The nascent polypeptide‐associated complex is a key regulator of proteostasis

The adaptation of protein synthesis to environmental and physiological challenges is essential for cell viability. Here, we show that translation is tightly linked to the protein‐folding environment of the cell through the functional properties of the ribosome bound chaperone NAC (nascent polypeptide‐associated complex). Under non‐stress conditions, NAC associates with ribosomes to promote translation and protein folding. When proteostasis is imbalanced, NAC relocalizes from a ribosome‐associated state to protein aggregates in its role as a chaperone. This results in a functional depletion of NAC from the ribosome that diminishes translational capacity and the flux of nascent proteins. Depletion of NAC from polysomes and re‐localisation to protein aggregates is observed during ageing, in response to heat shock and upon expression of the highly aggregation‐prone polyglutamine‐expansion proteins and Aβ‐peptide. These results demonstrate that NAC has a central role as a proteostasis sensor to provide the cell with a regulatory feedback mechanism in which translational activity is also controlled by the folding state of the cellular proteome and the cellular response to stress.     

Organism complexity anti-correlates with proteomic beta-aggregation propensity

We introduce a novel approach to estimate differences in the beta-aggregation potential of eukaryotic proteomes. The approach is based on a statistical analysis of the beta-aggregation propensity of polypeptide segments, which is calculated by an equation derived from first principles using the physicochemical properties of the natural amino acids. Our analysis reveals a significant decreasing trend of the overall beta-aggregation tendency with increasing organism complexity and longevity. A comparison with randomized proteomes shows that natural proteomes have a higher degree of polarization in both low and high beta-aggregation prone sequences. The former originates from the requirement of intrinsically disordered proteins, whereas the latter originates from the necessity of proteins with a stable folded structure.     

A comparative study of the relationship between protein structure and beta-aggregation in globular and intrinsically disordered proteins

A growing number of proteins are being identified that are biologically active though intrinsically disordered, in sharp contrast with the classic notion that proteins require a well-defined globular structure in order to be functional. At the same time recent work showed that aggregation and amyloidosis are initiated in amino acid sequences that have specific physico-chemical properties in terms of secondary structure propensities, hydrophobicity and charge. In intrinsically disordered proteins (IDPs) such sequences would be almost exclusively solvent-exposed and therefore cause serious solubility problems. Further, some IDPs such as the human prion protein, synuclein and Tau protein are related to major protein conformational diseases. However, this scenario contrasts with the large number of unstructured proteins identified, especially in higher eukaryotes, and the fact that the solubility of these proteins is often particularly good. We have used the algorithm TANGO to compare the beta aggregation tendency of a set of globular proteins derived from SCOP and a set of 296 experimentally verified, non-redundant IDPs but also with a set of IDPs predicted by the algorithms DisEMBL and GlobPlot. Our analysis shows that the beta-aggregation propensity of all-alpha, all-beta and mixed alpha/beta globular proteins as well as membrane-associated proteins is fairly similar. This illustrates firstly that globular structures possess an appreciable amount of structural frustration and secondly that beta-aggregation is not determined by hydrophobicity and beta-sheet propensity alone. We also show that globular proteins contain almost three times as much aggregation nucleating regions as IDPs and that the formation of highly structured globular proteins comes at the cost of a higher beta-aggregation propensity because both structure and aggregation obey very similar physico-chemical constraints. Finally, we discuss the fact that although IDPs have a much lower aggregation propensity than globular proteins, this does not necessarily mean that they have a lower potential for amyloidosis.     

Nucleotide sugars and glycosyltransferases for synthesis of cell wall matrix polysaccharides

The current interest in cell wall biosynthesis is expanding because of the increasing evidence that the properties of the cell wall mediate cellular interactions during growth, development and differentiation. Much effort has been put forward to the identification of glycosyltransferases because of their obvious importance in polysaccharide synthesis. Enzymes involved in nucleotide sugar production and transport are also important because of the potential to manipulate the composition of cell walls through substrate level control. Molecular genetics have begun to uncover genes for important enzymes in polysaccharide biosynthesis including glycosyltransferases and enzymes of nucleotide sugar metabolism; but at this time, much is inferred from comparisons to bacteria, yeast and animal cells. This review examines the production and transport of nucleotide sugars, the protein structure of glycosyltransferases, and implications for the cellular mechanisms of cell wall biosynthesis.     

