Genetic analysis of mediastinal nonseminomatous germ cell tumors in children and adolescents

Primary mediastinal germ cell tumors (M-GCTs) represent a heterogeneous group of tumors that varies with regard to age at presentation, histologic differentiation, and outcome. We retrospectively analyzed archival tissue samples of mediastinal mature and immature teratomas (n = 15) and malignant nonseminomatous M-GCTs (n = 20) with comparative genomic hybridization (CGH). The aim of this study was to define distinct genetic subgroups of M-GCT among the pediatric cohort that may differ in their clinical behavior and prognosis. All pure teratomas showed normal CGH profiles. Malignant M-GCTs in infants and children < 8 years old most frequently showed a gain of 1q, 3, and 20q and a loss of 1p, 4q, and 6q. Gain of 12p and sex chromosomal abnormalities were not observed in this age group. In contrast, the gain of 12p was the most common aberration in M-GCTs that arose in children > or = 8 years old. Additional recurrent changes included the loss of chromosome 13 and the gain of chromosome 21. All ten adolescents with malignant M-GCT were male, and five showed a gain of the X chromosome. In two of these five patients, Klinefelter syndrome was confirmed by cytogenetic analysis or by fluorescence in situ hybridization (FISH). In conclusion, CGH analysis of M-GCTs defines distinct genetic subgroups. Mediastinal teratomas show no genetic gains or losses. Malignant M-GCTs in children < 8 years old show the same pattern of gains and losses identified in sacrococcygeal and testicular GCTs at this age, and they lack sex-chromosomal abnormalities. Malignant M-GCTs in children > or = 8 years old show the same genetic profile previously reported in gonadal GCTs at this age. In addition, approximately 50% demonstrate a gain of the X chromosome, consistent with Klinefelter syndrome. Cooperative group studies reveal a significantly better prognosis of malignant M-GCT arising in infants compared to that in adolescents, suggesting that these genetic differences are associated with differences in clinical behavior.     

Cytogenetic and molecular analysis of human male germ cell tumors: chromosome 12 abnormalities and gene amplification

We report karyotypic analysis of 24 male germ cell tumors (GCTs) with clonally abnormal karyotypes biopsied from testicular and extragonadal lesions from 20 patients belonging to the histologic categories seminoma, teratoma, embryonal carcinoma, choriocarcinoma, and endodermal sinus tumor. Chromosomes 1, 7, 9, 12, 17, 21, 22, and the X chromosome were nonrandomly gained in these tumors. Nonrandom structural changes affected most frequently chromosomes 1 and 12, the latter as i(12p) and/or del(12)(q13----q22). The i(12p) was seen in 90% of tumors which included all histologic subtypes and gonadal as well as extragonadal presentation. Our present results, along with those from published data on fresh GCT biopsies, establish that i(12p) is a highly nonrandom chromosome marker of all histologic as well as anatomic presentations of GCTs. in contrast, we found del(12)(q13----q22) exclusively in nonseminomatous GCTs (NSGCTs) and mixed GCTs (MGCTs) occurring in 44% of such lesions. Because successful cytogenetic analysis of fresh tumor specimens is not always possible, we developed a method based on DNA analysis to detect i(12p) as increased copy number of 12p. In addition to the changes affecting chromosome 12 identified above, we have detected, for the first time, cytological evidence of gene amplification in the form of homogeneously staining regions (HSRs) and double minute chromosomes (dmins) in treated as well as untreated primary extragonadal and metastatic GCTs and confirmed the presence of amplified DNA in one of these tumors at the molecular level by the in-gel renaturation method. Hybridization of DNA from cultured cells from an HSR-bearing tumor with a panel of probes for genes known to be amplified or otherwise perturbed in diverse tumor systems did not identify the amplified gene, suggesting amplification of a novel gene or genes. This study comprises the largest series of GCT cytogenetics attempted so far. Notably, it includes data on a series of primary mediastinal tumors, a group which previously has not been studied in any detail.     

