Plant proteases: from molecular mechanisms to functions in development and immunity

Autophagy (from Greek: ‘self-eating’) is a major catabolic process in eukaryotic cells in which cytoplasmic components are collected and delivered to the lysosomes or vacuoles for recycling. It plays a paramount role in plant fitness and immunity. At present, the frontiers of our understanding of the process are extending exponentially, with new, plant-specific mechanisms and functions being uncovered. In this special issue, original research articles and reviews enlighten this knowledge from lipid metabolism and dynamics, membrane trafficking and proteolysis to pathogen-mediated modulation of the process and the emerging role of autophagy-related approaches in crop improvement. Today, after less than two decades since the first genetic analyses of plant autophagy (Doelling et al., 2002; Hanaoko et al., 2002), it is known to be implicated in virtually all aspects of plant biology. Plant autophagy research is advancing at an unprecedented pace: initially focused mainly on finding similarities with yeast and animal models, the field has now reached a point where it can ‘dictate a fashion’ to the wider field of autophagy research through uncovering novel mechanisms in plants that might or might not be conserved in non-plant species (e.g. Minina et al., 2013a ; Gao et al., 2015; Marshall et al., 2015; Hafren et al., 2017; for recent updates see review by Soto-Burgos et al., 2018). Nevertheless, while tremendous advances are being made, many fundamental questions remain hotly debated (Box 1), and as our frontiers expand, so many challenges have opened up (Box 2). This special issue of Journal of Experimental Botany contains a collection of reviews and original research papers at the cutting edge of plant autophagy research, and will be valuable not only to ‘autophagists’ but also, considering the truly multifunctional nature of autophagy, all plant scientists. Membranes, lipids and autophagy The autophagy process per se can be visualized as a sequence of membrane-dependent events, including the formation of a double-membraned structure, the phagophore, which expands and closes, yielding a double-membraned vesicle, the autophagosome, and its subsequent fusion with an endolytic compartment. While very substantial progress has been made in understanding the roles of autophagy-related (Atg) and other proteins in directing the autophagy process, the major constituents of the autophagic membranes (i.e. lipids) remain far less well understood. Gomez et al. (2018) place lipids and membrane-modifying proteins in the centre of the discussion about the mechanisms specifying the initiation, expansion and maturation of the autophagosomes. The authors summarize and compare current knowledge on the structural and signalling roles of various classes of lipids in autophagy in plants and other organisms, and highlight key questions, such as (i) where autophagosomal lipids come from, (ii) how lipids are mobilized towards the autophagy pathway, and (iii) how lipid supply to the autophagy pathway is regulated. In addition to membranes, lipid droplets are another major pool of lipids in cells. During nutrient deprivation or stress, triacylglycerols (TAGs) stored in these bodies are catabolized into fatty acids that fuel cellular rates of β-oxidation. Lipid droplets are, therefore, crucial for maintaining cellular energy homeostasis and, in animals, autophagy plays a dual role, participating in both their deposition and their degradation (Zechner et al., 2017). Two studies published in this issue demonstrate that autophagy might, similarly to animals, be required for the deposition of lipid droplets in plants. Couso et al. (2018) observed that inhibition of vacuolar degradation by concanamycin A in Chlamydomonas reinhardtii abrogates an increase in autophagic flux, TAG biosynthesis and lipid droplet formation induced by nitrogen or phosphate starvation. In another study using a collection of Arabidopsis mutants with blocked or enhanced autophagy, Minina et al. (2018) demonstrate direct correlation between autophagic activity and accumulation of seed fatty acids. Additionally, recent work in Arabidopsis revealed an accumulation of most lipid classes in carbon-deprived, autophagy-deficient (atg) mutant seedlings (Avin-Wittenberg et al., 2015). These studies provide a foundation for further deciphering of the mechanistic details of the developmental context-specific, autophagy-mediated regulation of lipid stores in plants. Continuing the lipid theme, Elander et al. (2018) present a trans-kingdom overview of processes regulating formation and degradation of lipid droplets, emphasizing possible differences, rather than similarities, among animals, fungi and plants. Autophagy and its lipid-selective route, lipophagy, is given special attention. The authors provide an update on the roles and mechanisms of autophagy in the regulation of lipid deposition and lipolysis in fungi and animals, and discuss examples