Trends in Biochemical Sciences - Current Research Articles
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Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 4 Jennifer F. Kugel, James A. Goodrich Non-coding RNAs (ncRNAs) are now recognized as active participants in controlling many biological processes. Indeed, these products of transcription can even control the process of transcription itself. In the past several years, ncRNAs have been found to regulate transcription of single genes, as well as entire transcriptional programs, affecting the expression of hundreds to thousands of genes in response to developmental or environmental signals. Compared to more classical protein regulators, the list of ncRNAs that regulate mRNA transcription in mammalian cells is still small; however, the rate at which new ncRNA transcriptional regulators are being discovered is rapid, suggesting that models for how gene expression is controlled will continue to be redefined as this field develops.
Publication year: 2012 Source:Trends in Biochemical Sciences Sérgio F. de Almeida, Maria Carmo-Fonseca In human cell nuclei, the vast majority of mRNA precursors (pre-mRNA) are spliced in more than one way. The process of alternative splicing creates enormous biological complexity from a limited number of genes, and its misregulation often leads to disease. Splicing regulation relies primarily on RNA-binding proteins that recognize specific target features in the pre-mRNA. Evidence accumulated over the past decade has further shown that most splicing occurs co-transcriptionally and that transcription modulates splicing. More recently, chromatin emerged as a novel node in the network of splicing regulatory interactions. Chromatin structure influences splicing choices but splicing can also actively modulate the pattern of histone modification in chromatin. This review discusses how splicing, transcription and chromatin are interwoven bi-directionally.
Publication year: 2011 Source:Trends in Biochemical Sciences, Volume 36, Issue 12 Justin L. MacCallum, D. Peter Tieleman The partitioning of amino acid sidechains into the membrane is a key aspect of membrane protein folding. However, lipid bilayers exhibit rapidly changing physicochemical properties over their nanometer-scale thickness, which complicates understanding the thermodynamics and microscopic details of membrane partitioning. Recent data from diverse approaches, including protein insertion by the Sec translocon, folding of a small beta-barrel membrane protein and computer simulations of the exact distribution of a variety of small molecules and peptides, have joined older hydrophobicity scales for membrane protein prediction. We examine the correlations among the scales and find that they are remarkably correlated even though there are large differences in magnitude. We discuss the implications of these scales for understanding membrane protein structure and function.
Publication year: 2012 Source:Trends in Biochemical Sciences Jorge Moscat, Maria T. Diaz-Meco Since its initial discovery as an atypical protein kinase C (PKC)-interacting protein, p62 has emerged as a crucial molecule in a myriad of cellular functions. This multifunctional role of p62 is explained by its ability to interact with several key components of various signaling mechanisms. Not surprisingly, p62 is required for tumor transformation owing to its roles as a key molecule in nutrient sensing, as a regulator and substrate of autophagy, as an inducer of oxidative detoxifying proteins, and as a modulator of mitotic transit and genomic stability; all crucial events in the control of cell growth and cancer.
