Primary anaplastic pilocytic astrocytoma

We report two adult patients with pilocytic astrocytomas with anaplastic features at initial diagnosis. Pilocytic astrocytomas are low-grade astrocytomas that occur rarely in adults. Initial presentation of a pilocytic astrocytoma with anaplastic features is particularly uncommon and making a definitive diagnosis of pilocytic astrocytoma with anaplastic features can be challenging. It is critical to differentiate glioblastoma (World Health Organization [WHO] grade 4) and pilocytic astrocytoma with anaplastic features (WHO grade 3) from pilocytic astrocytoma (WHO grade 1) as there are significant therapeutic and prognostic implications. Improved therapeutic strategies are required for pilocytic astrocytomas with anaplastic features.     

Low-grade gliomas -- current concepts

Diffuse astrocytomas, oligodendrogliomas, and oligoastrocytomas (mixed gliomas) WHO grade II, pleomorphic xanthoastrocytomas (PXAs), pilocytic astrocytomas, and subependymal giant cell astrocytomas (SEGAs) are often referred to as low-grade gliomas. WHO grade II astrocytomas, oligodendrogliomas, and mixed gliomas are characterized by their infiltrative growth, frequent tumor recurrence and a more than 50 % risk for malignant progression. In contrast, pilocytic astrocytomas and SEGAs are circumscribed tumors amenable to a (radio)surgical cure. There are few universally accepted guidelines for the treatment of low-grade gliomas. In this review, three neurosurgeons, a neurologist, a neuropathologist, and a radiation oncologist discuss some of the difficult issues surrounding the diagnosis and treatment of low-grade gliomas from their individual points of view (i. e., classification and neuropathology, MR imaging, stereotactic biopsy, microsurgery, interstitial radiotherapy/brachytherapy, radiotherapy, wait and see strategy).     

J1‐31 protein expression in astrocytes and astrocytomas

J1‐31 is one of the astrocytic proteins, the expression of which has not been evaluated in astrocytomas. In the present study, we studied the expression of J1‐31 protein in astrocytes and astrocytomas in comparison with GFAP, p53 and Ki‐67. Materials consisted of formalin‐fixed paraffin‐embedded tissue specimens that included five cases of normal brain, 17 of gliosis, 15 of pilocytic astrocytoma (WHO grade I), 26 of low‐grade diffuse astrocytoma (WHO grade II), four of anaplastic astrocytoma (WHO grade III), and eight of glioblastoma (WHO grade IV). GFAP was highly expressed in all specimens examined. The anti‐J1‐31 antibody exhibited strong cytoplasmic staining of reactive gliosis in 17/17 (100%) cases with a higher intensity of staining than that observed in the adjacent normal astrocytes. The antibody showed reactivity with tumor cells in 12/15 (80%) cases of pilocytic astrocytoma, although intensity of staining was generally weaker and more focal than observed in reactive gliosis. J1‐31‐positive tumor cells were detected in only 9/26 (35%) cases of the low‐grade diffuse astrocytoma and none of the cases of anaplastic astrocytoma and glioblastoma. Increasing Ki‐67 indices paralleled advancing tumor grades. p53 protein was expressed more commonly in infiltrating astrocytomas compared to pilocytic astrocytoma. In conclusion, down‐regulation of J1‐31 expression correlates with advancing grade of astrocytomas. The result suggests this protein plays some role in astrocytes that is progressively lost in malignant progression. The anti‐J1‐31 antibody may help further our understanding of astrocytes in disease and may be useful as an aid in the pathologic diagnosis of astrocytic lesions.     

