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http://dx.doi.org/10.1007/s00381-006-0187-3
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Current concepts in the molecular genetics of pediatric brain tumors:implications for emerging therapies
Child's Nervous System DOI 10.1007/s00381-006-0187-3
Tamber Bansal Liang Mainprize Salhia Northcott Taylor Rutka
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Child's Nervous System
10.1007/s00381-006-0187-3
James T. RutkaJames T. RutkaThe Division of Neurosurgery, Suite1504, The Hospital for SickChildren, 555 University Avenue,Toronto, Ontario, 518, Canada
The Division of Neurosurgery, Suite1504, The Hospital for SickChildren, 555 University Avenue,Toronto, Ontario, 518, Canada
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Metadata of the article that will be visualized in OnlineFirst
1 Article Title Current concepts in the molecular genetics of pediatric braintumors: implications for emerging therapies
2 Journal Name Child's Nervous System3
CorrespondingAuthor
Family Name Rutka4 Particle5 Given Name James T.6 Suffix7 Organization The Hospital for Sick Children8 Division The Division of Neurosurgery, Suite 15049 Address 555 University Avenue, Toronto 518, Ontario, Canada
10 Organization The University of Toronto11 Division Division of Neurosurgery, The Hospital for Sick
Children12 Address Toronto , Ontario, Canada13 Organization The University of Toronto14 Division Arthur and Sonia Labatt Brain Tumor Research
Centre, The Hospital for Sick Children15 Address Toronto , Ontario, Canada16 e-mail [email protected]
Author
Family Name Tamber18 Particle19 Given Name Mandeep S.20 Suffix21 Organization The University of Toronto22 Division Division of Neurosurgery, The Hospital for Sick
Children23 Address Toronto , Ontario, Canada24 Organization The University of Toronto25 Division Arthur and Sonia Labatt Brain Tumor Research
Centre, The Hospital for Sick Children26 Address Toronto , Ontario, Canada27 e-mail28
Author
Family Name Bansal29 Particle30 Given Name Krishan31 Suffix32 Organization The University of Toronto33 Division Division of Neurosurgery, The Hospital for Sick
Children34 Address Toronto , Ontario, Canada
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35 Organization The University of Toronto36 Division Arthur and Sonia Labatt Brain Tumor Research
Centre, The Hospital for Sick Children37 Address Toronto , Ontario, Canada38 e-mail39
Author
Family Name Liang40 Particle41 Given Name Muh-Lii42 Suffix43 Organization The University of Toronto44 Division Division of Neurosurgery, The Hospital for Sick
Children45 Address Toronto , Ontario, Canada46 Organization The University of Toronto47 Division Arthur and Sonia Labatt Brain Tumor Research
Centre, The Hospital for Sick Children48 Address Toronto , Ontario, Canada49 e-mail50
Author
Family Name Mainprize51 Particle52 Given Name Todd G.53 Suffix54 Organization The University of Toronto55 Division Division of Neurosurgery, The Hospital for Sick
Children56 Address Toronto , Ontario, Canada57 Organization The University of Toronto58 Division Arthur and Sonia Labatt Brain Tumor Research
Centre, The Hospital for Sick Children59 Address Toronto , Ontario, Canada60 e-mail61
Author
Family Name Salhia62 Particle63 Given Name Bodour64 Suffix65 Organization The University of Toronto66 Division Division of Neurosurgery, The Hospital for Sick
Children67 Address Toronto , Ontario, Canada68 Organization The University of Toronto69 Division Arthur and Sonia Labatt Brain Tumor Research
Centre, The Hospital for Sick Children70 Address Toronto , Ontario, Canada71
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e-mail72
Author
Family Name Northcott73 Particle74 Given Name Paul75 Suffix76 Organization The University of Toronto77 Division Division of Neurosurgery, The Hospital for Sick
Children78 Address Toronto , Ontario, Canada79 Organization The University of Toronto80 Division Arthur and Sonia Labatt Brain Tumor Research
Centre, The Hospital for Sick Children81 Address Toronto , Ontario, Canada82 e-mail83
Author
Family Name Taylor84 Particle85 Given Name Michael86 Suffix87 Organization The University of Toronto88 Division Division of Neurosurgery, The Hospital for Sick
Children89 Address Toronto , Ontario, Canada90 Organization The University of Toronto91 Division Arthur and Sonia Labatt Brain Tumor Research
Centre, The Hospital for Sick Children92 Address Toronto , Ontario, Canada93 e-mail94
ScheduleReceived 14 March 2006
95 Revised96 Accepted97 Abstract Background: The revolution in molecular biology that has taken place over the
past 2 decades has provided researchers with new and powerful tools fordetailed study of the molecular mechanisms giving rise to the spectrum ofpediatric brain tumors. Application of these tools has greatly advanced ourunderstanding of the molecular pathogenesis of these lesions.Review: After familiarizing readers with some promising new techniques in thefield of oncogenomics, this review will present the current state of knowledge as
it pertains to the molecular biology of pediatric brain neoplasms. Along the way,we hope to highlight specific instances where the detailed mechanisticknowledge acquired thus far may be exploited for therapeutic advantage.
98 Keywordsseparated by ' - ' Brain neoplasms - Molecular biology - Pediatrics - Review - Therapeutics
99 Foot noteinformation
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1
2
3 INVITED PAPER
4 Current concepts in the molecular genetics of pediatric
5 brain tumors: implications for emerging therapies
6 Mandeep S. Tamber & Krishan Bansal & Muh-Lii Liang &
7 Todd G. Mainprize & Bodour Salhia & Paul Northcott &
8 Michael Taylor & James T. Rutka
9 Received: 14 March 2006
10 # Springer-Verlag 2006
13 Abstract14 Background The revolution in molecular biology that has
15 taken place over the past 2 decades has provided research-
16 ers with new and powerful tools for detailed study of the
17 molecular mechanisms giving rise to the spectrum of
18 pediatric brain tumors. Application of these tools has
19 greatly advanced our understanding of the molecular
20 pathogenesis of these lesions.
21 Review After familiarizing readers with some promising
22 new techniques in the field of oncogenomics, this review
23 will present the current state of knowledge as it pertains to
24 the molecular biology of pediatric brain neoplasms. Along
25 the way, we hope to highlight specific instances where the26 detailed mechanistic knowledge acquired thus far may be
27 exploited for therapeutic advantage.