including those studies mentioned above implicating autophagy in lipid droplet turnover in plants. Box 1. Questions for ongoing research The following are all points of debate in the plant autophagy field: The function of the Atg9 protein. Furthermore, is its absence at all compensated for by a functional analogue? The primordial role of phosphatidylinositol 3-phosphate (PI3P). Does this lipid have a function in autophagosome membrane formation/structure besides its signalling activity? How is the PI3-kinase complex recruited at the phagophore assembly site in plant cells, which lack Atg14, the autophagy-specific PI3-kinase component? The platform of phagophore assembly. Is the endoplasmic reticulum (ER) the only platform for phagophore assembly in plant cells? Are membrane contact sites involving the ER required for autophagosome formation, similarly to other organisms? The existence of endosomal compartments, such as amphisomes, in which endosomal and autophagic transport merge. Direct participation of autophagy in the deposition and breakdown of lipid stores. The existence of a functional plant analogue of the yeast vacuolar Atg15 lipase. The reason why all Arabidopsis atg mutants, except for atg6, are viable and do not display major developmental defects. The possibility of autophagy in plant cells that do not contain lytic vacuoles (e.g. embryonic cells with storage vacuoles). In addition, if this is the case, what compartment is responsible for degradation of autophagic cargo? The existence of microautophagy (i.e. direct vacuolar engulfment of the cytoplasmic cargo) in plants. The mechanistic role of autophagy in cell death. The composition of the cargo of defence-related selective autophagy. Is the cargo degraded or secreted? Nutrient remobilization from source to sink organs. How and under which conditions is autophagy essential for this process? The sources of nutrients specifically remobilized by autophagy. The extent to which autophagy is critical in cell resource management and degradation, and the balance between cell survival and death. Fitness costs of enhanced autophagy. Enigmatic crossroads: autophagy and other trafficking pathways On roads and highways, traffic jams can be devastating and it is no different in cells, where they can jeopardize normal functions and lead to demise and disease, highlighting the necessity of strict co-regulation of various trafficking events. It is well-documented that in animal and yeast cells, autophagy intersects with other membrane trafficking pathways by sharing key regulatory proteins (for review see Tooze et al., 2014; Molino et al., 2017). In the plant autophagy field there is a growing interest in deciphering the mechanistic connection between autophagic and other routes of membrane trafficking. Recent works have established that plant autophagy is mediated by core molecular components of endosomal protein sorting and vacuolar trafficking (Katsiarimpa et al., 2013; Munch et al., 2015), retrograde transport to the trans-Golgi network (Zouhar et al., 2009) and exocytosis (Kulich et al., 2013). Importantly, the crosstalk between autophagy and other trafficking pathways is essential for normal plant physiology and immunity. Kalinowska and Isono (2018) update our understanding of this crosstalk, with an emphasis on the endosomal sorting complex required for transport (ESCRT). The authors provide a phylogenetically broad analysis of the mechanisms co-regulating autophagy and endosomal pathways by comparing results obtained using Arabidopsis membrane trafficking mutants with animal and fungal trafficking models. Box 2. Future challenges The following are key topics for future research into plant autophagy: Crosstalk between autophagy and photosynthesis. Transcriptional and post-transcriptional regulation. The lipid composition of autophagosomal membranes, and the way lipids are mobilized, delivered and assembled within them. Mechanisms and physiological roles of granulophagy and ribophagy in plants. The potential roles for autophagic receptors of ­ubiquitinated targets in ubiquitin-dependent endosomal trafficking. Mechanisms and directionality of autophagosome trafficking. The selectivity of bulk autophagy. The role of selective autophagy in nutrient acquisition by host-adapted pathogens. The role of autophagy in cell remodelling during cell differentiation. Manipulation of autophagy for better nutrient management at the whole-plant level. Regulation of autophagy by sink-strength demand. Metabolic checkpoints in autophagy regulation in source and sink tissues. Non-invasive monitoring of autophagic flux in planta. Development of drugs to manipulate plant-specific autophagy. Autophagy and proteolysis Proteolysis has at least three fundamental implications for autophagy: (i) modification of Atg proteins through limited proteolysis, (ii) crosstalk between the ubiquitin–proteasome system and autophagy pathway, and (iii) digestive proteolysis of autophagic cargo in the lysosomes or lytic vacuoles (for reviews