancer in a large series of brain tumor patients. Our study included 5,088 relatives of 639 probands (3,810 first- and 1,278 second-degree), diagnosed with a
glioma
between June 1992 and June 1995 at The University of Texas M. D. Anderson Cancer Center, Houston, Texas, with diagnosis under age 65 years, and residents of the United States or Canada. We conducted an in-person or telephone interview with patients and/or their next-of-kin, and obtained family histories for the probands' first-degree (parents, siblings, offspring) and selected second-degree relatives (aunts, uncles, grandparents) using a sequential sampling strategy. Reported cancers were documented by medical records and/or death certificates (if the relative was deceased and medical records were unavailable). We conducted segregation analysis using the Pedigree Analysis Program (PAP). The analyses were divided into two categories: (1) all 639 families, and (2) a subset of families whose gliomas stained positive on p53 immunohistochemistry analysis. We demonstrated that a multifactorial Mendelian model was favored, while a model postulating a purely environmental cause of brain cancer was rejected. This study indicates that
familial cancer
in relatives of
glioma
patients are probably a result of multigenic action, and familial clustering of cancer among relatives of
glioma
patients may involve unknown environmental exposures.
...
PMID:Segregation analysis of cancer in families of glioma patients. 1118 Apr 51
Several different types of tumors, benign and malignant, have been identified in the central nervous system (CNS). The prognoses for these tumors are related to several factors, such as the age of the patient and the location and histology of the tumor. In adults, about half of all CNS tumors are malignant, whereas in pediatric patients, more than 75% are malignant. For most benign CNS tumors that require treatment, neurosurgeons can offer curative resections or at least provide significant relief from mass effect. Unfortunately, we still lack effective treatments for most primary and secondary malignant CNS tumors. However, the past decade has witnessed an explosion in the understanding of the early molecular events in malignant primary CNS tumors, and for the first time in history, oncologists are seeing that a plethora of new therapies targeting these molecular events are being tested in clinical trials. There is hope on the horizon for the fight against these deadly tumors. The distribution of CNS tumors by location has remained constant for numerous years. The majority of primary CNS tumors arise in the major cortical lobes. Twenty nine percent of primary CNS tumors arise from the dural meninges that encase the CNS structures. The vast majority of these are meningiomas, of which over 90% are benign. About 10% of primary CNS tumors are found in the sella turcica region, where the pituitary gland resides. Other much less common sites of primary CNS tumors include the pineal region, ventricular system, cerebellum, brain stem, cranial nerves, and spinal cord. The distribution of CNS tumors by histology has seen a slight increase in more malignant tumors over the past decade, possibly due to increased neuroimaging practices or environmental exposures. Arising from glial cells, gliomas represent over 36% of all primary CNS tumors and consist of astrocytomas, oligodendrogliomas, ependymomas, mixed gliomas, and neuroepithelial tumors. The benign meningiomas make up 32% of primary CNS tumors, followed by nerve sheath tumors and pituitary tumors. Primary CNS lymphomas, embryonal tumors, and craniopharyngiomas are uncommon. The most common gliomas are astrocytomas, and these tumors are typically classified by the World Health Organization (WHO) as Grades I through IV. Grade IV, the most malignant grade of astrocytoma, includes glioblastoma multiforme (GBM), the most common malignant primary CNS
glioma
in adults, which represents 51% of all CNS gliomas. GBM is unfortunately the most challenging to effectively treat and has the worst patient survival. This chapter is therefore primarily devoted to the current understanding of this topic. Here we describe the molecular and cellular events associated with malignant
glioma
initiation and progression. We also review the importance of
glioma
stem cell biology and tumor immunology in early gliomagenesis. In addition, we present a brief description of the most common malignant primary CNS
glioma
in pediatric patients - medulloblastoma, as well as
familial cancer
syndromes that include gliomas as part of the syndrome.
...