28 Keywords Brain neoplasms . Molecular biology .
29 Pediatrics . Review . Therapeutics
3Introduction
3In the past 2 decades, the textbooks on the molecular
3 biology of pediatric brain tumors have been rewritten
3several times. This has been principally due to the
3tremendous advances that have been made in our under-
3standing of these tumors from a basic science standpoint,
3a dv an ce s which a re in large p art d ue to the n ew
3technologies that have come forward to query the genetic
3underpinnings of these lesions. Suffice it to say that we are
3now poised, greater than ever before, to utilize the
4information that has been garnered toward tangible
4improvements in the way children with brain tumors are4treated.
4In this review, we will summarize the salient molecular
4genetic changes that characterize pediatric astrocytomas,
4 both low- and high-grade lesions, ependymoma, medullo-
4 blastoma and primitive neuroectodermal tumors, atypical
4teratoid rhabdoid tumor (AT/RT), germ cell tumors (GCTs),
4and sarcomas. During the review of each tumor type, we
4will attempt to provide clues as to how detailed knowledge
5of the molecular pathogenesis of these lesions may be
5harnessed toward translational research opportunities
5designed to improve patient outcomes.
5New techniques in the field of oncogenomics
5In the past 30 years, advanced cancer cytogenetics have
5been applied to numerous cancer subtypes, including many
5of the pediatric brain tumors. For additional details
5regarding these techniques, the interested reader is referred
5to several excellent review articles on this topic [ 136, 159].
5Here we will describe array comparative genomic hybrid-
Childs Nerv Syst
DOI 10.1007/s00381-006-0187-3
M. S. Tamber: K. Bansal : M.-L. Liang : T. G. Mainprize :
B. Salhia: P. Northcott: M. Taylor: J. T. Rutka
Division of Neurosurgery, The Hospital for Sick Children,
The University of Toronto,
Toronto, Ontario, Canada
M. S. Tamber: K. Bansal : M.-L. Liang : T. G. Mainprize :
B. Salhia: P. Northcott: M. Taylor: J. T. Rutka
Arthur and Sonia Labatt Brain Tumor Research Centre,
The Hospital for Sick Children, The University of Toronto,
Toronto, Ontario, Canada
J. T. Rutka (*)
The Division of Neurosurgery, Suite 1504,
The Hospital for Sick Children,
555 University Avenue,
Toronto, Ontario 518, Canada
e-mail: [email protected]
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60 ization (CGH), single nucleotide polymorphism (SNP)
61 arrays, microarray analysis of gene expression, and exon
62 resequencing as new techniques which have been and will
63 be applied to the study of pediatric brain tumors (Table 1).
64 Array comparative genomic hybridization
65 Array comparative genomic hybridization is similar to66 CGH, but instead of hybridizing the labeled probes to
67 metaphase chromosomes, the probes are hybridized to
68 microarray slides in which thousands of fragments of
69 DNA that span the genome have been arrayed out [29,
70 70, 114, 115]. The array CGH chip can be spotted with
71 DNA composed of genomic clones, cDNA sets, or
72 oligonucleotide probes depending on the array design. A
73 major advantage of array CGH over traditional CGH is the
74 significantly higher resolution offered by the array plat-
75 form, allowing investigators to identify smaller areas of
76 aberration. For example, bacterial artificial chromosome
77 (BAC) arrays consisting of greater than 30,000 BAC clones78 representing the entire human genome are now widely used
79 in array CGH, permitting whole-genome copy number
80 analysis at resolutions of less than 1 Mb, compared with the
81 much lower resolution achieved using traditional CGH
82 (~5 Mb) [72, 83].
8The highest resolution for array CGH is now provided
8 by genome tiling arrays which interrogate entire genomes
8with evenly spaced oligonucleotide probes [8, 19]. The
8increased resolution offered by modern array CGH plat-
8forms will allow for the incredibly fine mapping of focal
8amplifications and deletions not possible using previous
8generation arrays. Weaknesses of array CGH include an
9inability to detect structural anomalies such as reciprocal9translocations and the inability to detect copy-number-
9neutral loss of heterozygosity (LOH) events.
9Array CGH technology has recently been applied by a
9number of groups studying DNA copy number changes in
9pediatric brain tumors [24, 68, 99, 135, 161, 164]. Using a
9combination of array CGH and oligonucleotide gene
9expression arrays (discussed below) in a study of ependy-
9moma, Taylor et al. recently reported that histologically
9similar anatomical subtypes of ependymoma could be
1distinguished based upon their distinct patterns of copy-
1number-driven gene expression [161]. These authors also
1used array CGH and expression microarrays to identify a1number of genes that are both amplified and overexpressed
1in ependymoma (i.e., oncogenes). The results of this study
1emphasize the power of array CGH in the identification of
1genomic aberrations in cancer and demonstrate its utility
1when combined with complementary technical platforms
1such as gene expression arrays.
t1.1 Table 1 Summary of molecular and cytogenetic techniques discussed in the text
Technique CGH SKY Array CGH SNP array Expression
array
Exon
resequencingt1.2
Primary
application
Mapping regions
of amplification
and deletion
Identification of
structural
aberrations
Copy number
analysis
Copy number
analysis; LOH
mapping
Gene
expression
profiling
Mutation
detectiont1.3
Platform type Fluorescence
microscopy
Fluorescence
microscopy
Microarray:
BAC,
oligonucleotide
Microarray:
oligonucleotide
Microarray:
oligonucleotide
Dideoxy
sequencingt1.4
Starting
material
Genomic DNA Metaphase
chromosomes from
cultured cells
Genomic DNA Genomic DNA Total RNA or
mRNA
Genomic DNAt1.5
Advantages Assay only
requires genomic
DNA
Capacity to detect
balanced
translocations
Good resolution;
whole-genome
screening
High
resolution;
whole-genome
screening
Whole
transcriptome
screening
possible
Highest
resolution;
no restriction
on choice of
genes
t1.6
Disadvantages Poor resolution;
unable to detect
balanced
translocations
Prone to erroneous
interpretations and
classification errors
LOH mapping
not possible
Data analysis
intensive
Data analysis
and
interpretation
issues
Limited to user-
defined genes
and gene
families;
expensive
t1.7
t1.8 Listed are some of the current platforms employed in cancer genetics to identify novel disease-causing genes, highlighting the type of platform
used, biological material required, as well as primary strengths and weaknesses of each technique. Detailed information for each assay type,
including relevant clinical examples, is described in the text.
