Genetic inactivation of the pancreatitis-inducible gene Nupr1 impairs PanIN formation by modulating KrasG12D-induced senescence

Nuclear protein 1 (Nupr1), a small chromatin protein, has a critical role in cancer development, progression and resistance to therapy. Previously, we had demonstrated that Nupr1 cooperates with Kras^G12D to induce pancreas intraepithelial neoplasias (PanIN) formation and pancreatic ductal adenocarcinoma development in mice. However, the molecular mechanisms by which Nupr1 influences Kras-mediated preneoplastic growth remain to be fully characterized. In the current study, we report evidence supporting a role for Nupr1 as a gene modifier of Kras^G12D-induced senescence, which must be overcome to promote PanIN formation. We found that genetic inactivation of Nupr1 in mice impairs Kras-induced PanIN, leading to an increase in β-galactosidase-positive cells and an upregulation of surrogate marker genes for senescence. More importantly, both of these cellular and molecular changes are recapitulated by the results of mechanistic experiments using RNAi-based inactivation of Nupr1 in human pancreatic cancer cell models. In addition, the senescent phenotype, which results from Nupr1 inactivation, is accompanied by activation of the FoxO3a-Skp2-p27^Kip1-pRb-E2F pathway in vivo and in vitro. Thus, combined, these results show, for the first time, that Nupr1 aids oncogenic Kras to bypass senescence in a manner that cooperatively promotes PanIN formation. Besides its mechanistic importance, this new knowledge bears medical relevance as it delineates early pathobiological events that may be targeted in the future as a means to interfere with the formation of preneoplastic lesions early during pancreatic carcinogenesis.Pancreatic ductal adenocarcinoma (PDAC) is a highly aggressive cancer with <5% survival after 5 years and a median survival of <6 months after diagnosis.¹ PDAC progresses from precursor lesions named pancreas intraepithelial neoplasias (PanINs). In this regard, it has been firmly established that oncogenic mutations in KRAS behave as one of the earliest stimuli for the formation of PanINs.^{2, 3} These data are strongly supported by animal models, such as the Pdx1-Cre; LSL-Kras^G12D transgenic mice, in which the pancreas-specific expression of oncogenic Kras promotes PanIN occurrence⁴ and, at a lower frequency, pancreatic cancer. Thus, the role of Kras as an initiating cancer mutation is one of the best-established pathobiological mechanisms required for the development of pancreatic cancer. Noteworthy, however, during the initiation stage, pancreatic cells not only trigger protumoral processes but also cellular events that aim at counteracting transformation. One of these tumor-suppressive processes elicited by Kras activation is cellular senescence (oncogene-induced senescence). In the pancreas, the induction of senescence underlies the resistance of exocrine cells to oncogenic Kras-mediated transformation⁵ so as to prevent tumor promotion, which is often supported by common diseases such as chronic pancreatitis.⁶ Indeed, tissue injury, as it occurs in pancreatitis, weakens the defense mechanism posed by senescence leading to its bypass by exocrine cells, which can then readily form PanINs.⁵ Therefore, the molecular mechanism that supports the development of oncogene-induced senescence (OIS) needs to be fully elucidated, if we want to advance our understanding of pancreatic cancer development.The nuclear protein 1 (Nupr1) is a basic helix–loop–helix molecule that is strongly induced by acute pancreatitis and several other cell stresses.^{7, 8} Nupr1 is also overexpressed in several types of human cancers, including PDAC. In this regard, the expression of genes that are targets for regulation by Nupr1 has been implicated in key protumorigenic pathways, including cell cycle regulation, matrix remodeling, autophagy, cell cannibalism and apoptosis inhibition.^{9, 10, 11, 12, 13, 14, 15, 16} Moreover, the fundamental role that Nupr1 has in pancreatic tumorigenesis is underscorded by recent results, which showed that, in mice, the oncogenic form of Kras^G12D is unable to promote PanINs in the absence of this chromatin protein,¹⁷ although the mechanisms responsible for this effect remain an area of active investigation. Consequently, we designed the current study with the aim of testing the hypothesis that Nupr1 cooperates with oncogenic Kras to induce PanIN formation by modulating the expression of gene networks that are necessary for bypassing senescence. To address this question, we characterized the effects that Nupr1 inactivation has on Kras-induced senescence using genome-wide expression profiling, as well as both cellular and molecular assays for this process. As a result of these experiments, we found that, indeed, the genetic inactivation of Nupr1 induces cellular senescence in exocrine pancreatic cells and reduces Kras-induced PanIN formation. At the molecular level, we demonstrated that this phenomenon is characterized by the upregulation of gene networks, which are known mediators of this phenomenon, by regulating at the G1/S transition. Taken together, these results provide mechanistic insights into how Nupr1 cooperates with Kras to promote the development of pancreatic preneoplastic lesions by discovering and characterizing a role for this pancreatitis-inducible protein in modulating cellular senescence. Thus, the new information emerging from this study has both mechanistic and biomedical implications for a better understanding of the pathobiology of pancreatic cancer.     