A nucleo-cytoplasmic SR protein functions in viral IRES-mediated translation initiation

A significant number of viral and cellular mRNAs utilize cap-independent translation, employing mechanisms distinct from those of canonical translation initiation. Cap-independent translation requires noncanonical, cellular RNA-binding proteins; however, the roles of such proteins in ribosome recruitment and translation initiation are not fully understood. This work demonstrates that a nucleo-cytoplasmic SR protein, SRp20, functions in internal ribosome entry site (IRES)-mediated translation of a viral RNA. We found that SRp20 interacts with the cellular RNA-binding protein, PCBP2, a protein that binds to IRES sequences within the genomic RNAs of certain picornaviruses and is required for viral translation. We utilized in vitro translation in HeLa cell extracts depleted of SRp20 to demonstrate that SRp20 is required for poliovirus translation initiation. Targeting SRp20 in HeLa cells with short interfering RNAs resulted in inhibition of SRp20 protein expression and a corresponding decrease in poliovirus translation. Our data have identified a previously unknown function of an SR protein (i.e., the stimulation of IRES-mediated translation), further documenting the multifunctional nature of this important class of cellular RNA-binding proteins.     

Characterization of Ccw7p cell wall proteins and the encoding genes of Saccharomyces cerevisiae wine yeast strains: relevance for flor formation

The specific flavour of Sherry-type wines requires aromatic compounds produced as by-products of the oxidative metabolism of yeasts that are able to form a biofilm (flor) at the wine surface. A similar yeast pellicle develops on the surface of 'Tokaji Szamorodni', one of the traditional Hungarian botrytized wines, during maturation. In this work, patterns of biotinylated cell wall proteins extracted from film-forming and nonfilm-forming Saccharomyces cerevisiae strains were compared. It was found that all the tested 23 film-forming 'Szamorodni' yeast strains had a decreased size of the Ccw7/Hsp150 protein, one of the members of the Pir-protein family. Sequencing of the encoding genes revealed that the strains were lacking three out of the 11 repeating sequences characteristic to this protein family. One of the film-forming strains contained CCW7 alleles of different length, which was generated by intragenic tandem duplication of a sequence containing two repetitive domains. Unlike the film-forming strains, 16 nonfilm-forming wine yeasts isolated from a different botrytized wine, 'Tokaji Aszu', showed pronounced polymorphism of the CCW7 locus. It is highly probable that the modified Ccw7 protein does not contribute to the increased hydrophobicity of film-forming strains but it may influence molecular reorganization of the cell wall during stress adaptation.     

应用酵母双杂交系统筛选AMPK相互作用蛋白

一磷酸腺苷激活蛋白激酶(AMPK)是调节体内代谢平衡的丝氨酸/苏氨酸蛋白激酶。应用酵母双杂交系统,以AMPKβ1亚基作为"诱饵"蛋白,筛选均一化的人源cDNA文库,寻找与AMPK相互作用的蛋白。通过对150个阳性克隆进行验证,最终得到了63个与AMPKβ1亚基相互作用的蛋白。其中,包括代谢酶、转录因子或转录相关蛋白、蛋白转运相关蛋白、GTP结合蛋白、支架蛋白、细胞周期调节蛋白、RNA结合蛋白等以及一些未知功能的蛋白。从酵母双杂交的结果来看,AMPK不仅在代谢领域,而且在许多非代谢领域,如核受体及其它转录因子的调节、信号转导、DNA修复及细胞周期调节等,可能都起到非常重要的作用。     