CGH comparative genomic hybridization, SKY spectral karyotyping, SNP single nucleotide polymorphism, LOH loss of heterozygosity,
BAC bacterial artificial chromosome
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109 Single nucleotide polymorphism arrays
110 Single nucleotide polymorphisms represent the most com-
111 mon form of genetic variation in the human genome [2, 62,
112 137, 169]. SNPs are naturally occurring variations in DNA
113 sequence that occur regularly throughout the genome, with
114 an average frequency of one SNP for every 200 bases of
115 DNA. Recently, array-based technologies that use SNPs as116 a means of investigating both DNA copy number and SNP
117 genotype have become commercially available [67, 79, 95,
118 96]. Unlike array CGH which involves simultaneous
119 cohybridization of both a test sample and a reference
120 sample to the microarray, SNP arrays hybridize only a test
121 sample, with DNA copy number calculated by comparison
122 of signal intensity data obtained from a test sample to data
1from control samples hybridized to the same array type. In
1SNP array analysis, DNA from a test sample is first
1digested with a specific restriction enzyme (e.g., Hind or
1Xba) and then ligated to an adaptor which permits
1amplification of the digested fragments. Amplified DNA
1is subsequently fragmented and labeled before hybridiza-
1tion to a specific SNP array (e.g. 50K Hind or 50K Xba
1array) (Fig. 1).1The arrays consist of 25-mer oligonucleotide probes
1that are designed to genotype the test sample for either of
1two alleles of a given SNP (arbitrarily designated A and B
1alleles). Each SNP is represented by a set of perfect match
1A and perfect match B probes, as well as an equal number
1of mismatch probes for both alleles. For any given SNP,
1the possible genotypes for a test sample include AA, BB,
Fig. 1 Analysis of LOH and chromosomal copy number using SNP
arrays. Data obtained from SNP array experiments can be analyzed
visually to identify instances of LOH and copy number gains and
losses. a Inferred LOH view of a medulloblastoma cell line exhibiting
genetic loss on chromosome 17p. The middle panel depicts inferred
regions of LOH in blue and those retaining heterozygosity in yellow.
The significance curve shown on the right demonstrates a high
probability of LOH on 17p for this sample. b Copy number view of a
medulloblastoma cell line with high-level genomic amplifications on
chromosome 8q24. Copy number is displayed in the middle panel
using a user-defined scale, with gains and losses represented by darker
and lighter color intensities, respectively. The right panel clearly
identifies the 8q24 amplifications in this sample as sharp peaks in copy
number, with values dramatically exceeding the threshold value of 2 at
these loci
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138 or AB, with genotype determined by the pattern of perfect
139 match and mismatch signal intensities obtained for that
140 SNP. Accuracy of SNP genotyping relies on the availabil-
141 ity of a highly purified DNA sample; analysis of tumor
142 tissue may therefore be problematic due to the presence of
143 contaminating normal cells. Modern array platforms
144 interrogate from 100,000 to 500,000 SNPs, resulting in
145 high-resolution genome coverage with median SNP146 spacing of ~8.5 and ~2.5 kb, respectively. This resolution
147 is more than 1,000 times better than classic CGH. As a
148 result of the high resolution and sensitivity associated
149 with SNP arrays, it is possible to identify microamplifi-
150 cations and microdeletions present in cancer samples, as
151 well as larger aberrations including aneuploidy. A major
152 advantage of SNP array technology over other platforms
153 used in cancer genetics is the simultaneous acquisition of
154 both copy number and genotype information. Whereas
155 copy number data are critical for mapping regions of
156 amplification and homozygous deletion in tumor samples,
157 genotyping information can identify loci which have158 undergone loss of heterozygosity without a decrease in
159 copy number (copy-number-neutral LOH). Although
160 SNP-array-based approaches have not yet been reported
161 for pediatric brain tumors, they have proven to be a
162 valuable tool when applied to studies of other tumor types
163 [49, 65, 140, 162, 176, 179, 180].
164 Microarray analysis of gene expression
165 In recent years, microarrays designed to study global gene
166 expression profiles have become an indispensable tool for
167 cancer researchers [16, 127, 142]. Significant improve-
168 ments with respect to array design, in combination with a
169 more comprehensive knowledge of the human transcrip-
170 tome, has resulted in the evolution of arrays which allow
171 for evaluation of the expression of every known human
172 gene [47, 60, 87, 88, 141]. In addition, new-generation
173 high-resolution arrays have recently been developed,
174 including platforms which interrogate every annotated
175 human exon. Now, genome tiling arrays capable of
176 measuring gene expression every 25 base pairs across
177 entire genome have been developed in order to measure
178 expression from cryptic transcriptional units [21, 75, 78].
179 This technology has found expression of countless tran-
180 scripts that previously lacked annotation, many from so-
181 called gene deserts.
182 Conventional arrays for gene expression analysis consist
183 of 25-mer oligonucleotide probes that are complementary in
184 sequence to their target, with multiple perfect match and
185 mismatch probes existing for each interrogated target and
186 multiple probe sets present for each gene represented on the
187 array. Total RNA from a tumor sample is first reverse-
188 transcribed using a T7-oligo(dT) promoter primer to
1generate first-strand cDNA. First-strand cDNA is then
1converted to double-stranded cDNA which serves as a
1template for the synthesis of complementary RNA (cRNA)
1in an in vitro transcription (IVT) reaction. IVT is carried out
1by T7 RNA polymerase in the presence of biotin-labeled
1ribonucleotides. The biotinylated cRNA is subsequently
1purified, fragmented, and hybridized to an expression array.
1Hybridized arrays are then stained, washed, and scanned to1determine the signal intensity for each probe on the array,
1with the signal intensity being proportional to the amount
1of bound target. Data obtained from such a gene expression
2array can then be used to identify the gene expression
2 profile characteristic of a particular tumor [100]. Gene
2expression arrays have proven useful in the identification of
2aberrantly expressed genes and gene families in pediatric
2 brain tumors, with some of these candidates potentially
2representing important prognostic markers and/or serving
2as targets for future therapeutics [44, 51, 92, 119].
2Exon resequencing
2Advances in DNA sequencing technologies, along with the
2availability of comprehensive genomic databases, have
2recently led to a number of large-scale resequencing efforts
2aimed at identifying novel mutations in groups or families
2of preselected candidate genes [7, 27, 28, 122, 145, 146,
2170, 171]. The resequencing approach involves choosing a
2set of genes for analysis (e.g., kinases) and performing
2 polymerase chain reaction (PCR) amplification of all
2coding exons including the intronexon splice site junctions
2for that set of genes, with genomic DNA isolated from
2 patient tumor samples or cell lines serving as a template.