Publication year: 2012 Source:Trends in Biochemical Sciences Barbara Chaneton, Eyal Gottlieb Cancer cell metabolism is exemplified by high glucose consumption and lactate production. Pyruvate kinase (PK), which catalyzes the final step of glycolysis, has emerged as a potential regulator of this metabolic phenotype. The M2 isoform of PK (PKM2) is highly expressed in cancer cells. However, the mechanisms by which PKM2 coordinates high energy requirements with high anabolic activities to support cancer cell proliferation are still not completely understood. Current research has elucidated novel regulatory mechanisms for PKM2, contributing to its important role in cancer. This review summarizes the current understanding and explores future directions in the field, highlighting controversies regarding the activity and specificity of PKM2 in cancer. In light of this knowledge, the potential therapeutic implications and strategies are critically discussed.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 4 Danny C. Leung, Matthew C. Lorincz Retrotransposons, such as endogenous retroviruses (ERVs), have colonized the genomes of all metazoans. As retrotransposition can be deleterious, numerous pathways have evolved to repress the expression of these parasitic elements. For example, methylation of the fifth carbon of the cytosine base in DNA (5-methylcytosine, 5mC) is required for transcriptional silencing of ERVs in differentiated cells. However, this epigenetic mark is generally dispensable for ERV silencing during early stages of mouse embryogenesis and in mouse embryonic stem cells (mESCs). In this Opinion, we evaluate recent findings on the exceptional role of covalent modifications of histones in ERV silencing in these cell types. In addition, we discuss the potential role of TET proteins, which catalyze the oxidation of 5mC to 5-hydroxymethylcytosine (5hmC), in perturbing transcriptional silencing, and propose that histone modification-based pathways may be used to silence ERVs during those developmental stages when DNA methylation-mediated silencing is compromised.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 1 Walter Fast, Peter A. Tipton N-Acyl-L-homoserine lactones (AHLs) are a major class of quorum-sensing signals used by Gram-negative bacteria to regulate gene expression in a population-dependent manner, thereby enabling group behavior. Enzymes capable of generating and catabolizing AHL signals are of significant interest for the study of microbial ecology and quorum-sensing pathways, for understanding the systems that bacteria have evolved to interact with small-molecule signals, and for their possible use in therapeutic and industrial applications. The recent structural and functional studies reviewed here provide a detailed insight into the chemistry and enzymology of bacterial communication.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 4 Yuan Liu, Samuel H. Wilson The expansion of trinucleotide repeat (TNR) sequences in human DNA is considered to be a key factor in the pathogenesis of more than 40 neurodegenerative diseases. TNR expansion occurs during DNA replication and also, as suggested by recent studies, during the repair of DNA lesions produced by oxidative stress. In particular, the oxidized guanine base 8-oxoguanine within sequences containing CAG repeats may induce formation of pro-expansion intermediates through strand slippage during DNA base excision repair (BER). In this article, we describe how oxidized DNA lesions are repaired by BER and discuss the importance of the coordinated activities of the key repair enzymes, such as DNA polymerase ?, flap endonuclease 1 (FEN1) and DNA ligase, in preventing strand slippage and TNR expansion.
Publication year: 2012 Source:Trends in Biochemical Sciences Renée F. Johnson, Neil D. Perkins Among the characteristics acquired by many tumour cells is a shift from using oxidative phosphorylation to using glycolysis for ATP production. Although the nuclear factor (NF)-?B family of transcriptional regulators have important roles in tumorigenesis, their ability to function as regulators of metabolism has only been recently investigated. This has revealed the importance of crosstalk between NF-?B, the p53 tumour suppressor and other crucial cell signalling pathways. This review discusses the mechanisms through which NF-?B regulates tumour cell metabolism and the important role of p53 in determining the consequences of NF-?B activity. It also proposes a model in which NF-?B contributes to the shift to glycolytic ATP production through regulation of both nuclear and mitochondrial gene expression.
Publication year: 2012 Source:Trends in Biochemical Sciences Fabian Fischer, Andrea Hamann, Heinz D. Osiewacz Mitochondria are organelles of eukaryotic cells with various functions. Best known is their role in energy transduction leading to the formation of ATP. As byproducts of this process, reactive oxygen species (ROS) are formed that can damage different types of molecules leading to mitochondrial dysfunction. Different quality control (QC) mechanisms keep mitochondria functional. Although several components involved in mitochondrial QC have been characterized in some detail, others remain to be integrated into what is currently emerging as a hierarchical network of interacting pathways. The elucidation of this network holds the key to the understanding of complex biological processes such as aging and the development of age-related diseases.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 3 Monique Gangloff TLR4 is unique among pathogen-recognition receptors in that it initiates different pathways in different cellular locations. Binding of a bridging factor, Mal, allows recruitment of an adapter protein, MyD88, at the plasma membrane, which leads to the production of proinflammatory cytokines. Upon internalization, TLR4 uses a different bridging factor, TRAM, to activate a MyD88-independent pathway that results in type I interferon expression. Interestingly, both Mal and TRAM are localised initially at the plasma membrane. In this Opinion, I suggest a possible mechanism by which endosomal acidification triggers the differential adaptor usage of TLR4. I discuss the evidence of the pH sensitivity of TLR4 and propose a new dimerisation mode for TLR4 based on the crystal structure of the related receptor TLR3 bound to its ligand, double-stranded RNA.
