Predicted residue–residue contacts can help the scoring of 3D models

During the 7th Critical Assessment of Protein Structure Prediction (CASP7) experiment, it was suggested that the real value of predicted residue–residue contacts might lie in the scoring of 3D model structures. Here, we have carried out a detailed reassessment of the contact predictions made during the recent CASP8 experiment to determine whether predicted contacts might aid in the selection of close‐to‐native structures or be a useful tool for scoring 3D structural models. We used the contacts predicted by the CASP8 residue–residue contact prediction groups to select models for each target domain submitted to the experiment. We found that the information contained in the predicted residue–residue contacts would probably have helped in the selection of 3D models in the free modeling regime and over the harder comparative modeling targets. Indeed, in many cases, the models selected using just the predicted contacts had better GDT‐TS scores than all but the best 3D prediction groups. Despite the well‐known low accuracy of residue–residue contact predictions, it is clear that the predictive power of contacts can be useful in 3D model prediction strategies. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Iodination of proteins by IPy2BF4, a new tool in protein chemistry

Iodination is a very useful method for protein characterization and labeling. However, derivatization chemistries used in most conventional iodination procedures may cause substantial alterations in protein structure and function. The IPy(2)BF(4) reagent [bis(pyridine)iodonium (I) tetrafluoroborate] has been shown to be an effective iodinating reagent for peptides. Herein we report the first application of IPy(2)BF(4) in protein iodination in an aqueous medium using three representative substrates: insulin, lysozyme, and the enzyme 1,3-1,4-beta-d-4-glucanohydrolase. Our results show that IPy(2)BF(4) has clear advantages over existing methods in that the reaction is quantitative, fast, and selective for the most accessible Tyr residues of a protein, and it preserves the functional integrity of the protein when moderate Tyr labeling levels are pursued.     

Biological activity of hamster interferon-gamma is modulated by the carboxyl-terminal tail

The Syrian golden hamster (Mesocricetus auratus) is highly susceptible to a number of intracellular pathogens. Interferon-gamma (IFN-γ), the primary macrophage-activating cytokine, plays a key role in the host defense against intracellular pathogens. The hamster IFN-γ cDNA encodes a 174 amino acid protein that has an additional 17 amino acids at the carboxyl-terminus compared to IFN-γ of mice and rats. A homologous C-terminal tail is also found in other non-murine rodents. The biological activity of hamster IFN-γ had not been investigated previously so we first demonstrated the activity of native IFN-γ in assays of IFN-γ-induced receptor signaling and antiviral activity against vesicular stomatitis virus. We then tested the hypothesis that the C-terminal tail of hamster IFN-γ could influence its biological activity. A truncated hamster IFN-γ, in which the C-terminal 17 aa were removed by insertion of a stop codon at the position corresponding to the stop codon in the mouse sequence, had approximately 10-fold greater activity than the full length protein when measured in the two bioassays. Polyclonal and monoclonal anti-hamster IFN-γ antibodies specifically inhibited this biological activity. Collectively, these data indicate that this unique structural feature influences the biological activity of hamster IFN-γ.     

Matrin 3 is a Ca2+/calmodulin-binding protein cleaved by caspases

Matrin 3 is a nuclear matrix protein that has been implicated in interacting with other nuclear proteins to anchor hyperedited RNAs to the nuclear matrix, in modulating the activity of proximal promoters, and as the main PKA substrate following NMDA receptor activation. In our proteome-wide selections for calmodulin (CaM) binding proteins and for caspase substrates using mRNA-displayed human proteome libraries, matrin 3 was identified as both a Ca(2+)-dependent CaM-binding protein and a downstream substrate of caspases. We report here, the in vitro characterization of the CaM-binding motif and the caspase cleavage site on matrin 3. Significantly, the Ca(2+)/CaM-binding motif is partially overlapped by the RRM of matrin 3 and is also very close to the bipartite NLS that is essential for its nuclear localization. The caspase cleavage site is downstream of the NLS but upstream of the second U1-like zinc finger. Our results suggest that the functions of matrin 3 could be regulated by both Ca(2+)-dependent interaction with CaM and caspase-mediated cleavage.     