Identification of nucleases related to nutrient mobilization in senescing cotyledons from French bean

The knowledge about the physiological function of plant nucleases is scarce besides that they have been involved in nucleic acid degradation related with programmed cell death processes. Cotyledons provide a suitable system to investigate this process and the changes associated to nutrient mobilization. Nuclease activities have been determined in French bean seedlings. The total nuclease activity in French bean cotyledons is lower than in embryonic axes; however, several nucleases were detected by in-gel nuclease activity assays with extracts from cotyledons of French bean and ssDNA as substrate. The nuclease activities induced during cotyledon senescence showed higher activity at neutral than at acidic pH. Five different nuclease genes belonging to S1/P1 family have been identified in French bean genome database named PVN1 to PVN5. Their relative expression in cotyledons has been determined from the start of imbibition to senescence, and three genes from this family showed expression in cotyledons. PVN1 was expressed during early stages of seedlings development, whereas PVN4 and PVN5 were expressed during cotyledons senescence. The removal of epicotyl in French bean seedlings resulted in a decrease in the activity and in the expression of the genes associated with the cotyledons senescence process, i.e. PVN4 and PVN5. At the same time, the mobilization of reserves in those cotyledons was slowed down. In the same way, the deficit in phosphate and nitrate during seedlings development led to an acceleration of induction of these genes at the same time that reserves were utilized early on the time. Therefore, the induction of PVN4 and PVN5, the two S1 nuclease genes involved in the process of cotyledon senescence, is related to nutrient mobilization, supporting a possible role for nucleic acids in nutrient recycling during cotyledon senescence.     

Regulation of Jasmonate-Induced Leaf Senescence by Antagonism between bHLH Subgroup IIIe and IIId Factors in Arabidopsis

Plants initiate leaf senescence to relocate nutrients and energy from aging leaves to developing tissues or storage organs for growth, reproduction, and defense. Leaf senescence, the final stage of leaf development, is regulated by various environmental stresses, developmental cues, and endogenous hormone signals. Jasmonate (JA), a lipid-derived phytohormone essential for plant defense and plant development, serves as an important endogenous signal to activate senescence-associated gene expression and induce leaf senescence. This study revealed one of the mechanisms underlying JA-induced leaf senescence: antagonistic interactions of the bHLH subgroup IIIe factors MYC2, MYC3, and MYC4 with the bHLH subgroup IIId factors bHLH03, bHLH13, bHLH14, and bHLH17. We showed that MYC2, MYC3, and MYC4 function redundantly to activate JA-induced leaf senescence. MYC2 binds to and activates the promoter of its target gene SAG29 (SENESCENCE-ASSOCIATED GENE29) to activate JA-induced leaf senescence. Interestingly, plants have evolved an elaborate feedback regulation mechanism to modulate JA-induced leaf senescence: The bHLH subgroup IIId factors (bHLH03, bHLH13, bHLH14, and bHLH17) bind to the promoter of SAG29 and repress its expression to attenuate MYC2/MYC3/MYC4-activated JA-induced leaf senescence. The antagonistic regulation by activators and repressors would mediate JA-induced leaf senescence at proper level suitable for plant survival in fluctuating environmental conditions.     

<Emphasis Type="Italic">GmDim1</Emphasis> Gene Encodes Nucleolar Localized U5-Small Nuclear Ribonucleoprotein in <Emphasis Type="Italic">Glycine max</Emphasis>

The dim1⁺ gene family is essential for G2/M transition during mitosis and encodes a small nuclear ribonucleoprotein that functions in the mRNA splicing machinery of eukaryotes. However, the plant homolog of DIM1 gene has not been defined yet. Here, we identified a gene named GmDim1 positioned on chromosome 9 of soybean (Glycine max (L.) Merr.) with 80% homology to other eukaryotic dim1⁺ family genes. A domain of soybean DIM1 protein was primarily conserved with U5 snRNP protein family and secondarily aligned with mitotic DIM1 protein family. The GmDim1 gene was expressed constitutively in all soybean organs. The transgenic Arabidopsis thaliana (L.) plants overexpressing GmDim1 showed early flowering and stem elongation, produced multiple shoots and continued flowering after the post-flowering stage. DIM1 proteins transiently expressed in onion cells were localized in the nucleus with dense deposition in the nucleolus. Therefore, we propose that the soybean GmDim1 gene is a component of plant U5 snRNP involved in mRNA splicing and normal progress of plant growth.     