Increased microglia proliferation separates pilocytic astrocytomas from diffuse astrocytomas: a double labeling study

It is not known how many non-tumorous cells in gliomas contribute to the proliferation rate. We investigated the proliferative activity of microglia in an immunohistochemical double-labeling study of pilocytic astrocytomas and astrocytomas WHO grade II-IV using the antibodies MIB-1 (Ki67) as proliferation-marker and Ki-M1P (CD68) as microglia marker. We found the highest indices of proliferating microglia in pilocytic astrocytomas with an average rate of 32% (+/- 6.8) of all proliferating cells. In contrast, the proliferation indices of microglia were lowest in fibrillary astrocytomas with 8.6% (+/- 2.5) of all proliferating cells. In anaplastic astrocytomas and glioblastomas the percentage of proliferating microglia showed a slight increase to 8.8% (+/- 3.6) and 13.4% (+/- 8.7), respectively. We conclude that microglial cells in astrocytic brain tumors proliferate and show different proliferative activities at different grades of malignancy with the highest rates of proliferating microglia especially in pilocytic astrocytomas. Thus, the proliferation rate does not solely reflect the proliferation of tumor cells, but also of non-tumorous cells. This should be considered in particular when proliferation rates are used as a criterion for prognosis and grading of pilocytic astrocytomas.     

Altered expression of immune defense genes in pilocytic astrocytomas

Pilocytic astrocytoma (WHO grade I) is a circumscribed, slowly growing, benign astrocytoma that most frequently develops in the cerebellar hemispheres and in midline structures and occurs predominantly in childhood and adolescence. In contrast to diffusely infiltrating gliomas in adults (e.g. grade II astrocytomas, oligodendrogliomas), survival of patients with pilocytic astrocytoma is excellent after surgical intervention. To search for potential molecular mechanisms underlying its benign biologic behavior, we compared gene expression profiles of pilocytic astrocytomas (8 cases) with those of normal cerebellum (4 cases), low-grade astrocytomas (WHO grade II; 15 cases), and oligodendrogliomas (WHO grade II; 17 cases) by cDNA array analysis. A number of immune system-related genes such as HLA-DRalpha, HLA-DPB1, HLA-DQB1, IgG3, IgGK, FCER1G, A2M, FCRN, IFI-56K, and DAP12 were upregulated in pilocytic astrocytomas relative to normal cerebellum, grade II astrocytomas, and oligodendrogliomas. Genes expressed at higher levels in pilocytic astrocytomas than in grade II astrocytomas and oligodendrogliomas include HLA-DRalpha, HLA-DPA1, HLA-DPB1, HLA-DQB1, A2M, TIMP1, TIMP2, CDKN1A, and SOCS3 and those expressed at lower levels include EGFR and PDGFRA. Hierarchical clustering analysis using the entire set of 1176 genes distinguished pilocytic astrocytomas from grade II astrocytomas and oligodendrogliomas. Clustering analysis using selected subgroups of genes based on their molecular functions revealed that immune system-related genes (75 genes) or cell adhesion, migration, and angiogenesis-related genes (69 genes) showed similar power to the entire gene set for separation of pilocytic astrocytomas from diffusely infiltrating low-grade gliomas. Immunohistochemistry revealed that HLA-DRalpha is expressed diffusely in neoplastic cells in pilocytic astrocytomas, whereas in oligodendrogliomas, expression was limited to scattered reactive astrocytes. These results suggest that gene expression profiles of pilocytic astrocytomas differ significantly from those of diffusely infiltrating low-grade gliomas and that their benign biologic behavior may be related to upregulation of immune defense-associated genes.     

Loss of heterozygosity for alleles on chromosome 10 in human brain tumours

Abstract

We analysed for loss of alleles on chromosome 10, 25 astrocytomas, 3 ependymomas, 2 medulloblastomas, 2 juvenile pilocytic astrocytomas, 2 gangliogliomas, 1 subependymal giant cell astrocytoma and 1 anaplastic oligoastrocytoma. A battery of 12 DNA markers spanning chromosome 10 was employed. Loss of heterozygosity on chromosome 10 was seen in 16 tumours (13 glioblastoma multiforme, 2 anaplastic astrocytomas; and 1 anaplastic oligoastrocytoma), but not in any of the low-grade astrocytomas examined. High-resolution restriction fragment length polymorphism (RFLP) analysis showed that the loss of alleles in a number of tumours involved two separate large regions of chromosome 10 (10p-proximal 10q and distal 10q). However, a small common region of deletion overlap could not be identified. Our data indicate that the loss of alleles on chromosome 10 is a common finding, seen in over two-thirds of malignant astrocytomas, and may be suggestive of the presence of two or more chromosome 10 tumour suppressor genes involved in astrocytoma formation. Nevertheless, the possibility of these genetic changes being secondary and not causative of the deregulated cell growth cannot be excluded. Regardless of the mechanisms involved, however, chromosome 10deletions may be a genetic marker for malignant astrocytomas. [Neurol Res 1993; 15: 59-67]     

