Characterization of ScORK28, a transmembrane functional protein receptor kinase predominantly expressed in ovaries from the wild potato species Solanum chacoense

Solanum chacoense ovule receptor kinase 28 (ScORK28) was found among 30 receptor kinases from an ovule cDNA library enriched for weakly expressed mRNAs. This LRR-RLK displayed high level of tissue specificity at the RNA and protein levels and was predominantly expressed in female reproductive tissues. Protein expression analyses in planta revealed that ScORK28 was N-glycosylated and ScORK28::GFP fusion analyses showed that it was localized at the plasma membrane. Bacterial expression of ScORK28 catalytic domain followed by kinase activity assays revealed that ScORK28 is an active Mg2+-dependent protein kinase and that the juxtamembrane domain is necessary for kinase activity.     

Dimerization properties of the transmembrane domains of Arabidopsis CRINKLY4 receptor-like kinase and homologs

CRINKLY4 (CR4) is a plant serine–threonine receptor kinase. In Zea mays, CR4 functions in the differentiation of the leaf epidermis and the aleurone cell layer and, in Arabidopsis thaliana, the ortholog ACR4 is involved in the development of the integument and seed coat. The Arabidopsis genome also encodes four CR4-related proteins (CRR) whose functions are not known. Based on studies of animal receptor kinase proteins it is likely that the molecular basis of function of CR4 and related proteins is mediated by receptor dimerization. The importance of the transmembrane (TM) domain in the dimerization of several receptor kinases has been demonstrated by the TOXCAT system, a genetic assay that measures helix interactions in a natural membrane environment. In this study, we have used the TOXCAT assay to investigate the potential of the CR4 and CR4-related TM domains to homo-dimerize. Our investigation indicates that the CR4 TM domain and the CRR TM domains have higher propensities for homo-dimerization than the ACR4 TM domain. Interestingly, the dimerization potential of the ACR4 TM domain is significantly weaker even though 13 of 24 amino acids are identical to that of the CR4 TM domain. In order to determine the contributions of specific amino acids to the higher dimerization potential of CR4 compared to ACR4, mutations were made at specific sites in ACR4 TM domain and the strength of the dimer assessed by the TOXCAT assay. One mutation restored the activity to the CR4 level, while other mutations produced either no change or significantly increased the dimerization potential of the ACR4 TM domain. Our results indicate that the TM domains of CR4, ACR4 and the CRR receptor family of proteins have the intrinsic capacity to homo-dimerize, albeit with varying degrees of affinity.     

A lectin receptor-like kinase is required for pollen development in Arabidopsis

Lectin receptor-like kinases (Lectin RLKs) are a large family of receptor-like kinases with an extracellular legume lectin-like domain. There are approximately 45 such receptor kinases in Arabidopsis thaliana. Surprisingly, although receptor-like kinases in general are well investigated in Arabidopsis, relatively little is known about the functions of members of the Lectin RLK family. A number of studies implicated members of this family in various functions, such as disease resistance, stress responses, hormone signaling, and legume-rhizobium symbiosis. Our current work demonstrated that mutation in one Lectin RLK gene led to male sterility in Arabidopsis. The sterility was due to defects in pollen development. Pollen development proceeded normally in the mutant until anther stage 8. After that, all pollen grains deformed and collapsed. Mature pollen grains were much smaller than wild-type pollen grains, glued together, and totally collapsed. Therefore, the mutant was named sgc, standing for small, glued-together, and collapsed pollen mutant. The mutant phenotype appeared to be caused by an unidentified sporophytic defect due to the mutation. As revealed by analysis of the promoter-GUS transgenic plants and the gene expression analysis using RT-PCR, the gene showed an interesting temporal and spatial expression pattern: it had no or a low expression in young flowers (roughly before anther stage 6), reached a maximum level around stages 6-7, and then declined gradually to a very low level in young siliques. No expression was detected in microspores or pollen. Together, our data demonstrated that SGC Lectin RLK plays a critical role in pollen development.     

SbRLK1, a receptor-like protein kinase of Sorghum bicolor (L.) Moench that is expressed in mesophyll cells

To study the metabolic interactions between mesophyll and bundle-sheath cells of C₄ plants, protein kinases possibly involved in the regulatory processes and signal transduction pathways have been cloned and characterized. A receptor-like protein kinase (RLK) cDNA clone from the C₄ plant Sorghum bicolor (L.) Moench has been identified. The deduced protein was designated SbRLK1 for receptor-like protein kinase from S. bicolor. The putative cytoplasmic domain of SbRLK1 contains all amino acids that are characteristic of protein kinases. The extracellular domain contains five leucine-rich repeats. The mRNA of the SbRLK1 gene accumulated to much higher levels in mesophyll cells than in the bundle-sheath and was almost undetectable in roots. This expression pattern indicates that SbRLK1 might be involved in the regulation of specific processes in mesophyll cells. Received: 13 August 1998 / Accepted: 22 December 1998     