Piriformospora indica enhances plant growth by transferring phosphate

Piriformospora indica is an endophytic fungus that colonized monocot as well as dicot. P. indica has been termed as plant probiotic because of its plant growth promoting activity and its role in enhancement of the tolerance of the host plants against abiotic and biotic stresses. In our recent study, we have characterized a high affinity phosphate transporter (PiPT) and by using RNAi approach, we have demonstrated the involvement of PiPT in P transfer to the host plant. When knockdown strains of PiPT-P. indica was colonized with the host plant, it resulted in the impaired growth of the host plants. Here we have analyzed and discussed whether the growth promoting activity of P. indica is its intrinsic property or it is dependent on P availability. Our data explain the correlation between the availability of P and growth-promoting activity of P. indica.Key words: Piriformospora indica, phosphate transport, plant growth promotionPhosphorous (P) is one of the most essential mineral nutrients for plant growth and development. In the soil P is present mainly in the form of sparingly soluble complexes that are not directly accessible to plants. Thus, it is the nutrient that limits crop production throughout the world.¹ Plants have therefore evolved a range of strategies to increase the availability of soil P, which include both morphological and biochemical changes at the soil-root interface. For example, increased root growth and branching, proliferation of root hairs, and release of root exudates can increase plant access to inorganic phosphate (Pi) from otherwise poorly available sources.^2,3 Plant root possess two distinct modes of phosphate uptake, direct uptake by its own transporters and indirect uptake through mycorrhizal associations. In plants several high affinity P transporters specifically associated with the uptake of Pi from soil solution. Expression of these transporters is induced in response to P deficiency and enables Pi to be effectively taken up against the large concentration gradient that occurs between the soil solution and internal plant tissues.⁴ However, in arbuscular mycorrhizal associations (indirect uptake), plants acquire Pi from the extensive network of fine extra radical hyphae of fungus, that extend beyond root depletion zones to mine new regions of the soil.⁵ In the case of arbuscular mycorrhizal fungi (AMF), including Glomus versiforme and G. intraradices, the regulation of phosphate transporters that are expressed, typically upregulated under P deficiency but their role in P transfer to the host plant have not been characterized.^5,6P. indica was reported to be involved in high salt tolerance, disease resistance and strong growth-promoting activities leading to enhancement of host plant yield.^7–9 Recently, we have shown the role of PiPT in the P transport to the host plant.¹⁰ Here we discuss the performance of P. indica (grown under P-rich and -deprived conditions and colonized with the host plant) and its involvement in the P transportation to, and the growth of the host plant.     

pH as a proxy for estimating plant-available Si? A case study in rice fields in Karnataka (South India)

Background and aims

Soil nutrient dynamics are affected by root-microbe interactions and plant development. We investigated the influence of plant growth stage and arbuscular mycorrhiza fungi (AMF) on carbon (C) and nitrogen (N) rhizodeposition and the transfer into the microbial biomass (MB).

Methods

Pea varieties (Pisum sativum L.) with (Frisson) and without mycorrhiza (P2) were ¹³C-¹⁵N-labelled and harvested at 45, 63, 71, and 95 days after sowing. Mycorrhization, MB, total C, N, ¹³C, ¹⁵N were determined in plant and soil compartments to calculate C and N derived from rhizodeposition (CdfR, NdfR).

Results

Total CdfR increased until pea maturity, NdfR until end of flowering. Their relative contribution steadily decreased over time, accounting for 4–10% of total plant C and N at harvest. Rhizodeposition contributed between 1 and 6% to MB C and N, although 20% of the rhizodeposits were discovered in the MB. Frisson released more NdfR than P2 but it was not possible to accurately estimate AMF effects on C and N due to differences in biomass partitioning.

Conclusions

CdfR followed an even flow from early growth until senescence. NdfR flow ceased after flowering possibly due to N relocation within the plant. Rhizodeposits contribute very little to MB in our study.

     

Leaf Senescence Signaling: The Ca2+-Conducting Arabidopsis Cyclic Nucleotide Gated Channel2 Acts through Nitric Oxide to Repress Senescence Programming

