Heterologous expression of rice calnexin (OsCNX) confers drought tolerance in Nicotiana tabacum

Calnexin (CNX) is an integral membrane protein of endoplasmic reticulum (ER) and is a critical component of ER quality control machinery. It acts as a chaperone and ensures proper folding of newly synthesised glycoproteins. CNX shares a considerable homology with its luminal counterpart calreticulin (CRT). Together, they constitute CNX/CRT cycle which is imperative for proper folding of nascent proteins. CNX deficient organisms develop severe complications because of improper folding of proteins and consequently ER stress. CNX maintains calcium homeostasis by binding to the Ca²⁺ which is a central node in various signaling pathways. Phosphorylation of cytoplasmic tail of CNX controls the sarco endoplasmic reticulum calcium ATPase and thus the movement of Ca²⁺ in and out of its store-house, i.e. ER. Our studies on Oryza sativa CNX (OsCNX) reveal constitutive expression at various developmental stages and various tissues, thereby proving its requirement throughout the plant development. Further, its expression under various stress conditions gives an insight of the crosstalk existing between ER stress and abiotic stress signaling. This was confirmed by heterologous expression of OsCNX (OsCNX-HE) in tobacco and the OsCNX-HE lines were observed to exhibit better germination under mannitol stress and survival under dehydration stress conditions. The dehydration tolerance conferred by OsCNX appears to be ABA-dependent pathway.     

Calnexin and calreticulin promote folding, delay oligomerization and suppress degradation of influenza hemagglutinin in microsomes.

Calnexin (CNX) and calreticulin (CRT) are molecular chaperones that bind preferentially to monoglucosylated trimming intermediates of glycoproteins in the endoplasmic reticulum. To determine their role in the maturation of newly synthesized glycoproteins, we analyzed the folding and trimerization of in vitro translated influenza hemagglutinin (HA) in canine pancreas microsomes under conditions in which HA's interactions with CNX and CRT could be manipulated. While CNX bound to all folding intermediates (IT1, IT2 and NT), CRT was found to associate preferentially with the earliest oxidative form (IT1). If HA's binding to CNX and CRT was inhibited using a glucosidase inhibitor, castanospermine (CST), the rate of disulfide formation and oligomerization was doubled but the overall efficiency of maturation of HA decreased due to aggregation and degradation. If, on the other hand, HA was arrested in CNX-CRT complexes, folding and trimerization were inhibited. This suggested that the action of CNX and CRT, like that of other chaperones, depended on an 'on-and-off' cycle. Taken together, these results indicated that CNX and CRT promote correct folding by inhibiting aggregation, preventing premature oxidation and oligomerization, and by suppressing degradation of incompletely folded glycopolypeptides.     

Structural basis of carbohydrate recognition by calreticulin

The calnexin cycle is a process by which glycosylated proteins are subjected to folding cycles in the endoplasmic reticulum lumen via binding to the membrane protein calnexin (CNX) or to its soluble homolog calreticulin (CRT). CNX and CRT specifically recognize monoglucosylated Glc₁Man₉GlcNAc₂ glycans, but the structural determinants underlying this specificity are unknown. Here, we report a 1.95-Å crystal structure of the CRT lectin domain in complex with the tetrasaccharide α-Glc-(1→3)-α-Man-(1→2)-α-Man-(1→2)-Man. The tetrasaccharide binds to a long channel on CRT formed by a concave β-sheet. All four sugar moieties are engaged in the protein binding via an extensive network of hydrogen bonds and hydrophobic contacts. The structure explains the requirement for glucose at the nonreducing end of the carbohydrate; the oxygen O₂ of glucose perfectly fits to a pocket formed by CRT side chains while forming direct hydrogen bonds with the carbonyl of Gly¹²⁴ and the side chain of Lys¹¹¹. The structure also explains a requirement for the Cys¹⁰⁵–Cys¹³⁷ disulfide bond in CRT/CNX for efficient carbohydrate binding. The Cys¹⁰⁵–Cys¹³⁷ disulfide bond is involved in intimate contacts with the third and fourth sugar moieties of the Glc₁Man₃ tetrasaccharide. Finally, the structure rationalizes previous mutagenesis of CRT and lays a structural groundwork for future studies of the role of CNX/CRT in diverse biological pathways.     