2The PCR is carried out using a high-fidelity polymerase to
2avoid introduction of de novo mutations during the
2amplification reaction. PCR products are purified and then
2subjected to bidirectional dideoxy sequencing to identify
2putative mutations. Ideally, patient-matched normal DNA is
2analyzed using the same procedure and then compared with
2results from sequencing of the tumor DNA to allow for
2distinction between possible mutations and natural poly-
2morphisms. This strategy for mutation identification has
2 been successfully applied in studies of lung, colorectal,
2 breast, and brain tumors [7, 27, 28, 122, 145, 146, 170,
2171]. For example, a resequencing project analyzing the
2receptor tyrosine kinase family of genes in human
2glioblastomas found mutations of the fibroblast growth
2receptor-1 gene and the platelet-derived growth factor
2receptor (PDGFR) gene [122]. To date, exon resequenc-
2ing has been most extensively applied to the tyrosine kinase
2and associated phosphatase gene families [7, 27, 28, 122,
2145, 146, 171]; however, there are no limitations on the
2types or families of genes that can be interrogated using this
2strategy.
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240 Molecular genetics of specific pediatric brain tumors
241 High-grade astrocytoma
242 High-grade astrocytomas in children are relatively rare
243 lesions when compared with adults. Whereas the prognosis
244 of children with anaplastic astrocytoma or glioblastoma
245 multiforme may be better than that of adults with a246 comparable histological lesion, the majority of children
247 will still succumb from progressive disease within 25 years
248 after diagnosis [152]. What has been very interesting, and
249 as yet incompletely characterized, is the fact that the genetic
250 alterations that accompany the childhood high-grade astro-
251 cytic neoplasms are distinct from those that occur in adults.
252 The genetic alterations that are the hallmark of adult
253 anaplastic astrocytomasloss of p53, PTEN, p14ARF, and
254 amplification of the epidermal growth factor receptor
255 (EGFR) III mutantare relatively rare in pediatric anaplas-
256 tic astrocytomas (see below). In light of this and other
257 evidence, it appears as if the development of pediatric high-258 grade astrocytomas may follow pathways distinct from the
259 well-established primary and secondary paradigm of adult
260 glioblastomas.
261 Common chromosomal losses in pediatric high-grade
262 gliomas include those of chromosome 16p, 17p, 19p, 19q,
263 and 22 [129]. Within the spectrum of high-grade gliomas,
264 distinct cytogenetic changes are observed in pediatric
265 anaplastic astrocytomas, which are typified by gains of
266 chromosome 5q and losses of chromosomes 6q, 9q, 12q,
267 and 22q, and in pediatric glioblastoma, which is character-
268 ized by gains in chromosomes 1q and 16p and losses of
269 chromosomes 8q and 17p [129]. The finding of 1q
270 amplification is noteworthy because it may be a marker of
271 poor survival.
272 Whereas microsatellite instability appears to be generally
273 absent in the setting of adult high-grade astrocytomas,
274 nearly 25% of pediatric malignant astrocytomas may
275 display a microsatellite instability phenotype as a manifes-
276 tation of mutations in various DNA mismatch repair genes
277 [1, 22].
278 In addition to being characterized by their respective
279 patterns of structural chromosomal abnormalities, pediatric
280 high-grade astrocytomas may be distinguished from their
281 adult counterparts on the basis of differential expression of
282 oncogenes and tumor suppressor genes that are involved in
283 signal transduction pathways critical to the process of
284 gliomagenesis. The pertinent pathways for the adult tumors
285 include the growth factor/growth factor receptor/PI3-kinase/
286 Akt/PTEN pathway, the p53/MDM2/p14ARF pathway, and
287 the pRB/cyclinD1/cyclin-dependent kinase (CDK) 4/p16
288 pathway. The interested reader is referred to a review by
289 Ichimura et al. for a recent synopsis of the interplay of these
290 various pathways in the molecular pathogenesis of astro-
2cytic tumors [69]. In the remainder of this section, each
2pathway will be examined in turn in order to characterize
2the patterns of abnormality present within and to highlight
2the often dichotomous nature of the importance of an
2individual pathway to the genesis of pediatric vs adult high-
2grade gliomas.
2Although amplification of the EGFR gene is observed in
2up to 40% of adult glioblastomas and 15% of adult2anaplastic astrocytomas, it is not a common finding in
3 pediatric high-grade astrocytomas [22, 121, 148]. Similarly,
3whereas de novo adult glioblastomas have a high frequency
3of mutations in the PTEN tumor suppressor gene, pediatric
3malignant gliomas rarely contain such mutations. Although
3LOH at 10q2325 may be present in as many as 80% of
3informative cases, homozygous deletions of the PTEN gene
3are seen in only 8% of pediatric high-grade astrocytomas
3[22]. Where mutations of PTEN are observed, they may
3herald a poor prognosis for children with high-grade
3astrocytomas.
3The majority of adult secondary glioblastomas demon-3strate mutations of the p53 tumor suppressor gene located
3on chromosome 17p. A relatively small subset of high-
3grade gliomas, mostly occurring in older children, may also
3harbor frequent p53 mutations. In this population, there
3appears to be a nearly 2:1 frequency of p53 gene mutations
3in high-grade brainstem astrocytomas as opposed to non-
3brainstem astrocytomas [22, 90, 117].
3Homozygous deletions of the CDKN2A/pl4ARF locus at
39p21, which encodes both the p16 and p14ARFproteins, are
3found in 10% of pediatric malignant astrocytomas [103].
3Overexpression of the MDM2 oncogene is seen in 67% of
3 pediatric malignant astrocytomas, although there is no
3concomitant amplification of the MDM2 gene at a genomic
3level [148]. Overall, inactivation of the p53/MDM2/p14ARF
3 pathway, either by mutation of p53, overexpression of
3MDM2, or deletion of p14ARF, is seen in more than 95% of
3 pediatric malignant astrocytomas, a situation which is
3similar to the observed frequency of p53/MDM2/p14ARF
3 pathway inactivation in the setting of adult malignant
3astrocytomas [148]. However, as outlined earlier, mutations
3of p53 are seldom seen in malignant gliomas of children
3younger than 3 years, once again suggesting that malignant
3gliomas in very young children may follow a distinct
3molecular pathway as compared with older children and
3adults [118].
