The Psb27 assembly factor binds to the CP43 complex of photosystem II in the cyanobacterium Synechocystis sp. PCC 6803

We have investigated the location of the Psb27 protein and its role in photosystem (PS) II biogenesis in the cyanobacterium Synechocystis sp. PCC 6803. Native gel electrophoresis revealed that Psb27 was present mainly in monomeric PSII core complexes but also in smaller amounts in dimeric PSII core complexes, in large PSII supercomplexes, and in the unassembled protein fraction. We conclude from analysis of assembly mutants and isolated histidine-tagged PSII subcomplexes that Psb27 associates with the "unassembled" CP43 complex, as well as with larger complexes containing CP43, possibly in the vicinity of the large lumenal loop connecting transmembrane helices 5 and 6 of CP43. A functional role for Psb27 in the biogenesis of CP43 is supported by the decreased accumulation and enhanced fragmentation of unassembled CP43 after inactivation of the psb27 gene in a mutant lacking CP47. Unexpectedly, in strains unable to assemble PSII, a small amount of Psb27 comigrated with monomeric and trimeric PSI complexes upon native gel electrophoresis, and Psb27 could be copurified with histidine-tagged PSI isolated from the wild type. Yeast two-hybrid assays suggested an interaction of Psb27 with the PsaB protein of PSI. Pull-down experiments also supported an interaction between CP43 and PSI. Deletion of psb27 did not have drastic effects on PSII assembly and repair but did compromise short-term acclimation to high light. The tentative interaction of Psb27 and CP43 with PSI raises the possibility that PSI might play a previously unrecognized role in the biogenesis/repair of PSII.     

Constitutively active rhodopsin mutants causing night blindness are effectively phosphorylated by GRKs but differ in arrestin-1 binding

The effects of activating mutations associated with night blindness on the stoichiometry of rhodopsin interactions with G protein-coupled receptor kinase 1 (GRK1) and arrestin-1 have not been reported. Here we show that the monomeric form of WT rhodopsin and its constitutively active mutants M257Y, G90D, and T94I, reconstituted into HDL particles are effectively phosphorylated by GRK1, as well as two more ubiquitously expressed subtypes, GRK2 and GRK5. All versions of arrestin-1 tested (WT, pre-activated, and constitutively monomeric mutants) bind to monomeric rhodopsin and show the same selectivity for different functional forms of rhodopsin as in native disc membranes. Rhodopsin phosphorylation by GRK1 and GRK2 promotes arrestin-1 binding to a comparable extent, whereas similar phosphorylation by GRK5 is less effective, suggesting that not all phosphorylation sites on rhodopsin are equivalent in promoting arrestin-1 binding. The binding of WT arrestin-1 to phospho-opsin is comparable to the binding to its preferred target, P-Rh*, suggesting that in photoreceptors arrestin-1 only dissociates after opsin regeneration with 11-cis-retinal, which converts phospho-opsin into inactive phospho-rhodopsin that has lower affinity for arrestin-1. Reduced binding of arrestin-1 to the phospho-opsin form of G90D mutant likely contributes to night blindness caused by this mutation in humans.     

UniqTag: Content-Derived Unique and Stable Identifiers for Gene Annotation

When working on an ongoing genome sequencing and assembly project, it is rather inconvenient when gene identifiers change from one build of the assembly to the next. The gene labelling system described here, UniqTag, addresses this common challenge. UniqTag assigns a unique identifier to each gene that is a representative k-mer, a string of length k, selected from the sequence of that gene. Unlike serial numbers, these identifiers are stable between different assemblies and annotations of the same data without requiring that previous annotations be lifted over by sequence alignment. We assign UniqTag identifiers to ten builds of the Ensembl human genome spanning eight years to demonstrate this stability. The implementation of UniqTag in Ruby and an R package are available at https://github.com/sjackman/uniqtag sjackman/uniqtag. The R package is also available from CRAN: install.packages ("uniqtag"). Supplementary material and code to reproduce it is available at https://github.com/sjackman/uniqtag-paper.     