Deficient Rab11 activity underlies glucose hypometabolism in primary neurons of Huntington's disease mice

Huntington's disease (HD) is a progressive neurodegenerative disorder caused by a CAG repeat expansion in the huntingtin gene. Positron emission tomography studies have revealed a decline in glucose metabolism in the brain of patients with HD by a mechanism that has not been established. We examined glucose utilization in embryonic primary cortical neurons of wild-type (WT) and HD knock-in mice, which have 140 CAG repeats inserted in the endogenous mouse huntingtin gene (HD(140Q/140Q)). Primary HD(140Q/140Q) cortical neurons took up significantly less glucose than did WT neurons. Expression of permanently inactive and permanently active forms of Rab11 correspondingly altered glucose uptake in WT neurons, suggesting that normal activity of Rab11 is needed for neuronal uptake of glucose. It is known that Rab11 activity is diminished in HD(140Q/140Q) neurons. Expression of dominant active Rab11 to enhance the activity of Rab11 normalized glucose uptake in HD(140Q/140Q) neurons. These results suggest that deficient activity of Rab11 is a novel mechanism for glucose hypometabolism in HD.     

The Rapidly Evolving Centromere-Specific Histone Has Stringent Functional Requirements in Arabidopsis thaliana

Centromeres control chromosome inheritance in eukaryotes, yet their DNA structure and primary sequence are hypervariable. Most animals and plants have megabases of tandem repeats at their centromeres, unlike yeast with unique centromere sequences. Centromere function requires the centromere-specific histone CENH3 (CENP-A in human), which replaces histone H3 in centromeric nucleosomes. CENH3 evolves rapidly, particularly in its N-terminal tail domain. A portion of the CENH3 histone-fold domain, the CENP-A targeting domain (CATD), has been previously shown to confer kinetochore localization and centromere function when swapped into human H3. Furthermore, CENP-A in human cells can be functionally replaced by CENH3 from distantly related organisms including Saccharomyces cerevisiae. We have used cenh3-1 (a null mutant in Arabidopsis thaliana) to replace endogenous CENH3 with GFP-tagged variants. A H3.3 tail domain–CENH3 histone-fold domain chimera rescued viability of cenh3-1, but CENH3''s lacking a tail domain were nonfunctional. In contrast to human results, H3 containing the A. thaliana CATD cannot complement cenh3-1. GFP–CENH3 from the sister species A. arenosa functionally replaces A. thaliana CENH3. GFP–CENH3 from the close relative Brassica rapa was targeted to centromeres, but did not complement cenh3-1, indicating that kinetochore localization and centromere function can be uncoupled. We conclude that CENH3 function in A. thaliana, an organism with large tandem repeat centromeres, has stringent requirements for functional complementation in mitosis.CENTROMERES are essential for chromosome inheritance, because they nucleate kinetochores, the protein complexes on eukaryotic chromosomes that attach to spindle microtubules. Despite the essential requirement for centromeres in chromosome segregation, their DNA sequences and the sequences of kinetochore proteins are highly variable. Kinetochores in Saccharomyces cerevisiae and related budding yeasts assemble on small, unique centromere DNAs (125 bp in S. cerevisiae) (Meraldi et al. 2006). Centromere DNAs in the fission yeast Schizosaccharomyces pombe are larger, consisting of a central core sequence of 4–5 kb, which binds kinetochore proteins, flanked by large inverted repeats whose heterochromatic nature is important for centromere function (the total size of the S. pombe centromere DNA is 35–110 kb). At the other extreme from small yeast centromeres are holocentric organisms, such as Caenorhabditis elegans, in which kinetochore proteins bind along the entire length of mitotic chromosomes (Dernburg 2001). Most plants and animals have extremely large centromere DNA tracts consisting of megabases of simple tandem repeats. The repeat sequence evolves extremely rapidly, and only a small fraction of the repeat array is likely to be bound by kinetochore proteins. Furthermore, kinetochores can be nucleated by noncentromeric DNA sequences in plant and animal cells (Amor and Choo 2002; Nagaki et al. 2004; Nasuda et al. 2005; Heun et al. 2006; Wade et al. 2009). Despite these findings, the maintenance of massive centromere repeat arrays in both animal and plant taxa suggests that repeats are a central feature of centromere biology in these organisms.Although centromere DNAs are extremely diverse, all eukaryote kinetochores contain the centromere-specific histone H3 variant CENH3 (originally described as CENP-A in human) (Henikoff and Dalal 2005; Black and Bassett 2008). CENH3 replaces conventional H3 specifically in a subset of centromere nucleosomes. It is essential for kinetochore