利用酵母双杂交系统筛选与黄瓜花叶病毒外壳蛋白互作的寄主蛋白

利用酵母双杂交系统,以黄瓜花叶病毒(Cucumber mosaic virus,CMV)的外壳蛋白(coat protein,CP)为诱饵,从番茄叶片c DNA文库中筛选与其互作的蛋白。结果显示,诱饵载体pBT3-SUC-CMV-CP均能在酵母细胞中正确表达,无自激活活性而且对酵母无毒性;通过对酵母双杂交文库的筛选和回转验证,共获得了98个阳性克隆,分别编码67个可能与CMV-CP相互作用的蛋白,分别参与植物防御反应、光合作用、物质转运、信号转导、能量代谢、氨基酸代谢、细胞壁的形态建成、植物的激素代谢等。本研究结果表明,CMV CP可同时调控寄主的多个代谢过程,在CMV的致病过程中有多重功能。     

小麦Ven型胞质雄性不育植株与可育植株花药蛋白质组差异研究

普通小麦具有偏凸山羊草（Ae. ventricosa）细胞质的不育系为Ven型胞质雄性不育系（Ven cytoplasmic male sterility, Ven CMS）,是粘类小麦CMS的一种类型。该研究对小麦Ven型雄性不育系冀5418A及其同型保持系冀5419B的单核期和二核期的花药进行差异蛋白质组学分析,探讨小麦质核互作雄性不育的分子机制。通过双向电泳分离花药蛋白,基质辅助激光解析飞行时间串联质谱（MALDI TOF TOF）对差异表达蛋白进行质谱鉴定,利用生物信息学进行差异表达蛋白鉴定和功能注释分析。结果表明,在分子量19.0～100.0 kD、等电点4～7线性范围内,共检测到约2 000个蛋白点。2个时期共检测到差异蛋白98个,其中两个时期差异表达变化一致的蛋白点56个;数据库搜索获得鉴定的蛋白点41个,其中18个蛋白的表达量在冀5418A 中显著下调,23个在冀5418B 中明显下调。在不育系和可育系中均有参与能量代谢、活性氧代谢、核糖体合成、花粉物质合成的差异蛋白。GO分析预测差异蛋白生物学过程多涉及电子传递和能量代谢、核糖体代谢、活性氧代谢等,细胞组成主要是在膜区域和线粒体,分子功能主要是DNA和RNA结合功能和水解酶等。KEGG分析表明,较多蛋白分布于碳水化合物代谢、活性氧代谢和蛋白组装和折叠途径。推测不育系冀5418A 的雄性不育性除了涉及能量代谢、活性氧清除过程,核糖体蛋白、伴侣蛋白等也有重要作用,雄性不育性可能还与蛋白质加工、物质合成过程的紊乱有关。     

Gel and gel-free proteomics to identify Saccharomyces cerevisiae cell surface proteins

The study of Saccharomyces cerevisiae cell surface proteins was performed because of their important role in cell wall biogenesis and in the physiology of the yeast. Two different proteomic approaches were carried out. First, proteins loosely associated or S–S linked to structural wall components were released by treatment of whole intact cells with dithiothreitol, separated by 2D-PAGE and identified by mass spectrometry. Second, cell surface-exposed proteins (surfome) were digested with trypsin and DTT from whole intact cells, and analyzed by LC–MS/MS. Ninety-nine different proteins were identified: 67 with DTT treatment and 52 with DTT and trypsin digestion. These proteins were classified in different cellular processes: control of cell wall organization, cell rescue, defence, and virulence, protein fate, protein synthesis and metabolism. Most of the proteins have already been reported as present on the cell surface showing that the yeast cell surface is composed not only by typical but also by atypical cell wall proteins. “Bona fide” cell wall proteins were identified by both protocols but a higher number with the non-gel strategy. However, only 20% of the proteins identified were common to both protocols, thus, for a complete knowledge of the cell surface proteome, several strategies have to be used.     