Double Knockout Mutants of Arabidopsis Grown under Normal Conditions Reveal that the Plastidial Phosphorylase Isozyme Participates in Transitory Starch Metabolism

In leaves of two starch-related single-knockout lines lacking either the cytosolic transglucosidase (also designated as disproportionating enzyme 2, DPE2) or the maltose transporter (MEX1), the activity of the plastidial phosphorylase isozyme (PHS1) is increased. In both mutants, metabolism of starch-derived maltose is impaired but inhibition is effective at different subcellular sites. Two constitutive double knockout mutants were generated (designated as dpe2-1 × phs1a and mex1 × phs1b) both lacking functional PHS1. They reveal that in normally grown plants, the plastidial phosphorylase isozyme participates in transitory starch degradation and that the central carbon metabolism is closely integrated into the entire cell biology. All plants were grown either under continuous illumination or in a light-dark regime. Both double mutants were compromised in growth and, compared with the single knockout plants, possess less average leaf starch when grown in a light-dark regime. Starch and chlorophyll contents decline with leaf age. As revealed by transmission electron microscopy, mesophyll cells degrade chloroplasts, but degradation is not observed in plants grown under continuous illumination. The two double mutants possess similar but not identical phenotypes. When grown in a light-dark regime, mesophyll chloroplasts of dpe2-1 × phs1a contain a single starch granule but under continuous illumination more granules per chloroplast are formed. The other double mutant synthesizes more granules under either growth condition. In continuous light, growth of both double mutants is similar to that of the parental single knockout lines. Metabolite profiles and oligoglucan patterns differ largely in the two double mutants.During the last two decades, biochemical analyses of starch metabolism in higher plants have been favored by the availability of large sets of insertion mutants deficient in a single starch-related gene product. Based on phenotypical characterization of these mutants followed by the identification of the respective locus in the genome, novel starch-related proteins were discovered that reside inside the plastid, in the cytosol, in the nucleus, and in the plastidial envelope membranes. Taken together, these results have largely altered the current view on starch metabolism (Zeeman et al., 2010; Fettke et al., 2012a; Smith, 2012).Despite this progress, phenotypical analyses of starch-related mutants are complex and, under certain circumstances, yield misleading conclusions. Loss of function of metabolic steps may cause the entire starch synthesizing or degrading process to become nonfunctional. In this case, mutants are expected to have starch levels that are significantly altered. If, however, single knockout mutants are capable of partially or fully compensating the loss of function by other routes, the resulting phenotypes are less obvious and more difficult to predict. Carbon fluxes through existing paths may be enhanced, or novel metabolic routes may be established that compensate the lost function. As an example, leaves of Arabidopsis (Arabidopsis thaliana) mutants constitutively lacking the plastidial hexose-phosphate isomerase strongly express a distinct plastidial Glc-6-P/orthophosphate antiporter isoform that in wild-type plants is found only in heterotrophic tissues (Kunz et al., 2010). In mesophyll cells of the mutant, the reductive pentose phosphate cycle cannot drive assimilatory starch biosynthesis, as chloroplasts are unable to convert Fru-6-P to Glc-6-P. However, their capacity of transporting Glc-6-P between the cytosolic and the chloroplastic compartment is strongly increased. Furthermore, nonfunctionality of some starch-related proteins can lead to enlarged or diminished metabolite pools that via sensing processes, lead to cellular alterations distant from central carbon metabolism. This complexity is evidenced by several starch-related Arabidopsis mutants that possess a largely altered plastidial ultrastructure and exhibit premature degradation of the entire chloroplast (Stettler et al., 2009; Cho et al., 2011).Furthermore, several starch-related enzymes are capable of forming homomeric or heteromeric complexes that are functionally relevant but, to some extent, variable (Delatte et al., 2005; Utsumi and Nakamura, 2006; Kubo et al., 2010; Emes and Tetlow, 2012; Nakamura et al., 2012; Streb et al., 2012).In starch or glycogen storing prokaryotic and eukaryotic cells, α-glucan phosphorylase (EC 2.4.1.1) is common. Initially, this enzyme was considered to be the main starch synthesizing activity (Hanes, 1940). Later, both starch and glycogen synthases have been discovered that utilize either ADPglucose or UDPglucose (or both; Deschamps et al., 2006) as hexosyl donor. Ample evidence has been presented that these enzymes are essential biosynthetic enzymes (Ballicora et al., 2003; Zeeman et al., 2010; Roach