PMID:Central nervous system. 2211 77
The majority of gliomas are sporadic in origin. Familial gliomas have been reported, though they are exceptionally rare. Several
familial cancer
syndromes are associated with autosomal dominant
glioma
risk, typically with incomplete penetrance. When two siblings are affected in the absence of a known dominantly inherited cancer syndrome, an autosomal recessive condition may be suspected (e.g. constitutional mismatch repair syndrome). We present two separate sets of siblings, one set with low grade gliomas, and the other with high grade gliomas. Histology for all tumors were either oligodendroglioma or had features of oligodendroglioma. Interestingly, there is a nearly identical histopathology and anatomical localization noted in these clinical presentations. For one family, genetic testing and family inquiry have resulted in no identifiable genetic pattern of disease. High-penetrance familial mutations and common low-penetrance susceptibility loci (e.g. single-nucleotide polymorphism (SNPs)) may contribute to familial
glioma
risk. We present two instances of familial
glioma
without an identifiable genetic cause. These cases implicate a potential heritable etiology for
glioma
families in which Mendelian disorders have not been identified. Further investigation should focus on identifying the potential genetic links involved with cases such as the ones presented here.
...
PMID:Familial gliomas: cases in two pairs of brothers. 2520 78
During the past six years, researchers have made major progress identifying common inherited genetic variation that increases risk for primary adult
glioma
. This paper summarizes knowledge about rare
familial cancer
syndromes that include adult
glioma
and reviews the available literature on the more recently discovered common inherited variation. Ten independent inherited variants in eight chromosomal regions have been convincingly associated with increased risk for adult
glioma
. Most of these variants increase relative risk of primary adult
glioma
by 20% to 40%, but the TP53 variant rs78378222 confers a two-fold relative risk (ie, 200%), and rs557505857 on chromosome 8 confers a six-fold relative risk of
IDH
-mutated astrocytomas and oligodendroglial tumors (ie, 600%). Even with a six-fold relative risk, the overall risk of developing adult
glioma
is too low for screening for the high-risk variant on chromosome 8. Future studies will help clarify which inherited adult
glioma
risk variants are associated with subtypes defined by histology and/or acquired tumor mutations. This review also provides an information sheet for primary adult
glioma
patients and their families.
...
PMID:Understanding inherited genetic risk of adult glioma - a review. 2694 59
PALB2
(partner and localizer of BRCA2) gene encodes a protein that colocalizes with
BRCA2
in nuclear foci and likely permits the stable intranuclear localization and accumulation of
BRCA2
PALB2
plays a critical role in maintaining genome integrity through its role in the Fanconi anemia and homologous recombination DNA repair pathways. It has a known loss-of-function disease mechanism. Biallelic
PALB2
pathogenic variants have been described in autosomal recessive Fanconi anemia. Heterozygous pathogenic variants in
PALB2
are associated with increased risk for female and male breast cancer and pancreatic cancer (
Science
324: 217;
Cancer Res
71: 2222-2229;
N Engl J Med
371: 497-506). Heterozygous germline
PALB2
mutations have also been observed in patients with medulloblastoma (
Lancet Oncol
19: 785-798). However,
PALB2
-related cancer predisposition to high-grade gliomas has not been reported. Here we report a germline
PALB2
pathogenic variant (c.509_510delGA, p.Arg170Ilefs*14, NM_024675.3) found in a pediatric patient with high-grade
glioma
. This variant was first identified by tumor sequencing using the Children's Hospital of Philadelphia (CHOP) Comprehensive Solid Tumor Panel and then confirmed to be a germline change using the CHOP Comprehensive
Hereditary Cancer
Panel on DNA from a blood sample of this patient. Parental studies showed that this variant was paternally inherited. Further studies are needed to illustrate if pathogenic variants in
PALB2
convey increased risk to developing brain tumor. This case also highlights the potential of identifying germline mutation through tumor sequencing.
...
PMID:A germline
PALB2
pathogenic variant identified in a pediatric high-grade glioma. 3255 98
