Multiple truncated transcripts of TSG101 in gastrointestinal cancers

Genetic analysis of ESCRT function in Drosophila: a tumour model for human Tsg101

Class E Vps (vacuolar protein sorting) proteins are components of the ESCRTs (endosomal sorting complexes required for transport) which are required for protein sorting at the early endosome. Most of these genes have been identified and genetically characterized in yeast. Recent genetic studies in Drosophila have revealed the phenotypic consequences of loss of vps function in multicellular organisms. In the present paper, we review these studies and discuss a mechanism which may explain how loss of the human Tsg101 (tumour susceptibility gene 101), a vps23 orthologue, causes tumours.

Common and distinct genetic properties of ESCRT-II components in Drosophila

Background

Genetic studies in yeast have identified class E vps genes that form the ESCRT complexes required for protein sorting at the early endosome. In Drosophila, mutations of the ESCRT-II component vps25 cause endosomal defects leading to accumulation of Notch protein and increased Notch pathway activity. These endosomal and signaling defects are thought to account for several phenotypes. Depending on the developmental context, two different types of overgrowth can be detected. Tissue predominantly mutant for vps25 displays neoplastic tumor characteristics. In contrast, vps25 mutant clones in a wild-type background trigger hyperplastic overgrowth in a non-autonomous manner. In addition, vps25 mutant clones also promote apoptotic resistance in a non-autonomous manner.

Principal Findings

Here, we genetically characterize the remaining ESCRT-II components vps22 and vps36. Like vps25, mutants of vps22 and vps36 display endosomal defects, accumulate Notch protein and – when the tissue is predominantly mutant – show neoplastic tumor characteristics. However, despite these common phenotypes, they have distinct non-autonomous phenotypes. While vps22 mutations cause strong non-autonomous overgrowth, they do not affect apoptotic resistance. In contrast, vps36 mutations increase apoptotic resistance, but have little effect on non-autonomous proliferation. Further characterization reveals that although all ESCRT-II mutants accumulate Notch protein, only vps22 and vps25 mutations trigger Notch activity.

Conclusions/Significance

The ESCRT-II components vps22, vps25 and vps36 display common and distinct genetic properties. Our data redefine the role of Notch for hyperplastic and neoplastic overgrowth in these mutants. While Notch is required for hyperplastic growth, it appears to be dispensable for neoplastic transformation.

Malfunctions within the Cbl interactome uncouple receptor tyrosine kinases from destructive transport

Proteins of the Cbl family are adaptor molecules and ubiquitin ligases with major functions in the regulation, intracellular transport and degradation of receptor tyrosine kinases (RTKs). Due to this central role, mutations that cause malfunctions of Cbl or their associated proteins - termed the Cbl interactome - easily lead to the transformation of affected cells and eventually the development of cancer. This review intends to give an overview on the mechanisms of Cbl-mediated cell transformation in light of the dysregulated intracellular trafficking of RTKs.

vps25 mosaics display non-autonomous cell survival and overgrowth, and autonomous apoptosis

Appropriate cell-cell signaling is crucial for proper tissue homeostasis. Protein sorting of cell surface receptors at the early endosome is important for both the delivery of the signal and the inactivation of the receptor, and its alteration can cause malignancies including cancer. In a genetic screen for suppressors of the pro-apoptotic gene hid in Drosophila, we identified two alleles of vps25, a component of the ESCRT machinery required for protein sorting at the early endosome. Paradoxically, although vps25 mosaics were identified as suppressors of hid-induced apoptosis, vps25 mutant cells die. However, we provide evidence that a non-autonomous increase of Diap1 protein levels, an inhibitor of apoptosis, accounts for the suppression of hid. Furthermore, before they die, vps25 mutant clones trigger non-autonomous proliferation through a failure to downregulate Notch signaling, which activates the mitogenic JAK/STAT pathway. Hid and JNK contribute to apoptosis of vps25 mutant cells. Inhibition of cell death in vps25 clones causes dramatic overgrowth phenotypes. In addition, Hippo signaling is increased in vps25 clones, and hippo mutants block apoptosis in vps25 clones. In summary, the phenotypic analysis of vps25 mutants highlights the importance of receptor downregulation by endosomal protein sorting for appropriate tissue homeostasis, and may serve as a model for human cancer.

Role of protein ubiquitylation in regulating endocytosis of receptor tyrosine kinases

Growth factors and their transmembrane receptor tyrosine kinases play pivotal roles in morphogenesis, cell fate determination and pathogenesis, including multiple stages of cancer. The amplitude and kinetics of signaling by growth factor receptors are determined by an endocytic process, which sorts activated, autophosphorylated receptors to degradation in lysosomes. Recent studies uncovered the role of protein ubiquitylation in vesicular trafficking of growth factor receptors. Decoration of ligand-activated receptors by multiple monomeric ubiquitins distinguishes this degradative route from the proteasome-mediated pathway, which involves polymeric chains of ubiquitin. Although receptor ubiquitylation occurs at the cell surface, its major role is to sort internalized receptors to the lumen of the multivesicular body, en route to the lysosome. The ubiquitin ligases that control this late sorting event belong to the Cbl family of RING finger adaptors, which bind specific phosphotyrosine residues in the receptors upon activation by ligand. Another group of E3 ubiquitin ligases, the Nedd4 family, regulates the initial sorting event, which targets receptors to clathrin-coated regions of the plasma membrane. This step entails ubiquitin-dependent assembly of a clathrin-binding complex of adaptors such as epsins, which share ubiquitin-interacting motifs. The concerted action of both ubiquitin-binding adaptors of membrane coats and E3 ligases, as well as their regulation by protein phosphorylation and ubiquitylation, ensure robust endocytosis of growth factor receptors. Genetic defects and virus-mediated manipulations of the endocytic pathway divert receptors to a default recycling pathway, thereby enabling unrestrained signaling characteristic to transformed cells.

