Craig Kamibayashi

The interaction of SV40 small tumor antigen with protein phosphatase 2A stimulates the map kinase pathway and induces cell proliferation

Interaction with SV40 small tumor antigen (small t) compromised the ability of multimeric protein phosphatase 2A to inactivate the mitogen-activated protein kinase ERK1 and the mitogen-activated protein kinase kinase MEK1. Transient expression of small t in CV-1 cells activated MEK and ERK but did not affect Raf activity. Small t stimulated the growth of quiescent CV-1 cells almost as effectively as did serum. Coexpression of kinase-deficient ERK2 blocked most, but not all, of the proliferation caused by small t. Activation of the mitogen-activated protein kinase pathway and stimulation of cell growth were dependent on the interaction of small t with protein phosphatase 2A. These findings indicate that SV40 small t is capable of inducing cell growth through blockade of protein phosphatase and deregulation of the mitogen-activated protein kinase cascade.

Molecular Interactions among Protein Phosphatase 2A, Tau, and Microtubules IMPLICATIONS FOR THE REGULATION OF TAU PHOSPHORYLATION AND THE DEVELOPMENT OF TAUOPATHIES

Hyperphosphorylated forms of the neuronal microtubule (MT)-associated protein tau are major components of Alzheimer’s disease paired helical filaments. Previously, we reported that ABαC, the dominant brain isoform of protein phosphatase 2A (PP2A), is localized on MTs, binds directly to tau, and is a major tau phosphatase in cells. We now describe direct interactions among tau, PP2A, and MTs at the submolecular level. Using tau deletion mutants, we found that ABαC binds a domain on tau that is indistinguishable from its MT-binding domain. ABαC binds directly to MTs through a site that encompasses its catalytic subunit and is distinct from its binding site for tau, and ABαC and tau bind to different domains on MTs. Specific PP2A isoforms bind to MTs with distinct affinities in vitro, and these interactions differentially inhibit the ability of PP2A to dephosphorylate various substrates, including tau and tubulin. Finally, tubulin assembly decreases PP2A activity in vitro, suggesting that PP2A activity can be modulated by MT dynamics in vivo. Taken together, these findings indicate how structural interactions among ABαC, tau, and MTs might control the phosphorylation state of tau. Disruption of these normal interactions could contribute significantly to development of tauopathies such as Alzheimer’s disease.

Physical and Functional Interactions between Type I Transforming Growth Factor β Receptors and Bα, a WD-40 Repeat Subunit of Phosphatase 2A

ABSTRACT We have previously shown that a WD-40 repeat protein, TRIP-1, associates with the type II transforming growth factor β (TGF-β) receptor. In this report, we show that another WD-40 repeat protein, the Bα subunit of protein phosphatase 2A, associates with the cytoplasmic domain of type I TGF-β receptors. This association depends on the kinase activity of the type I receptor, is increased by coexpression of the type II receptor, which is known to phosphorylate and activate the type I receptor, and allows the type I receptor to phosphorylate Bα. Furthermore, Bα enhances the growth inhibition activity of TGF-β in a receptor-dependent manner. Because Bα has been characterized as a regulator of phosphatase 2A activity, our observations suggest possible functional interactions between the TGF-β receptor complex and the regulation of protein phosphatase 2A.

Reduced binding of protein phosphatase 2A to tau protein with frontotemporal dementia and parkinsonism linked to chromosome 17 mutations.

Abstract: Coding region and intronic mutations in the tau gene cause frontotemporal dementia and parkinsonism linked to chromosome 17 (FTDP‐17). We have previously reported that ABαC, a major form of protein phosphatase 2A (PP2A) in brain, binds tightly to tau protein in vitro and is a major tau phosphatase in vivo. Using in vitro assays, we show here that the FTDP‐17 mutations G272V, ΔK280, P301L, P301S, S305N, V337M, G389R, and R406W inhibit by ∼20‐95% the binding of recombinant three‐repeat and four‐repeat tau isoforms to the ABαC holoenzyme and the AC core enzyme of PP2A. Reduction in binding was maximal for tau proteins with the G272V, ΔK280, and V337M mutations. We also show that tau protein can be specifically coimmunoprecipitated with endogenous PP2A from both rat brain and transfected cell extracts. It is significant that, by using similar coimmunoprecipitation assays, we show that all FTDP‐17 mutations tested, including the N279K mutation, alter the ability of tau to associate with cellular PP2A. Taken together, these results indicate that FTDP‐17 mutations induce a significant decrease in the binding affinity of tau for PP2A in vivo. We propose that altered protein‐protein interactions between PP2A and tau may contribute to FTDP‐17 pathogenesis.

