LZTS2: A novel and independent prognostic biomarker for clear cell renal cell carcinoma.

PURPOSE: Leucine zipper tumor suppressor 2 (LZTS2), a putative tumor suppressor gene, has been demonstrated to be a negative regulator of microtubule severing during cytokinesis and a negative regulator of the Wnt signaling pathway. In a genetically modified mouse model, deletion of Lzts2 altered normal ureteric bud branching morphogenesis and caused cystogenesis in mice. Cyst-lining cells demonstrated atypical features, closely resembling those observed in mouse models of human clear cell renal cell carcinoma (ccRCC), which could represent a preneoplastic lesion. These findings suggest that LZTS2 may play a role in ccRCC tumorigenesis. The aim of this study was to establish an association between LZTS2 differential expression and clinicopathological features of ccRCC and to investigate its prognostic value as well as the underlying mechanisms in ccRCC progression. MATERIALS AND METHODS: Gene expression data by RNA-sequencing for cohorts of 510 ccRCC cases with clinical outcome data were extracted from The Cancer Genome Atlas (TCGA) using cBioPortal. Chi-square test of independence, Kaplan-Meier curves, and Cox regression models were used to investigate the possible relationship between LZTS2 mRNA expression levels and clinicopathological parameters as well as patient survival to establish its prognostic values. To examine its cellular localization, we performed LZTS2 antibody staining and scored the expression levels in a pilot study on a tissue microarray (TMA) containing 31 clear cell RCCs, 32 chromophobe RCCs, 12 papillary RCCs, and 20 adjacent benign renal tissue, as well as placental tissue diagnosed between 2001 and 2007 at the University of California San Francisco Medical Center. Staining was subsequently repeated in 15 ccRCCs on whole section slides to confirm the results. RESULTS: Our analysis of TCGA data demonstrated that LZTS2 expression levels were associated with tumor grade (p = 0.005), T stage (p < 0.001), metastasis status (p < 0.001), and overall clinical stage (p < 0.001). High level of expression was correlated with worse overall survival (p < 0.001), disease-specific survival (p < 0.001), progression-free survival (p < 0.001), and disease-free survival (p < 0.001) compared to low level of expression. Multivariate Cox regression analysis revealed that high LZTS2 expression was an independent poor prognostic factor for overall survival (HR = 2.083, p < 0.001), disease-specific survival (HR = 2.298, p < 0.001), and progression-free survival (HR = 1.896, p < 0.001) in patients with ccRCC. A few known driver mutations in ccRCC pathogenesis, including BAP1, NF2, and RELN, were enriched in LZTS2 high expression tumors. In particular, LZTS2 expression level could be a biomarker for risk stratification of the prognosis of BAP1-mutated ccRCCs. Immunohistochemical staining with anti-LZTS2 antibody was performed to examine its cellular localization in ccRCC and demonstrated centrosomal and acentrosomal distribution in tumors of various Fuhrman nuclear grades. Furthermore, high LZTS2 cytoplasmic expression was associated with centrosomal amplification (p = 0.030) in this small-scale study. CONCLUSIONS: The current study established an independent prognostic value of LZTS2 expression in ccRCC and explored the molecular mechanisms of LZTS2 in predicting the prognosis of ccRCC. Further studies are needed to validate our analysis and to provide a precise understanding of the function of LZTS2 in ccRCC.

Overexpression of the PLK4 Gene as a Novel Strategy for the Treatment of Autosomal Recessive Microcephaly by Improving Centrosomal Dysfunction.

Autosomal recessive microcephaly and chorioretinopathy (MCCRP) is a neurodevelopmental disorder characterized by delayed psychomotor development, growth retardation with dwarfism, and ocular abnormalities, and its occurrence has been found to be closely related to variants of the gene encoding centrosomes. However, the association between centrosomal duplication defects and the etiology of microcephaly syndromes is poorly understood. It is well known that polo-like kinase 4 (PLK4) is a key regulator of centriole duplication, and the abnormalities of centrosomal function caused by its protein variation need to be further explored in the pathogenesis of microcephaly. In our study, we found that a patient with microcephaly and chorioretinopathy harbored compound heterozygous missense variants NM_014264.4: c.2221C > T (p.Gln741*) and NM_014264.4: c.2062 T > C (p.Tyr688His) in the PLK4 gene. Overexpression experiments of the variant PLK4 proteins then showed that the G741 variant rather than the T688H variant had lost centrosomal amplification ability, and the G741 variant but not the T688H variant induced centrosomal replication disorder, which further inhibited cell proliferation, cycle division and cytoskeleton morphology in HeLa cells. Moreover, the overexpression of the two variant proteins had inconsistent effects on the target protein PLK4 by western blot analysis, also indicating that T688H variant overexpression is not functionally equivalent to WT-PLK4 overexpression. Therefore, all data support the idea that the PLK4 mutation induces centriolar duplication disorder and reduces the efficiency of mitosis inducing cell death or cell proliferation in the etiology of microcephaly disorder.

Use of Ciliogenesis to Detect Aneugens: The Role of Primary Cilia.