Ca²⁺ and nitric oxide (NO) are essential components involved in plant senescence signaling cascades. In other signaling pathways, NO generation can be dependent on cytosolic Ca²⁺. The Arabidopsis (Arabidopsis thaliana) mutant dnd1 lacks a plasma membrane-localized cation channel (CNGC2). We recently demonstrated that this channel affects plant response to pathogens through a signaling cascade involving Ca²⁺ modulation of NO generation; the pathogen response phenotype of dnd1 can be complemented by application of a NO donor. At present, the interrelationship between Ca²⁺ and NO generation in plant cells during leaf senescence remains unclear. Here, we use dnd1 plants to present genetic evidence consistent with the hypothesis that Ca²⁺ uptake and NO production play pivotal roles in plant leaf senescence. Leaf Ca²⁺ accumulation is reduced in dnd1 leaves compared to the wild type. Early senescence-associated phenotypes (such as loss of chlorophyll, expression level of senescence-associated genes, H₂O₂ generation, lipid peroxidation, tissue necrosis, and increased salicylic acid levels) were more prominent in dnd1 leaves compared to the wild type. Application of a Ca²⁺ channel blocker hastened senescence of detached wild-type leaves maintained in the dark, increasing the rate of chlorophyll loss, expression of a senescence-associated gene, and lipid peroxidation. Pharmacological manipulation of Ca²⁺ signaling provides evidence consistent with genetic studies of the relationship between Ca²⁺ signaling and senescence with the dnd1 mutant. Basal levels of NO in dnd1 leaf tissue were lower than that in leaves of wild-type plants. Application of a NO donor effectively rescues many dnd1 senescence-related phenotypes. Our work demonstrates that the CNGC2 channel is involved in Ca²⁺ uptake during plant development beyond its role in pathogen defense response signaling. Work presented here suggests that this function of CNGC2 may impact downstream basal NO production in addition to its role (also linked to NO signaling) in pathogen defense responses and that this NO generation acts as a negative regulator during plant leaf senescence signaling.Senescence can be considered as the final stage of a plant’s development. During this process, nutrients will be reallocated from older to younger parts of the plant, such as developing leaves and seeds. Leaf senescence has been characterized as a type of programmed cell death (PCD; Gan and Amasino, 1997; Quirino et al., 2000; Lim et al., 2003). During senescence, organelles such as chloroplasts will break down first. Biochemical changes will also occur in the peroxisome during this process. When the chloroplast disassembles, it is easily observed as a loss of chlorophyll. Mitochondria, the source of energy for cells, will be the last cell organelles to undergo changes during the senescence process (Quirino et al., 2000). At the same time, other catabolic events (e.g. protein and lipid breakdown, etc.) are occurring (Quirino et al., 2000). Hormones may also contribute to this process (Gepstein, 2004). From this information we can infer that leaf senescence is regulated by many signals.Darkness treatment can induce senescence in detached leaves (Poovaiah and Leopold, 1973; Chou and Kao, 1992; Weaver and Amasino, 2001; Chrost et al., 2004; Guo and Crawford, 2005; Ülker et al., 2007). Ca²⁺ can delay the senescence of detached leaves (Poovaiah and Leopold, 1973) and leaf senescence induced by methyl jasmonate (Chou and Kao, 1992); the molecular events that mediate this effect of Ca²⁺ are not well characterized at present.Nitric oxide (NO) is a critical signaling molecule involved in many plant physiological processes. Recently, published evidence supports NO acting as a negative regulator during leaf senescence (Guo and Crawford, 2005; Mishina et al., 2007). Abolishing NO generation in either loss-of-function mutants (Guo and Crawford, 2005) or transgenic Arabidopsis (Arabidopsis thaliana) plants expressing NO degrading dioxygenase (NOD; Mishina et al., 2007) leads to an early senescence phenotype in these plants compared to the wild type. Corpas et al. (2004) showed that endogenous NO is mainly accumulated in vascular tissues of pea (Pisum sativum) leaves. This accumulation is significantly reduced in senescing leaves (Corpas et al., 2004). Corpas et al. (2004) also provided evidence that NO synthase (NOS)-like activity (i.e. generation of NO from l-Arg) is greatly reduced in senescing leaves. Plant NOS activity is regulated by Ca²⁺/calmodulin (CaM; Delledonne et al., 1998; Corpas et al., 2004, 2009; del Río et al., 2004; Valderrama et al., 2007; Ma et al., 2008). These studies suggest a link between Ca²⁺ and NO that could be operating during senescence.In animal cells, all three NOS isoforms require Ca²⁺/CaM as a cofactor (Nathan and Xie, 1994; Stuehr, 1999; Alderton et al., 2001). Notably, animal NOS contains a CaM binding domain (Stuehr, 1999). It is unclear whether Ca²⁺/CaM can directly modulate plant NOS or if Ca²⁺/CaM impacts plant leaf development/senescence through (either direct or indirect) effects on NO generation. However, recent studies from our lab suggest that Ca²⁺/CaM acts as an activator of NOS activity in plant innate immune response signaling (Ali et al., 2007; Ma et al., 2008).Although Arabidopsis NO ASSOCIATED PROTEIN1 (AtNOA1; formerly named AtNOS1) was thought to encode a NOS enzyme, no NOS-encoding gene has yet been identified in plants (Guo et al., 2003; Crawford et al., 2006; Zemojtel et al., 2006). However, the AtNOA1 loss-of-function mutant does display reduced levels of NO generation, and several groups have used the NO donor sodium nitroprusside (SNP) to reverse some low-NO related phenotypes in Atnoa1 plants (Guo et al., 2003; Bright et al., 2006; Zhao et al., 2007). Importantly, plant endogenous NO deficiency (Guo and Crawford, 2005; Mishina et al., 2007) or abscisic acid/methyl jasmonate (Hung and Kao, 2003, 2004) induced early senescence can be successfully rescued by application of exogenous NO. Addition of NO donor can delay GA-elicited PCD in barley (Hordeum vulgare) aleurone layers as well (Beligni et al., 2002).It has been suggested that salicylic acid (SA), a critical pathogen defense metabolite, can be increased in natural (Morris et al., 2000; Mishina et al., 2007) and transgenic NOD-induced senescent Arabidopsis leaves (Mishina et al., 2007). Pathogenesis related gene1 (PR1) expression is up-regulated in transgenic Arabidopsis expressing NOD (Mishina et al., 2007) and in leaves of an early senescence mutant (Ülker et al., 2007).Plant cyclic nucleotide gated channels (CNGCs) have been proposed as candidates to conduct extracellular Ca²⁺ into the cytosol (Sunkar et al., 2000; Talke et al., 2003; Lemtiri-Chlieh and Berkowitz, 2004; Ali et al., 2007; Demidchik and Maathuis, 2007; Frietsch et al., 2007; Kaplan et al., 2007; Ma and Berkowitz, 2007; Urquhart et al., 2007; Ma et al., 2009a, 2009b). Arabidopsis “defense, no death” (dnd1) mutant plants have a null mutation in the gene encoding the plasma membrane-localized Ca²⁺-conducting CNGC2 channel. This mutant also displays no hypersensitive response to infection by some pathogens (Clough et al., 2000; Ali et al., 2007). In addition to involvement in pathogen-mediated Ca²⁺ signaling, CNGC2 has been suggested to participate in the process of leaf development/senescence (Köhler et al., 2001). dnd1 mutant plants have high levels of SA and expression of PR1 (Yu et al., 1998), and spontaneous necrotic lesions appear conditionally in dnd1 leaves (Clough et al., 2000; Jirage et al., 2001). Endogenous H₂O₂ levels in dnd1 mutants are increased from wild-type levels (Mateo et al., 2006). Reactive oxygen species molecules, such as H₂O₂, are critical to the PCD/senescence processes of plants (Navabpour et al., 2003; Overmyer et al., 2003; Hung and Kao, 2004; Guo and Crawford, 2005; Zimmermann et al., 2006). Here, we use the dnd1 mutant to evaluate the relationship between leaf Ca²⁺ uptake during plant growth and leaf senescence. Our results identify NO, as affected by leaf Ca²⁺ level, to be an important negative regulator of leaf senescence initiation. Ca²⁺-mediated NO production during leaf development could control senescence-associated gene (SAG) expression and the production of molecules (such as SA and H₂O₂) that act as signals during the initiation of leaf senescence programs.     

