The Visual Perception of Material Properties Affects Motor Planning in Prehension: An Analysis of Temporal and Spatial Components of Lifting Cups.

The current study examined the role of visually perceived material properties in motor planning, where we analyzed the temporal and spatial components of motor movements during a seated reaching task. We recorded hand movements of 14 participants in three dimensions while they lifted and transported paper cups that differed in weight and glossiness. Kinematic- and spatial analysis revealed speed-accuracy trade-offs to depend on visual material properties of the objects, in which participants reached slower and grabbed closer to the center of mass for stimuli that required to be handled with greater precision. We found grasp-preparation during the first encounters with the cups was not only governed by the anticipated weight of the cups, but also by their visual material properties, namely glossiness. After a series of object lifting, the execution of reaching, the grip position, and the transportation of the cups from one location to another were preeminently guided by the object weight. We also found the planning phase in reaching to be guided by the expectation of hardness and surface gloss. The findings promote the role of general knowledge of material properties in reach-to-grasp movements, in which visual material properties are incorporated in the spatio-temporal components.

Loss of KLHL6 promotes diffuse large B-cell lymphoma growth and survival by stabilizing the mRNA decay factor roquin2.

Kelch-like protein 6 (KLHL6) is an uncharacterized gene mutated in diffuse large B-cell lymphoma (DLBCL). Here we report that KLHL6 assembles with cullin3 to form a functional cullin-RING ubiquitin ligase. Mutations in KLHL6 inhibit its ligase activity by disrupting the interaction with cullin3. Loss of KLHL6 favours DLBCL growth and survival both in vitro and in xenograft models. We further established that the mRNA decay factor roquin2 is a substrate of KLHL6. Degradation of roquin2 is dependent on B-cell receptor activation, and requires the integrity of the Tyr691 residue in roquin2 that is essential for its interaction with KLHL6. A non-degradable roquin2(Y691F) mutant requires its RNA-binding ability to phenocopy the effect of KLHL6 loss. Stabilization of roquin2 promotes mRNA decay of the tumour suppressor and NF-κB pathway inhibitor, tumour necrosis factor-α-inducible gene 3. Collectively, our findings uncover the tumour suppressing mechanism of KLHL6.

Association of the herpes simplex virus major tegument structural protein VP22 with chromatin.

The abundant tegument protein VP22 has homologs throughout the alphaherpesvirus family. Numerous groups have been involved in the examination of these homologs, trying to decipher their multiple functions. Investigations early on indicated that VP22 associates with chromatin and further evidence has accumulated in recent years, correlating this protein with chromatin and its components. Ongoing and future studies will determine whether this association with chromatin is specific and whether it serves a function during infection in a physiologically relevant setting.

Role of viral chromatin structure in the regulation of herpes simplex virus 1 gene expression and replication.

Herpes simplex virus 1 initially infects epithelial cells during the lytic phase of its infectious cycle, followed by establishment of the latent phase within neuronal cells. The two different phases of infection are characterized by distinct gene-expression profiles, involving a temporal gene-expression pattern during the lytic phase succeeded by a complete shutdown of all gene expression, except for one abundant transcript, during the latent phase. The mechanisms controlling these varying degrees of gene expression appear to involve regulation of the viral chromatin structure, presumably using many of the same tactics employed by the host cell.

Histone H3 K4 demethylation during activation and attenuation of GAL1 transcription in Saccharomyces cerevisiae.

In mammalian cells, histone lysine demethylation is carried out by two classes of enzymes, the LSD1/BHC110 class and the jumonji class. The enzymes of the jumonji class in the yeast Saccharomyces cerevisiae have recently also been shown to have lysine demethylation activity. Here we report that the protein encoded by YJR119c (termed KDM5), coding for one of five predicted jumonji domain proteins in yeast, specifically demethylates trimethylated histone H3 lysine 4 (H3K4me3), H3K4me2, and H3K4me1 in vitro. We found that loss of KDM5 increased mono-, di-, and trimethylation of lysine 4 during activation of the GAL1 gene. Interestingly, cells deleted of KDM5 also displayed a delayed reduction of K4me3 upon reestablishment of GAL1 repression. These results indicate that K4 demethylation has two roles at GAL1, first to establish appropriate levels of K4 methylation during gene activation and second to remove K4 trimethylation during the attenuation phase of transcription. Thus, analysis of lysine demethylation in yeast provides new insight into the physiological roles of jumonji demethylase enzymes.

Functional dissection of protein complexes involved in yeast chromosome biology using a genetic interaction map.