Frequent Fas gene mutations in testicular germ cell tumors

The Fas (Apo-1/CD95)/Fas ligand (L) system is involved in cell death signaling, and has been suggested to be important for the regulation of germ cell apoptosis in the testis. Mutations of the Fas gene may result in accumulation of germ cells and thus might contribute to testicular carcinogenesis. The open reading frame of Fas cDNA was examined in 24 cases of testicular germ cell tumors (TGCTs), comprised of 19 pure histological type (15 seminomas, 3 embryonal carcinomas, 1 immature teratoma) and 5 mixed-type tumors. Mutations of the Fas gene were found in nine (37.5%) of these cases. Each lesion with a homogeneous histological picture was selectively microdissected using a laser capture microdissection method: samples consisted of 18 lesions from seminomas, 7 embryonal carcinomas, 4 immature teratomas, 2 choriocarcinomas, and 1 from a yolk sac tumor. Microdissected genomic DNA was examined to determine which mutations were derived from which kind of histological lesion. Eleven mutations were detected in 10 TGCT lesions from nine cases, but none were found in benign lesions. All were point mutations, and eight missense mutations occurred in exon 9 encoding the core protein of the death domain essential for apoptotic signal transduction. Three were silent mutations. Mutations were found in the seminoma (27.8%) and embryonal carcinoma lesions (62.5%), but none were found in the one yolk sac tumor, two choriocarcinomas, or four immature teratoma lesions. Each seminoma and embryonal carcinoma lesion found in the same case had a different type of Fas mutation from the others. Mouse T-cell lymphoma cells transfected with missense mutated genes were resistant to apoptosis induced by anti-Fas antibody, indicating these to be loss-of-function mutations. These findings suggested a role of Fas gene mutations in the pathogenesis of TGCTs.     

Molecular cytogenetic analysis of i(12p)-negative human male germ cell tumors

The i(12p) chromosome has been shown to characterize more than 80% of male germ cell tumors (GCTs) and is an important diagnostic marker. Although recent cytogenetic analyses of GCTs have defined nonrandom chromosome abnormalities in these tumors, no attempt has so far been made to compare i(12p)-positive and -negative tumors in terms of their cytogenetic, histologic, and clinical features. During a 5-year period, we have ascertained 202 GCTs, of which 117 had clonally abnormal karyotypes. Among the latter, 91 had one or more copies of i(12p), whereas 26 lacked an i(12p). We report here the karyotypic analysis of these 26 i(12p)-negative GCTs. In this group, nonrandom sites of chromosomal rearrangements included 12p13 (9/26) and 1p11-q11 (5/26). Comparison of the cytogenetic features of i(12p)-negative tumors with i(12p)-positive tumors revealed the only significant difference to be rearrangements affecting 12p 13 in the former (35%) as compared to their absence in the latter (3%). Hybridization of metaphase preparations of 9 i(12p)-negative tumors with a chromosome 12 painting probe and with a microdissected 12p painting probe revealed extra copies of chromosome 12 segments incorporated into marker chromosomes whose composition could not otherwise be resolved by banding analysis; all were shown to be derived from 12p. These data demonstrate that both i(12p)-negative and -positive groups are characterized by an increased copy number of 12p, which is consistent with a lack of significant clinical or biological difference between them. An increased 12p copy number thus is a specific aberration of significance to the development of germ cell tumors. © 1993 Wiley-Liss, Inc.     

Analysis of the DND1 gene in men with sporadic and familial testicular germ cell tumors

A base substitution in the mouse Dnd1 gene resulting in a truncated Dnd protein has been shown to be responsible for germ cell loss and the development of testicular germ cell tumors (TGCT) in the 129 strain of mice. We investigated the human orthologue of this gene in 263 patients (165 with a family history of TGCT and 98 without) and found a rare heterozygous variant, p. Glu86Ala, in a single case. This variant was not present in control chromosomes (0/4,132). Analysis of the variant in an additional 842 index TGCT cases (269 with a family history of TGCT and 573 without) did not reveal any additional instances. The variant, p. Glu86Ala, is within a known functional domain of DND1 and is highly conserved through evolution. Although the variant may be a rare polymorphism, a change at such a highly conserved residue is characteristic of a disease-causing variant. Whether it is disease-causing or not, mutations in DND1 make, at most, a very small contribution to TGCT susceptibility in adults and adolescents.     