Loss of Specific Chaperones Involved in Membrane Glycoprotein Biosynthesis during the Maturation of Human Erythroid Progenitor Cells

The production of erythrocytes requires the massive synthesis of red cell-specific proteins including hemoglobin, cytoskeletal proteins, as well as membrane glycoproteins glycophorin A (GPA) and anion exchanger 1 (AE1). We found that during the terminal differentiation of human CD34⁺ erythroid progenitor cells in culture, key components of the endoplasmic reticulum (ER) protein translocation (Sec61α), glycosylation (OST48), and protein folding machinery, chaperones BiP, calreticulin (CRT), and Hsp90 were maintained to allow efficient red cell glycoprotein biosynthesis. Unexpected was the loss of calnexin (CNX), an ER glycoprotein chaperone, and ERp57, a protein-disulfide isomerase, as well as a major decrease of the cytosolic chaperones, Hsc70 and Hsp70, components normally involved in membrane glycoprotein folding and quality control. AE1 can traffic to the cell surface in mouse embryonic fibroblasts completely deficient in CNX or CRT, whereas disruption of the CNX/CRT-glycoprotein interactions in human K562 cells using castanospermine did not affect the cell-surface levels of endogenous GPA or expressed AE1. These results demonstrate that CNX and ERp57 are not required for major glycoprotein biosynthesis during red cell development, in contrast to their role in glycoprotein folding and quality control in other cells.The production of red blood cells involves the terminal differentiation of hematopoietic stem cells in the bone marrow followed by release into the peripheral blood (1, 2). Red blood cells remain in circulation for ∼120 days and require the prior production of abundant red cell-specific proteins including hemoglobin, cytoskeletal proteins, and membrane glycoproteins such as anion exchanger 1 (AE1)³ and glycophorin A (GPA). During differentiation, erythroid progenitor cells undergo extensive remodeling of their cytoskeleton and loss of nuclei and other organelles like the endoplasmic reticulum (ER). AE1 and GPA are known to be synthesized late in differentiation when these key cellular components are lost (3). The efficient biosynthesis of these red cell membrane glycoproteins, however, is expected to require robust ER assembly machinery involving protein translocation, N-glycosylation, and protein folding chaperones.The proper folding of membrane glycoproteins engages the quality control function of cytosolic and ER chaperone proteins (4, 5). Newly synthesized proteins undergo cycles of binding and release with chaperones, minimizing aggregation and facilitating folding. Chaperones also play a role in the retention and degradation of misfolded proteins and in apoptosis (6-8). The membrane-bound ER chaperone calnexin (CNX) and its luminal paralog calreticulin (CRT) interact with folding intermediates via their lectin and protein binding domains, thereby preventing aggregation (9). A wide variety of glycoprotein substrates have been identified, with some binding to one or both chaperones, and both have been shown to be vital in the prevention of aggregation and proper maturation of membrane glycoproteins (9, 10). Disruption of interactions with CNX and CRT can allow misfolded membrane glycoproteins to escape the ER and traffic to the plasma membrane (9).In the present study, we examined the integrity of the ER protein translocation, N-glycosylation, and quality control machinery during the differentiation of human CD34⁺ erythroid cells in culture. We found that specific components of the protein quality control system were completely lost (CNX and ERp57) or diminished (Hsc70 and Hsp70) before the production of the major glycoproteins, AE1 and GPA, was completed. Components of the protein translocation (Sec61α) and N-glycosylation machinery (OST48) were, however, maintained. Chaperones that play other roles in erythrocyte maturation and survival (CRT, BiP, and Hsp90) were also retained (11). AE1 was found to traffic efficiently to the plasma membrane in mouse embryonic fibroblasts completely lacking the ER chaperone CNX or CRT. Furthermore, disruption of CNX/CRT-glycoprotein interactions in human K562 cells did not affect the cell-surface expression of GPA or AE1. These results demonstrate that CNX and ERp57 are not required for the efficient synthesis and folding of red cell membrane glycoproteins during terminal erythropoiesis. The lack of engagement with the quality control and disulfide folding machinery may allow the more rapid production of red cell glycoproteins late in differentiation, sacrificing quality for quantity.     