In vitro evidence for senescent multinucleated melanocytes as a source for tumor-initiating cells

Oncogenic signaling in melanocytes results in oncogene-induced senescence (OIS), a stable cell-cycle arrest frequently characterized by a bi- or multinuclear phenotype that is considered as a barrier to cancer progression. However, the long-sustained conviction that senescence is a truly irreversible process has recently been challenged. Still, it is not known whether cells driven into OIS can progress to cancer and thereby pose a potential threat. Here, we show that prolonged expression of the melanoma oncogene N-RAS^61K in pigment cells overcomes OIS by triggering the emergence of tumor-initiating mononucleated stem-like cells from senescent cells. This progeny is dedifferentiated, highly proliferative, anoikis-resistant and induces fast growing, metastatic tumors. Our data describe that differentiated cells, which are driven into senescence by an oncogene, use this senescence state as trigger for tumor transformation, giving rise to highly aggressive tumor-initiating cells. These observations provide the first experimental in vitro evidence for the evasion of OIS on the cellular level and ensuing transformation.Cellular senescence is characterized by cell-cycle arrest and alterations in cell shape and metabolism, and can be triggered either by the sequential loss of telomeres or by numerous forms of cellular stress, for example, UV irradiation, oxidative stress or aberrant oncogenic signaling (premature senescence). In particular, oncogene-induced senescence (OIS), driven for example by activated RAS or BRAF, is an anti-cancer protection mechanism that prevents tumor generation despite the presence of oncogenic mutations. For instance, human nevi exhibit enhanced MAPK signaling caused by activating mutations in B-RAF or N-RAS. They display classical characteristics of senescence,¹ and remain benign in the large majority of cases. However, nevi are also supposed to give rise to a quarter of all melanomas.²Along the same lines, oncogenic RAS clearly triggers OIS in different cell types in vivo,^{3, 4, 5, 6} but activated RAS is detected in up to 30% of human cancers.^{7, 8} This indicates that senescence bypass is a key feature of cancer development. The fact that many premalignant tissues with tumorigenic potential display features of senescence has led to the concept that OIS precedes transformation, and tumors arise from senescent tissue.^{1, 5, 6, 9} However, as OIS was long considered to be irreversible, it was not clear how this transformation process can take place. Recently, there has been accumulating evidence that OIS can be reversed under certain circumstances on the cellular level. Specifically, H-RAS^12V induces senescence in fibroblasts, which is caused by ribonucleotide reductase (RRM2) suppression and accompanying dNTP reduction.¹⁰ Interestingly, the forced re-expression of RRM2 is able to overcome senescence. Still, is not known whether a senescent primary cell might give rise to cancer. While the later steps of tumor progression are fairly well understood, early events in tumorigenesis such as the transition of a benign senescent lesion to a tumor are still enigmatic.Here, we reveal that long-term NRAS^61K activation in melanocytes triggers a strong senescent phenotype characterized by multinucleation, which then is followed by the post-senescence generation of tumor-initiating cells with stem cell-like properties. The results demonstrate that senescence in melanocytes can be overcome on the cellular level and can also be a source for malignant cancer cells.     