Publication year: 2012 Source:Trends in Biochemical Sciences Daniel R. Semlow, Jonathan P. Staley The faithful expression of genes requires that cellular machinery select substrates with high specificity at each step in gene expression. High specificity is particularly important at the stage of nuclear pre-mRNA splicing, during which the spliceosome selects splice sites and excises intervening introns. With low specificity, the usage of alternative sites would yield insertions, deletions and frame shifts in mRNA. Recently, biochemical, genetic and genome-wide approaches have significantly advanced our understanding of splicing fidelity. In particular, we have learned that DExD/H-box ATPases play a general role in rejecting and discarding suboptimal substrates and that these factors serve as a paradigm for proofreading NTPases in other systems. Recent advances have also defined fundamental questions for future investigations.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 4 Michelle Pirruccello, Pietro De Camilli The precise regulation of phosphoinositide lipids in cellular membranes is crucial for cellular survival and function. Inositol 5-phosphatases have been implicated in a variety of disorders, including various cancers, obesity, type 2 diabetes, neurodegenerative diseases and rare genetic conditions. Despite the obvious impact on human health, relatively little structural and biochemical information is available for this family. Here, we review recent structural and mechanistic work on the 5-phosphatases with a focus on OCRL, whose loss of function results in oculocerebrorenal syndrome of Lowe and Dent 2 disease. Studies of OCRL emphasize how the actions of 5-phosphatases rely on both intrinsic and extrinsic membrane recognition properties for full catalytic function. Additionally, structural analysis of missense mutations in the catalytic domain of OCRL provides insight into the phenotypic heterogeneity observed in Lowe syndrome and Dent disease.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 2 Joshua S. Silverman, Jeffrey R. Skaar, Michele Pagano In response to genotoxic stress, eukaryotic cells activate the DNA damage response (DDR), a series of pathways that coordinate cell cycle arrest and DNA repair to prevent deleterious mutations. In addition, cells possess checkpoint mechanisms that prevent aneuploidy by regulating the number of centrosomes and spindle assembly. Among these mechanisms, ubiquitin-mediated degradation of key proteins has an important role in the regulation of the DDR, centrosome duplication and chromosome segregation. This review discusses the functions of a group of ubiquitin ligases, the SCF (SKP1-CUL1-F-box protein) family, in the maintenance of genome stability. Given that general proteasome inhibitors are currently used as anticancer agents, a better understanding of the ubiquitylation of specific targets by specific ubiquitin ligases may result in improved cancer therapeutics.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 4 Kristian K. Starheim, Kris Gevaert, Thomas Arnesen The majority of eukaryotic proteins are subjected to N-terminal acetylation (Nt-acetylation), catalysed by N-terminal acetyltransferases (NATs). Recently, the structure of an NAT–peptide complex was determined, and detailed proteome-wide Nt-acetylation patterns were revealed. Furthermore, Nt-acetylation just emerged as a multifunctional regulator, acting as a protein degradation signal, an inhibitor of endoplasmic reticulum (ER) translocation, and a mediator of protein complex formation. Nt-acetylation is regulated by acetyl-coenzyme A (Ac-CoA) levels, and thereby links metabolic cell states to cell death. The essentiality of NATs in humans is stressed by the recent discovery of a human hereditary lethal disease caused by a mutation in an NAT gene. Here, we discuss how these recent findings shed light on NATs as major protein regulators and key cellular players.
Publication year: 2012 Source:Trends in Biochemical Sciences Shimon Schuldiner It is usually assumed that to ensure proper function, membrane proteins must be inserted in a unique topology. However, a number of dimeric small multidrug transporters can function in the membrane in various topologies. Thus, the dimers can be a random mixture of NiCi (N and C termini facing the cell cytoplasm) and NoCo (N and C termini facing the outside) orientation. In addition, the dimer functions whether the two protomers are parallel (N and C termini of both protomers on the same side of the membrane) or antiparallel (N and C termini of each protomer on opposite sides of the membrane). This unique phenomenon provides strong support for a simple mechanism of transport where the directionality is determined solely by the driving force.