The two Caenorhabditis elegans UDP-glucose:glycoprotein glucosyltransferase homologues have distinct biological functions

The UDP-Glc:glycoprotein glucosyltransferase (UGGT) is the sensor of glycoprotein conformations in the glycoprotein folding quality control as it exclusively glucosylates glycoproteins not displaying their native conformations. Monoglucosylated glycoproteins thus formed may interact with the lectin-chaperones calnexin (CNX) and calreticulin (CRT). This interaction prevents premature exit of folding intermediates to the Golgi and enhances folding efficiency. Bioinformatic analysis showed that in C. elegans there are two open reading frames (F48E3.3 and F26H9.8 to be referred as uggt-1 and uggt-2, respectively) coding for UGGT homologues. Expression of both genes in Schizosaccharomyces pombe mutants devoid of UGGT activity showed that uggt-1 codes for an active UGGT protein (CeUGGT-1). On the other hand, uggt-2 coded for a protein (CeUGGT-2) apparently not displaying a canonical UGGT activity. This protein was essential for viability, although cnx/crt null worms were viable. We constructed transgenic worms carrying the uggt-1 promoter linked to the green fluorescent protein (GFP) coding sequence and found that CeUGGT-1 is expressed in cells of the nervous system. uggt-1 is upregulated under ER stress through the ire-1 arm of the unfolded protein response (UPR). Real-time PCR analysis showed that both uggt-1 and uggt-2 genes are expressed during the entire C. elegans life cycle. RNAi-mediated depletion of CeUGGT-1 but not of CeUGGT-2 resulted in a reduced lifespan and that of CeUGGT-1 and CeUGGT-2 in a developmental delay. We found that both CeUGGT1 and CeUGGT2 play a protective role under ER stress conditions, since 10 μg/ml tunicamycin arrested development at the L2/L3 stage of both uggt-1(RNAi) and uggt-2(RNAi) but not of control worms. Furthermore, we found that the role of CeUGGT-2 but not CeUGGT-1 is significant in relieving low ER stress levels in the absence of the ire-1 unfolding protein response signaling pathway. Our results indicate that both C. elegans UGGT homologues have distinct biological functions.     

Regulation of SOBIR1 accumulation and activation of defense responses in bir1–1 by specific components of ER quality control

Receptor‐like kinases play diverse roles in plant biology. Arabidopsis BAK1‐INTERACTING RECEPTOR‐LIKE KINASE 1 (BIR1) functions as a negative regulator of plant immunity. bir1‐1 mutant plants display spontaneous cell death and constitutive defense responses that are dependent on SUPPRESSOR OF BIR1,1 (SOBIR1) and PHYTOALEXIN DEFICIENT4 (PAD4). Here we report that mutations in three components of ER quality control, CALRETICULIN3 (CRT3), ER‐LOCALIZED DnaJ‐LIKE PROTEIN 3b (ERdj3b) and STROMAL‐DERIVED FACTOR‐2 (SDF2), also suppress the spontaneous cell death and constitutive defense responses in bir1‐1. Further analysis revealed that accumulation of the SOBIR1 protein is reduced in crt3‐1 and erdj3b‐1 mutant plants. These data suggest that ER quality control plays important roles in the biogenesis of SOBIR1, and is required for cell death and defense responses in bir1‐1.     

