Plasma Membrane Protein Ubiquitylation and Degradation as Determinants of Positional Growth in Plants

Being sessile organisms, plants evolved an unparalleled plasticity in their post-embryonic development, allowing them to adapt and fine-tune their vital parameters to an ever-changing environment. Crosstalk between plants and their environment requires tight regulation of information exchange at the plasma membrane (PM). Plasma membrane proteins mediate such communication, by sensing variations in nutrient availability, external cues as well as by controlled solute transport across the membrane border. Localization and steady-state levels are essential for PM protein function and ongoing research identified cis- and trans-acting determinants, involved in control of plant PM protein localization and turnover. In this overview, we summarize recent progress in our understanding of plant PM protein sorting and degradation via ubiquitylation, a post-translational and reversible modification of proteins. We highlight characterized components of the machinery involved in sorting of ubiquitylated PM proteins and discuss consequences of protein ubiquitylation on fate of selected PM proteins. Specifically, we focus on the role of ubiquitylation and PM protein degradation in the regulation of polar auxin transport (PAT). We combine this regulatory circuit with further aspects of PM protein sorting control, to address the interplay of events that might control PAT and polarized growth in higher plants.     

Phosphorylation-Mediated Control of Histone Chaperone ASF1 Levels by Tousled-Like Kinases

Histone chaperones are at the hub of a diverse interaction networks integrating a plethora of chromatin modifying activities. Histone H3/H4 chaperone ASF1 is a target for cell-cycle regulated Tousled-like kinases (TLKs) and both proteins cooperate during chromatin replication. However, the precise role of post-translational modification of ASF1 remained unclear. Here, we identify the TLK phosphorylation sites for both Drosophila and human ASF1 proteins. Loss of TLK-mediated phosphorylation triggers hASF1a and dASF1 degradation by proteasome-dependent and independent mechanisms respectively. Consistent with this notion, introduction of phosphorylation-mimicking mutants inhibits hASF1a and dASF1 degradation. Human hASF1b is also targeted for proteasome-dependent degradation, but its stability is not affected by phosphorylation indicating that other mechanisms are likely to be involved in control of hASF1b levels. Together, these results suggest that ASF1 cellular levels are tightly controlled by distinct pathways and provide a molecular mechanism for post-translational regulation of dASF1 and hASF1a by TLK kinases.     

Plant F-box Proteins – Judges between Life and Death

Selective protein degradation through the ubiquitin–26S proteasome system is a key mechanism for post-translational control of regulatory proteins in all eukaryotes. The pivotal components in this system are the multi-subunit E3 Ub-ligase enzymes responsible for specific recognition and ubiquitination of degradation targets. In this review, we focus on plant F-box proteins which confer specificity to the SCF-type E3 enzyme complexes. F-box proteins represent one of the largest and most heterogeneous superfamilies in plants, with hundreds of different representatives exposing an extensive variability of C-terminal target-binding domains, and as such, modulating almost every aspect of plant growth and development. Since the first reports on plant F-box proteins over a decade ago, a lot of progress has been made in our understanding of their relevance for plant physiology. In this review, we combine well-established knowledge with the most recent advances related to plant F-box proteins and their role in plant development, hormone signaling and defense pathways. We also elaborate on the yet poorly described carbohydrate-binding plant F-box proteins presumably targeting glycoproteins for proteasomal degradation.     

Roles of various cullin-RING E3 ligases involved in hormonal and stress responses in plants

Post-translational modification plays an important role in the regulation of protein stability, enzyme activity, and the cellular localization of proteins. Ubiquitination is a representative post-translational modification in eukaryotes that is mainly responsible for protein degradation. There have been a number of reports on the role of ubiquitination in various cellular responses in plants, such as regulation of the cell division cycle, stress responses and hormonal signaling. Among the three types of ubiquitination-related enzymes, E3 ubiquitin ligase is critical in determining substrate specificity. The importance of cullin-RING E3 ligase (CRL), a type of E3 ligase, has been emphasized during the recent decade due to its large number and its involvement in various plant cellular processes. Here, we describe how CRL E3 ligase complexes are involved in cellular events mediated by plant hormones and during plant stress adaptation while focusing on their substrate receptors.     