function in all eukaryotes where this requirement has been tested. Conventional histones are among the most conserved proteins in eukaryote genomes. In contrast, CENH3 is rapidly evolving. The C-terminal histone-fold domain, which complexes with other histones to form the globular nucleosome core, can be aligned with conventional H3''s but evolves rapidly and shows signatures of adaptive evolution in some residues (Malik and Henikoff 2001; Talbert et al. 2002; Cooper and Henikoff 2004). The N-terminal tail domain of conventional histone H3 protrudes from the nucleosome core and is not resolved in the structure solved by X-ray crystallography (Luger et al. 1997). In CENH3, the tail domain evolves so rapidly that its sequence can barely be aligned between closely related species.Experiments in yeast and in animals have delineated functionally important regions within CENH3. S. cerevisiae kinetochores contain only a single CENH3/Cse4p nucleosome (Furuyama and Biggins 2007). In S. cerevisiae Cse4p, amino acid residues required for normal function are distributed throughout the histone-fold domain (Keith et al. 1999). The N-terminal tail of Cse4p contains an essential region termed the END domain, but overexpression of a Cse4p lacking the tail altogether can rescue a cse4 deletion mutant (Chen et al. 2000; Morey et al. 2004). In Drosophila melanogaster cells, CENH3/Cid from the distantly related D. bipectinata did not localize to kinetochores unless a specific region of the histone-fold domain, loop 1, was swapped with the corresponding region from D. melanogaster CENH3/Cid (Vermaak et al. 2002). In human, the histone-fold domain is important for centromere targeting (Sullivan et al. 1994). The functionally important region within the histone-fold domain was further defined by inserting loop 1 and the α-2 helix from CENH3/CENP-A (termed the CENP-A targeting domain, or CATD) into conventional H3 (Black et al. 2004). H3 containing the CATD acquires several functions of CENP-A when expressed in human cells. It localizes to kinetochores, binds the kinetochore protein CENP-N, has a rigid secondary structure when assembled into nucleosomes, and can restore normal chromosome segregation in cells depleted for CENP-A using RNA interference (RNAi) (Black et al. 2004, 2007a,b; Carroll et al. 2009).Despite these extensive studies, questions about structure–function relationships within CENH3 remain. CENH3 function may differ between small yeast centromeres and the large tandem repeat centromeres of animals and plants, particularly because larger centromere DNAs are likely to contain many more CENH3 nucleosomes and may require a higher level of organization. Experiments in D. melanogaster and in human cells have used RNAi to downregulate the endogenous protein, and a conditional knockout has been made in chicken DT-40 cells (Blower and Karpen 2001; Goshima et al. 2003; Regnier et al. 2005; Black et al. 2007b). These experiments are challenging because CENH3 is very stable. If preexisting CENH3 is partitioned equally between duplicated sister centromeres, its amount will be approximately halved at each cell division. Therefore the protein may persist for many cell divisions after induction of RNAi, as shown by Western blots indicating that ∼10% of endogenous CENH3 remains in human cells subjected to two rounds of RNAi (Black et al. 2007b).We have chosen to study CENH3 in the model plant A. thaliana, which combines facile genetics and transgenesis with centromere DNA structure that is similar to most plants and animals (megabases of tandem repeats with a repeating unit of 178 bp) (Murata et al. 1994; Copenhaver et al. 1999). Although Drosophila and mouse CENH3 knockout mutants have been characterized (Howman et al. 2000; Blower et al. 2006), a large-scale structure–function analysis of CENH3 has not been attempted in these organisms. A cenh3 null mutant in A. thaliana allows us to completely replace the endogenous protein with transgenic variants (Ravi and Chan 2010). Here we report four major conclusions regarding CENH3 function in A. thaliana: (1) CENH3 function requires an N-terminal histone tail domain, although either the CENH3 tail or the H3 tail can support mitotic chromosome segregation. (2) Inserting the CENP-A targeting domain of CENH3 into H3 does not confer CENH3 function. (3) Complementation of cenh3 by heterologous CENH3 requires that the species of origin be closely related to A. thaliana. (4) Localization of a heterologous CENH3 protein to kinetochores in the presence of native CENH3 does not necessarily indicate that it can complement a cenh3 mutant. Overall, our results indicate that requirements for CENH3 function in A. thaliana are more stringent that those obtained in human cells. They underscore the usefulness of comparative studies of centromere function using genetically tractable experimental organisms.     