Genetic and transformation studies reveal negative regulation of ERS1 ethylene receptor signaling in Arabidopsis

Background  

Ethylene receptor single mutants of Arabidopsis do not display a visibly prominent phenotype, but mutants defective in multiple ethylene receptors exhibit a constitutive ethylene response phenotype. It is inferred that ethylene responses in Arabidopsis are negatively regulated by five functionally redundant ethylene receptors. However, genetic redundancy limits further study of individual receptors and possible receptor interactions. Here, we examined the ethylene response phenotype in two quadruple receptor knockout mutants, (ETR1) ers1 etr2 ein4 ers2 and (ERS1) etr1 etr2 ein4 ers2, to unravel the functions of ETR1 and ERS1. Their functions were also reciprocally inferred from phenotypes of mutants lacking ETR1 or ERS1. Receptor protein levels are correlated with receptor gene expression. Expression levels of the remaining wild-type receptor genes were examined to estimate the receptor amount in each receptor mutant, and to evaluate if effects of ers1 mutations on the ethylene response phenotype were due to receptor functional compensation. As ers1 and ers2 are in the Wassilewskija (Ws) ecotype and etr1, etr2, and ein4 are in the Columbia (Col-0) ecotype, possible effects of ecotype mixture on ethylene responses were also investigated.     

Hypergravity prevents seed production in <Emphasis Type="Italic">Arabidopsis</Emphasis> by disrupting pollen tube growth

How tightly land plants are adapted to the gravitational force (g) prevailing on Earth has been of interest because unlike many other environmental factors, g presents as a constant force. Ontogeny of mature angiosperms begins with an embryo that is formed after tip growth by a pollen tube delivers the sperm nucleus to the egg. Because of the importance to plant fitness, we have investigated how gravity affects these early stages of reproductive development. Arabidopsis thaliana (L.) Heynh. plants were grown for 13 days prior to being transferred to growth chambers attached to a large diameter rotor, where they were continuously exposed to 2-g or 4-g for the subsequent 11 days. Plants began flowering 1 day after start of the treatments, producing hundreds of flowers for analysis of reproductive development. At 4-g, Arabidopsis flowers self-pollinated normally but did not produce seeds, thus derailing the entire life cycle. Pollen viability and stigma esterase activity were not compromised by hypergravity; however, the growth of pollen tubes into the stigmas was curtailed at 4-g. In vitro pollen germination assays showed that 4-g average tube length was less than half that for 1-g controls. Closely related Brassica rapa L., which produces seeds at 4-g, required forces in excess of 6-g to slow in vitro tube growth to half that at 1-g. The results explain why seed production is absent in Arabidopsis at 4-g and point to species differences with regard to the g-sensitivity of pollen tube growth.     

Penetration and Post-Penetration Resistance to Magnaporthe oryzae in Arabidopsis

The rate of entry of Magnaporthe oryzae into the Arabidopsis pen2 quintuple (pen2 NahG pmr5 agb1 mlo2) mutant was significantly higher than those into the pen2 quadruple (pen2 NahG pmr5 agb1 and pen2 NahG pmr5 mlo2) mutants. The lengths of the infection hyphae in the pen2 quintuple mutant were intermediate between the pen2 quadruple mutants. These results suggest that different genetic networks, consisting of PEN2, PMR5, AGB1, and MLO2, control penetration and post-penetration resistance to M. oryzae in Arabidopsis.     

Mechanism of mutant calreticulin-mediated activation of the thrombopoietin receptor in cancers

Myeloproliferative neoplasms (MPNs) are frequently driven by mutations within the C-terminal domain (C-domain) of calreticulin (CRT). CRT_Del52 and CRT_Ins5 are recurrent mutations. Oncogenic transformation requires both mutated CRT and the thrombopoietin receptor (Mpl), but the molecular mechanism of CRT-mediated constitutive activation of Mpl is unknown. We show that the acquired C-domain of CRT_Del52 mediates both Mpl binding and disulfide-linked CRT_Del52 dimerization. Cysteine mutations within the novel C-domain (C400A and C404A) and the conserved N-terminal domain (N-domain; C163A) of CRT_Del52 are required to reduce disulfide-mediated dimers and multimers of CRT_Del52. Based on these data and published structures of CRT oligomers, we identify an N-domain dimerization interface relevant to both WT CRT and CRT_Del52. Elimination of disulfide bonds and ionic interactions at both N-domain and C-domain dimerization interfaces is required to abrogate the ability of CRT_Del52 to mediate cell proliferation via Mpl. Thus, MPNs exploit a natural dimerization interface of CRT combined with C-domain gain of function to achieve cell transformation.     