3Sure et al. were able to demonstrate loss of expression of
3p16 in 11 of 18 pediatric glioblastomas [149]. However, the
3 pRb/cyclin D1/CDK4/p16 pathway appears to be inacti-
3vated in only about 25% of pediatric malignant astrocyto-
3mas, as opposed to inactivation in more than 80% of the
3corresponding adult tumors [148].
3To date, there have been no published reports of cDNA
3microarray analyses on pediatric high-grade gliomas.
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344 Low-grade astrocytoma
345 Whereas tremendous advances have been made in the
346 understanding of the molecular pathogenesis of pediatric
347 high-grade astrocytomas, there have been comparatively
348 few studies focusing on the low-grade and pilocytic
349 astrocytomas of childhood.
350 Consistent with the fact that they are low-grade lesions,351 cytogenetic studies have revealed a normal karyotype in the
352 majority of pilocytic astrocytomas examined, and where
353 abnormal profiles have been observed, no consistent
354 karyotype abnormalities have been identified [138, 178].
355 Pediatric pilocytic astrocytomas show fewer chromosomal
356 changes than adult tumors; where observed, they are
357 usually gains of only a single chromosome, such as
358 chromosome 7 or 8, as has been demonstrated in
359 approximately one third of pediatric pilocytic astrocytomas
360 using fluorescent in situ hybridization (FISH) analysis
361 [173].
362 Individuals with neurofibromatosis type I (NF1) have an363 increased propensity to develop pilocytic astrocytomas,
364 especially of the optic/hypothalamic region. As sporadic
365 pilocytic astrocytomas occasionally show LOH on chro-
366 mosome 17q (the location of the NF1 tumor suppressor
367 gene), one would predict that mutations of the NF1 gene
368 with consequent loss of expression would be found in
369 sporadic pilocytic astrocytomas. In fact, this appears not to
370 be the case. In actuality, the expression of the NF1 tumor
371 suppressor gene in sporadic pilocytic astrocytomas is often
372 upregulated, perhaps as a reactive response to excessive
373 cellular proliferation [116, 175]. This is in contrast to
374 pilocytic astrocytomas arising in NF1 patients, where loss
375 of NF1 expression is an obligatory finding [54]. The precise
376 origin of the differing contribution of the NF1 gene product
377 in the setting of NF1 vs non-NF1 pilocytic astrocytomas
378 remains to be elucidated.
379 Even with the use of various sensitive p53 mutation
380 detection assays, it appears that p53 mutations are absent or
381 at most infrequently present in the setting of pediatric
382 pilocytic astrocytomas [23, 71, 174]. Such results are in
383 concordance with the low frequency of allelic loss detected
384 at the p53 locus on chromosome 17p [23, 71, 174]. Taken
385 together, these findings indicate that abnormalities of p53
386 do not contribute in any significant way to the genesis of
387 pilocytic astrocytomas.
388 Most cases of pediatric pilocytic astrocytoma show
389 immunopositivity for p16 and CDK4, indicating that
390 abnormalities in the pRb/cyclinD1/CDK4/p16 pathway
391 likely do not play an important role in the evolution of
392 these tumors [23]. PTEN mutations are also likely not a
393 significant contributor to the pathogenesis of these lesions
394 [23, 37], as mutations in this tumor suppressor gene tend to
395 be reserved for higher-grade tumors [123].
3Ependymoma
3Chromosomal 22 defects are frequently found in ependy-
3moma. Mutation of the NF-2 gene product on chromosome
322 has been documented to predispose to the formation of
4various tumor types, including ependymoma, especially in
4 patients with NF-2 [41]. However, the vast majority of
4sporadic (non-NF-2) cases lack mutations in the NF-2 gene.4The most plausible explanation for these findings is the
4existence of another oncogene or tumor suppressor gene on
4chromosome 22 that is more commonly involved in the
4genesis of sporadic ependymoma than the NF-2 gene
4product [166].
4Pediatric intracranial ependymomas appear to have a
4chromosomal signature distinct from their adult counter-
4 parts. Pediatric tumors, which often occur in the
4infratentorial compartment, display balanced CGH pro-
4files in 3050% of cases, in comparison to only 10% of
4adult tumors [38, 63]. This finding suggests that pediatric
4intracranial ependymomas may progress along substantially4different pathways than those giving rise to adult supra-
4tentorial or spinal ependymomas [161].
4Where chromosomal aberrations are observed in pediat-
4ric ependymomas, monosomy 17 appears to be one of the
4most common lesions, with an approximately 50% fre-
4quency [166]. The p53 tumor suppressor gene resides on
417p, and individual case reports have identified some
4instances of p53 mutation in ependymoma patients,
4including a family who had concurrent mutation in
4chromosome 22 [104].
4Gain of chromosome 1q is also a frequent finding in
4pediatric ependymoma [38]. A putative region of interest on
4chromosome 1q may be the region between 1q22 and 31
4[82]. Several studies have made an association between the
4 presence of 1q gain and a poor clinical course, suggesting
4that the presence of one or more genes located on 1q may
4 be responsible for tumor progression and/or response to
4therapy [38, 63].
4Loss of a region on 6q has been documented in a number
4of case reports; however, no known oncogene or tumor
4suppressor gene has yet been implicated at this locus [82,
4125, 131]. Other frequent chromosomal alterations include
4losses of chromosomes 1p, 6, 9q, 11, 13q, 16p, 16q, 19q,
420p, and 20q, and gains of 1q, 2, 5, 9, 12, 15, 18, 20q, and
4X [63, 163].
4Microarray experiments designed to document the gene
4expression profile of ependymomas have been performed.
4A recent examination of a panel of 12,627 genes identified
4a subset of 112 genes as being abnormally expressed in
4 pediatric ependymoma when compared with normal brain
4controls [147]. Genes with increased expression included
4the oncogene WNT5A, the p53 homologue p63, and
4several cell cycle, cell adhesion, and cell proliferation
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448 genes. Underexpressed genes included the NF2 interacting
449 gene SCHIP-1 and the adenomatous polyposis coli (APC)-
450 associated gene EB1 among others. These genes represent
451 candidate genes for further study; further validation work is
452 necessary in order to clarify their precise contribution to
453 ependymoma tumorigenesis.