see Kaminskyy and Zhivotovsky, 2012; Minina et al., 2017). While proteases executing the degradation of cargo at the final step of autophagy have been described for yeasts and animals, there is more to be learned about this process in plants. In fact, scrutinizing substrate preferences of lysosomal or vacuolar proteases can give a valuable hint about cargo specificity of constitutive autophagy and autophagy induced by various kinds of stresses or developmental signals. Blocked or decreased degradation of protein cargoes is a biochemical hallmark of autophagy deficiency in various systems, including higher plants (e.g. Guiboileau et al., 2013; Hirota et al., 2018). Couso et al. (2018) extend this notion to the Chlamydomonas model by revealing that concanamycin A treatment of algal cells prevents degradation of ribosomal proteins RPS6 and RPL37 induced by nitrogen or phosphate starvation. The authors surmise that Chlamydomonas might recycle its ribosomal components through a ribophagy-like pathway (Kraft et al., 2008) recently shown to operate in Arabidopsis (Floyd et al., 2015). It was previously shown that Arabidopsis atg mutants have increased endopeptidase and carboxypeptidase activities (Guiboileau et al., 2013). To identify proteases exhibiting differential abundance (at the protein level) and catalytic activity in atg plants versus wild-type plants, Havé et al. (2018) have now combined transcriptomics, quantitative proteomics and activity profiling. The study has revealed that autophagy deficiency, especially under nitrogen-limiting conditions, leads to increased abundance and activity of a subset of vacuolar papain-like cysteine proteases (PLCPs; C1 family proteases), as well as the 26S proteasome. The authors discuss increased PLCP activity in light of the spontaneous cell-death lesion phenotype typical for atg mutants and as a potential compensatory mechanism for protein degradation under autophagy deficiency (Havé et al., 2018). Elevated proteasomal activity and accumulation of proteasomal subunits in atg plants are in agreement with a selective route of autophagy for the disposal of the 26S proteasome, as recently discovered in Arabidopsis (Marshall et al., 2015). In animals, the cysteine cathepsins, which are members of the PLCP family, are major executioners involved in lysosomal protein degradation during autophagy (Kaminskyy and Zhivotovsky, 2012). In plants, while the actual input of cathepsins in autophagic recycling in cells remains unknown, these proteases are certainly crucial components of developmental and stress-induced cell death pathways (Hofius et al., 2009; Zhao et al., 2013; Ge et al., 2016). Bárány et al. (2018) demonstrate the involvement of cathepsin-like activities and autophagy in cold stress-induced microspore cell death in barley. The microspores that evade death can transdifferentiate to haploid embryos, providing a potent biotechnological tool to barley breeding. Interestingly, pharmacological inhibition of either autophagy or cysteine proteases (or both) suppressed cell death and increased the frequency of embryo formation. Transcriptional stimulation of autophagy Regulation of autophagy is complex, including transcriptional, post-transcriptional and post-translational steps (Feng et al., 2015; Frankel et al., 2017). Previous studies in Arabidopsis and maize repeatedly demonstrated that transcription of genes encoding the components of Atg8 and Atg12 conjugation systems is increased with senescence, nutrient limitations and other stresses, i.e. autophagy-stimulating conditions (e.g. Thompson et al., 2005; Chung et al., 2009). These observations pointed to the interesting possibility that some of these components might be rate-limiting for autophagic flux. In a new study, Minina et al. (2018) demonstrate that Atg5 and Atg7 are rate-limiting factors of the Atg8–phosphatidylethanolamine conjugation pathway in Arabidopsis. The authors reveal that Atg5 exerts its effect on Atg8 lipidation by directly controlling the rate of Atg12–Atg5 conjugation, whereas Atg7 presumably acts by catalyzing formation of the Atg8–Atg3 conjugate. Accordingly, overexpression of ATG5 or ATG7 facilitates Atg8 lipidation, and as a result stimulates both autophagosome formation and autophagic flux. Autophagy in plant fitness and immunity Genetic suppression of autophagy in plants correlates with an overall decrease in plant fitness, including reduced vegetative growth and fecundity, accelerated senescence and enhanced susceptibility to diverse types of stresses. Since autophagy is essential for nitrogen remobilization and seed filling (Guiboileau et al., 2012), and little is known about the seed-autonomous role of autophagy, Di Berardino et al. (2018) have focused on monitoring autophagy in developing Arabidopsis seeds and on uncovering additional causes of reduced fecundity in autophagy-deficient plants. Using ATG8f–GFP reporter lines, the authors demonstrate high autophagic activity in embryos at late developmental stages. Comparison of seed