Primary cilia arise from the centrosomes of quiescent or post-mitotic cells, and serve as sensory organelles that communicate mechanical and chemical stimuli from the environment to the interior of the cell. Cilium formation may, therefore, become a useful end point signaling exposure to genotoxins or aneugens. Here we have used the aneugen, zidovudine (AZT), an antiretroviral drug that induces DNA replication arrest and centrosomal amplification (>2 centrosomes per quiescent cell), to evaluate cilia formation in retinal epithelial (pigmented) cells. Since cilia are derived from centrosomes, and aneugens can induce centrosomal amplification, the production of multiple cilia arising from multiple centrosomes may reveal the aneugenic nature of the agents. Cells were exposed to AZT to induce centrosomal amplification, cultured without serum to allow the centrioles to develop cilia, and immunostained to visualize cilia and centrosomes. Nuclear DNA was stained with DAPI. Preliminary observations suggest that cells with multiple centrosomes are able to generate extra cilia.

MAP4-dependent regulation of microtubule formation affects centrosome, cilia, and Golgi architecture as a central mechanism in growth regulation.

Numerous genes are involved in human growth regulation. Recently, autosomal-recessive inherited variants in centrosomal proteins have been identified in Seckel syndrome, primary microcephaly, or microcephalic osteodysplastic primary dwarfism. Common hallmarks of these syndromic forms are severe short stature and microcephaly. In a consanguineous family with two affected children with severe growth retardation and normocephaly, we used homozygosity mapping and next-generation sequencing to identify a homozygous MAP4 variant. MAP4 is a major protein for microtubule assembly during mitosis. High-expression levels in the somite boundaries of zebrafish suggested a role in growth and body segment patterning. The identified variant affects binding sites of kinases necessary for dynamic instability of microtubule formation. We found centrosome amplifications in mitotic fibroblast cells in vivo and in vitro. These numeric centrosomal aberrations were also present during interphase resulting in aberrant ciliogenesis. Furthermore, affected cells showed a dysfunction of the microtubule-dependent assembly of the Golgi apparatus, indicated by a significant lack of compactness of Golgi membranes. These observations demonstrated that MAP4 mutations contribute to the clinical spectrum of centrosomal defects and confirmed the complex role of a centrosomal protein in centrosomal, ciliary, and Golgi regulation associated with severe short stature.

Role of nucleotide excision repair and p53 in zidovudine (AZT)-induced centrosomal deregulation.

The nucleoside reverse transcriptase inhibitor zidovudine (AZT) induces genotoxic damage that includes centrosomal amplification (CA > 2 centrosomes/cell) and micronucleus (MN) formation. Here we explored these end points in mice deficient in DNA repair and tumor suppressor function to evaluate their effect on AZT-induced DNA damage. We used mesenchymal-derived fibroblasts cultured from C57BL/6J mice that were null and wild type (WT) for Xpa, and WT, haploinsufficient and null for p53 (6 different genotypes). Dose-responses for CA formation, in cells exposed to 0, 10, and 100 µM AZT for 24 hr, were observed in all genotypes except the Xpa((+/+)) p53((+/-)) cells, which had very low levels of CA, and the Xpa((-/-)) p53((-/-)) cells, which had very high levels of CA. For CA there was a significant three-way interaction between Xpa, p53, and AZT concentration, and Xpa((-/-)) cells had significantly higher levels of CA than Xpa((+/+)) cells, only for p53((+/-)) cells. In contrast, the MN and MN + chromosomes (MN + C) data showed a lack of AZT dose response. The Xpa((-/-)) cells, with p53((+/+)) or ((+/-)) genotypes, had levels of MN and MN + C higher than the corresponding Xpa((+/+)) cells. The data show that CA is a major event induced by exposure to AZT in these cells, and that there is a complicated relationship between AZT and CA formation with respect to gene dosage of Xpa and p53. The loss of both genes resulted in high levels of damage, and p53 haploinsufficicency strongly protected Xpa((+/+)) cells from AZT-induced CA damage.

Perinatal exposure of patas monkeys to antiretroviral nucleoside reverse-transcriptase inhibitors induces genotoxicity persistent for up to 3 years of age.

BACKGROUND: Erythrocebus patas (patas) monkeys were used to model antiretroviral (ARV) drug in human immunodeficiency virus type 1-infected pregnant women. METHODS: Pregnant patas dams were given human-equivalent doses of ARVs daily during 50% of gestation. Mesenchymal cells, cultured from bone marrow of patas offspring obtained at birth and at 1 and 3 years of age, were examined for genotoxicity, including centrosomal amplification, micronuclei, and micronuclei containing whole chromosomes. RESULTS: Compared with controls, statistically significant increases (P < .05) in centrosomal amplification, micronuclei, and micronuclei containing whole chromosomes were found in mesenchymal cells from most groups of offspring at the 3 time points. CONCLUSIONS: Transplacental nucleoside reverse-transcriptase inhibitor exposures induced fetal genotoxicity that was persistent for 3 years.