454 Our understanding of the origins of ependymoma
455 increased dramatically with the recent publication of Taylor456 et al. in which histologically identical, but genetically
457 distinct, ependymomas showed patterns of gene expression
458 that recapitulate those of radial glia cells in corresponding
459 regions of the central nervous system [161]. In this study,
460 supratentorial, infratentorial, and intraspinal ependymomas
461 demonstrated distinct genetic signatures and were shown to
462 arise from restricted populations of radial glia stem cells.
463 For the supratentorial tumors, CDK4 and several Notch
464 signaling pathway genes were overexpressed; for the
465 infratentorial tumors, IFG-1 and several HOX homeobox
466 genes were overexpressed; and for the spinal tumors, the ID
467 genes and the aquaporins were overexpressed. The impli-468 cations of this study are that ependymomas should be
469 treated with therapies that target the cell signal pathways
470 that maintain subsets of ependymoma stem cells rather than
471 the histological or clinical forms of the disease [161].
472 Atypical teratoid rhabdoid tumor
473 Molecular studies have been able to distinguish CNS AT/
474 RT from the other primitive pediatric brain tumors,
475 establishing it as a unique pathological entity [133, 134].
476 AT/RT frequently demonstrates deletion of the long arm of
477 chromosome 22q11.2, and further molecular studies have
478 led to the identification of the INI1/hSNF5 tumor suppres-
479 sor gene at this location [1013]. A somatic mutation in this
480 gene predisposes children to develop AT/RT [1013]. The
481 hSNF5 protein is the smallest member of a highly
482 conserved family of proteins that function in chromatin
483 remodeling via the nucleosome. By winding and un-
484 winding DNA, this complex changes the configuration of
485 genomic DNA, thus allowing or denying transcription
486 factors access to the DNA, consequently changing patterns
487 of gene expression.
488 Some children with AT/RT are born with heterozygous
489 germ line mutations of the hSNF5 gene, suggesting that
490 these children were predisposed to develop AT/RT [155]; in
491 most cases, however, these germ line mutations arise de
492 novo.
493 Heterozygous mSNF5 +/ knockout mice develop
494 tumors resembling AT/RT, supporting the role of hSNF5 as
495 a tumor suppressor gene [130]. Although most AT/RTs
496 show evidence of some genetic derangement at the hSNF5
497 locus, mutational analysis of the hSNF5 gene in a series of
498 primitive neuroectodermal tumors/medulloblastomas dis-
4covered mutations in only 4 of 52 tumors [155]. Of those
5four, two were reclassified as AT/RT upon reexamination of
5the pathology, but there was insufficient clinical material to
5establish an accurate diagnosis in the other two cases. This
5suggests that tumors which are histologically diagnosed as
5 primitive neuroectodermal tumors/medulloblastomas but
5which also harbor hSNF5 mutations are most likely AT/
5RT. Although mutation/deletion of hSNF5 is not currently5sufficient for a diagnosis of AT/RT, it appears to be related
5to the clinical outcome; consequently, determination of the
5status of the AT/RT gene by DNA sequence analysis, FISH,
5or immunohistochemistry is rapidly becoming an integral
5 part of the neuropathological diagnosis of primitive
5pediatric malignant brain tumors (Fig. 2).
5Medulloblastoma
5Recent gene expression studies have shown that medullo-
5 blastoma is molecularly distinct from the supratentorial
5 primitive neuroectodermal tumors (sPNETs) [119]. The5Sonic Hedgehog (SHH), Wingless(WNT/WG), and
5receptor tyrosine kinase I family ERBB pathway are
5emerging as central developmental signaling pathway
5systems in the formation of medulloblastoma [17, 110].
5The specific contributions of these pathways to the genesis
5of medulloblastoma will be discussed in turn.
5Medulloblastoma has been reported in the setting of a
5number of different hereditary cancer syndromes, including
5nevoid basal cell carcinoma syndrome (NBCCS), Turcot
5syndrome, LiFraumeni syndrome and RubensteinTaybi
5syndrome [156]. In the mid-1990s, it was discovered that
5NBCCS arises from germ line mutations of PTCH1, which
Fig. 2 Pattern of INI-1 staining in AT/RTs of childhood. Immuno-
histochemical staining with an anti-INI-1 antibody fails to stain the
nuclei of tumor cells but does stain the nuclei of normal or reactive
tissues in the vicinity
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529 encodes the receptor for the Hedgehog (Hh) family of
530 signaling proteins. PTCH1 is a 12-pass transmembrane
531 receptor protein that represses activity of the Hh signaling
532 pathway in its unbound state by suppressing the activity of
533 the seven-pass transmembrane protein Smoothened(S-
534 MOH) [56, 74, 94]. Upon ligand binding, PTCH1s tonic
535 inhibition of SMOH is lifted, leading to the release of GLI
536 transcription factor from a tetra-protein complex which also537 includes suppressor of fused (SUFU), fused (FU), and
538 costal-2 (COS2). Upon its release, GLI is activated and
539 translocated to the nucleus where it binds to promoters in a
540 sequence-specific fashion to increase the transcription of
541 various growth-promoting genes such as cyclin D [94].
542 Mutations in the various molecules comprising this signal-
543 ing complex, including SHH, PTCH1, SMOH, and SUFU,
544 have been shown to occur in both familial and sporadic
545 tumors [43, 113, 126, 158]. Another recent report demon-
546 strated a crucial role for polycomb group gene Bmi1 in
547 clonal expansion of granule cell precursors in vivo and
548 linked overexpression of BMI1 and patched (PTCH), a549 finding that is suggestive of an alternative or additive
550 mechanism of SHH pathway activation in the pathogenesis
551 of medulloblastomas [84]. A novel putative tumor suppres-
552 sor, human REN(KCTD11), incidentally maps to 17p13.2,
553 a chromosomal region which is frequently lost in medul-
554 loblastoma [45]. The REN tumor suppressor inhibits
555 medulloblastoma growth by impairing both Gli2-dependent
556 gene transcription and SHH-enhanced expression of the
557 target Gli1 mRNA, thereby decreasing the expression of
558 downstream genes [34, 35].
559 Cyclopamine, a plant-derived teratogen that binds to
560 SMOH and interrupts its ability to activate downstream
561 signaling, may have some important therapeutic implica-
562 tions. Mice harboring human medulloblastoma explants
563 showed tumor regression upon drug administration. Less
564 toxic derivatives of cyclopamine are being used in
565 preclinical trials of medulloblastoma. Although this com-
566 pound will probably only be effective for patients with
567 NBCCS or those whose tumors harbor PTCH and SMOH
568 mutations, it carries great potential as a targeted molecular
569 therapy in such instances [9, 151].