development in atg5 plants versus wild-type plants has revealed that autophagy deficiency compromises storage protein deposition and promotes embryonic arrest and seed abortion. Since mere overexpression of ATG5 or ATG7 was sufficient to increase autophagic flux in Arabidopsis, Minina et al. (2018) have used these transgenic plants as a model for studying the impact of enhanced autophagy on plant fitness. The analyses have shown that enhanced autophagy suppresses plant senescence, stimulates vegetative growth and sustains flowering, resulting in increased seed set. The authors, however, point out that the phenotypic differences between overexpressor and wild-type disappear when plants are grown under decreased light intensity, known to stimulate autophagy and to suppress ageing in wild-type Arabidopsis (Minina et al., 2013b ). Plants must cope with growth–defence trade-offs throughout their lives, and maximizing growth-related traits is often achieved at the expense of compromised stress resistance (Huot et al., 2014). Surprisingly, improved growth of ATG5- or ATG7-overexpressing plants was accompanied by increased resistance to oxidative stress and the necrotrophic fungus Alternaria brassicicola (Minina et al., 2018). The only fitness cost for these plants detected so far is decreased resistance against the virulent bacterial pathogen Pseudomonas syringae pv. tomato DC3000 (Üstün et al., 2018). Autophagy machinery is an integral component of immune systems (Deretic et al., 2013). Similarly to the situation in animals, plants and pathogens co-opt plant autophagy to fulfil their conflicting interests. Furthermore, eukaryotic phytopathogens employ their own autophagy machinery for more-efficient colonization of the hosts. These are some of the central themes discussed by Leary et al. (2018), who review different strategies evolved by various types of pathogens in modulating plant autophagy, with special emphasis on the emerging role of selective autophagy. Considering the critical role of autophagy in plant fitness and immunity, Avin-Wittenberg et al. (2018) give a holistic overview of the field, connecting fundamental facts about the regulation of plant autophagy with potential application of this knowledge for improving agronomically important traits. Since our ability to efficiently control the level of autophagy has become a crucial bottleneck, the authors present an up-to-date arsenal of approaches for monitoring and manipulating plant autophagy and discuss their advantages and limitations. This is an exciting time for plant autophagy research, and very inviting for new scientists, thus we hope it will continue to bring new discoveries with strong benefits for human health, plant production and the bioeconomy.

Increasing drought stress poses a severe threat to agricultural productivity. Plants, however, have evolved numerous mechanisms to cope with such environmental stress. Here we report that the stress-induced production of a peptide signal contributes to stress tolerance. The expression of phytosulfokine (PSK) peptide precursor genes, and transcripts of three subtilisin-like serine proteases, SBT1.4, SBT3.7, and SBT3.8, were found to be up-regulated in response to osmotic stress. Stress symptoms were more pronounced in sbt3.8 loss-of-function mutants and could be alleviated by PSK treatment. Osmotic stress tolerance was improved in plants overexpressing the PSK1 precursor (proPSK1) or SBT3.8, resulting in higher fresh weight and improved lateral root development in transgenic plants compared with wild-type plants. We further showed that SBT3.8 is involved in the biogenesis of the bioactive PSK peptide. ProPSK1 was cleaved by SBT3.8 at the C-terminus of the PSK pentapeptide. Processing by SBT3.8 depended on the aspartic acid residue directly following the cleavage site. ProPSK1 processing was impaired in the sbt3.8 mutant. The data suggest that increased expression of proPSK1 in response to osmotic stress followed by the post-translational processing of proPSK1 by SBT3.8 leads to the production of PSK as a peptide signal for stress mitigation.

Abstract Secreted proteases act at the front line of defence and play pivotal roles in disease resistance. However, the criteria for apoplastic immune proteases are not always defined and followed. Here, we critically reviewed 46 apoplastic proteases that function in plant defence. We found that most apoplastic immune proteases are induced upon infection, and 17 proteases are genetically required for the immune response. Proteolytic activity has been confirmed for most of the proteases but is rarely shown to be required for biological function, and the apoplastic location of proteases can be subjective and dynamic. Pathogen-derived inhibitors have only been described for cysteine and serine proteases, and the selection pressure acting on immune proteases is rarely investigated. We discuss six different mechanisms by which these proteases mediate plant immunity and summarize the challenges for future research.