MOTHER OF FT AND TFL1 regulates seed germination and fertility relevant to the brassinosteroid signaling pathway

Brassinosteroids (BRs) are a family of plant steroid hormones that play diverse roles in many aspects of plant growth and development. For example, BRs promote seed germination by counteracting the inhibitory effect of ABA and regulate plant reproductive development, thus affecting seed yield. We have recently reported that MOTHER OF FT AND TFL1 (MFT) regulates seed germination through a negative feedback loop modulating ABA signaling in Arabidopsis. Here, we show that MFT function is also relevant to the BR signaling pathway. In mft loss-of-function mutants, the application of BR could not fully antagonize the inhibitory effect of exogenous ABA on seed germination, suggesting that BR promotes seed germination against ABA partly through MFT. In addition, mft enhances the low-fertility phenotype of det2 in which BR biosynthesis is blocked. This phenotype, together with the observation that MFT is expressed in gametophytes and developing seeds, suggests that MFT and BR play redundant roles in regulating fertility. Therefore, these results suggest that MFT affects seed germination and fertility relevant to the BR signaling pathway.Key words: Arabidopsis, brassinosteroid, abscisic acid, fertility, seed germinationPlant hormones exert profound effects on many fundamental processes during plant growth and development. With respect to seed development and germination, it has long been known that abscisic acid (ABA) and gibberellin (GA) are two major types of phytohormones that play antagonistic roles in regulating these events. Not until recently, another group of phytohormones, namely brassinosteroids (BRs), has also been found to counteract the inhibitory effect of ABA on seed germination.^1,2 In addition, BR has been suggested to act in parallel with GA to promote cell elongation and germination.^1,3,4BRs are a class of polyhydroxysteroids that are found in a wide variety of plant species.⁵ They can be detected in almost every plant tissue, with the highest abundance in the pollen and seeds.⁶ The most active component in the family of BRs is 24-epibrassinolide (BL), which is capable of activating BR signaling.⁶ In Arabidopsis, when the early steps of BR biosynthesis are blocked, the resulting defects include reduced male fertility under normal growth conditions^7,8 and decreased germination percentage in the presence of exogenous ABA.¹ Thus, BR plays an indispensible role in the control of seed development and also contributes to the regulation of seed germination.We have previously reported that MOTHER OF FT AND TFL1 (MFT) responds to both ABA and GA signals to regulate seed germination.⁹ Here we show that MFT functions in regulating seed germination and fertility, which is also relevant to the BR signaling pathway. Thus, MFT seems to function specifically in seeds in response to various phytohormones.     