Publication year: 2012 Source:Trends in Biochemical Sciences Minna-Liisa Änkö, Karla M Neugebauer RNA-binding proteins (RBPs) impact every process in the cell; they act as splicing and polyadenylation factors, transport and localization factors, stabilizers and destabilizers, modifiers, and chaperones. RNA-binding capacity can be attributed to numerous protein domains that bind a limited repertoire of short RNA sequences. How is specificity achieved in cells? Here we focus on recent advances in determining the RNA-binding properties of proteins in vivo and compare these to in vitro determinations, highlighting insights into how endogenous RNA molecules are recognized and regulated. We also discuss the crucial contribution of structural determinations for understanding RNA-binding specificity and mechanisms.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 5 John E. Ladbury, Stefan T. Arold Noise caused by stochastic fluctuations in genetic circuits (transcription and translation) is now appreciated as a central aspect of cell function and phenotypic behavior. Noise has also been detected in signaling networks, but the origin of this noise and how it shapes cellular outcomes remain poorly understood. Here, we argue that noise in signaling networks results from the intrinsic promiscuity of protein–protein interactions (PPIs), and that this noise has shaped cellular signal transduction. Features promoted by the presence of this molecular signaling noise include multimerization and clustering of signaling components, pleiotropic effects of gross changes in protein concentration, and a probabilistic rather than a linear view of signal propagation.
Publication year: 2012 Source:Trends in Biochemical Sciences Nikolina Sekulic, Ben E. Black Centromeres direct faithful chromosome inheritance at cell division but are not defined by a conserved DNA sequence. Instead, a specialized form of chromatin containing the histone H3 variant, CENP-A, epigenetically specifies centromere location. We discuss current models where CENP-A serves as the marker for the centromere during the entire cell cycle in addition to generating the foundational chromatin for the kinetochore in mitosis. Recent elegant experiments have indicated that engineered arrays of CENP-A-containing nucleosomes are sufficient to serve as the site of kinetochore formation and for seeding centromeric chromatin that self-propagates through cell generations. Finally, recent structural and dynamic studies of CENP-A-containing histone complexes – before and after assembly into nucleosomes – provide models to explain underlying molecular mechanisms at the centromere.
Publication year: 2012 Source:Trends in Biochemical Sciences Nihal Altan-Bonnet, Tamas Balla Several RNA viruses have recently been shown to hijack members of the host phosphatidylinositol (PtdIns) 4-kinase (PI4K) family of enzymes. They use PI4K to generate membranes enriched in phosphatidylinositide 4-phosphate (PtdIns4P or PI4P) lipids, which can be used as replication platforms. Viral replication machinery is assembled on these platforms as a supramolecular complex and PtdIns4P lipids regulate viral RNA synthesis. This article highlights these recent studies on the regulation of viral RNA synthesis by PtdIns4P lipids. It explores the potential mechanisms by which PtdIns4P lipids can contribute to viral replication and discusses the therapeutic potential of developing antiviral molecules that target host PI4Ks as a form of panviral therapy.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 5 Aaron A. Hoskins, Melissa J. Moore With more than a hundred individual RNA and protein parts and a highly dynamic assembly and disassembly pathway, the spliceosome is arguably the most complicated macromolecular machine in the eukaryotic cell. This complexity has made kinetic and mechanistic analysis of splicing incredibly challenging. Yet, recent technological advances are now providing tools for understanding this process in much greater detail. Ranging from genome-wide analyses of splicing and creation of an orthogonal spliceosome in vivo, to purification of active spliceosomes and observation of single molecules in vitro, such new experimental approaches are yielding significant insight into the inner workings of this remarkable machine. These experiments are rewriting the textbooks, with a new picture emerging of a dynamic, malleable machine heavily influenced by the identity of its pre-mRNA substrate.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 3 Thomas Becker, Lena Böttinger, Nikolaus Pfanner Mitochondria, the powerhouses of the cell, import most of their proteins from the cytosol. It was originally assumed that mitochondria imported precursor proteins via a general pathway but recent studies have revealed a remarkable variety of import pathways and mechanisms. Currently, five different protein import pathways can be distinguished. However, the import machineries cooperate with each other and are connected to other systems that function in the respiratory chain, mitochondrial membrane organization, protein quality control and endoplasmic reticulum-mitochondria junctions. In this Opinion, we propose that mitochondrial protein import should not be seen as an independent task of the organelle and that a network of cooperating machineries is responsible for major mitochondrial functions.