Overexpression of candidate tumor suppressor gene FUS1 isolated from the 3p21.3 homozygous deletion region leads to G1 arrest and growth inhibition of lung cancer cells.

Recently we identified FUS1 as a candidate tumor suppressor gene (TSG) in the 120 kb 3p21.3 critical region contained in nested lung and breast cancer homozygous deletions. Mutation of FUS1 is infrequent in lung cancers which we have confirmed in 40 other primary lung cancers. In addition, we found no evidence for FUS1 promoter region methylation. Because haploinsufficiency or low expression of Fus1 may play a role in lung tumorigenesis, we tested the effect of exogenously induced overexpression of Fus1 protein and found 60–80% inhibition of colony formation for non-small cell lung cancer lines NCI-H1299 (showing allele loss for FUS1) and NCI-H322 (containing only a mutated FUS1 allele) in vitro. By contrast, a similar level of expression of a tumor-acquired mutant form of FUS1 protein did not significantly suppress colony formation. Also, induced expression of Fus1 under the control of an Ecdysone regulated promoter decreased colony formation 75%, increased the doubling time twofold, and arrested H1299 cells in G1. In conclusion, our data are consistent with the hypothesis that FUS1 may function as a 3p21.3 TSG, warranting further studies of its function in the pathogenesis of human cancers.

Increased expression and no mutation of the Flap endonuclease (FEN1) gene in human lung cancer.

The underlying molecular mechanisms leading to microsatellite alteration and mutations in human lung cancer remain unknown. Since Flap endonuclease1 (Fen1), which functions in the base excision repair system, has been shown to be involved in tumor progression of mouse models with microsatellite instability in a haplo-insufficient manner, we performed expression and mutation analyses for FEN1 in human lung cancer cell lines. Reverse transcriptase PCR analysis revealed that all 49 lung cancer cell lines (20 small cell lung cancers (SCLCs) and 29 non-small cell lung cancers (NSCLCs)) expressed FEN1. In addition, microarray analysis showed that FEN1 expression was elevated significantly by 1.65-fold (P=0.001) in SCLC cell lines compared to normal lung controls (normal human lung cultures and immortalized normal human bronchial epithelial cell lines). FEN1 protein was abundantly expressed in all 23 lung cancer cell lines (10 SCLCs and 13 NSCLCs) and was expressed at lower levels in three of four normal lung epithelial culture controls. Direct sequencing of genomic DNAs revealed no FEN1 mutation in seven SCLCs and nine NSCLCs. As part of this analysis we discovered and sequenced a FEN1 pseudogene (GenBank accession #AY249897) located at 1p22.2. This pseudogene is amplified from cDNA preparations contaminated with genomic DNA and must be taken into account in any FEN1 mutation analysis studies. Our results suggest that alterations of FEN1 are not likely to contribute to development of lung cancer.

Searching for microsatellite mutations in coding regions in lung, breast, ovarian and colorectal cancers

RepX represents a new informatics approach to probe the UniGene database for potentially polymorphic repeat sequences in the open reading frame (ORF) of genes, 56% of which were found to be actually polymorphic. We now have performed mutational analysis of 17 such sites in genes not found to be polymorphic (<0.03 frequency) in a large panel of human cancer genomic DNAs derived from 31 lung, 21 breast, seven ovarian, 21 (13 microsatellite instability (MSI)+ and eight MSI−) colorectal cancer cell lines. In the lung, breast and ovarian tumor DNAs we found no mutations (<0.03–0.04 rate of tumor associated open reading frame mutations) in these sequences. By contrast, 18 MSI+ colorectal cancers (13 cancer cell lines and five primary tumors) with mismatch repair defects exhibited six mutations in three of the 17 genes (SREBP-2, TAN-1, GR6) (P<0.000003 compared to all other cancers tested). We conclude that coding region microsatellite alterations are rare in lung, breast, ovarian carcinomas and MSI (−) colorectal cancers, but are relatively frequent in MSI (+) colorectal cancers with mismatch repair deficits.