Chloroplasts autophagy during senescence of individually darkened leaves

We recently reported that autophagy plays a role in chloroplasts degradation in individually-darkened senescing leaves. Chloroplasts contain approximately 80% of total leaf nitrogen, mainly as photosynthetic proteins, predominantly ribulose 1, 5-bisphosphate carboxylase/oxygenase (Rubisco). During leaf senescence, chloroplast proteins are degraded as a major source of nitrogen for new growth. Concomitantly, while decreasing in size, chloroplasts undergo transformation to non-photosynthetic gerontoplasts. Likewise, over time the population of chloroplasts (gerontoplasts) in mesophyll cells also decreases. While bulk degradation of the cytosol and organelles is mediated by autophagy, the role of chloroplast degradation is still unclear. In our latest study, we darkened individual leaves to observe chloroplast autophagy during accelerated senescence. At the end of the treatment period chloroplasts were much smaller in wild-type than in the autophagy defective mutant, atg4a4b-1, with the number of chloroplasts decreasing only in wild-type. Visualizing the chloroplast fractions accumulated in the vacuole, we concluded that chloroplasts were degraded by two different pathways, one was partial degradation by small vesicles containing only stromal-component (Rubisco containing bodies; RCBs) and the other was whole chloroplast degradation. Together, these pathways may explain the morphological attenuation of chloroplasts during leaf senescence and describe the fate of chloroplasts.Key words: Arabidopsis, autophagy, chloroplast, dark treatment, leaf senescence, nutrients recyclingThe most abundant chloroplast protein is Rubisco, comprising approximately 50% of the soluble protein.¹ The amount of Rubisco decreases rapidly in the early phase of leaf senescence, and more slowly in the later phase. During senescence, chloroplasts gradually shrink and their numbers gradually decrease in mesophyll cells.^2,3 During leaf senescence, leaves lose approximately 75% of their Rubisco, while chloroplast numbers decrease by only about 15%.⁴ Previous studies showed chloroplasts localized within the central vacuole by electron microscopy, indicating chloroplast degradation in the highly hydrolytic vacuole.⁵ However, there was no direct evidence showing translocation of chloroplasts from the cytosol to the vacuole, and the mechanism of transportation was also unclear.Recent reverse genetic approaches are helping to elucidate the autophagy system in plants, which has a similar molecular mechanism as in yeast.^6–11 In Arabidopsis (Arabidopsis thaliana), atg mutants have phenotypically accelerated leaf senescence, insufficient root elongation in nutrient starvation condition and reduced seeds yields, therefore, autophagy is considered to be important for nutrient recycling especially nutrient starvation and senescence in plants.¹²In Arabidopsis, individually darkened rosette leaves (IDLs) exhibit enhanced senescence.¹³ Appling IDLs treatment as an experimental model of leaf senescence, we recently demonstrated that chloroplasts are degraded in two different pathways by autophagy, one for RCBs,^14,15 and one for whole chloroplast.¹⁶ Darkened leaves became pale in 3 to 5 days treatment, while illuminated parts normally grow in both wild-type and autophagy defective mutant, atg4a4b-1. Furthermore, genes specifically expressed during senescence, SAG12 and SEN1, were rapidly upregulated, meanwhile, photosynthetic genes, such as RBCS2B and CAB2B, were gradually downregulated. All analyzed ATG genes were also upregulated under IDL treatment, which suggests that autophagy is important in IDL senescence. It has been reported that approximately three quarter genes of upregulated in IDL were also upregulated in naturally senescing leaves, including the ATG genes.¹⁷ This suggests that the autophagy pathways used in IDLs are also used in naturally senescing leaves.Over the 5 day treatment period, chloroplasts of wild-type IDL shrink to approximately one third their original size. In atg4a4b-1, by contrast, chloroplasts shrinkage occurred immediately after the start of IDL treatment after which no further shrinkage was noted. While the shrunk chloroplasts in fixed cells of wild-type were still smooth and round, while wrinkly chloroplasts were observed in atg4a4b-1. At same time, in the living mesophyll cells of wild-type IDL, RCBs accumulated in the vacuole (Fig 1B). The shrinkage of chloroplasts may be due to the consumption of the chloroplast envelope by RCB formation. Immunological quantification of inner and outer envelope proteins might confirm this hypothesis. The chloroplast number was also gradually decreased in IDL of wild-type plants, but no decline in chloroplast number was noted in atg4a4b-1. Chloroplasts exhibiting chlorophyll auto-fluorescence were found in the vacuole of wild-type IDLs, but not in atg4a4b-1 IDLs. These results show that whole chloroplast degradation is also performed by autophagy. However, the transport pathway of whole chloroplasts into the vacuole remains unclear. The chloroplast, even in its shrunken state, is a large organelle, and the autophagosome, the carrier bodies of autophagy, which usually target small spherical organelles like mitochondria and peroxisomes, may be incapable of isolating large organelles. In the yeast autophagy system, specific cellular organelles and fractions are also transported via vacuolar membrane invagination using the microautophagy system.¹⁸ RCB uptake into the vacuole is termed macroautophagy, while larger organelles, such as chloroplasts, are engulfed in a process known as microautophagy. Whether there exists a molecular difference between these processes, or whether this is an arbitrary division based solely on the size of the consumed body is unclear.Open in a separate windowFigure 1Visualization of stroma-targeted DsRed and chlorophyll autofluorescence in living mesophyll cells of wild-type plants by laser-scanning confocal microscopy. A excised control leaf (A, Light) and an individually darkened leaf (B, IDL) from plants grown under 14 h-photoperiod condition and a leaf from whole-plant darkened condition (WD, C) for 5days were incubated with 1 µM concanamycin A in 10 mM MES-NaOH (pH 5.5) at 23C° for 20 h in darkness. Stroma-targeted DsRed appears green and chlorophyll fluorescence appears red. In merged images, overlap of DsRed and chlorophyll fluorescence appears yellow. Small vesicles with stromal-targeted DsRed, i.e. RCBs, can be found in the vacuole (A, B). In IDL (B), massive accumulation of stroma-targeted DsRed is entirely seen in the vacuolar lumen and chloroplasts losing DsRed fluorescence are found in some cells. Bars = 50 µm.Whole darkened plants exhibit retarded leaf aging, in contrast to the accelerated senescence in IDLs.¹³ Whole darkened plants suppress leaf senescence with the leaves retaining green color. After 5 days, in the mesophyll cells of whole darkened plants, any translocation of chloroplast components, stroma-targeted DsRed, RCBs, and whole chloroplasts, into the vacuole could hardly be detected (Fig. 1C). This suggests that autophagy is not induced by darkness alone, and is associated closely with senescence. ATG genes were downregulated in the whole darkened wild-type plants less than control plants during the treatment. Previous studies have shown that following about 5 day period of whole plant darkening, atg mutants lose their ability to protect themselves against photo-damage.⁷ Upon return to the light, these plant quickly undergo terminal photo-bleaching.Concentrations of chlorophyll, soluble protein, leaf nitrogen and Rubisco rapidly declined under IDL condition of both wild-type and atg4a4b-1. Considering the accumulated fluorescence of stroma-targeted Ds-Red in the vacuole and autophagy dependent size shrinkage of chloroplasts in IDL, in wild-type plants RCB autophagy appear to be responsible for a sizable proportion of chloroplast protein degradation. In atg4a4b-1 which cannot form RCBs, alternative degradation pathways must be upregulated, with chloroplast proteases the most likely candidates. Intriguingly, the decrease in Rubisco concentration proceeds at the almost identical rates in both wild-type and atg4a4b-1 plants, despite the different degradation pathways. It seems likely that the rate of Rubisco degradation may be regulated at an early step in the degradation pathway, by some, as yet unknown, factors.Chloroplasts appear to have the ability to control their volume during cell division, dividing and increasing their density up to the certain level,¹⁹ and transferring their cellular components between them via stromules.²⁰ How chloroplasts are able to regulate their volume remains unclear, but it seems likely that chloroplasts grow and divide, like any other bacteria, as long as sufficient resources remain in the environment, in this case the cell. Total chloroplast volume, therefore, may be limited by the availability of carbon, nitrogen, or other nutrients in the cell during leaf emergence. Chloroplasts may be also able to reduce and control their volumes during leaf senescence via multiple degradation pathways. Our next goal is to estimate the contribution of both RCBs and whole chloroplasts autophagy in chloroplast protein degradation during natural leaf senescence. Further investigations are required for understanding the specific molecular mechanisms of RCB production and whole chloroplast degradation.     