A molecular dynamics approach to the structural characterization of amyloid aggregation

A novel computational approach to the structural analysis of ordered beta-aggregation is presented and validated on three known amyloidogenic polypeptides. The strategy is based on the decomposition of the sequence into overlapping stretches and equilibrium implicit solvent molecular dynamics (MD) simulations of an oligomeric system for each stretch. The structural stability of the in-register parallel aggregates sampled in the implicit solvent runs is further evaluated using explicit water simulations for a subset of the stretches. The beta-aggregation propensity along the sequence of the Alzheimer's amyloid-beta peptide (Abeta(42)) is found to be highly heterogeneous with a maximum in the segment V(12)HHQKLVFFAE(22) and minima at S(8)G(9), G(25)S(26), G(29)A(30), and G(38)V(39), which are turn-like segments. The simulation results suggest that these sites may play a crucial role in determining the aggregation tendency and the fibrillar structure of Abeta(42). Similar findings are obtained for the human amylin, a 37-residue peptide that displays a maximal beta-aggregation propensity at Q(10)RLANFLVHSSNN(22) and two turn-like sites at G(24)A(25) and G(33)S(34). In the third application, the MD approach is used to identify beta-aggregation "hot-spots" within the N-terminal domain of the yeast prion Ure2p (Ure2p(1-94)) and to design a double-point mutant (Ure2p-N4748S(1-94)) with lower beta-aggregation propensity. The change in the aggregation propensity of Ure2p-N4748S(1-94) is verified in vitro using the thioflavin T binding assay.     

Protein-RNA cross-linking in the ribosomes of yeast under oxidative stress

Living systems have efficient degradative pathways for dealing with the fact that reactive oxygen species (ROS) derived from cellular metabolism and the environment oxidatively damage proteins and DNA. But aggregation and cross-linking can occur as well, leading to a series of problems including disruption of cellular regulation, mutations, and even cell death. The mechanism(s) by which protein aggregation occurs and the macromolecular species involved are poorly understood. In the study reported here, evidence is provided for a new type of aggregate between proteins and RNA in ribosomes. While studying the effect of oxidative stress induced in the yeast proteome it was noted that ribosomal proteins were widely oxidized. Eighty six percent of the proteins in yeast ribosomes were found to be carbonylated after stressing yeast cell cultures with hydrogen peroxide. Moreover, many of these proteins appeared to be cross-linked based on their coelution patterns during RPC separation. Since they were not in direct contact, it was not clear how this could occur unless it was through the RNA separating them in the ribosome. This was confirmed in a multiple-step process, the first being derivatization of all carbonylated proteins in cell lysates with biotin hydrazide through Schiff base formation. Following reduction of Schiff bases with sodium cyanoborohydride, biotinylated proteins were selected from cell lysates with avidin affinity chromatography. Oxidized proteins thus captured were then selected again using boronate affinity chromatography to capture vicinal diol-containing proteins. This would include proteins cross-linked to an RNA fragment containing a ribose residue with 2',3'-hydroxyl groups. Some glycoproteins would also be selected by this process. LC/MS/MS analyses of tryptic peptides derived from proteins captured by this process along with MASCOT searches resulted in the identification of 37 ribosomal proteins that appear to be cross-linked to RNA. Aggregation of proteins with ribosomal RNA has not been previously reported. The probable impact of this phenomenon cells is to diminish the protein synthesis capacity.     

The small subunit processome is required for cell cycle progression at G1

Without ribosome biogenesis, translation of mRNA into protein ceases and cellular growth stops. We asked whether ribosome biogenesis is cell cycle regulated in the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe, and we determined that it is not regulated in the same manner as in metazoan cells. We therefore turned our attention to cellular sensors that relay cell size information via ribosome biogenesis. Our results indicate that the small subunit (SSU) processome, a complex consisting of 40 proteins and the U3 small nucleolar RNA necessary for ribosome biogenesis, is not mitotically regulated. Furthermore, Nan1/Utp17, an SSU processome protein, does not provide a link between ribosome biogenesis and cell growth. However, when individual SSU processome proteins are depleted, cells arrest in the G1 phase of the cell cycle. This arrest was further supported by the lack of staining for proteins expressed in post-G1. Similarly, synchronized cells depleted of SSU processome proteins did not enter G2. This suggests that when ribosomes are no longer made, the cells stall in the G1. Therefore, yeast cells must grow to a critical size, which is dependent upon having a sufficient number of ribosomes during the G1 phase of the cell cycle, before cell division can occur.     

