The Effects of Phosphomimetic Lid Mutation on the Thermostability of the N-terminal Domain of MDM2

The multidomain E3 ubiquitin ligase MDM2 catalyzes p53 ubiquitination by a “dual-site” docking mechanism whereby MDM2 binding to at least two distinct peptide motifs on p53 promotes ubiquitination. One protein-protein interaction occurs between the N-terminal hydrophobic pocket of MDM2 and the transactivation motif of p53, and the second interaction occurs between the acidic domain of MDM2 and a motif in the DNA-binding domain of p53. A flexible N-terminal pseudo-substrate or “lid” adjacent to the N-terminal hydrophobic pocket of MDM2 has a phosphorylation site, and there are distinct models proposed on how the phosphorylated lid could affect MDM2 function. Biochemical studies have predicted that phosphomimetic mutation will stabilize the lid on the surface of MDM2 and will “open” the hydrophobic pocket and stabilize the MDM2-p53 complex, while NMR studies proposed that phosphomimetic mutation “closes” the lid over the MDM2 pocket and inhibits MDM2-p53 complex formation. To resolve these discrepancies, we utilized a quantitative fluorescence-based dye binding assay to measure the thermal unfolding of wild-type (wt), ΔLid, and S17D N-terminal domains of MDM2 as a function of increasing ligand concentration. Our data reveal that S17D lid mutation increases, rather than decreases, the thermostability of the N-terminal domain of MDM2 in the absence or in the presence of ligand. ΔLid mutation, by contrast, increases MDM2 thermoinstability. This is consistent with biochemical data, using full-length MDM2, showing that the S17D mutation stabilizes the MDM2-p53 complex and increases the specific activity of the E3 ubiquitin ligase function of MDM2. These data indicate that phosphomimetic lid mutation results in an “opening,” rather than a “closing,” of the pocket of MDM2 and highlight the ability of small intrinsically disordered or unstructured peptide motifs to regulate the specific activity of a protein.     

Titin (Visco-) Elasticity in Skeletal Muscle Myofibrils

Titin is the third most abundant protein in sarcomeres and fulfills a number of mechanical and signaling functions. Specifically, titin is responsible for most of the passive forces in sarcomeres and the passive visco-elastic behaviour of myofibrils and muscles. It has been suggested, based on mechanical testing of isolated titin molecules, that titin is an essentially elastic spring if Ig domain un/refolding is prevented either by working at short titin lengths, prior to any unfolding of Ig domains, or at long sarcomere (and titin) lengths when Ig domain un/refolding is effectively prevented. However, these properties of titin, and by extension of muscles, have not been tested with titin in its natural structural environment within a sarcomere. The purpose of this study was to gain insight into the Ig domain un/refolding kinetics and test the idea that titin could behave essentially elastically at any sarcomere length by preventing Ig domain un/refolding during passive stretch-shortening cycles. Although not completely successful, we demonstrate here that titin’s visco-elastic properties appear to depend on the Ig domain un/refolding kinetics and that indeed, titin (and thus myofibrils) can become virtually elastic when Ig domain un/refolding is prevented.     

Identification of valid reference genes for the normalization of RT qPCR gene expression data in human brain tissue

Background

Transfection of cells with gene-specific, single-stranded oligonucleotides can induce the targeted exchange of one or two nucleotides in the targeted gene. To characterize the features of the DNA-repair mechanisms involved, we examined the maximal distance for the simultaneous exchange of two nucleotides by a single-stranded oligonucleotide. The chosen experimental system was the correction of a hprt-point mutation in a hamster cell line, the generation of an additional nucleotide exchange at a variable distance from the first exchange position and the investigation of the rate of simultaneous nucleotide exchanges.

Results

The smaller the distance between the two exchange positions, the higher was the probability of a simultaneous exchange. The detected simultaneous nucleotide exchanges were found to cluster in a region of about fourteen nucleotides upstream and downstream from the first exchange position.

Conclusion

We suggest that the mechanism involved in the repair of the targeted DNA strand utilizes only a short sequence of the single-stranded oligonucleotide, which may be physically incorporated into the DNA or be used as a matrix for a repair process.     