Defining the functional relationships between proteins is critical for understanding virtually all aspects of cell biology. Large-scale identification of protein complexes has provided one important step towards this goal; however, even knowledge of the stoichiometry, affinity and lifetime of every protein-protein interaction would not reveal the functional relationships between and within such complexes. Genetic interactions can provide functional information that is largely invisible to protein-protein interaction data sets. Here we present an epistatic miniarray profile (E-MAP) consisting of quantitative pairwise measurements of the genetic interactions between 743 Saccharomyces cerevisiae genes involved in various aspects of chromosome biology (including DNA replication/repair, chromatid segregation and transcriptional regulation). This E-MAP reveals that physical interactions fall into two well-represented classes distinguished by whether or not the individual proteins act coherently to carry out a common function. Thus, genetic interaction data make it possible to dissect functionally multi-protein complexes, including Mediator, and to organize distinct protein complexes into pathways. In one pathway defined here, we show that Rtt109 is the founding member of a novel class of histone acetyltransferases responsible for Asf1-dependent acetylation of histone H3 on lysine 56. This modification, in turn, enables a ubiquitin ligase complex containing the cullin Rtt101 to ensure genomic integrity during DNA replication.

Histone sumoylation is a negative regulator in Saccharomyces cerevisiae and shows dynamic interplay with positive-acting histone modifications.

Covalent histone post-translational modifications such as acetylation, methylation, phosphorylation, and ubiquitylation play pivotal roles in regulating many cellular processes, including transcription, response to DNA damage, and epigenetic control. Although positive-acting post-translational modifications have been studied in Saccharomyces cerevisiae, histone modifications that are associated with transcriptional repression have not been shown to occur in this yeast. Here, we provide evidence that histone sumoylation negatively regulates transcription in S. cerevisiae. We show that all four core histones are sumoylated and identify specific sites of sumoylation in histones H2A, H2B, and H4. We demonstrate that histone sumoylation sites are involved directly in transcriptional repression. Further, while histone sumoylation occurs at all loci tested throughout the genome, slightly higher levels occur proximal to telomeres. We observe a dynamic interplay between histone sumoylation and either acetylation or ubiquitylation, where sumoylation serves as a potential block to these activating modifications. These results indicate that sumoylation is the first negative histone modification to be identified in S. cerevisiae and further suggest that sumoylation may serve as a general dynamic mark to oppose transcription.

Maintenance of low histone ubiquitylation by Ubp10 correlates with telomere-proximal Sir2 association and gene silencing.

Low levels of histone covalent modifications are associated with gene silencing at telomeres and other regions in the yeast S. cerevisiae. Although the histone deacetylase Sir2 maintains low acetylation, mechanisms responsible for low H2B ubiquitylation and low H3 methylation are unknown. Here, we show that the ubiquitin protease Ubp10 targets H2B for deubiquitylation, helping to localize Sir2 to the telomere. Ubp10 exhibits reciprocal Sir2-dependent preferential localization proximal to telomeres, where Ubp10 serves to maintain low H2B Lys123 ubiquitylation in this region and, through previously characterized crosstalk, maintains low H3 Lys4 and Lys79 methylation in a slightly broader region. Ubp10 is also localized to the rDNA locus, a second silenced domain, where it similarly maintains low histone methylation. We compare Ubp10 to Ubp8, the SAGA-associated H2B deubiquitylase involved in gene activation, and show that telomeric and gene-silencing functions are specific to Ubp10. Our results suggest that these H2B-deubiquitylating enzymes have distinct genomic functions.

H2B ubiquitin protease Ubp8 and Sgf11 constitute a discrete functional module within the Saccharomyces cerevisiae SAGA complex.

The SAGA complex is a multisubunit protein complex involved in transcriptional regulation in Saccharomyces cerevisiae. SAGA combines proteins involved in interactions with DNA-bound activators and TATA-binding protein (TBP), as well as enzymes for histone acetylation (Gcn5) and histone deubiquitylation (Ubp8). We recently showed that H2B ubiquitylation and Ubp8-mediated deubiquitylation are both required for transcriptional activation. For this study, we investigated the interaction of Ubp8 with SAGA. Using mutagenesis, we identified a putative zinc (Zn) binding domain within Ubp8 as being critical for the association with SAGA. The Zn binding domain is required for H2B deubiquitylation and for growth on media requiring Ubp8's function in gene activation. Furthermore, we identified an 11-kDa subunit of SAGA, Sgf11, and showed that it is required for the Ubp8 association with SAGA and for H2B deubiquitylation. Different approaches indicated that the functions of Ubp8 and Sgf11 are related and separable from those of other components of SAGA. In particular, the profiles of Ubp8 and Sgf11 deletions were remarkably similar in microarray analyses and synthetic genetic interactions and were distinct from those of the Spt3 and Spt8 subunits of SAGA, which are involved in TBP regulation. These data indicate that Ubp8 and Sgf11 likely represent a new functional module within SAGA that is involved in gene regulation through H2B deubiquitylation.