Distinct structural elements of rab5 define its functional specificity.

Members of the rab family of small GTPases are localized to distinct cellular compartments and function as specific regulators of vesicle transport between organelles. Overexpression of rab5, which is associated with early endosomes and the plasma membrane, increases the rate of endocytosis [Bucci et al. (1992) Cell, 70, 715-728]. From sequence alignments and molecular modelling we identified structural elements that might contribute to the definition of the functional specificity of rab5. To test the role of these elements experimentally, we transplanted them onto rab6, which is associated with the Golgi complex. The chimeric proteins were assayed for intracellular localization and stimulation of endocytosis. First, we found that the C-terminus of rab5 could target rab6 to the plasma membrane and early endosomes but it did not confer rab5-like stimulation of endocytosis. Further replacement of other regions revealed that the N-terminus, helix alpha 2/loop 5 and helix alpha 2/loop 7 were all required to functionally convert rab6 into rab5. Reciprocal hybrids of rab5 containing these regions replaced with those of rab6 were inactive, demonstrating that each region is essential for rab5 function. These results indicate that distinct structural elements specify the localization, membrane association and regulatory function of rab5.     

The ratio of acetate‐to‐glucose oxidation in astrocytes from a single 13C NMR spectrum of cerebral cortex

The ¹³C‐labeling patterns in glutamate and glutamine from brain tissue are quite different after infusion of a mixture of ¹³C‐enriched glucose and acetate. Two processes contribute to this observation, oxidation of acetate by astrocytes but not neurons, and preferential incorporation of α‐ketoglutarate into glutamate in neurons, and incorporation of α‐ketoglutarate into glutamine in astrocytes. The acetate:glucose ratio, introduced previously for analysis of a single ¹³C NMR spectrum, provides a useful index of acetate and glucose oxidation in the brain tissue. However, quantitation of relative substrate oxidation at the cell compartment level has not been reported. A simple mathematical method is presented to quantify the ratio of acetate‐to‐glucose oxidation in astrocytes, based on the standard assumption that neurons do not oxidize acetate. Mice were infused with [1,2‐¹³C]acetate and [1,6‐¹³C]glucose, and proton decoupled ¹³C NMR spectra of cortex extracts were acquired. A fit of those spectra to the model indicated that ¹³C‐labeled acetate and glucose contributed approximately equally to acetyl‐CoA (0.96) in astrocytes. As this method relies on a single ¹³C NMR spectrum, it can be readily applied to multiple physiologic and pathologic conditions.

     

Isolation of high molecular weight DNA from wholeEuglena cells

Summary A method for isolating high quality DNA from wholeEuglena cells is described. The procedure consists in: the weakening of the cell pellicle in glycerol avoiding the mechanical disruption of cells and shearing damage in DNA molecules; the decondensation ofEuglena compact chromatin directly inside the cells; the complete dissociation of cells and nucleoproteins in sarkosyl detergent; the optional digestion of proteins and RNA with DNase-free enzymes and the final purification of DNA by isopycnic banding in CsCl gradients. Degradation of DNA is prevented all along the extraction procedure by glycerol, antioxydants, EDTA and sarkosyl detergent. Using the enzymatic digestion step, DNA containing few single-stranded nicks is obtained with a yield approaching 100%. DNA with no single-stranded nick could be obtained with a 35% yield when the enzymatic digestion step was omitted. In both cases, the double-stranded DNA has an average molecular weight equal or greater than 6×10⁷. It is free of contaminants and could be easily digested with restriction enzymes. After digestion with Eco RI and size-fractionation in agarose gel this DNA has permitted specific hybridization of the rDNA sequences with a radioactive rRNA probe.Abbreviations Kbp kilobasepairs - Kb kilobases