Molecular genetic alterations in pleomorphic xanthoastrocytoma

Pleomorphic xanthoastrocytoma (PXA) is a low-grade glioma that may recur as a malignant diffuse astrocytoma such as glioblastoma (GBM). While the molecular genetic basis of diffuse astrocytomas has been studied extensively, PXAs have not been analyzed in detail. We, therefore analyzed DNA from archival primary and recurrent PXAs from eight patients (three grade II PXAs without recurrence, one grade II PXA with recurrence as grade II PXA, two grade II PXAs with progression to GBM, and two grade III anaplastic PXAs with recurrence as grade III anaplastic PXA or GBM) for genetic changes associated with diffuse astrocytomas. Single-strand conformation polymorphism analysis of p53 exons 5–8 revealed migration shifts in two cases, one primary PXA without recurrence and one recurrent grade II PXA in which the primary tumor did not show a shift. DNA sequencing showed two missense mutations in codons 220 (exon 6) and 292 (exon 8), respectively, mutations which have not been previously noted in astrocytomas. Differential polymerase chain reaction analysis demonstrated epidermal growth factor receptor gene amplification in only one tumor, a GBM without allelic loss of chromosome 10 that was the second GBM recurrence of an initial grade II PXA. Loss of heterozygosity studies on tumors from five patients, using three microsatellite polymorphisms on chromosome 10q and three on chromosome 19q, did not disclose allelic loss in any recurrent tumor. These findings suggest that the genetic events that underlie PXA formation and progression may differ significantly from those involved in diffuse astrocytoma tumorigenesis. Received: 18 July 1995 / Revised, accepted: 15 September 1995     

Multiple cystic brain lesions in a patient with pilocytic astrocytoma.

Pilocytic astrocytomas are usually present as solitary posterior cranial fossa tumours. An unusual case of pilocytic astrocytoma in a 3 year and 8 month old boy is presented. The patient presented over the course of 10 months with intermittent headaches, vomiting, gait ataxia and drowsiness. After extensive investigations magnetic resonance imaging (MRI) revealed widespread lesions throughout the central nervous system, including multiple cystic cerebral grey matter lesions. A brain biopsy was performed and pathological studies revealed pilocytic astrocytoma. The literature pertaining to neuraxis dissemination of pilocytic astrocytomas in the paediatric population is reviewed. There are only a very limited number of reports of pilocytic astrocytoma ca using multiple brain lesions, with no publications of multiple cystic brain lesions. We believe this to be a unique case of pilocytic astrocytoma presenting with widespread cystic lesions throughout the brain.     

Characterisation of molecular alterations in microdissected archival gliomas

Classification of gliomas according to their molecular characteristics may be important in future histopathological diagnosis. However, gliomas frequently display heterogeneity at the histological, biological and molecular level. In this study of archival diagnostic gliomas, precision microdissection was used to enrich samples in the most malignant cells or to investigate intratumoural histological heterogeneity. Analysis of tumour samples microdissected from the most aggressive regions, representative of the histopathological diagnosis, revealed PTEN mutations in 4/14 anaplastic astrocytomas, 4/13 glioblastomas and 1 gliosarcoma, but not in 19 low-grade gliomas. Using a novel PCR procedure and direct sequence analysis of the entire coding sequence, TP53 mutations were detected in 1/3 pilocytic astrocytomas, 3/13 astrocytomas, 4/14 anaplastic astrocytomas, 5/13 glioblastomas and 1 gliosarcoma. All but one of the tumours with TP53 mutation showed p53 immunopositivity, but 5 low-grade and 10 high-grade gliomas had p53 protein nuclear accumulation in the absence of detectable mutation. p53 status was unrelated to p21 expression. Neither PTEN nor TP53 mutations influenced the proliferative index or microvessel density of high-grade astrocytomas. Unusual findings include: TP53 mutation in a juvenile pilocytic astrocytoma; TP53 and PTEN mutations in a de novo glioblastoma, a gliosarcoma with identical mutations in gliomatous and sarcomatous components, and an infratentorial anaplastic astrocytoma with an earlier supratentorial grade II astrocytoma bearing the same TP53 mutation but not the PTEN mutation or loss of heterozygosity (LOH) of 10q23. Similarly, the transition to high-grade histology was associated with acquisition of PTEN mutations and 10q23.3 LOH in two de novo high-grade tumours with regions of low-grade histology.     

