The amplified cancer gene LAPTM4B promotes tumor growth and tolerance to stress through the induction of autophagy.

Autophagy is a fundamental salvage pathway that encapsulates damaged cellular components and delivers them to the lysosome for degradation and recycling. This pathway usually conducts a protective cellular response to nutrient deprivation and various stresses. Tumor cells live with metabolic stress and use autophagy for their survival during tumor progression and metastasis. Genomic instability in tumor cells may result in amplification of crucial gene(s) for autophagy and upregulate the autophagic pathway. We demonstrate that a cancer-associated gene, LAPTM4B, plays an important role in lysosomal functions and is critical for autophagic maturation. Its amplification and overexpression promote autophagy, which renders tumor cells resistant to metabolic and genotoxic stress and results in more rapid tumor growth.

Lysosomal transmembrane protein LAPTM4B promotes autophagy and tolerance to metabolic stress in cancer cells.

Amplification of chromosome 8q22, which includes the gene for lysosomal associated transmembrane protein LAPTM4B, has been linked to de novo anthracycline resistance in primary breast cancers with poor prognosis. LAPTM4B overexpression can induce cytosolic retention of anthracyclines and decrease drug-induced DNA damage. In this study, we tested the hypothesis that LAPTM4B may contribute to tumor cell growth or survival in the absence of a chemotherapeutic exposure. In mammary cells, LAPTM4B protein was localized in lysosomes where its depletion increased membrane permeability, pH, cathepsin release, and cellular apoptosis. Loss of LAPTM4B also inhibited later stages of autophagy by blocking maturation of the autophagosome, thereby rendering cells more sensitive to nutrient deprivation or hypoxia. Conversely, enforced overexpression of LAPTM4B promoted autophagic flux and cell survival during in vitro starvation and stimulated more rapid tumor growth in vivo. Together, our results indicate that LAPTM4B is required for lysosome homeostasis, acidification, and function, and that LAPTM4B renders tumor cells resistant to lysosome-mediated cell death triggered by environmental and genotoxic stresses.

Amplification of LAPTM4B and YWHAZ contributes to chemotherapy resistance and recurrence of breast cancer.

Adjuvant chemotherapy for breast cancer after surgery has effectively lowered metastatic recurrence rates. However, a considerable proportion of women suffer recurrent cancer at distant metastatic sites despite adjuvant treatment. Identification of the genes crucial for tumor response to specific chemotherapy drugs is a challenge but is necessary to improve outcomes. By using integrated genomics, we identified a small number of overexpressed and amplified genes from chromosome 8q22 that were associated with early disease recurrence despite anthracycline-based adjuvant chemotherapy. We confirmed the association in an analysis of multiple independent cohorts. SiRNA-mediated knockdown of either of two of these genes, the antiapoptotic gene YWHAZ and a lysosomal gene LAPTM4B, sensitized tumor cells to anthracyclines, and overexpression of either of the genes induced anthracycline resistance. Overexpression of LAPTM4B resulted in sequestration of the anthracycline doxorubicin, delaying its appearance in the nucleus. Overexpression of these two genes was associated with poor tumor response to anthracycline treatment in a neoadjuvant chemotherapy trial in women with primary breast cancer. Our results suggest that 8q22 amplification and overexpression of LAPTM4B and YWHAZ contribute to de novo chemoresistance to anthracyclines and are permissive for metastatic recurrence. Overexpression of these two genes may predict anthracycline resistance and influence selection of chemotherapy.

Allorecognition of an HLA-A*01 aberrant allele by an HLA identical family member carrying the HLA-A*0101 allele.

We identified and characterized an HLA-A1 aberrant allele (A*0118N) resulting from a novel molecular mechanism; this allele was present in an unusually informative family with a near identical parental HLA haplotype (c d) differing only by one nucleotide substitution in one HLA-A allele, A*0118N, of the maternal HLA haplotype (c) and not of the paternal HLA haplotype (a). Although serologic HLA typing showed a "blank," DNA molecular HLA typing detected a HLA-A*0118N allele. Sequence based typing identified the substitution of guanine by cytosine at the nucleotide position 215, which resulted in the replacement of arginine by proline at position 48 of the HLA-A1 H chain. The loss of surface protein expression was also found by FACS analysis. Isoelectric-focusing analysis detected a HLA-A H chain with a unique isoelectric-focusing pattern, which does not associate with the L chain (beta(2)-microglobulin). These results suggest that the residue 48-containing interaction site on the alpha(1) domain plays a critical role in the association between HLA class I H chain and beta(2)-microglobulin. Functional studies showed that the T cells of the propositus (HLA haplotypes c d) carrying this null allele recognized its wild-type counterpart, HLA-A*010101, in her HLA-identical son that carries the HLA-A*0101 heterodimer. This is the first example of the generation of cytotoxic T cells in the absence of proliferation of CD4(+) T cells (mixed lymphocyte culture) and the description of an aberrant allele, A*0118N, that may behave as a minor histocompatibility Ag, with implications in allorecognition by cytolytic T cells in solid organ and stem cell transplantation.

Genome-wide analysis for loss of heterozygosity in primary and recurrent phyllodes tumor and fibroadenoma of breast using single nucleotide polymorphism arrays.

Phyllodes tumors of the breast are biphasic stromal and epithelial tumors histologically similar to benign fibroadenomas, but with a neoplastic stromal component. In contrast to fibroadenoma, phyllodes tumors can recur and be locally aggressive or be malignant. This study uses SNP array analysis to present a genome-wide map of loss of heterozygosity (LOH) in a cohort of phyllodes tumors and fibroadenomas. LOH is frequent and sometimes extensive in phyllodes tumors, but is rarely seen in fibroadenomas. There is heterogeneity between phyllodes tumors of different patients and no one LOH marker identifies a majority of these lesions. However, a subset of LOH loci occur in multiple cases of phyllodes tumors and are not found in fibroadenomas. Primary phyllodes tumors and paired recurrences from the same patient share common regions of LOH. In contrast, metachronous fibroadenomas from the same patient have different LOH patterns with no indication of a shared origin. Specific LOH loci may be associated with pathologic progression in recurrent phyllodes tumors. In a single case of phyllodes tumor containing a malignant epithelial component the malignant epithelium and stroma partially share an LOH genotype, suggesting a common precursor cell for the biphasic malignant components.