Molecular mapping of the cnx2 locus involved in molybdenum cofactor biosynthesis in rice (Oryza sativa L.)

Molybdenum cofactor (Moco) is essential for nitrate reductase (NR), xanthine dehydrogenase (XDH), and aldehyde oxidase to perform their catalytic functions in plants. Moco biosynthesis is a complex process involving many genes. Little is known about the genetics and molecular aspects of Moco biosynthesis in plants and other eukaryotes. In rice, we previously isolated a Moco mutant C25 with a mutation in the CNX2 gene from a mutagenized indica cultivar IR30 and characterized its biochemical properties. This mutant was crossed with a japonica cultivar, Norin 8, to investigate the linkage of cnx2 to restriction fragment length polymorphism (RFLP) and cleaved amplified polymorphic sequence (CAPS) markers. Chlorate resistance was used to trace the cnx2 mutation because of its cosegregation with the loss of NR and XDH activities observed earlier. RFLP and CAPS analyses show the location of the cnx2 locus on the long arm of chromosome 4. It is mapped between RFLP markers C513 and C377 with a distance of 9.5 and 13.1 cM, respectively. It is also linked with CAPS marker RA0738 at a distance of 30.3 cM. Received: 25 June 2000 / Accepted: 31 August 2000     

Glutathione synthesis is essential for pollen germination in vitro

Background  

The antioxidant glutathione fulfills many important roles during plant development, growth and defense in the sporophyte, however the role of this important molecule in the gametophyte generation is largely unclear. Bioinformatic data indicate that critical control enzymes are negligibly transcribed in pollen and sperm cells. Therefore, we decided to investigate the role of glutathione synthesis for pollen germination in vitro in Arabidopsis thaliana accession Col-0 and in the glutathione deficient mutant pad2-1 and link it with glutathione status on the subcellular level.     

Chaperones of the endoplasmic reticulum are required for Ve1‐mediated resistance to Verticillium

The tomato receptor‐like protein (RLP) Ve1 mediates resistance to the vascular fungal pathogen Verticillium dahliae. To identify the proteins required for Ve1 function, we transiently expressed and immunopurified functional Ve1‐enhanced green fluorescent protein (eGFP) from Nicotiana benthamiana leaves, followed by mass spectrometry. This resulted in the identification of peptides originating from the endoplasmic reticulum (ER)‐resident chaperones HSP70 binding proteins (BiPs) and a lectin‐type calreticulin (CRT). Knock‐down of the different BiPs and CRTs in tomato resulted in compromised Ve1‐mediated resistance to V. dahliae in most cases, showing that these chaperones play an important role in Ve1 functionality. Recently, it has been shown that one particular CRT is required for the biogenesis of the RLP‐type Cladosporium fulvum resistance protein Cf‐4 of tomato, as silencing of CRT3a resulted in a reduced pool of complex glycosylated Cf‐4 protein. In contrast, knock‐down of the various CRTs in N. benthamiana or N. tabacum did not result in reduced accumulation of mature complex glycosylated Ve1 protein. Together, this study shows that the BiP and CRT ER chaperones differentially contribute to Cf‐4‐ and Ve1‐mediated immunity.     

Arabidopsis DOK1 encodes a functional dolichol kinase involved in reproduction

Dolichol phosphate (Dol‐P) serves as a carrier of complex polysaccharides during protein glycosylation. Dol‐P is synthesized by the phosphorylation of dolichol or the monodephosphorylation of dolichol pyrophosphate (Dol‐PP); however, the enzymes that catalyze these reactions remain unidentified in Arabidopsis thaliana. We performed a genome‐wide search for cytidylyltransferase motif‐containing proteins in Arabidopsis, and found that At3g45040 encodes a protein homologous with Sec59p, a dolichol kinase (DOK) in Saccharomyces cerevisiae. At3g45040, designated AtDOK1, complemented defects in the growth and N‐linked glycosylation of the S. cerevisiae sec59 mutant, suggesting that AtDOK1 encodes a functional DOK. To characterize the physiological roles of AtDOK1 in planta, we isolated two independent lines of T‐DNA‐tagged AtDOK1 mutants, dok1‐1 and dok1‐2. The heterozygous plants showed developmental defects in male and female gametophytes, including an aberrant pollen structure, low pollen viability, and short siliques. Additionally, the mutations had incomplete penetrance. These results suggest that AtDOK1 is a functional DOK required for reproductive processes in Arabidopsis.     