The Proteome Response to Amyloid Protein Expression In Vivo

Protein misfolding disorders such as Alzheimer, Parkinson and transthyretin amyloidosis are characterized by the formation of protein amyloid deposits. Although the nature and location of the aggregated proteins varies between different diseases, they all share similar molecular pathways of protein unfolding, aggregation and amyloid deposition. Most effects of these proteins are likely to occur at the proteome level, a virtually unexplored reality. To investigate the effects of an amyloid protein expression on the cellular proteome, we created a yeast expression system using human transthyretin (TTR) as a model amyloidogenic protein. We used Saccharomyces cerevisiae, a living test tube, to express native TTR (non-amyloidogenic) and the amyloidogenic TTR variant L55P, the later forming aggregates when expressed in yeast. Differential proteome changes were quantitatively analyzed by 2D-differential in gel electrophoresis (2D-DIGE). We show that the expression of the amyloidogenic TTR-L55P causes a metabolic shift towards energy production, increased superoxide dismutase expression as well as of several molecular chaperones involved in protein refolding. Among these chaperones, members of the HSP70 family and the peptidyl-prolyl-cis-trans isomerase (PPIase) were identified. The latter is highly relevant considering that it was previously found to be a TTR interacting partner in the plasma of ATTR patients but not in healthy or asymptomatic subjects. The small ubiquitin-like modifier (SUMO) expression is also increased. Our findings suggest that refolding and degradation pathways are activated, causing an increased demand of energetic resources, thus the metabolic shift. Additionally, oxidative stress appears to be a consequence of the amyloidogenic process, posing an enhanced threat to cell survival.     

Amyloid-like properties of Saccharomyces cerevisiae cell wall glucantransferase Bgl2p

Glucantransferase Bgl2p is a major conserved cell wall constituent described for a wide range of yeast species. In the baker’s yeast Saccharomyces cerevisiae it is the only non-covalently bound cell wall protein that cannot be released from cell walls by sequential SDS and trypsin treatment. It contains 7 amyloidogenic determinants. Circular dichroism analysis and fluorescence spectroscopy with thioflavin T indicate the presence of β-sheet structures in Bgl2p isolates. Bgl2p forms fibrils, a process that is enforced in the presence of other cell wall components. Thus the data obtained is the first evidence for amyloid-like properties of yeast cell wall protein – glucantransferase Bgl2p.     

The WD-repeat protein GRWD1: potential roles in myeloid differentiation and ribosome biogenesis

A cDNA fragment originally identified in U-937 cells as a vitamin D(3)-regulated gene is here designated the glutamate-rich WD-repeat (GRWD1) gene. WD-repeat proteins are a class of functionally divergent molecules that cooperate with other proteins to regulate cellular processes. GRWD1 encodes a 446-amino-acid protein containing a glutamate-rich region followed by four WD repeats. The yeast homologue of GRWD1, Rrb1, has been shown to be an essential protein involved in ribosome biogenesis. Northern analysis of GRWD1 message levels in the myeloid cell line HL-60 undergoing differentiation induced by vitamin D(3) or retinoic acid demonstrate downregulation coincident with slowing of cellular proliferation. A siRNA designed to downregulate GRWD1 similarly results in a decrease in cellular proliferation within 293 cells. Metabolic labeling of cells expressing the siRNA to GRWD1 shows a decrease in global protein synthesis. Finally, nuclear fractionation studies show cosedimentation of GRWD1 with preribosomal complexes, as well as the WD-repeat-containing protein Bop1, which has previously been implicated in ribosome biogenesis. These studies suggest that within mammalian cells GRWD1 plays a role in ribosome biogenesis and during myeloid differentiation its levels are regulated.