Novel insights into DAPK autophagic signalling using peptide aptamer combinatorial protein-interaction screens

DAPK represents a relatively unique enzyme in the protein kinase superfamily whose major biological functions are linked to both autophagy and signal-mediated apoptosis. However, genetic studies have not yet uncovered how DAPK integrates into the core autophagy-related (Atg) machinery since DAPK is not present in a genetically tractable eukaryotic cell such as yeast. Furthermore, there have been no definitive DAPK binding proteins identified in metazoan systems that play a direct role in cooperating with DAPK in autophagy. We have utilized a growing concept in systems biology that invokes linear peptide-motifs as a fundamental mechanism driving protein-protein interactions and as a key switch underlying the dynamics of a signal transduction pathway. By using peptide combinatorial libraries as an assay that reflects the diversity of the linear peptide motif repertoire in the mammalian proteome, we identified microtubule-associated protein 1B (MAP1B) as a novel DAPK interacting protein that stimulates DAPK-dependent membrane blebbing and autophagy. MAP1B has previously been shown to form a functional interaction with the autophagosomal protein Atg8 (LC3). Together these studies define a genetic interaction between DAPK-MAP1B in the regulation of autophagy that may have particular relevance to cellular signalling pathways that regulate cell survival or cell death under distinct environmental stresses.     

UVB radiation and 17‐hydroxygeranyllinalool diterpene glycosides provide durable resistance against mirid (Tupiocoris notatus) attack in field‐grown Nicotiana attenuata plants

Depending on geographical location, plants are exposed to variable amounts of UVB radiation and herbivore attack. Because the role(s) of UVB in the priming and/or accumulation of plant defence metabolites against herbivores are not well understood, we used field‐grown Nicotiana attenuata plants to explore the effects of UVB on herbivore performance. Consistent with previous reports, UVB‐exposed plants accumulated higher levels of ultraviolet (UV)‐absorbing compounds (rutin, chlorogenic acid, crypto‐chlorogenic acid and dicaffeoylspermidine). Furthermore, UVB increased the accumulation of jasmonic acid, jasmonoyl‐L‐isoleucine and abscisic acid, all phytohormones which regulate plant defence against biotic and abiotic stress. In herbivore bioassays, N. attenuata plants experimentally protected from UVB were more infested by mirids in three consecutive field seasons. Among defence metabolites measured, 17‐hydroxygeranyllinalool diterpene glycosides (HGL‐DTGs) showed strongly altered accumulation patterns. While constitutive HGL‐DTGs levels were higher under UVB, N. attenuata plants exposed to mirid bugs (Tupiocoris notatus) had still more HGL‐DTGs under UVB, and mirids preferred to feed on HGL‐DTGs‐silenced plants when other UVB protecting factors were eliminated by UVB filters. We conclude that UVB exposure not only stimulates UV protective screens but also affects plant defence mechanisms, such as HGL‐DTGs accumulation, and modulates ecological interactions of N. attenuata with its herbivores in nature.     

Response of cackling geese (Branta hutchinsii taverneri) to spatial and temporal variation in the production of crowberries on the Alaska Peninsula

Arctic geese often feed on berries during premigratory fattening. We hypothesized that during autumn staging on the Alaska Peninsula, the distribution of Taverner’s cackling geese (Branta hutchinsii taverneri) would be correlated with spatial variation in crowberry (Empetrum nigrum) abundance. We also predicted that daily rates of fat increase among cackling geese would be higher in years when crowberries were abundant, compared to years when the crowberry crop was poor. Apparent distribution of geese based on fecal densities mirrored patterns of berry abundance, with areas that had highest densities of crowberries being used most heavily by geese. In areas where apparent use was greatest, geese consumed approximately 30 % of the berry crop between early September and mid-October. From 1999 to 2002, annual mean crowberry density in early September ranged from 205 berries m^?2 (1999) to 12 berries m^?2 (2002). Daily rates of lipid increase averaged 7.6 g day^?1 for juvenile and 11.4 g^?1 day for adult cackling geese and did not differ among years despite a >90 % difference in annual berry abundance. Although cackling geese used areas with higher densities of berries and apparently consumed a relatively large percentage of the crowberry crop, we could not detect an effect of annual variation in berry abundance on rates of fattening. Berries may have provided relatively little metabolizable biomass due to their high (90 %) water content. However, consumption of crowberries may provide geese with other physiological benefits such as water for osmoregulation or antioxidants and fatty acids that contribute to metabolic performance during migration.