46 research outputs found
Ubiquitin Reference Technique and Its Use in Ubiquitin-Lacking Prokaryotes
In a pulse-chase assay, the in vivo degradation of a protein is measured through a brief labeling of cells with, for example, a radioactive amino acid, followed by cessation of labeling and analysis of cell extracts prepared at different times afterward (“chase”), using immunoprecipitation, electrophoresis and autoradiography of a labeled protein of interest. A conventional pulse-chase assay is fraught with sources of data scatter, as the efficacy of labeling and immunoprecipitation can vary, and sample volumes can vary as well. The ubiquitin reference technique (URT), introduced in 1996, addresses these problems. In eukaryotes, a DNA-encoded linear fusion of ubiquitin to another protein is cleaved by deubiquitylases at the ubiquitin-protein junction. A URT assay uses a fusion in which the ubiquitin moiety is located between a downstream polypeptide (test protein) and an upstream polypeptide (a long-lived reference protein). The cotranslational cleavage of a URT fusion by deubiquitylases after the last residue of ubiquitin produces, at the initially equimolar ratio, a test protein with a desired N-terminal residue and a reference protein containing C-terminal ubiquitin moiety. In addition to being more accurate than pulse-chases without a reference, URT makes it possible to detect and measure the degradation of a test protein during the pulse (before the chase). Because prokaryotes, including Gram-negative bacteria such as, for example, Escherichia coli and Vibrio vulnificus, lack the ubiquitin system, the use of URT in such cells requires ectopic expression of a deubiquitylase. We describe designs and applications of plasmid vectors that coexpress, in bacteria, both a URT-type fusion and Ubp1, a deubiquitylase of the yeast Saccharomyces cerevisiae. This single-plasmid approach extends the accuracy-enhancing URT assay to studies of protein degradation in prokaryotes
Ubiquitylation in plants: signaling hub for the integration of environmental signals
A fundamental question in biology is how organisms integrate the plethora of environmental cues that they perceive
to trigger a co-ordinated response. The regulation of protein stability, which is largely mediated by the ubiquitin–proteasome system in eukaryotes, plays a pivotal role in these processes. Due to their sessile lifestyle and the need to
respond rapidly to a multitude of environmental factors, plants are thought to be especially dependent on proteolysis
to regulate cellular processes. In this review, we present the complexity of the ubiquitin system in plants, and discuss
the relevance of the proteolytic and non-proteolytic roles of this system in the regulation and co-ordination of plant
responses to environmental signals. We also discuss the role of the ubiquitin system as a key regulator of plant signaling pathways. We focus more specifically on the functions of E3 ligases as regulators of the jasmonic acid (JA), salicylic acid (SA), and ethylene hormone signaling pathways that play important roles to mount a co-ordinated response
to multiple environmental stresses. We also provide examples of new players in this field that appear to integrate
different cues and signaling pathway
Evidence for Two Distinct Effector-Binding Sites in Threonine Deaminase by Site-Directed Mutagenesis, Kinetic, and Binding Experiments
A three-dimensional structure comparison between the dimeric regulatory serine-binding domain of Escherichia coli D-3-phosphoglycerate dehydrogenase [Schuller, D. J., Grant, G. A., and Banaszak, L. J. (1995) Nat. Struct. Biol. 2, 69-76] and the regulatory domain of E. coli threonine deaminase [Gallagher, D. T., Gilliland, G. L., Xiao, G., Zondlo, J., Fisher, K. E., Chinchilla, D. , and Eisenstein, E. (1998) Structure 6, 465-475] led us to make the hypothesis that threonine deaminase could have two binding sites per monomer. To test this hypothesis about the corresponding plant enzyme, site-directed mutagenesis was carried out on the recombinant Arabidopsis thaliana threonine deaminase. Kinetic and binding experiments demonstrated for the first time that each regulatory domain of the monomers of A. thaliana threonine deaminase possesses two different effector-binding sites constituted in part by Y449 and Y543. Our results demonstrate that Y449 belongs to a high-affinity binding site whose interaction with a first isoleucine induces conformational modifications yielding a conformer displaying a higher activity and with enhanced ability to bind a second isoleucine on a lower-affinity binding site containing Y543. Isoleucine interaction with this latter binding site is responsible for conformational modifications leading to final inhibition of the enzyme. Y449 interacts with both regulators, isoleucine and valine. However, interaction of valine with the high-affinity binding site induces different conformational modifications leading to reversal of isoleucine binding and reversal of inhibition
Lessons from Comparison of Hypoxia Signaling in Plants and Mammals
Hypoxia is an important stress for organisms, including plants and mammals. In plants,
hypoxia can be the consequence of flooding and causes important crop losses worldwide. In