et al., 2012; Palm et al., 2013). Furthermore, it is widely accepted that in glycogen-storing cells, phosphorylase is indispensible for the degradation of the storage polysaccharide (Hwang et al., 1989; Alonso-Casajús et al., 2006; Wilson et al., 2010; Roach et al., 2012; Gazzerro et al., 2013).In plant cells, the metabolic function of phosphorylase is more complex and far from being clear. In lower and higher plants, two distinct phosphorylase types exist as plastid- and cytosol-specific isozymes and are designated as Pho1 (or, in Arabidopsis, PHS1) and Pho2 (PHS2), respectively. Based on the large differences in the affinities for glycogen, the plastidial and the cytosolic phosphorylases are also named as low-affinity (L-type) and high-affinity (H-type) isozymes, respectively. As starch is restricted to the plastids, only the Pho1 (PHS1) type appears to possess direct access to native starch and/or plastidial starch-derived α-glucans.Conflicting phenotypical features have been reported for several mutants possessing altered levels of the plastidial phosphorylase isozyme(s). In the starch-related mutant4 of the unicellular green alga Chlamydomonas reinhardtii, the lack of one plastidial Pho1 isozyme (designated as PhoB) was associated with a lower cellular starch content, abnormally shaped granules, a modified amylopectin structure, and an elevated amylose-to-amylopectin ratio when the cells were kept under nitrogen limitation (Dauvillée et al., 2006). These phenotypical features suggest an involvement of the plastidial phosphorylase PhoB in the biosynthesis of a storage polysaccharide resembling the reserve starch of higher plants. Similarly, a rapid incorporation of ¹⁴C into starch was observed when tuber discs from various transgenic potato lines were incubated with [U-¹⁴C]Glc-1-P. The rate of starch labeling was found to reflect the activity of the plastidial phosphorylase isozyme Pho1 (Fettke et al., 2010, 2012b). By contrast, transgenic potato (Solanum tuberosum) lines have been generated that due to expression of an antisense construct, possess a largely diminished total Pho1 activity in leaves. Leaf starch content is essentially unchanged compared with that of the wild-type plants, suggesting that under normal growth conditions, the plastidial phosphorylase is not necessarily involved in starch metabolism or, alternatively, can easily be replaced by other enzymes (Sonnewald et al., 1995). Likewise, the phenotype (including leaf starch content) of an Arabidopsis mutant lacking functional PHS1 has been reported not to differ from the wild type when the plants were grown under normal conditions. However, under water stress conditions, significantly more local leaf lesions have been reported to occur (Zeeman et al., 2004).When leaf discs from bean (Phaseolus vulgaris) or Arabidopsis plants were exposed to conditions favoring photorespiration (i.e. an atmosphere consisting of 30% [v/v] O₂ and 70% [v/v] N₂ but lacking CO₂), transitory starch was degraded in the light at a high rate and the plastidial Glc-6-P pool increased. In Arabidopsis mutants deficient in PHS1, the Glc monophosphate pool did not respond to photorespiratory conditions (Weise et al., 2006). These data lead to the conclusion that in illuminated leaves with very high rates of photorespiration, PHS1 is involved in the conversion of starch to Glc monophosphates but does not to participate in the nocturnal starch degradation.When studying several starch-related Arabidopsis mutants, we noticed that two single knockout mutations that both affect the maltose metabolism but differ in the subcellular location of the target protein possess a significantly increased PHS1 activity (Malinova et al., 2011a, 2011b). One mutant constitutively lacks the functional cytosolic transglucosidase (also designated as disproportionating enzyme2; DPE2) and, therefore, the cytosolic route of starch-derived maltose metabolism is impaired (Chia et al., 2004; Lu and Sharkey, 2004). The other mutant does not express the plastidial maltose transporter MEX1, resulting in a massively enlarged maltose pool (Niittylä et al., 2004). Thus, in the two mutants, the metabolism of starch-derived maltose is blocked at different subcellular sites, i.e. the cytosol and the chloroplast. The enhanced PHS1 activity as observed for the two mutants is difficult to explain unless a more general function of the phosphorylase isozyme in starch metabolism is assumed.For a detailed functional analysis of PHS1-related processes, we generated two types of constitutive PHS1-deficient double knockout mutants (DPE2 plus PHS1 or MEX1 plus PHS1) and studied their phenotypes in more detail under various experimental conditions. Shoot growth and leaf chlorophyll content are reduced when the plants are grown under a light-dark regime, but under continuous illumination, both effects are far less pronounced. Based on these data, we propose that the plastidial phosphorylase participates in both the turnover of transitory starch and in the maintenance of intact chloroplasts.     