Analysis of protein phosphorylation: methods and strategies for studying kinases and substrates

Protein phosphorylation is a highly conserved mechanism for regulating protein function, being found in all prokaryotes and eukaryotes examined. Phosphorylation can alter protein activity or subcellular localization, target proteins for degradation and effect dynamic changes in protein complexes. In many cases, different kinases may be involved in each of these processes for a single protein, allowing a large degree of combinatorial regulation at the post-translational level. Therefore, knowing which kinases are activated during a response and which proteins are substrates is integral to understanding the mechanistic regulation of a wide range of biological processes. In this paper, I will describe methods for monitoring kinase activity, investigating kinase-substrate specificity, examining phosphorylation in planta and the determination of phosphorylation sites in a protein. In addition, strategic considerations for experimental design and variables will be discussed.     

The pupylation pathway and its role in mycobacteria

Pupylation is a post-translational protein modification occurring in actinobacteria through which the small, intrinsically disordered protein Pup (prokaryotic ubiquitin-like protein) is conjugated to lysine residues of proteins, marking them for proteasomal degradation. Although functionally related to ubiquitination, pupylation is carried out by different enzymes that are evolutionarily linked to bacterial carboxylate-amine ligases. Here, we compare the mechanism of Pup-conjugation to target proteins with ubiquitination, describe the evolutionary emergence of pupylation and discuss the importance of this pathway for survival of Mycobacterium tuberculosis in the host.     

The role of atypical ubiquitination in cell regulation

Ubiquitination is a type of intracellular proteins post-translational modification (PTM) characterized by covalent attachment of ubiquitin molecules to target proteins. This includes monoubiquitination (attachment of one ubiquitin molecule), multiple monoubiquitination also known as multiubiquitination (attachment of several monomeric ubiquitin molecules to a target protein), and polyubiquitination (attachment of ubiquitin chains consisting of several, most frequently four ubiquitin monomers to a target protein). In the case of polyubiquitination, linear or branched polyubiquitin chains are formed. Their formation involves various lysine residues of monomeric ubiquitin. The best studied is Lys48-linked polyubiquitination, which targets proteins for proteasomal degradation. In this review we have considered examples of so-called atypical polyubiquitination, which mainly involves other lysine residues (Lys6, Lys11, Lys27, Lys29, Lys33, Lys63) and also N-terminal methionine. The considered examples convincingly demonstrate that polyubiquitination of proteins (not necessarily) targets proteins for their proteolytic degradation in proteasomes. Atypically polyubiquitinated proteins are involved in regulation of various processes including immune response, genome stability, signal transduction, etc. Alterations of ubiquitination machinery is crucial for development of serious diseases.     

Post-translational regulation of nitrate reductase: mechanism, physiological relevance and environmental triggers

Assimilatory nitrate reductase (NR) of higher plants is a most interesting enzyme, both from its central function in plant primary metabolism and from the complex regulation of its expression and control of catalytic activity and degradation. Here, present knowledge about the mechanism of post-translational regulation of NR is summarized and the properties of the regulatory enzymes involved (protein kinases, protein phosphatases and 14-3-3-binding proteins) are described. It is shown that light and oxygen availability are the major external triggers for the rapid and reversible modulation of NR activity, and that sugars and/or sugar phosphates are the internal signals which regulate the protein kinase(s) and phosphatase. It is also demonstrated that stress factors like nitrate deficiency and salinity have remarkably little direct influence on the NR activation state. Further, changes in NR activity measured in vitro are not always associated with changes in nitrate reduction rates in vivo, suggesting that NR can be under strong substrate limitation. The degradation and half-life of the NR protein also appear to be affected by NR phosphorylation and 14-3-3 binding, as NR activation always correlates positively with its stability. However, it is not known whether the molecular form of NR in vivo affects its susceptibility to proteolytic degradation, or whether factors that affect the NR activation state also independently affect the activity or induction of the NR protease(s). A second and potentially important function of NR, the production of nitric oxide (NO) from nitrite is briefly described, but it remains to be determined whether NR produces NO for pathogen/stress signalling in vivo.     