mammals, hypoxia stress may be the result of pathological conditions. Understanding the regulation
of responses to hypoxia offers insights into novel approaches for crop improvement, particularly for
the development of flooding-tolerant crops and for producing better therapeutics for hypoxia-related
diseases such as inflammation and cancer. Despite their evolutionary distance, plants and mammals
deploy strikingly similar mechanisms to sense and respond to the different aspects of hypoxia-related stress, including low oxygen levels and the resulting energy crisis, nutrient depletion, and
oxidative stress. Over the last two decades, the ubiquitin/proteasome system and the ubiquitin-like
protein SUMO have been identified as key regulators that act in concert to regulate core aspects of
responses to hypoxia in plants and mammals. Here, we review ubiquitin and SUMO-dependent
mechanisms underlying the regulation of hypoxia response in plants and mammals. By comparing
and contrasting these mechanisms in plants and mammals, this review seeks to pinpoint conceptually
similar mechanisms but also highlight future avenues of research at the junction between different
fields of research
Gene network analysis of Arabidopsis thaliana flower development through dynamic gene perturbations
Understanding how flowers develop from undifferentiated stem cells has occupied developmental biologists for decades. Key to unraveling this process is a detailed knowledge of the global regulatory hierarchies that control developmental transitions, cell differentiation and organ growth. These hierarchies may be deduced from gene perturbation experiments, which determine the effects on gene expression after specific disruption of a regulatory gene. Here, we tested experimental strategies for gene perturbation experiments during Arabidopsis thaliana flower development. We used artificial miRNAs (amiRNAs) to disrupt the functions of key floral regulators, and expressed them under the control of various inducible promoter systems that are widely used in the plant research community. To be able to perform genome‐wide experiments with stage‐specific resolution using the various inducible promoter systems for gene perturbation experiments, we also generated a series of floral induction systems that allow collection of hundreds of synchronized floral buds from a single plant. Based on our results, we propose strategies for performing dynamic gene perturbation experiments in flowers, and outline how they may be combined with versions of the floral induction system to dissect the gene regulatory network underlying flower development
Experimental comparison of two methods to study barley responses to partial submergence
peer-reviewedBackground
Crop yield is dependent on climate conditions, which are becoming both more variable and extreme in some areas of the world as a consequence of global climate change. Increased precipitation and flooding events are the cause of important yield losses due to waterlogging or (partial) submergence of crops in the field. Our ability to screen efficiently and quickly for varieties that have increased tolerance to waterlogging or (partial) submergence is important. Barley, a staple crop worldwide, is particularly sensitive to waterlogging. Screening for waterlogging tolerant barley varieties has been ongoing for many years, but methods used to screen vary greatly, from the type of soil used to the time at which the treatment is applied. This variation makes it difficult to cross-compare results.
Results
Here, we have devised a scoring system to assess barley tolerance to waterlogging and compare two different methods when partial submergence is applied with either water or a starch solution at an early developmental stage, which is particularly sensitive to waterlogging or partial submergence. The use of a starch solution has been previously shown to result in more reducing soil conditions and has been used to screen for waterlogging tolerance.
Conclusions
Our results show that the two methods provide similar results to qualitatively rank varieties as tolerant or sensitive, while also affecting plants differently, in that application of a starch solution results in stronger and earlier symptoms than applying partial submergence with water
Molecular basis for the specification of floral organs by APETALA3 and PISTILLATA
How different organs are formed from small sets of undifferentiated
precursor cells is a key question in developmental biology. To
understand the molecular mechanisms underlying organ specification
in plants, we studied the function of the homeotic selector
genes APETALA3 (AP3) and PISTILLATA (PI), which control the
formation of petals and stamens during Arabidopsis flower development.
To this end, we characterized the activities of the transcription
factors that AP3 and PI encode throughout flower
development by using perturbation assays as well as transcript profiling
and genomewide localization studies, in combination with
a floral induction system that allows a stage-specific analysis of
flower development by genomic technologies. We discovered considerable
spatial and temporal differences in the requirement for
AP3/PI activity during flower formation and show that they control
different sets of genes at distinct phases of flower development.