The involvement of the Arabidopsis CRT1 ATPase family in disease resistance protein-mediated signaling

Resistance (R) gene-mediated immunity provides plants with rapid and strain-specific protection against pathogen infection. Our recent study using the genetically tractable Arabidopsis and turnip crinkle virus (TCV) pathosystem revealed a novel component, named CRT1 (compromised for recognition of the TCV CP), that is involved in general R gene-mediated signaling, including that mediated by HRT, an R gene against TCV. The Arabidopsis CRT1 gene family contains six additional members, of which two share high homology to CRT1 (75 and 81% a.a. identity); either CRT1 or its closest homolog restore the cell death phenotype suppressed by crt1. Analysis of single knock-out mutants for CRT1 and its closest homologs suggest that each may have unique and redundant functions. Here, we provide insight into the screening conditions that enabled identification of a mutant gene despite the presence of functionally redundant family members. We also discuss a potential mechanism that may regulate the interaction between CRT1 and R proteins.Key words: resistance gene, ATPase, suppressor screening, Arabidopsis, turnip crinkle virusPlant resistance (R) proteins activate defense signaling pathways following detection of a specific pathogen-encoded effector, or perception that a host factor has been altered by a pathogen effector. The vast majority of R proteins contain nucleotide binding site (NBS) and leucine-rich repeat (LRR) domains. These R proteins can be further divided into two subgroups, TIR-NBS-LRR and CC-NBS-LRR, depending on whether the N terminus consists of a Toll-interleukin 1 receptor (TIR) or a coiled-coiled (CC) domain, respectively.¹ Subsequent to pathogen perception, the signal(s) generated by various R proteins likely converge into a limited set of pathways, with CC-NBS-LRR proteins usually utilizing NDR1 and TIR-NBS-LRR proteins generally requiring EDS1.² However, the molecular mechanism(s) through which R proteins recognize a pathogen(s) and initiate a defense signal(s) remains unclear.To gain insights into this elusive signaling process, several groups have performed genetic screens to isolate mutants whose R gene-mediated resistance responses are suppressed following either pathogen infection or expression of a transgene-encoded bacterial effector protein. Several proteins, including HSP90, SGT1 and RAR1, were shown to be required for resistance triggered by a variety of R proteins, suggesting their universal function in R protein-mediated resistance.^3–7 However, while some R protein-mediated signaling pathways required both RAR1 and SGT1, others needed only one or neither protein. Thus, the requirement for RAR1 and SGT1 appears to be specific to each pathway.⁸ Further studies revealed that SGT1, RAR1 and HSP90 regulate the stability/accumulation of various R proteins,^8–11 raising the possibility that they serve as (co)chaperones for assembling an active R protein complex.The Arabidopsis R protein HRT was previously shown to recognize the coat protein (CP) of turnip crinkle virus (TCV) and trigger necrotic lesion formation in the inoculated leaf, as well as local and systemic defense responses.¹² To identify components of the HRT-mediated signaling pathway, a line containing HRT and an inducible CP transgene was constructed and screened for suppressors of CP-induced cell death.¹³ One mutant, named crt1 (compromised for recognition of the TCV CP), was identified; it contains a mutation in a GHKL (Gyrase, Hsp90, histidine kinase, MutL) ATPase.¹³ Interestingly, HSP90 also belongs to this recently recognized ATPase superfamily, although sequence homology between HSP90 and CRT1 is limited to the ATPase domain.¹⁴ Either wt CRT1 or its closest homolog, CRT1-h1 (81% a.a. identity to CRT1; 13 suggesting that CRT1 and CRT1-h1 are functionally redundant.

Table 1

Amino-acid sequence identity between CRTI family members in Arabidopsis