570 Germ line mutations of APC in patients with Turcot
571 syndrome have been reported to increase the risk of
572 developing medulloblastomas [58]. The inactivation of the
573 APC gene leads to aberrant signaling in the WNT pathway,
574 resulting in the inability of the multiprotein complex
575 containing APC, axin, and glycogen synthase kinase-3
576 (GSK-3) to phosphorylate and cause degradation of -
577 catenin. This leads to an overabundance of -catenin and
578 its translocation to the nucleus where it activates the TCF/
579 LEF transcriptional complex. The -catenin/TCF dimer
580 activates the transcription of other growth-regulating genes,
581 some of which are known oncogenes (e.g., c-MYC and
5cyclin D) [42, 101, 150]. Mutations in WNT pathway
5members occur in about 15% of sporadic medulloblastoma
5[25, 66, 77, 181]. A recent report also demonstrated that
5mutations in SUFU can cause a decreased efficiency of-
5catenin nuclear export, thereby also resulting in increased
5-catenin/TCF signaling [160].
5The ERBB or epidermal growth factor family of receptor
5tyrosine kinases plays a crucial role in regulating cellular5 proliferation, apoptosis, migration, and differentiation.
5Activation of these receptors through ligand binding,
5dimerization, and autophosphorylation culminate in down-
5stream signaling through mitogen-activated protein kinase
5(MAPK), AKT, and STAT [107]. Interestingly, one of the
5four members of the ERBB family, ERBB2, has been
5shown to be highly expressed in medulloblastoma [52]. A
5high level of ERBB2 and ERBB4 coexpression signifies an
5increased risk of metastases and is associated with poor
5prognosis in cases of medulloblastoma [48, 50]. Microarray
6analysis of medulloblastoma cell lines demonstrate that
6S100A4, a prometastatic gene known to be linked to breast6and bladder cancers, is a direct target of ERBB2 signaling
6in medulloblastoma cells via the AKT/PI3K pathway [61].
6Compounds such as OSI-774 (erlotinib, also known as
6gefitinif) inhibit ERBB2 signaling in human medulloblas-
6toma cells and may have therapeutic potential [61].
6The PDGFR and downstream activation of the RAS/
6MAPK signaling pathway (including MAP2K1, MAP2K2,
6and MAPK1/3) have also been uncovered as potential
6mediators of medulloblastoma metastasis [33, 51, 92].
6The mRNA expression level of TrkC, a neurotrophin
6signaling receptor, was identified as a positive prognostic
6factor for progression-free and overall survival in medul-
6loblastoma [53, 124]. The MYC protooncogenes (MYCN
6and MYCC) are amplified and/or overexpressed in a
6subset of large cell medulloblastomas and also correlate
6with poor clinical outcome [39, 40]. However, other
6studies of TrkC, MYCC, and MYCN mRNA expression
6or immunoreactivity did not demonstrate a significant
6 prognostic effect [48, 80].
6Loss of chromosome 17p, often through the formation of
6an isochromosome 17q i(17)(q10), is the most common
6chromosome aberration in childhood medulloblastoma,
6occurring in about 25% to 35% of cases. Either isolated
617p deletion or i(17)(q10) has been reported as a significant
6negative prognostic factor [50, 109]. Recent cytogenetic
6analysis using matrix CGH suggested that overexpression
6of CDK6 correlates with a worse prognosis [99].
6Most of the tumor suppressor genes shown to play a role
6in the formation of medulloblastoma have been identified
6through mutations; however, other epigenetic phenomena
6may lead to their decreased expression. Aberrant methyla-
6tion of CpG islands located in promoter regions represents
6one of the major mechanisms for silencing of cancer-related
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635 genes in tumor cells. Extensive hypermethylation of the
636 RASSF1A gene (ras-association domain family protein 1,
637 isoform A), an identified tumor suppressor gene located at
638 chromosome 3p21.3, occurs in about 80% of primary
639 medulloblastomas [86, 91]. Furthermore, complete methyl-
640 ation of the putative tumor suppressor HIC-1 (hyper-
641 methylated in cancer) and the apoptosis effector molecule
642 caspsase-8 has been found in a subset of medulloblastoma643 [132, 168, 182].
644 Germ cell tumors
645 Although the exact molecular and cytogenetic aberrations
646 in GCTs are still not well defined, the most consistent
647 cytogenetic abnormality observed in such tumors is
648 isochromosome 12p (i12p) [26, 31, 89]. Some tumors
649 without i12p have overrepresentation of 12p by other
650 mechanisms, such as duplication of the entire chromosome.
651 The exact role of genes implicated in 12p overrepresenta-652 tion in GCTs remains uncertain, but evidence suggests that
653 the genes located on this chromosome, such as cyclin D2,
654 may play a role in facilitating entry into S phase of the cell
655 cycle. The rather frequent finding of i12p is also highly
656 indicative of the existence of novel putative oncogenes on
657 12p which may be involved in the pathogenesis of GCTs.
658 Other chromosomal aberrations have also been observed
659 in pineal GCTs. In a study of 15 pineal region GCTs,
660 Rickert et al. reported that the most common chromosomal
661 imbalances in pineal germinomas were losses of 13q and
662 18q, and loss of chromosomes 4 and 5 [128]. Interestingly,
663 these authors infrequently found gain of 12p. A summary
664 of other reported genetic aberrations in these tumors can be
665 found in a recent review by Taylor et al. [157].
666 Although most GCTs are sporadic, a few genetic
667 syndromes do predispose individuals to their development.
668 Pineal germinomas or teratomas in patients with Klinefelter
669 syndrome have been reported [120]. That patients with
670 Klinefelter syndrome generally have increased risk of
671 developing malignancy is in keeping with the idea of the
672 existence of a putative oncogene on the X chromosome.
673 Patients with trisomy 21 have an increased risk of a number
674 of cancers including leukemia and gonadal and extragona-
675 dal GCTs [139].
676 Ewing sarcoma
677 Primary Ewing sarcoma (ES)/peripheral primitive neuro-
678 ectodermal tumors (pPNET) of the central nervous system
679 constitute a clinically important, albeit rare, subset of
680 pediatric soft tissue tumors. They typically arise extracra-
681 nially or paraspinally and often result in secondary invasion
682 of critical neural structures [18].