Sequence elements in both subunits of the DNA fragmentation factor are essential for its nuclear transport

DNA cleavage is a biochemical hallmark of apoptosis. In humans, apoptotic DNA cleavage is executed by DNA fragmentation factor (DFF) 40. In proliferating cells DFF40 is expressed in the presence of its chaperone and inhibitor DFF45, which results in the formation of the DFF complex. Here, we present a systematic analysis of the nuclear import of the DFF complex. Our in vitro experiments demonstrate that the importin alpha/beta-heterodimer mediates the translocation of the DFF complex from the cytoplasm to the nucleus. Both DFF subunits interact directly with the importin alpha/beta-heterodimer. However, importin alpha/beta binds more tightly to the DFF complex compared with the individual subunits. Additionally, the isolated C-terminal regions of both DFF subunits together bind importin alpha/beta more strongly than the individual C termini. Our results from in vivo studies reveal that the C-terminal regions of both DFF subunits harbor nuclear localization signals. Furthermore, nuclear import of the DFF complex requires the C-terminal regions of both subunits. In more detail, one basic cluster in the C-terminal region of each subunit, DFF40 (RLKRK) and DFF45 (KRAR), is essential for nuclear accumulation of the DFF complex. Based on these findings two alternative models for the interaction of importin alpha/beta with the DFF complex are presented.     

Patient ratings of chewing ability from a randomised crossover trial: lingualised vs. first premolar/canine-guided occlusion for complete dentures

Background: Complex procedures involving a facebow transfer and the use of lingualised teeth are deemed to have a positive influence on the chewing ability with complete dentures. Objectives: To determine if patients’ ratings of their ability to chew depend on the method of complete denture fabrication. Methods: Edentulous patients (n = 20) participated in a within‐subject crossover trial. Each patient received two sets of new complete dentures. One pair was manufactured based on intraoral tracing of centric relation and facebow transfer; semi‐anatomical teeth with lingualised occlusion denture (LOD) were chosen. The second pair was made using a simplified procedure without facebow transfer; jaw relations were recorded with wax occlusion rims, and anatomical teeth with a first premolar/canine‐guidance (CGD) were selected. The dentures were delivered in randomised order, and each was worn for 3 months. Three months after delivery, patients’ ratings of each new prosthesis were recorded on visual analogue scales for their ability to chew seven index foods. Repeated measurements analysis of variance was performed to investigate possible carry‐over effects accounting for confounding by treatment period. Results: When comparing the two treatments, participants rated their ability to chew in general, to masticate carrots, hard sausage, steak and raw apple in particular, was significantly better with the CGD (anatomical teeth) than with the LOD (p < 0.05). Conclusion: Comprehensive methods for the fabrication of complete dentures including semi‐anatomical lingualised teeth and a full registration do not seem to influence the perceived chewing ability, when compared with more simple procedures. Chewing ability for tough foods appears to benefit from the use of anatomical teeth.     

Expression of PSACH-associated mutant COMP in tendon fibroblasts leads to increased apoptotic cell death irrespective of the secretory characteristics of mutant COMP.

OBJECTIVE: Pseudoachondroplasia (PSACH) is a dominantly inherited chondrodysplasia associated with mutations of cartilage oligomeric matrix protein (COMP), characterized clinically by disproportionate dwarfism and laxity of joints and ligaments. Studies in chondrocytes and cartilage biopsies suggest that the cartilage disease is caused by retention of mutant COMP in the endoplasmic reticulum of chondrocytes and by disruption of the collagen network of the extracellular matrix. The pathogenesis of the tendon disease remains unclear in the absence of a cell culture model, with available tendon biopsies leading to conflicting results with respect to the intracellular retention of mutant COMP. METHODS: We established a cell culture model using adenoviral gene transfer in tendon fibroblast cultures. We compared the effect of expression of three PSACH-associated COMP mutants and the wildtype protein on COMP secretion, matrix composition and cellular viability. RESULTS: Our results show that mutants D475N and D469Delta are retained within the endoplasmic reticulum of tendon cells similar to what is known from chondrocytes, whereas mutant H587R is secreted like wildtype COMP. In spite of this difference, the collagen I matrix formed in culture appears disturbed for all three mutants. All COMP-mutants induce apoptotic cell death irrespective of their differing secretion patterns. CONCLUSION: Pathogenic pathways leading to tendon disease in humans appear to be heterogeneous between different COMP mutants.