In vivo differentiation and genomic evolution in adult male germ cell tumors

Germ cell tumors (GCTs) are the most common solid malignancy in young adult men, but the genes and genomic regions involved in their etiology are not fully defined. We report here an investigation of DNA copy number changes in GCTs using 1 Mb BAC arrays. As expected, 12p gain was the defining genomic alteration, occurring in 72/74 GCTs. Parallel expression profiling of these tumors identified potential oncogenes from gained regions (LYN and RAB25) and potential tumor suppressor genes in regions of loss (SYNPO2, TTC12, IGSF4, and EPB41L3). Notably, we observed specific genomic alterations associated with histology, including gain of 17p11.2-q21.32 and loss of 2p25.3 in embryonal carcinoma, gain of 8p23.3-12 and loss of 5p15.33-35.3, 11q23.1-25, and 13q12.11-34 in seminoma, and gain of 1q31.3-42.3, 3p, 14q11.2-32.33, and 20q and loss of 8q11.1-23.1 in yolk sac tumors (YST). Many significant genes that mapped to these regions had previously been associated with specific histologies, such as EOMES (chr3) and BMP2 (chr20) in YST and SPRY2 (chr13) and SOX17 (chr8) in seminomas. Additionally, our results suggest a model in which histologic differentiation of GCTs may drive genomic evolution.     

Genetic control of susceptibility to spontaneous testicular germ cell tumors in mice

Testicular germ cell tumors (TGCTs) are the most common cancer affecting young men. TGCT is a polygenic trait and genes that control susceptibility for TGCT development have not yet been identified. The 129/Sv inbred strain of mice is an important experimental model to study the genetics and development of TGCTs. We review several novel approaches that were developed to study the susceptibility of TGCTs in the 129/Sv mouse model and its application in humans. These approaches showed that several spontaneous and engineered mutations interact with 129/Sv-derived susceptibility genes to enhance or suppress susceptibility; two of these mutations (Ter and Trp53) revealed novel linkages for susceptibility genes in sensitized polygenic trait analysis. Linkage analysis with a chromosome substitution strains suggests that as many as 100 genes control susceptibility. Bilateral TGCTs result from the coincidental occurrence of unilateral tumors. These results highlight the important contributions that this mouse model can make to studies of TGCT susceptibility in humans.     

Mediastinal germ cell tumors

Germ Cell Tumors (GCT) represent an important group of mediastinal tumors. Because of genetic characteristics and behavior have been divided in prepubertal and postpubertal tumors, and their origin remains controversial. The genetic changes are diverse, but the most frequent is i (12p), and can be associated to gonadal disgenesis. Histological classification is similiar to that of gonadal tumors and all histological types have been described in the mediastinum. Teratomas may undergo malignant transformation with the emergence of somatic tumors such as haematological malignancies, sarcomas, carcinomas and neurogenic tumors, and such transformation may occur in the primary site or in the metastases. Prognostic factors in mediastinal germ cell tumors include: age of the patient, histological type, distant metastases, stage, status of resection, level of serum tumor markers and proliferation markers. Immunohistochemistry is especially useful when the primary GCT is occult, to separate types of immature GCT, and to determine the lineage of malignant transformation which may be important to design treatment strategies.     

Mammalian male germ cell cytogenetics

The methods used for the detection of chemically induced chromosomedamage in male germ cells are discussed. These tests have beendivided into direct and indirect cytogenetic methods. The directmethods assess chromosome damage in the dosed animal but analysisis restricted to the dividing spermatogonia and spermatocytes.Using indirect methods, chromosome damage is assessed in theF₁ progeny of the dosed male and analysis covers all germ cellstages. Both methods can provide evidence of germ cell exposurebut the data obtained from the indirect tests are consideredmore relevant since a positive result clearly constitutes unequivocalevidence of transmitted damage. The analysis of one-cell embryosfrom matings involving dosed parents is considered to be themost useful indirect test system since both structural and numericalaberrations in male and female F₁ offspring can be assessed.Although relevant to the assessment of mutagenic hazard, thetechnically demanding methods used in the germ cell techniquesprevent their use for preliminary screening programmes.     

Testicular tumors other than germ cell tumors

A heterogeneous group of neoplasms other than those of germ cell type may involve the testis. These tumors vary greatly in their histologic appearances and biologic behavior, and accurate pathologic interpretation is essential to patient care. This review of these various neoplasms emphasizes pathologic aspects, particularly problems in differential diagnosis that may arise.     