Immunohistochemical analysis of cyclin A in astrocytic tumours

Cyclins are important regulators of the cell cycle; there is increasing evidence that some cyclins are positively involved in carcinogenesis. Amplification and translocation of the cyclin genes and overexpression of their mRNAs and proteins have been observed in a variety of tumours. We studied cyclin A protein in astrocytic tumours by immunohistochemical analysis. Immunohistochemistry with microwave antigen retrieval was carried out on formalin fixed, paraffin embedded material from 15 glioblastomas (WHO grade IV), 10 anaplastic astrocytomas (WHO grade III), seven diffuse low grade astrocytomas (WHO grade II) and nine pilocytic astrocytomas (WHO grade I) using antibodies against cyclin A and a proliferation marker MIB1. Staining for these antibodies was seen mainly in the tumour cell nuclei; 66% of all cases showing staining for cyclin A and 95% of all cases staining for MIB1. Mean labelling indices (LI) for cyclin A were higher in glioblastoma (mean LI-6.7) and anaplastic astrocytoma (mean LI-5.9) than low grade diffuse astrocytoma (mean LI-1.7) and pilocytic astrocytoma (mean LI −0.12), although there was no clear cut off point between the various tumour types. A good correlation was seen between labelling indices of cyclin A and MIB1 (Pearson correlation coefficient r =0.59, P <0.0001). Cyclin A is variably expressed in astrocytic tumours, either reflecting increased tumour proliferation (cyclin A being an integral component of the cell cycle), an alteration of its gene, protein upregulation or regulation of apoptosis. The genetic basis of expression of cyclin A in astrocytic tumours remains to be determined.     

Combined molecular analysis of BRAF and IDH1 distinguishes pilocytic astrocytoma from diffuse astrocytoma

Separation of pilocytic astrocytoma from diffuse astrocytomas frequently poses problems mostly related to small sample size. Precise classification and grading are essential due to different therapeutic strategies prompted by diagnoses of pilocytic astrocytoma WHO grade I, diffuse astrocytomas WHO grade II or anaplastic astrocytoma WHO grade III. Recently, genomic aberrations with a high specificity for distinct glioma entities have been described. Pilocytic astrocytomas carry a duplication at chromosome band 7q34 containing a BRAF–KIAA1549 gene fusion in the majority of cases. IDH1 mutations are observed very frequently in adult astrocytomas and IDH2 mutations have been reported in some astrocytomas. We examined a series of 120 astrocytomas including 70 pilocytic astrocytomas WHO grade I and 50 diffuse astrocytomas WHO grade II for both, BRAF–KIAA1549 fusion with a newly developed FISH assay and mutations in IDH1 and IDH2 by direct sequencing. Pilocytic astrocytomas contained the BRAF fusion in 49 cases (70%) but neither IDH1 nor IDH2 mutations. Astrocytomas WHO grade II exhibited IDH1 mutations in 38 cases (76%) but neither IDH2 mutations nor BRAF fusions. Thus, combined molecular analysis of BRAF and IDH1 is a sensitive and highly specific approach to separate pilocytic astrocytoma from diffuse astrocytoma.     