Piriformospora indica mycorrhization increases grain yield by accelerating early development of barley plants

Root colonization by the basidiomycete fungus Piriformospora indica induces host plant tolerance against abiotic and biotic stress, and enhances growth and yield. As P. indica has a broad host range, it has been established as a model system to study beneficial plant-microbe interactions. Moreover, its properties led to the assumption that P. indica shows potential for application in crop plant production. Therefore, possible mechanisms of P. indica improving host plant yield were tested in outdoor experiments: Induction of higher grain yield in barley was independent of elevated pathogen levels and independent of different phosphate fertilization levels. In contrast to the arbuscular mycorrhiza fungus Glomus mosseae total phosphate contents of host plant roots and shoots were not significantly affected by P. indica. Analysis of plant development and yield parameters indicated that positive effects of P. indica on grain yield are due to accelerated growth of barley plants early in development.Key words: mycorrhiza, barley development, Piriformospora indica, phosphate uptake, grain yield, pathogen resistanceThe wide majority of plant roots in natural ecosystems is associated with fungi, which very often play an important role for the host plants'' fitness.¹ The widespread arbuscular mycorrhizal (AM) symbiosis formed by fungi of the phylum Glomeromycota is mainly characterized by providing phosphate to their host plant in exchange for carbohydrates.^2,3 Fungi of the order Sebacinales also form beneficial interactions with plant roots and Piriformospora indica is the best-studied example of this group.⁴ This endophyte was originally identified in the rhizosphere of shrubs in the Indian Thar desert,⁵ but it turned out that the fungus colonizes roots of a very broad range of mono- and dicotyledonous plants,⁶ including major crop plants.^7–9 Like other mutualistic endophytes, P. indica colonizes roots in an asymptomatic manner¹⁰ and promotes growth in several tested plant species.^6,11,12 The root endophyte, moreover, enhances yield in barley and tomato and increases in both plants resistance against biotic stresses,^7,9 suggesting that application in agri- and horticulture could be successful.