6In recent years, an examination of the genetic alterations
6 present within the spectrum of pediatric soft tissue tumors
6has demonstrated a fairly specific (although not absolute)
6association between specific nonrandom reciprocal chro-
6mosomal translocations and individual soft tissue tumor
6types [20]. Ongoing study of these fusion products has
6yielded profound insights into the biology of these tumors
6and may hold great promise for novel diagnostic and6therapeutic applications.
6Ewing sarcoma/pPNET-associated translocations charac-
6teristically involve the EWS gene on 22q12 and various
6members of the ETS family of protooncogenes (Fig. 3).
6Approximately 85% of ES/pPNET tumors harbor the
6translocation t(11;22)(q24;q12); in this subset of tumors,
6the translocation partner for EWS is the FLI1 gene product
6found on 11q24 [32]. In nearly 10% of cases, the
6translocation partner is ERG [t(21;22)(q22;q12)] [144],
7and in rare cases, EWS may be fused to the ETS domains
7of ETV-1 [t(7;22)(p22;q12)] [73], E1AF [t(17;22)(q12;
7q12)] [76], or FEV [t(2;22)(q33;q12)] [111].7The EWS gene product is a member of a growing family
7of highly conserved RNA-binding proteins [105]. Although
7the exact biological function of wild-type EWS and its
7homologues remains largely unknown, a growing body of
7evidence suggests that they are involved in mRNA
7transcription. EWS has been shown to form an adaptor
7ternary complex with RNA polymerase II and other
7heterogeneous RNA-binding proteins [112]; these findings
7are highly suggestive of an important role of EWS in basic
7transcriptional regulation.
7ETS-domain-containing proteins are DNA-binding tran-
7scription factors that are implicated in the control of cellular
7 proliferation. ETS family members appear to cooperate
7with other nuclear proteins to help establish promoter
7specificity, modulate transcriptional regulation, and facili-
7tate linkage to various signal transduction pathways,
7including RAS [36, 64, 143, 172].
7The ES/pPNET-associated translocations result in chi-
7meric proteins containing the N-terminal domain of EWS
7fused to the site-specific nucleic acid binding domain of the
7ETS transcription factor translocation partner (Fig. 3). This
7structure suggests that the chimeric protein is directed at the
7 promoter region of specific genes recognized by the
7translocated DNA-binding domain of the ETS member [5,
7106]. However, the ultimate targets of the EWS-ETS
7chimeric protein may not be solely dependent on the ETS
7domain; rather, other proteinprotein interactions unique to
7the chimeric molecule may be at play [98]. The actual
7target genes contributing to tumorigenesis are not known,
7but analysis of mRNAs differentially expressed in cell lines
7stably transfected with the EWS-FLI1 fusion has produced
7some interesting candidates, including manic fringe, c-myc,
7cyclin D1, mE2-C, MMP-1, and TGF-RIII [4, 6, 14].
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736 The fairly consistent presence of these recombinant gene
737 products in ES/pPNET suggests that they play a critical role
738 in the underlying biology of these tumors (Fig. 3). Trans-739 fection of EWS-FLI1 or EWS-ERG can transform mouse
740 NIH-3T3 cells if both the EWS and ETS domains are
741 functionally intact [98]. EWS-FLI1 antisense RNA trans-
742 fected into ES/pPNET cells results in marked growth
743 inhibition, suggesting that the EWS-ETS gene rearrange-
744 ment may also be necessary for maintaining the malignant
745 phenotype of ES/pPNET cell lines [153]. Furthermore,
746 expression of EWS-ETS fusion constructs may contribute
747 to tumorigenesis via inhibition of apoptosis; not surprisingly,
748 antisense inhibition of EWS-ETS fusion genes may enhance
749 susceptibility to chemotherapy-induced apoptosis [177].
750 The gene fusions characteristic of ES/pPNET exhibit an751 underlying molecular heterogeneity. There are two under-
752 lying sources of variability: the specific ETS fusion partner
753 and the breakpoint location within the genes. A better
754 outcome for patients with localized tumors expressing the
755 most common chimeric transcript (type I: EWS exon 7
756 fused to FLI1 exon 6) compared with the next most
757 common fusion types (type II: EWS exon 7 fused to FLI1
758 exon 5 or type III: EWS exon 10 fused to FLI1 exon 6) has
759 been reported, raising the possibility that heterogeneity in
7chimeric transcripts may reliably define clinically distinct
7risk groups [30, 85]. Preliminary work suggests that the
7better outcome associated with type I fusion transcripts may7be related to the weaker transcriptional activation properties
7of the type I transcript [30].
7Other less common numerical and structural chromo-
7somal aberrations may also be found in ES/pPNET [3, 15,
797, 102, 108, 154]. The most common numerical abnor-
7malities are +1q, +8, +12, and +20, and 1p, 16q, and
719q. More complex, multichromosome translocations,
7such as t(11;14;22)(q24;q11;q12) and t(10;11;22)(p11.2;
7q24;q12), may also occur and generally portend a poor
7prognosis.
7Changes in known tumor suppressor genes may be
7observed in some cases. Homozygous deletion of7CDKN2A (p14ARF) on 9p21 has been described in
7approximately 30% of cases [81]. Although mutations in
7p53 have been described in up to 50% of ES/pPNET cell
7lines [57], this appears to be a rare event in primary tumors
7[167]. Amplification of the MDM2 gene, an inactivator of
7 p53, is also rare in ES/pPNET, consistent with the
7hypothesis that p53 and regulators of its activity may not
7 play a dominant role in the pathogenesis of ES/pPNET
7[93].
Fig. 3 Schematic representation
of the two commonest fusion
genes in Ewing sarcoma and the
proposed effects of the onco-
genic chimeric protein on cellu-
lar proliferation and
tumorigenicity
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784 Conclusions
785 As is evident from this review, our understanding of the
786 fundamental mechanisms of brain tumorigenesis in children
787 has increased markedly over the past 2 decades. The pace
788 of subsequent advances will only quicken, owing to such
789 monumental technical feats as the sequencing of the human
790 genome. Concomitant developments in the field of bio-791 informatics will be equally important as they will allow us
792 to make sense of the volumes of data that will undoubtedly
793 emerge from the ongoing interrogation of the fundamental
794 molecular processes at work in the genesis of pediatric
795 brain tumors. The challenge for the next 2 decades will be
796 to consolidate our understanding of the molecular patho-
797 genesis of childhood brain tumors and to apply this
798 sophisticated knowledge toward the development of clini-
799 cally useful treatment strategies.
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