An isomorphic subtype of long-term epilepsy-associated astrocytomas associated with benign prognosis

The semi-benign nature of diffuse astrocytomas is characterized by an increased risk for tumor recurrence and malignant transformation. In patients with intractable seizures, however, length of history and clinical follow-up studies indicate a better prognosis of this tumor entity. Here, we present a clinico-neuropathological study of 19 patients with chronic seizures and diffuse astrocytomas. In 6 patients, long-term survival and lack of tumor progression after a maximal follow-up time of 13 years appeared to correlate with a histologically isomorphic phenotype. Cytological hallmarks comprise low cellularity, lack of mitotic activity and highly differentiated astroglial elements infiltrating into adjacent brain parenchyma. Compared to classical variants of diffuse astrocytomas (WHO grade II), immunohistochemical reactions revealed a cellular proliferation below 1%, absence of nuclear p53 accumulation, and a lack of glial MAP2 and CD34 expression. Histopathologically, the isomorphic astrocytoma subtype can be distinguished from gangliogliomas, pilocytic astrocytomas and dysembryoplastic neuroepithelial tumors as well as from cortical dysplasia or reactive gliosis. Our data support the concept of a rare variant of diffuse astrocytomas occurring in young adults with long-term epilepsy and a favorable prognosis, which corresponds to WHO grade I.The first two authors contributed equally to this work     

Increased expression of podoplanin in malignant astrocytic tumors as a novel molecular marker of malignant progression

Podoplanin (aggrus) is a mucin-like transmembrane sialoglycoprotein that is expressed on lymphatic endothelial cells. Podoplanin is putatively involved in cancer cell migration, invasion, metastasis, and malignant progression and may be involved in platelet aggregation. Previously, we showed upregulated expression of podoplanin in central nervous system (CNS) germinomas, but not in non-germinomatous germ cell tumors, except for parts of immature teratomas in limited numbers. However, little information exists about its role in CNS astrocytic tumors. In this study, 188 astrocytic tumors (30 diffuse astrocytomas, 43 anaplastic astrocytomas, and 115 glioblastomas) were investigated using immunohistochemistry with an anti-podoplanin antibody, YM-1. In 11 of 43 anaplastic astrocytomas (25.6%) and in 54 of 115 glioblastomas (47.0%), podoplanin was expressed on the surface of anaplastic astrocytoma cells and glioblastoma cells, especially around necrotic areas and proliferating endothelial cells. However, the surrounding brain parenchyma was not stained by YM-1. On the other hand, podoplanin expression was not observed in diffuse astrocytoma (0/30: 0%). Furthermore, we investigated the expression of podoplanin using quantitative real-time PCR and Western blot analysis in 54 frozen astrocytic tumors (6 diffuse astrocytomas, 14 anaplastic astrocytomas, and 34 glioblastomas). Podoplanin mRNA and protein expression were markedly higher in glioblastomas than in anaplastic astrocytomas. These data suggest that podoplanin expression might be associated with malignancy of astrocytic tumors.     

A biphasic tumor consisting of pilocytic astrocytoma with an anaplastic solitary fibrous tumor component in the pineal region: A case report and literature review

Here we report a case of a biphasic tumor consisting of pilocytic astrocytoma with anaplastic solitary fibrous tumor component in the pineal region. The majority of the tumor showed typical histologic features of pilocytic astrocytoma. A minor part of the tumor showed marked proliferation of short spindle cells around vessels. These spindle cells showed CD34 and CD99 immunoreactivity. From a review of the literature, we found that only one similar case has been reported. Contrary to the reported case, our case showed anaplastic features of solitary fibrous tumor histology.     

Radiologically typical pilocytic astrocytoma with histopathological signs of atypia

Pilocytic astrocytoma (PCA) is the most common CNS tumor in primary school-aged children. Herein, we report the case of a 7-month-old female child with a large cerebellar hypodense tumor on computer tomography occupying nearly the whole cerebellar hemisphere. Magnetic resonance imaging revealed characteristic features of a PCA, depicting a mass with hyperintense solid and cystic areas on T2-weighted images and with marked solid and ring-like enhancement pattern. Histopathological and immunohistochemical analysis showed partially typical features of a PCA, but also atypical features such as a high proliferation rate, hypercellularity, and focally diffuse infiltration pattern were present. However, definite signs of transformation to an anaplastic PCA were not observed. We therefore classified the tumor as pilocytic astrocytoma with signs of atypia instead of simple WHO grade I pilocytic astrocytoma. The case illustrates that neuroimaging features may give very important clues for the definite diagnosis in histopathologically atypical PCA.     