Detection of preferential NRAS mutations in human male germ cell tumors by the polymerase chain reaction

We have studied 31 male germ cell tumors (GCTs) for probable mutations in codons 12, 13, and 61 of HRAS, KRAS, and NRAS oncogenes using the polymerase chain reaction. Twenty of the thirty-one tumors exhibited NRAS gene mutations, 14 in codon 61, and six in codon 12, whereas no mutations were detected in HRAS and KRAS genes. The NRAS mutations were equally prevalent in seminomatous and nonseminomatous GCTs. Thus 13 of 22 seminomas, six of seven embryonal carcinomas, and one of two mixed tumors exhibited mutations. Two non-seminomatous tumors (an embryonal carcinoma and a yolk sac/teratoma) had mutations in both codons 12 and 61. The high frequency of NRAS mutations observed in the present study suggests that NRAS gene products may play an important role in growth regulatory functions of premalignant and malignant germ cells.     

Primary mediastinal germ cell tumors

Mediastinal germ cell tumors share similar histopathological, immunohistochemical, and molecular features with their counterparts in the gonads. Therefore, proper clinical and radiological evaluation of patients with an anterior mediastinal mass becomes essential in the final interpretation of these tumors. The gold standard for the diagnosis of these tumors remains histopathological evaluation. However, immunohistochemical stains and molecular studies also provide an aid in cases in which the histology is not typical. It is also important to keep in mind that a small mediastinoscopic biopsy may not be representative of the entire neoplasm. In this review, we will provide our perspective regarding histopathological diagnosis, staging, immunohistochemical and molecular profile, and briefly family of tumors address pertinent epidemiological, clinical and treatment options. However, the main emphasis is to review the process of pathological assessment in pre and post-treated tumors. Knowledge of the different growth patterns and histological associations is important, mainly when confronted with mediastinoscopic biopsies, which ultimately will determine treatment options.     

Recent developments in the pathology of germ cell tumors

This article describes some of the recent developments in the pathology of germ cell tumors of the testis. Many germ cell tumors show different types of differentiation. Two different explanations for this phenomenon include the differentiation of other germ cell elements from totipotential embryonal carcinoma cells or the direct differentiation of neoplasms from a malignant intratubular germ cell. Although the concept that there is a subset of seminomas having a poorer prognosis still exists, the histologic identification of such "anaplastic seminoma" remains an unachieved goal, and we, therefore, do not recommend the use of the term anaplastic seminoma at present. A recent analysis of spermatocytic seminomas has failed to demonstrate that they are capable of meiotic division. They are composed of cells differentiating in the direction of spermatocytes, but they have not achieved that stage. The prognosis, in general, remains excellent, although recently sarcomas have been reported in association with spermatocytic seminomas with metastasis of the sarcomatous elements. The presence of human chorionic gonadotropin-producing syncytiotrophoblastic giant cells in otherwise pure seminomas does not appear to adversely affect the prognosis. Yolk sac tumors have a varied histology that many pathologists do not recognize. The presence of intercellular basement membrane (parietal differentiation) is useful in the recognition of yolk sac tumor. Sometimes solid foci of yolk sac tumor may be mistaken for seminoma, and alpha-fetoprotein and cytokeratin stains may be useful in this situation, although the presence of basement membrane, hyaline globules, and focal microcysts by light microscopy may obviate the need to use them. Hepatic and enteric (or endometrioid) differentiation may occur in yolk sac tumors and cause diagnostic confusion. The development most "non-germ" cell malignancies in patients with germ cell tumors appears to occur by transformation of aneuploid teratomatous elements at the primary or metastatic site. The identification of such malignancies depends on the recognition of invasion by the elements rather than on high-grade cytologic atypia. Unusual patterns of choriocarcinoma and yolk sac tumor may be encountered following chemotherapy, and there is circumstantial evidence that some sarcomas and carcinomas occurring in patients with testis cancer may develop directly from yolk sac tumor.     

Chromosome changes in germ cell tumors of the testis

Chromosome analysis was performed on short-term cultures established from samples of six tumors of the testis. Histologically, four tumors were embryonal cell carcinomas (three primary, one metastatic) and two of mixed histology with predominance of teratoma. The modal chromosome number was hypotriploid in four tumors, triploid in one, and hypertriploid in another. All tumors contained structurally abnormal chromosomes, ranging in number from 1 to 10 in different cases. A small metacentric marker chromosome, identified as an isochromosome of the short arm of chromosome #12 [i(12p)], was present in all tumors analyzed. Unlike other marker chromosomes, this one was invariably present in at least two copies per metaphase in all cases; all other chromosome markers were present in single copy in all tumors. Together with the previous reports on the presence of i(12p) in seminoma and teratoma of the testis, our findings suggest that this karyotypic abnormality is characteristic for all histologic varieties of germ cell tumors of the testis.