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 3 Eman Basha, Heather O’Neill, Elizabeth Vierling The small heat shock proteins (sHSPs) and the related ?-crystallins (?Cs) are virtually ubiquitous proteins that are strongly induced by a variety of stresses, but that also function constitutively in multiple cell types in many organisms. Extensive research has demonstrated that a majority of sHSPs and ?Cs can act as ATP-independent molecular chaperones by binding denaturing proteins and thereby protecting cells from damage due to irreversible protein aggregation. As a result of their diverse evolutionary history, their connection to inherited human diseases, and their novel protein dynamics, sHSPs and ?Cs are of significant interest to many areas of biology and biochemistry. However, it is increasingly clear that no single model is sufficient to describe the structure, function or mechanism of action of sHSPs and ?Cs. In this review, we discuss recent data that provide insight into the variety of structures of these proteins, their dynamic behavior, how they recognize substrates, and their many possible cellular roles.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 3 Thomas Wild, Patrick Cramer Gene transcription in the nucleus of eukaryotic cells is carried out by three related multisubunit RNA polymerases, Pol I, Pol II and Pol III. Although the structure and function of the polymerases have been studied extensively, little is known about their biogenesis and their transport from the cytoplasm (where the subunits are synthesized) to the nucleus. Recent studies have revealed polymerase assembly intermediates and putative assembly factors, as well as factors required for Pol II nuclear import. In this review, we integrate the available data into a model of Pol II biogenesis that provides a framework for future analysis of the biogenesis of all RNA polymerases.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 5 Sebastian Klinge, Felix Voigts-Hoffmann, Marc Leibundgut, Nenad Ban Eukaryotic ribosomes are significantly larger and more complex than their prokaryotic counterparts. This parallels the increased complexity of the associated cellular machinery responsible for translation initiation, ribosome assembly, and the regulation of protein synthesis in eukaryotic cells. The recently determined crystal structures of the small (40S) and large (60S) ribosomal subunits and the 80S ribosome now provide an atomic description of this essential molecular machine and reveal its eukaryote-specific features. In this review, we discuss the common structural principles underlying the evolution of both ribosomal subunits. The recently obtained structural information provides a framework for further genetic, biochemical and structural studies of eukaryotic ribosomes. At the same time, it facilitates a direct comparison between prokaryotic and eukaryotic ribosomal features.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 3 Ron Mittler, Andrija Finka, Pierre Goloubinoff In plants, the heat stress response (HSR) is highly conserved and involves multiple pathways, regulatory networks and cellular compartments. At least four putative sensors have recently been proposed to trigger the HSR. They include a plasma membrane channel that initiates an inward calcium flux, a histone sensor in the nucleus, and two unfolded protein sensors in the endoplasmic reticulum and the cytosol. Each of these putative sensors is thought to activate a similar set of HSR genes leading to enhanced thermotolerance, but the relationship between the different pathways and their hierarchical order is unclear. In this review, we explore the possible involvement of different thermosensors in the plant response to warming and heat stress.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 2 Christoph Bieniossek, Tsuyoshi Imasaki, Yuichiro Takagi, Imre Berger Protein complexes composed of many subunits carry out most essential processes in cells and, therefore, have become the focus of intense research. However, deciphering the structure and function of these multiprotein assemblies imposes the challenging task of producing them in sufficient quality and quantity. To overcome this bottleneck, powerful recombinant expression technologies are being developed. In this review, we describe the use of one of these technologies, MultiBac, a baculovirus expression vector system that is particularly tailored for the production of eukaryotic multiprotein complexes. Among other applications, MultiBac has been used to produce many important proteins and their complexes for their structural characterization, revealing fundamental cellular mechanisms.