First identification of ITM2B interactome in the human retina.

Integral Membrane Protein 2 B (ITM2B) is a type II ubiquitous transmembrane protein which role remains unclear. ITM2B mutations have been associated with different disorders: mutations leading to longer mutant proteins have been reported in two distinct Alzheimer-like autosomal dominant disorders with early-onset progressive dementia and cerebellar ataxia. Both disorders share neurological features including severe cerebral amyloid angiopathy, non-neuritic plaques, and fibrillary tangles as in Alzheimer disease. Our group reported a missense mutation in ITM2B, in an unusual retinal dystrophy with no dementia. This finding suggests a specific role of ITM2B in the retina. As the identification of retinal-specific ITM2B partners could bring new insights into the cellular functions of ITM2B, we performed quantitative proteomics of ITM2B interactome of the human retina. Overall, 457 ITM2B partners were identified with 8 of them involved in visual transduction. In addition, bulk Gene Ontology analyses showed that many ITM2B partners are involved in several other biological functions, such as microtubule organization, protein translation and interestingly, mitochondrial homeostasis. These data represent the first report of the ITM2B interactome in the human retina and may serve as a valuable inventory of new potential ITM2B partners for future investigations of ITM2B physiological functions and dysfunctions.

Thioredoxin rod-derived cone viability factor protects against photooxidative retinal damage.

Rod-derived cone viability factor (RdCVF) is a trophic factor of the thioredoxins family that promotes the survival of cone photoreceptors. It is encoded by the nucleoredoxin-like gene 1 Nxnl1 which also encodes by alternative splicing a long form of RdCVF (RdCVFL), a thioredoxin enzyme that interacts with TAU. The known role of thioredoxins in the defense mechanism against oxidative damage led us to examine the retinal phenotype of the Nxnl1(-/-) mice exposed to photooxidative stress. Here we found that, in contrast to wild-type mice, the rod photoreceptors of Nxnl1(-/-) mice are more sensitive to light after exposure to 1700 or 2500 lx. The delivery of RdCVF by AAV to mice deficient of Nxnl1(-/-) protects rod photoreceptors from light damage. Interestingly, the RdCVF2L protein, encoded by the paralog gene Nxnl2, is able to reduce TAU phosphorylation, as does RdCVFL, but does not protect the rod from light damage. Our result shows that the Nxnl1 gene, through the thioredoxin RdCVFL, is part of an endogenous defense mechanism against photooxidative stress that is likely of great importance for human vision.

The contribution of the acidic domain of MDM2 to p53 and MDM2 stability.

p53 and MDM2 are both degraded by the ubiquitin-proteasome pathway. MDM2 binds p53 and promotes its rapid degradation. MDM2 is an E3 ligase that activates self and p53 ubiquitylation. Moreover, MDM2 nuclear-cytoplasmic shuttling contributes to p53 degradation in the cytoplasm. We have identified a new region of MDM2 which regulates the stability of both p53 and MDM2. The first 50 amino-acids of the MDM2 acidic domain (222-272) contribute to MDM2 and MDM2-mediated p53 degradation by a mechanism which is independent of either MDM2 E3-ligase activity or MDM2 nucleo-cytoplasmic shuttling. The transcriptional coactivator p300 could have been involved, since it binds to the MDM2 acidic domain. However, we found that p300 stabilises MDM2, even in absence of an intact acidic domain, indicating that the MDM2 acidic region contributes to proteolysis independently of p300. We propose that the MDM2 acidic domain is required for unbiquitylated MDM2 and p53 to be degraded by cytoplasmic proteasomes.

The contribution of the RING finger domain of MDM2 to cell cycle progression.

The MDM2 oncoprotein binds to p53 and abrogates p53-mediated G1 arrest and apoptosis. We show that MDM2 over-expression accelerates cell cycle progression of RPM12650 cells by overcoming the negative effect of endogenous wild type p53 at the G1/S checkpoint. The interaction with p53 and transcription inhibition are necessary but not sufficient. The RING finger domain of MDM2 is also required for the positive effect of MDM2 on the cell cycle. Surprisingly, several point mutants in the zinc binding sites of the RING finger are fully competent for cell cycle stimulation even though they abolish MDM2-directed degradation of p53 and MDM2 E3-ligase activity. In contrast, alterations in and around the cryptic nucleolar localization sequence (KR motif) inhibit MDM2-mediated cell cycle progression as well as p53 degradation and MDM2 E3 ligase activity. We found that all the RING mutants decrease inhibition of both p53 dependent reporters and endogenous p21CIP1/WAF1/SDI1. These results indicate that the RING finger of MDM2 has a role in the regulation of the cell cycle that is independent of p53 degradation and endogenous p21CIP1/WAF1/SDI1 regulation.