Analysis of p53 mutation and expression in pleomorphic xanthoastrocytoma

Pleomorphic xanthoastrocytoma (PXA) is a rare, superficially situated tumor that most frequently occurs in the temporal lobe of young adults and is often associated with seizures. It generally has a relatively favorable prognosis. Prior studies have shown that TP53 mutations may occur in up to 25% of PXAs, suggesting that PXA may have an etiology similar to diffuse astrocytoma rather than pilocytic astrocytoma. In the present study, we performed immunostaining for p53 protein and examined the mutation status of exons 5–8 of the p53 gene in 55 PXAs, 8 of which had undergone one or multiple recurrences. Of 55 primary PXAs, 35 (64%) showed staining in <1% of tumor cells, 15 (27%) in 1–10%, 4 (7%) in 11–50%, and only 1 (2%) in >50%. No significant increase in p53 protein expression was noted in recurrences, even when associated with increased histological anaplasia. We found a TP53 heterozygous mutation in exon 7 in 1 of 47 primary tumors that yielded useable DNA, and in its recurrence 3 years later. This tumor, a grade II PXA, did not show signs of anaplastic transformation at recurrence. Eleven additional recurrences from 7 patients, 5 of which showed signs of histological anaplasia, did not show TP53 mutations in exons 5–8. Based on our data, the p53 mutation appears to be an uncommon (2%) genetic event in PXA formation and does not appear to be involved in tumor progression. Consequently, our findings suggest that the genetic events that underlie PXA formation differ from those involved in diffuse astrocytoma. Electronic Publication     

Loss of neurofibromatosis 1 (NF1) gene expression in NF1-associated pilocytic astrocytomas

The critical role of the neurofibromatosis 1 (NF1) gene as a tumour suppressor has been clearly demonstrated for malignancies arising in NF1 patients. However, little is known about the more common benign tumours, such as the pilocytic astrocytoma. Most NF1-associated astrocytomas are benign and clinically non-progressive, though aggressive tumours are occasionally encountered. In this study, eight pilocytic astrocytomas from six individuals affected with NF1 were analysed for NF1 expression. All eight tumours demonstrated loss of neurofibromin expression by immunohistochemistry, which was confirmed in one case using Western blot analysis. Microsatellite analysis showed loss of a single NF1 allele (LOH) in two of four NF1-associated tumours. These results demonstrate that, in contrast to sporadic astrocytomas, loss of NF1 expression is an important primary genetic event in the pathogenesis of NF1-associated pilocytic astrocytomas.     

MRI评分在星形细胞起源肿瘤诊断中的应用

目的观察星形细胞起源肿瘤患者的MRI表现,探讨MRI评分与病理学分级之间的相关性。方法选择经手术病理证实的幕上星形细胞起源肿瘤患者44例,其中星形细胞瘤9例、间变性星形细胞瘤14例及多形性胶质母细胞瘤21例,手术后进行MRI评分。评分标准包括肿瘤是否越过中线、有无水肿、不均质性、出血、边界清晰、囊变或坏死、血管流空效应、强化程度和强化的不均质性等9项指标。结果MRI评分随肿瘤病理分级的提高而增加,星形细胞瘤患者的不均质性、水肿、边界清晰、血管流空效应、强化程度和强化的不均质性等6项指标均低于间变性星形细胞瘤和多形性胶质母细胞瘤,其差异具有显著性意义(均P<0.05);而间变性星形细胞瘤与多形性胶质母细胞瘤之间9项指标相比,仅不均质性和强化程度2项差异有显著性意义(P<0.05)。结论MRI评分对选择星形细胞起源肿瘤的治疗方法及判断患者预后具有重要临床参考价值。