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 2 Huan-Xiang Zhou Association between signaling proteins and their cellular targets is generally thought to be highly specific (implicating a high association constant, Ka) and, at the same time, transient or short-lived (corresponding to a high dissociation rate constant, kd). However, a combination of high Ka and high kd would lead to a high association rate constant (ka = Kakd), which poses a problem because there is a limit to which ka can be increased, set by the diffusional approach to form the complex. In this Opinion article, I propose that having the signaling protein disordered before binding to the target provides a way out of this quandary. The intrinsic disorder of the signaling protein would decrease Ka without sacrificing the specificity of the complex, and thus would allow kd to be increased to a range appropriate for signaling.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 5 Jon Burdach, Mitchell R. O’Connell, Joel P. Mackay, Merlin Crossley Classical zinc fingers (ZFs) are one of the most common protein domains in higher eukaryotes and have been known for almost 30 years to act as sequence-specific DNA-binding domains. This knowledge has come, however, from the study of a small number of archetypal proteins, and a larger picture is beginning to emerge that ZF functions are far more diverse than originally suspected. Here, we review the evidence that a subset of ZF proteins live double lives, binding to both DNA and RNA targets and frequenting both the cytoplasm and the nucleus. This duality can create an important additional level of gene regulation that serves to connect transcriptional and post-transcriptional control.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 2 Rhesa Budhidarmo, Yoshio Nakatani, Catherine L. Day Ubiquitylation, the covalent modification of proteins by the addition of ubiquitin, relies on a cascade of enzymes that culminates in an E3 ligase that promotes the transfer of ubiquitin from an E2 enzyme to the target protein. The most prevalent E3 ligases contain a type of zinc-finger domain called RING, and although an essential role for the RING domain in ubiquitin transfer is widely accepted, the molecular mechanism by which this is achieved remains uncertain. In this review, we highlight recent studies that have suggested that the RING domain modulates the stability of the E2?ubiquitin conjugate so that catalysis is promoted. We also review the role of RING dimerisation and emphasise the importance of studying RING domains in the context of the full-length protein.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 2 Jane A. Grasby, L. David Finger, Susan E. Tsutakawa, John M. Atack, John A. Tainer Structure-specific 5?-nucleases form a superfamily of evolutionarily conserved phosphodiesterases that catalyse a precise incision of a diverse range of DNA and RNA substrates in a sequence-independent manner. Superfamily members, such as flap endonucleases, exonuclease 1, DNA repair protein XPG, endonuclease GEN1 and the 5?-3?-exoribonucleases, play key roles in many cellular processes such as DNA replication and repair, recombination, transcription, RNA turnover and RNA interference. In this review, we discuss recent results that highlight the conserved architectures and active sites of the structure-specific 5?-nucleases. Despite substrate diversity, a common gating mechanism for sequence-independent substrate recognition and incision emerges, whereby double nucleotide unpairing of substrates is required to access the active site.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 5 Javier Peña-Diaz, Josef Jiricny A considerable surge of interest in the mismatch repair (MMR) system has been brought about by the discovery of a link between Lynch syndrome, an inherited predisposition to cancer of the colon and other organs, and malfunction of this key DNA metabolic pathway. This review focuses on recent advances in our understanding of the molecular mechanisms of canonical MMR, which improves replication fidelity by removing misincorporated nucleotides from the nascent DNA strand. We also discuss the involvement of MMR proteins in two other processes: trinucleotide repeat expansion and antibody maturation, in which MMR proteins are required for mutagenesis rather than for its prevention.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 1 Eitan Bibi Integral membrane proteins (IMPs) are usually synthesized by membrane-bound ribosomes, and this process requires proper localization of ribosomes and IMP-encoding transcripts. However, the underlying molecular mechanism of the pathway has not yet been fully established in vivo. The prevailing hypothesis is that ribosomes and transcripts are delivered to the membrane together during IMP translation by the signal recognition particle (SRP) and its receptor. Here, I discuss an alternative hypothesis that posits that ribosomes and transcripts are targeted separately. Ribosome targeting to the membrane might be mediated by the SRP receptor, rather than by SRP, and IMP-encoding transcripts might be targeted to the membrane in a translation-independent manner. According to this scenario, the SRP executes its essential function on the membrane at a later stage of the targeting pathway.