The genomewide identification of target genes revealed that
AP3/PI act as bifunctional transcription factors: they activate genes
involved in the control of numerous developmental processes required
for organogenesis and repress key regulators of carpel formation.
Our results imply considerable changes in the composition
and topology of the gene network controlled by AP3/PI during the
course of flower development. We discuss our results in light of
a model for the mechanism underlying sex-determination in seed
plants, in which AP3/PI orthologues might act as a switch between
the activation of male and the repression of female development
N-term 2017: Proteostasis via the N-terminus
N-term 2017 was the first international meeting to bring together researchers from diverse disciplines with a shared interest in protein N-terminal modifications and the N-end rule pathway of ubiquitin-mediated proteolysis, providing a platform for interdisciplinary cross-kingdom discussions and collaborations, as well as strengthening the visibility of this growing scientific community
Improving phenotyping in winter barley cultivars towards waterlogging tolerance by combining field trials under natural conditions with controlled growth condition experiments
Additional rainfall in Northern Europe due to global climate change is increasing the incidences of field flooding. Flooding causes hypoxic stress that results in a reduced capacity for photosynthesis, reduction in nutrient availability and uptake, increased production of toxic metabolites by anaerobic bacteria in the soil, and ultimately yield losses and crop death. To overcome hypoxic environmental conditions, new cultivars need to be bred and tested for waterlogging tolerance. We scored 403 winter barley cultivars from the ‘Association Genetics of UK Elite Barley’ (AGOUEB) population, taking advantage of the phenotypic changes associated with hypoxic stress. This enabled us to identify an initial set of waterlogging sensitive and tolerant cultivars. Comparative analysis of a subset of 65 cultivars exposed to waterlogging stress under field and growth cabinet environments showed variability in scores due to varying sensitivity to waterlogging over multi-season field trials. In field trials, we observed waterlogging damage resulting in reductions in biomass, grain yield and crop height. However, the effects varied between seasons and the severity of waterlogging due to differences in the topography of the field and the amount of rainfall. To overcome the seasonal variations in environmental conditions in multi-season field trials, we developed in parallel, an enhanced phenotyping method by complementing field experiments with phenotyping under controlled growth conditions. The phenotyping scoring method allows for the grouping of cultivars by sensitivity and tolerance to waterlogging, with limited variance between cultivars scored in the field and controlled conditions. Together, these two complementary approaches maximise the data available to breeders, allowing for the reliable selection of more tolerant cultivars able to grow under flooding conditions
Differential N-end rule degradation of RIN4/NOI fragments generated by the AvrRpt2 effector protease.
In plants, the protein RPM1-INTERACTING PROTEIN4 (RIN4) is a central regulator of both pattern-triggered immunity and
effector-triggered immunity. RIN4 is targeted by several effectors, including the Pseudomonas syringae protease effector AvrRpt2.
Cleavage of RIN4 by AvrRpt2 generates potentially unstable RIN4 fragments, whose degradation leads to the activation
of the resistance protein RESISTANT TO P. SYRINGAE2. Hence, identifying the determinants of RIN4 degradation is key
to understanding RESISTANT TO P. SYRINGAE2–mediated effector-triggered immunity, as well as virulence functions of
AvrRpt2. In addition to RIN4, AvrRpt2 cleaves host proteins from the nitrate-induced (NOI) domain family. Although
cleavage of NOI domain proteins by AvrRpt2 may contribute to pattern-triggered immunity regulation, the (in)stability
of these proteolytic fragments and the determinants regulating their stability remain unexamined. Notably, a common
feature of RIN4, and of many NOI domain protein fragments generated by AvrRpt2 cleavage, is the exposure of a new
N-terminal residue that is destabilizing according to the N-end rule. Using antibodies raised against endogenous RIN4,
we show that the destabilization of AvrRpt2-cleaved RIN4 fragments is independent of the N-end rule pathway (recently
renamed the N-degron pathway). By contrast, several NOI domain protein fragments are genuine substrates of the N-degron
pathway. The discovery of this set of substrates considerably expands the number of known proteins targeted for degradation
by this ubiquitin-dependent pathway in plants. These results advance our current understanding of the role of AvrRpt2 in
promoting bacterial virulence