MBP1: a novel mutant p53-specific protein partner with oncogenic properties.

Using a yeast two-hybrid screening strategy with a common tumour-derived p53 mutant as bait, we identified several mutant p53-interacting partners including the known proteins wild-type (wt) p53, hUBC9 and GBP/PIAS1. In addition, a novel protein partner was identified which we have termed MBP1, for Mutant p53-Binding Protein 1. MBP1 is a new member of the emerging fibulin gene family, which currently comprises fibulin-1, fibulin-2 and S1-5. Expression of MBP1 mRNA is differentially regulated both temporally during development of the mouse embryo and in a tissue-specific manner within the adult. Specific interaction between MBP1 and mutant p53 was illustrated by both two-hybrid analysis in yeast and co-immunoprecipitation in mammalian cells. MBP1 displayed the following order of binding specificity towards different p53 forms: H175 > G281 > H273 > or = W248>wt p53. Thus, MBP1 appears to bind preferentially to p53 mutants of the 'structural' rather than 'contact' class, reflecting a potential bias towards those mutants having a significant alteration in conformation from that assumed by wt p53. We propose that MBP1 is the product of a candidate oncogene as rates of both neoplastic transformation and tumour cell growth were shown to be significantly enhanced when the protein is ectopically overexpressed. Furthermore, MBP1 may play a role in determining if a 'gain of function' effect is seen with certain p53 mutants.

p53 mediated death of cells overexpressing MDM2 by an inhibitor of MDM2 interaction with p53.

The p53 tumour suppressor is frequently inactivated in human tumours. One form of inactivation results from overexpression of MDM2, that normally forms a negative auto-regulatory loop with p53 and inhibits its activity through complex formation. We have investigated whether disrupting the MDM2-p53 complex in cells that overexpress MDM2 is sufficient to trigger p53 mediated cell death. We find that expression of a peptide homologue of p53 that binds to MDM2 leads to increased p53 levels and transcriptional activity. The consequences are increased expression of the downstream effectors MDM2 and p21WAF1/CIP1, inhibition of colony formation, cell cycle arrest and cell death. There is also a decrease in E2F activity, that might have been due to the known physical and functional interactions of MDM2 with E2F1/DP1. However, this decrease is p53 dependent, as are also colony formation, cell cycle arrest and cell death. These results show that a peptide homologue of p53 is sufficient to induce p53 dependent cell death in cells overexpressing MDM2, and support the notion that disruption of the p53-MDM2 complex is a target for the development of therapeutic agents.

Metabolism of 5-fluoro-dopa and 6-fluoro-dopa enantiomers in aggregating cell cultures of fetal rat brain.

The cerebral metabolism of enantiomers of 5-fluoro-DOPA (5F-DOPA) and 6-fluoro-DOPA (6F-DOPA) was characterized in organotypic cell cultures of fetal rat brain. This system permits the investigation of metabolic processes in brain tissue exclusively, without the effects of peripheral metabolism and transport. Metabolic profiles for each substrate were determined in comparison with those of L-DOPA and D-DOPA. The uptake of DOPA and fluoro-DOPA in aggregating brain cell cultures is strongly preferential for L-enantiomers. Decarboxylation by aromatic L-amino acid decarboxylase is an active step: the major products are dopamine (DA) or 6F-DA and their corresponding products of oxidative deamination, i.e. dihydroxyphenylacetic acid (DOPAC) or 6F-DOPAC, respectively. Decarboxylation products of D-enantiomers occur in lower amounts, and 5F-D-DOPA is not decarboxylated. However, 5F-DOPA is O-methylated to a great extent, and levels of 3-O-methyl-5F-DOPA are higher after incubation with 5F-D-DOPA than with 5F-L-DOPA. These data may serve as a support for more detailed modeling of [18F]F-DOPA metabolism than can be applied to the evaluation of the cerebral biochemistry of the DA system with positron emission tomography in vivo.

Mixed micells: a new problem-free solution for omega-123I-heptadecanoic acid in comparison.

The most commonly used reagents for solubilization of 123I fatty acids have very serious drawbacks. Human serum albumin solubilizes the fatty acid only slowly and TWEEN 80 is not free of stability problems. Furthermore adverse reactions in human applications cannot be excluded. In comparison, the newly introduced mixed micells look very favourable: fast solubilization, good stability and no adverse reactions. Biodistribution experiments on rats show an adequate performance of the micells . Hitherto this solution has been applied in more than 200 patients without any complication.