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 1 Gerrit J.K. Praefcke, Kay Hofmann, R. Jürgen Dohmen In addition to being structurally related, the protein modifiers ubiquitin and SUMO (small ubiquitin-related modifier), share a multitude of functional interrelations. These include the targeting of the same attachment sites in certain substrates, and SUMO-dependent ubiquitylation in others. Notably, several cellular processes, including the targeting of repair machinery to DNA damage sites, require the sequential sumoylation and ubiquitylation of distinct substrates. Some proteins promote both modifications. By contrast, the activity of some enzymes that control either sumoylation or ubiquitylation is regulated by the respective other modification. In this review, we summarize recent findings regarding intersections between SUMO and ubiquitin that influence genome stability and cell growth and which are relevant in pathogen resistance and cancer treatment.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 1 Scott Ditch, Tanya T. Paull The ataxia–telangiectasia mutated (ATM) protein kinase is best known for its role in the DNA damage response, but recent findings suggest that it also functions as a redox sensor that controls the levels of reactive oxygen species in human cells. Here, we review evidence supporting the conclusion that ATM can be directly activated by oxidation, as well as various observations from ATM-deficient patients and mouse models that point to the importance of ATM in oxidative stress responses. We also discuss the roles of this kinase in regulating mitochondrial function and metabolic control through its action on tumor suppressor p53, AMP-activated protein kinase (AMPK), mammalian target of rapamycin (mTOR) and hypoxia-inducible factor 1 (HIF1), and how the regulation of these enzymes may be affected in ATM-deficient patients and in cancer cells.
Publication year: 2012 Source:Trends in Biochemical Sciences Emanuele Buratti, Francisco E. Baralle Since the discovery that 43 kDa TAR DNA binding protein (TDP-43) is involved in neurodegeneration, studies of this protein have focused on the global effects of TDP-43 expression modulation on cell metabolism and survival. The major difficulty with these global searches, which can yield hundreds to thousands of variations in gene expression level and/or mRNA isoforms, is our limited ability to separate specific TDP-43 effects from secondary dysregulations occurring at the gene expression and various mRNA processing steps. In this review, we focus on two biochemical properties of TDP-43: its ability to bind RNA and its protein–protein interactions. In particular, we overview how these two properties may affect potentially very important processes for the pathology, from the autoregulation of TDP-43 to aggregation in the cytoplasmic/nuclear compartments.
Publication year: 2012 Source:Trends in Biochemical Sciences, Volume 37, Issue 1 Steven M. Claypool, Carla M. Koehler Cardiolipin, the signature phospholipid of mitochondria, is a lipid dimer that is important for a diverse range of mitochondrial activities beyond the process of ATP production. Thus not surprisingly, derangements in cardiolipin metabolism are now appreciated to contribute to an assortment of pathological conditions. A comprehensive inventory of enzymes involved in cardiolipin biosynthesis and remodeling was just recently obtained. Post-biosynthesis, the acyl chain composition of cardiolipin is modified by up to three distinct remodeling enzymes that produce either a homogeneous tissue-specific mature form of cardiolipin or alternatively ‘bad’ cardiolipin that has been linked to mitochondrial dysfunction. In this review, we initially focus on the newly identified players in cardiolipin metabolism and then shift our attention to how changes in cardiolipin metabolism contribute to human disease.
Publication year: 2011 Source:Trends in Biochemical Sciences, Volume 36, Issue 12 Vrajesh Karkhanis, Yu-Jie Hu, Robert A. Baiocchi, Anthony N. Imbalzano, Saïd Sif Arginine methylation governs important cellular processes that impact growth and proliferation, as well as differentiation and development. Through their ability to catalyze symmetric or asymmetric methylation of histone and non-histone proteins, members of the protein arginine methyltransferase (PRMT) family regulate chromatin structure and expression of a wide spectrum of target genes. Unlike other PRMTs, PRMT5 works in concert with a variety of cellular proteins including ATP-dependent chromatin remodelers and co-repressors to induce epigenetic silencing. Recent work also implicates PRMT5 in the control of growth-promoting and pro-survival pathways, which demonstrates its versatility as an enzyme involved in both epigenetic regulation of anti-cancer target genes and organelle biogenesis. These studies not only provide insight into the molecular mechanisms by which PRMT5 contributes to growth control, but also justify therapeutic targeting of PRMT5.