E3 ubiquitin ligases as regulators of membrane protein trafficking and degradation

Ubiquitination is a regulated post-translational modification that conjugates ubiquitin (Ub) to lysine residues of target proteins and determines their intracellular fate. The canonical role of ubiquitination is to mediate degradation by the proteasome of short-lived cytoplasmic proteins that carry a single, polymeric chain of Ub on a specific lysine residue. However, protein modification by Ub has much broader and diverse functions involved in a myriad of cellular processes. Monoubiquitination, at one or multiple lysine residues of transmembrane proteins, influences their stability, protein-protein recognition, activity and intracellular localization. In these processes, Ub functions as an internalization signal that sends the modified substrate to the endocytic/sorting compartments, followed by recycling to the plasma membrane or degradation in the lysosome. E3 ligases play a pivotal role in ubiquitination, because they recognize the acceptor protein and hence dictate the high specificity of the reaction. The multitude of E3s present in nature suggests their nonredundant mode of action and the need for their controlled regulation. Here we give a short account of E3 ligases that specifically modify and regulate membrane proteins. We emphasize the intricate network of interacting proteins that contribute to the substrate-E3 recognition and determine the substrate's cellular fate.     

Genome stability roles of SUMO-targeted ubiquitin ligases

Post-translational modification of the cell's proteome by ubiquitin and ubiquitin-like proteins provides dynamic functional regulation. Ubiquitin and SUMO are well-studied post-translational modifiers that typically impart distinct effects on their targets. The recent discovery that modification by SUMO can target proteins for ubiquitination and proteasomal degradation sets a new paradigm in the field, and offers insights into the roles of SUMO and ubiquitin in genome stability.     

蛋白质SUMO化和泛素化修饰的关系

泛素化和SUMO化是蛋白质翻译后修饰的重要方式,广泛参与调节蛋白质功能和细胞生命活动各个环节。多聚泛素化降解蛋白质,而SUMO化主要调节蛋白质的相互作用和定位等。在不同情况下,SUMO化和泛素化既可协同调节蛋白质功能,也可相互拮抗。最近研究发现,某些底物的SUMO化能够激活体内一类新发现的SUMO依赖的泛素连接酶,启动泛素-蛋白酶体途径降解底物,导致蛋白质SUMO化和汔素化的关系进一步精细化和复杂化。     

Two-dimensional reference map of Agrobacterium tumefaciens proteins

Proteomics based on two-dimensional (2-D) gel electrophoresis of proteins followed by spot identification with mass spectrometry is a commonly used method for physiological studies. Physiological proteomics requires 2-D reference maps, on which most of the main proteins are identified. We present a reference map for the bacterial plant pathogen Agrobacterium tumefaciens proteins, which contains more than 300 entries with an isoelectric point (pI) between 4 and 7. The quantitative study of the proteins in the analytical window of the master gel demonstrated unique features, in comparison with other bacteria. In addition, a theoretical analysis of several protein parameters was performed and compared with the experimental results. A comparison of the theoretical molecular weight (MW) of the proteins and their theoretical pI with their vertical and horizontal migration distances, respectively, pointed out the existence of several proteins that strongly diverted from the graph trend-line. These proteins were clearly subjected to post-translational modifications, which changed their pI and/or MW. Additional support for post-translational modifications comes from the identification of multiple spots of the same gene products. Post-translational modifications appear to be more common than expected, at least for soluble proteins, as more than 10% of the proteins were associated with multiple spots.