Padmaja Kunapuli

Suppression of the cell proliferation and invasion phenotypes in glioma cells by the LGI1 gene.

The leucine-rich, glioma-inactivated (LGI1) gene, located in 10q24, was originally identified because it was interrupted and inactivated by a reciprocal chromosome translocation in the T98G glioma cell line. Loss of LGI1 expression in high-grade brain tumors is correlated with the frequent loss of chromosome 10 during progression of gliomas. To investigate whether this gene can suppress the malignant phenotype in glioma cells, we introduced the LGI1 gene into cells that do (U87) and do not (T98G and A172) express LGI1 endogenously. A172 and T98G cells showed a significant reduction in cell proliferation potential as a result of re-expression of LGI1, whereas U87 cells did not. Using BD matrigel matrix chamber assays we were also able to show that the migration ability of the reconstituted A172 and T98G cells was also reduced considerably. Finally, these reconstituted T98G and A172 cells showed a significant reduction in the ability to form colonies in soft agar compared with the parental cells. This analysis clearly demonstrates that re-expression of the LGI1 gene in glioma cells that were null for its activity can greatly reduce their malignant potential. These observations provide the opportunity to investigate the role of LGI1 in gliomagenesis and, since LGI1 is predicted to be a membrane-bound protein, potentially provides the opportunity to develop novel treatment strategies for malignant gliomas.

Arsenic trioxide affects signal transducer and activator of transcription proteins through alteration of protein tyrosine kinase phosphorylation

Purpose: Arsenic trioxide decreases proliferation of acute myeloid leukemia (AML) cells, but its precise mechanism of action is unknown. Experimental Design: We studied the effect of arsenic trioxide on patient samples and the AML cell line HEL, which, like leukemic blasts from 50% of AML cases, has constitutively activated signal transducer and activator of transcription (STAT) proteins. Results: Arsenic trioxide induced mitotic arrest starting at 24 hours and significant cell death at 48 hours. These events were preceded by an arsenic trioxide dose-dependent down-regulation of activated STAT proteins starting at 6 hours. We hypothesized that arsenic trioxide inhibits protein tyrosine kinases (PTK), which, among others, phosphorylate and activate STATs. We therefore studied arsenic trioxide effects on Janus kinases and on three oncogenic PTKs that are known to activate STATs [FLT3, ZNF198/fibroblast growth factor receptor 1 (FGFR1), and BCR/ABL]. Arsenic trioxide reduced STAT3 activation by Janus kinases, altered phosphorylation and electrophoretic mobility of ZNF198/fibroblast growth factor receptor 1, reduced kinase protein level, and decreased STAT3 protein phosphorylation. Arsenic trioxide also reduced the phosphorylation of BCR/ABL and FLT3 with corresponding decreased STAT5 phosphorylation. Conclusions: These results suggest a selective activity of arsenic trioxide on PTKs and will assist in developing clinical trials in AML.

ZNF198 protein, involved in rearrangement in myeloproliferative disease, forms complexes with the DNA repair-associated HHR6A/6B and RAD18 proteins

A highly specific t(8;13)(p11;q12) translocation has been consistently identified in bone marrow cells from patients with an atypical myeloproliferative disease that is associated with peripheral blood eosinophila and T- or B-cell leukemias. In all patients analysed to date, the translocation event results in a chimeric gene in which the atypical zinc-finger domain of ZNF198 is fused to the N-terminal end of the catalytic domain of the FGFR1 receptor tyrosine kinase. To understand more about the consequences of this rearrangement we have investigated the normal function of the ZNF198 gene. Using yeast two-hybrid analysis we identified HHR6 as a protein binding partner and confirmed this using immunoprecipitation studies. The ZNF198/FGFR1 fusion protein also binds to HHR6. We demonstrate here that the human RAD18 is also present in the ZNF198/HHR6 protein complex, although it does not coimmunoprecipitate with the fusion kinase. Cells expressing the fusion kinase gene show a marked increased sensitivity to UVB irradiation, suggesting that it acts in a dominant-negative way to affect DNA repair. These observations support the idea that ZNF198, through its interaction with HHR6 and RAD18, may be involved in the DNA repair process.