Analysis of BRCA1, TP53, and TSG101 germline mutations in German breast and/or ovarian cancer families

About 5%-10% of breast cancers are considered to be hereditary and associated with germline mutations of specific genes. As yet, the most frequently affected genes identified are BRCA1 and BRCA2, but also other genes such as TP53 are supposed to influence the predisposition toward breast cancer. In the present study, we analyzed patients of 19 German families with early onset breast cancer and/or a family history of breast and/or ovarian cancer for the presence of mutations in BRCA1 and TP53. In addition, we screened for germline mutations in the putative tumor suppressor gene TSG101. For this purpose we used direct sequence analysis of the entire coding regions for all three genes and, in the case of BRCA1, single-strand conformation polymorphism analysis and protein transcription-translation assays. We identified eight previously described polymorphisms and several aberrations in BRCA1: 1 unclassified missense mutation, 3 small protein truncating mutations, 1 novel pseudoexon, and 5 splicing variants. No mutation was detected in TP53. Analysis of TSG101 transcripts revealed an aberrant transcript in two breast cancer patients belonging to the same family, suggesting TSG101 as a predisposing gene in hereditary breast cancer.

Overexpression of tumor susceptibility gene TSG101 in human papillary thyroid carcinomas

Functional inactivation of tumor susceptibility gene tsg101 leads to cellular transformation and tumorigenesis in mice. While human TSG101 is located in a region where frequent loss of heterozygosity can be detected in a variety of cancers, no genomic deletion in TSG101 gene has been reported, casting a doubt on the role of TSG101 as a classical tumor suppressor. Some studies have revealed that TSG101 is a frequent target of splicing defects, which correlate with cellular stress and p53 status. Furthermore, recent reports have identified TSG101 as a part of the MDM2/p53 regulatory circuitry, a well-recognized circuitry that upon deregulation results in tumorigenesis. Interestingly, overexpression of tsg101 from an adventitious promoter also leads to neoplastic transformation. On the basis of this information, we have analysed TSG101 gene expression in 20 human papillary thyroid carcinomas (PTCs) by immunohistochemistry and demonstrated that the overexpression of TSG101 protein is closely associated with human PTCs. Further sequence analysis reveals no mutation in cDNA region encoding steadiness box in these PTC specimens, indicating that the upregulation of TSG101 protein is not caused by the alteration of this region. In situ hybridization analysis confirms that overexpression of TSG101 also occurs at the transcriptional level. In addition, semi-quantitative RT-PCR and subsequent Southern hybridization verify that the amounts of TSG101 transcripts are indeed lower in three normal thyroid tissues than in PTC specimens. Here we report the upregulation of TSG101 expression in PTC cells, providing the first evidence of the association of TSG101 overexpression with human tumors and suggesting that upregulation of TSG101 steady-state level might play a role in mediating tumorigenesis of human PTC.

Clinical implications of aberrant TSG101 transcripts in acute myeloblastic leukemia

Tsg101 is a mouse tumor suppressor gene whose homozygous deletion produces transformation of NIH3T3 cells and leads to metastases in nude mice. The human homologue of the gene, TSG101, is localized in chromosome 11p15.1-p15.2. Reduced TSG101 expression may cause the defect of the cell cycle checkpoint that leads to genetic instability and consequently to the progression of neoplasia. Aberrant TSG101 transcript have been identified in many types of cancers, and the relaxation of RNA splicing fidelity may be an onco-developmental marker in cancers and could play a general role in tumorigenesis. In our previous study, smaller TSG101 transcripts were found in AML specimens, hematopoietic cell lines and normal controls. The aberrant transcripts occurred more frequently in the AML cases and cell lines. The patients with aberrant TSG101 transcripts had higher initial white cell count, lower LDH level, and lower complete remission rate after induction chemotherapy. However, further multivariate analysis of clinical data revealed that there was no relationship to the TSG101 aberrant transcripts. The clinical significance of TSG101 aberrant transcript in AML needs further evaluation.

Stress-induced aberrant splicing of TSG101: association to high tumor grade and p53 status in breast cancers

The TSG101 gene, identified through insertional mutagenesis, is localized in a region that exhibits LOH in human cancers, suggesting that TSG101 might be a tumor suppressor gene. Numerous studies have then shown the presence of abnormal transcripts in various tumors which appear to result from aberrant splicing of the gene, rather than from intragenic deletions. Moreover, many studies demonstrated that these aberrantly spliced transcripts were not found in matched normal tissues. We have analysed TSG101 transcripts in 85 breast cancer samples and found that abnormal splicing of the gene is tightly correlated with tumor grade and p53 mutation. In addition, stress induced the appearance of these abnormal transcripts in primary lymphocytes. Hence, TSG101 splicing defects, while unrelated to the oncogenic process per se, could reflect the cellular environment of the tumor cells. The proposed role of stress and hypoxia to select p53 mutant cells could account for the tight association with p53 status.