Publication year: 2011 Source:Trends in Biochemical Sciences, Volume 36, Issue 12 Günter Fritz The receptor for advanced glycation end products (RAGE) is a central signaling molecule in the innate immune system and is involved in the onset and sustainment of the inflammatory response. RAGE belongs to a class of pattern recognition receptors that recognize common features rather than a specific ligand. Recent structural information on the extracellular portion (ectodomain) of RAGE shed new light on this unusual ability. X-ray crystallographic, NMR and biochemical data suggest that ligand binding is driven largely by electrostatic interactions between the positively charged surface of the ectodomain and negatively charged ligands. In this article, I propose a putative mechanism of RAGE ligand recognition of receptor activation.
Publication year: 2012 Source:Trends in Biochemical Sciences Steffen Preissler, Elke Deuerling De novo protein folding is delicate and error-prone and requires the guidance of molecular chaperones. Besides cytosolic and organelle-specific chaperones, cells have evolved ribosome-associated chaperones that support early folding events and prevent misfolding and aggregation. This class of chaperones includes the bacterial trigger factor (TF), the archaeal and eukaryotic nascent polypeptide-associated complex (NAC) and specialized eukaryotic heat shock protein (Hsp) 70/40 chaperones. This review focuses on the cellular activities of ribosome-associated chaperones and highlights new findings indicating additional functions beyond de novo folding. These activities include the assembly of oligomeric complexes, such as ribosomes, modulation of translation and targeting of proteins.
Publication year: 2011 Source:Trends in Biochemical Sciences, Volume 36, Issue 12 Loren D. Walensky, Evripidis Gavathiotis BAX, the BCL-2-associated X protein, is a cardinal proapoptotic member of the BCL-2 family, which regulates the critical balance between cellular life and death. Because so many medical conditions can be categorized as diseases of either too many or too few cells, dissecting the biochemistry of BCL-2 family proteins and developing pharmacological strategies to target them have become high priority scientific objectives. Here, we focus on BAX, a latent, cytosolic and monomeric protein that transforms into a lethal mitochondrial oligomer in response to cellular stress. New insights into the structural location of BAX's ‘on switch’, and the multi-step conformational changes that ensue upon BAX activation, are providing fresh opportunities to modulate BAX for potential benefit in human diseases characterized by pathologic cell survival or unwanted cellular demise.
Publication year: 2011 Source:Trends in Biochemical Sciences, Volume 36, Issue 12 Meritxell Canals, Patrick M. Sexton, Arthur Christopoulos G protein-coupled receptors (GPCRs) constitute the largest family of receptors in the genome and are the targets for at least 30% of current medicines. In recent years, there has been a dramatic increase in the discovery of allosteric modulators of GPCR activity and a growing appreciation of the diverse modes by which GPCRs can be regulated by both orthosteric and allosteric ligands. Interestingly, some of the contemporary views of GPCR function reflect characteristics that are shared by prototypical allosteric proteins, as encompassed in the classic Monod–Wyman–Changeux (MWC) model initially proposed for enzymes and subsequently extended to other protein families. In this review, we revisit the MWC model in the context of emerging structural, functional and operational data on GPCR allostery.
Publication year: 2011 Source:Trends in Biochemical Sciences, Volume 36, Issue 11 Christian S. Eichinger, Stefan Jentsch All living organisms are vulnerable to DNA damage. Cells respond to this hazard by activating a complex network of checkpoint and repair proteins to preserve genomic integrity. The DNA-encircling, ring-shaped heterotrimeric 9-1-1 complex, a relative of the replication protein PCNA, is a central coordinator of these events. 9-1-1 is loaded to damaged sites where it serves as a platform for the selective recruitment of checkpoint and repair proteins. In this Opinion article, 9-1-1 and proliferating cell nuclear antigen (PCNA) are compared and discussed in light of their respective structures and functions. We propose that the interaction partners of 9-1-1 possess specific 9-1-1-interaction boxes, which discriminate between 9-1-1 and PCNA thereby enabling specific interactions with individual 9-1-1 subunits.
Posted on 28 May 2012 | 12:48 pm
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