Mass Spectrometry Identifies LGI1-Interacting Proteins that Are Involved in Synaptic Vesicle Function in the Human Brain

The LGI1 gene has been shown to predispose to epilepsy and influence cell invasion in glioma cells. To identify proteins that interact with LGI1 and gain a better understanding of its function, we have used co-immunoprecipitation (co-IP) of a secreted green fluorescent protein-tagged LGI1 protein combined with mass spectrometry to identify interacting partners from lysates prepared from human subcortical white matter. Proteins were recovered from polyacrylamide gels and analyzed using liquid chromatography coupled to tandem mass spectrometry. This analysis identified a range of proteins, but in particular synaptotagmin, synaptophysin, and syntaxin 1A. Each of these proteins is found associated with synaptic vesicles. These interactions were confirmed independently by co-IP and Western blotting and implicate LGI1 in synapse biology in neurons. Other vesicle-related proteins that were recovered by co-IP include clathrin heavy chain 1, syntaxin binding protein 1, and a disintegrin and metalloprotease 23. These observations support a role for LGI1 in synapse vesicle function in neurons.

Inactivation of LGI1 expression accompanies early stage hyperplasia of prostate epithelium in the TRAMP murine model of prostate cancer

The LGI1 gene has been implicated in tumor cell invasion through regulation of the ERK pathway. To determine whether human prostate cancer cells (PC3, 22RV, Du145) are similarly affected by exposure to LGI1, we conducted scratch wound assays and demonstrated that the secreted LGI1 protein can reduce cell motility, an essential component of invasion and metastasis. These studies have now been extended to an in vivo mouse model of prostate cancer. Using a BAC transgenic mouse expressing a GFP reporter gene under the control of cis regulatory elements, we demonstrated that LGI1 is highly expressed in the normal prostate epithelium. To determine whether loss of LGI1 expression is associated with development and progression of murine prostate cancer, we bred the GFP reporter BAC transgenic mice with TRAMP mice which undergo early hyperplasia and progressive stages of prostate cancer. In the F1 animals, although the surrounding normal prostate epithelium expressed high levels of LGI1 in the double transgenic mice, the LGI1 gene had been inactivated even at the earliest stages of hyperplasia. This observation supports the suggestion that inactivation of LGI1 in certain cell types is related to tumor progression. Taken together these results suggest that LGI1 may be an important molecule for the arrest of prostate cancer cell invasion and possibly as a biomarker for early detection of prostate hyperplasia.

HSPA1A is an important regulator of the stability and function of ZNF198 and its oncogenic derivative, ZNF198-FGFR1.

Mass spectroscopy analysis demonstrated that the HSPA1A protein is found in complex with the ZNF198 protein which is involved in a chromosome rearrangement with the FGFR1 gene in an atypical myeloproliferative disease. HSPA1A is a member of the HSP70 family of genes which has been shown to be inducible in a variety of circumstances. Exogenous expression of the ZNF198–FGFR1 fusion kinase gene as well as ZNF198 in a model cell system results in a large (>650‐fold) increase in HSP70 mRNA levels. Using KNK437, a specific inhibitor of HSP70 transcription, we have demonstrated that an important function of HSPA1A is to stabilize the ZNF198 and ZNF198–FGFR1 proteins. In the absence of HSPA1A, specific functions of ZNF198–FGFR1 such as STAT3 phosphorylation is also lost. Treatment of cells with KNK437 in the presence of MG132, an inhibitor of proteasomal degradation of proteins, suggested that only the ZNF198–FGFR1 protein is subject to the proteasomal degradation pathway, while ZNF198 is not. These observations suggest an important role for HSPA1A in ZNF198 and ZNF198–FGFR1 mediated cellular function. J. Cell. Biochem. 102: 1308–1317, 2007.