Mutational evidence that the Arabidopsis MAP kinase MPK6 is involved in anther, inflorescence, and embryo development

Loss-of-function, dominant-negative, and change-of-function genetic approaches were used to investigate the role played by the Arabidopsis mitogen-activated protein (MAP) kinase MPK6 throughout development. Plants homozygous for T-DNA null alleles of MPK6 displayed reduced male fertility and abnormal anther development. In addition, a portion of the seed produced by mpk6 plants was found to contain embryos that had burst out of their seed coats. To address potential functional redundancy, a dominant-negative version of MPK6 was constructed by changing the TEY activation loop motif to the amino acid sequence AEF. Plants expressing MPK6AEF via the MPK6 native promoter were found to produce excessive stomata, consistent with the recently described role of MPK6 in stomatal patterning. A novel floral phenotype characterized by abnormal sepal development was also observed in MPK6AEF lines. The gene expression pattern of the MPK6 native promoter was determined using a YFP-MPK6 fusion construct, and expression was observed throughout most plant tissues, consistent with a role for MPK6 in multiple developmental processes. The YFP-MPK6 construct was found to rescue the fertility phenotype of mpk6 null alleles, indicating that the fusion protein retains its biological activity. It was also observed, however, that plants expressing YFP-MPK6 displayed reduced apical dominance and a shortening of inflorescence internodes. These results suggest that the YFP tag modifies the activity of MPK6 in a manner that affects inflorescence development but not anther development. Taken together, the present results indicate that MPK6 is involved in the regulation of multiple aspects of plant development.     

Use of proteomics to understand seed development in rice

Rice is an important cereal crop and has become a model monocot for research into crop biology. Rice seeds currently feed more than half of the world's population and the demand for rice seeds is rapidly increasing because of the fast‐growing world population. However, the molecular mechanisms underlying rice seed development is incompletely understood. Genetic and molecular studies have developed our understanding of substantial proteins related to rice seed development. Recent advancements in proteomics have revolutionized the research on seed development at the single gene or protein level. Proteomic studies in rice seeds have provided the molecular explanation for cellular and metabolic events as well as environmental stress responses that occur during embryo and endosperm development. They have also led to the new identification of a large number of proteins associated with regulating seed development such as those involved in stress tolerance and RNA metabolism. In the future, proteomics, combined with genetic, cytological, and molecular tools, will help to elucidate the molecular pathways underlying seed development control and help in the development of valuable and potential strategies for improving yield, quality, and stress tolerance in rice and other cereals. Here, we reviewed recent progress in understanding the mechanisms of seed development in rice with the use of proteomics.     

Farnesol kinase is involved in farnesol metabolism, ABA signaling and flower development in Arabidopsis

Farnesol, which is toxic to plant cells at high concentrations, is sequentially phosphorylated to farnesyl phosphate and farnesyl diphosphate. However, the genes responsible for the sequential phosphorylation of farnesol have not been identified and the physiological role of farnesol phosphorylation has not been fully elucidated. To address these questions, we confirmed the presence of farnesol kinase activity in Arabidopsis (Arabidopsis thaliana) membranes and identified the corresponding gene (At5g58560, FOLK). Heterologous expression in recombinant yeast cells established farnesol as the preferred substrate of the FOLK-encoded kinase. Moreover, loss-of-function mutations in the FOLK gene abolished farnesol kinase activity, caused an abscisic acid-hypersensitive phenotype and promoted the development of supernumerary carpels under water-stress conditions. In wild-type plants, exogenous abscisic acid repressed FOLK gene expression. These observations demonstrate a role for farnesol kinase in negative regulation of abscisic acid signaling, and provide molecular evidence for a link between farnesol metabolism, abiotic stress signaling and flower development.     

Endogenous protein phosphorylation and casein kinase activity during seed development in Araucaria angustifolia

Protein kinases and phosphatases are responsible for several cellular events mediated by protein phosphorylation and dephosphorylation. Among these events are cell growth and differentiation and cellular metabolism. Casein kinase I (CKI) and casein kinase II (CKII) are involved in the phosphorylation of several substrates. Endogenous protein phosphorylation and casein kinase activity were investigated in the megagametophyte of the native Brazilian conifer Araucaria angustifolia, during seed development. It was observed that a number of different polypeptides are phosphorylated in vitro in the three megagametophyte stages of development tested (from globular, cotyledonary and mature embryos, respectively) and the phosphate was incorporated mainly in serine residues. The use of okadaic acid and vanadate in the phosphorylation reactions increased phosphate incorporation in several polypeptides suggesting the presence of serine/threonine as well as tyrosine phosphatases in the megagametophyte. Also, the results obtained in experiments with CKII inhibitor, GTP as phosphate donor, RNA hybridizations, and in-gel kinase assays indicate the presence of CKII in the A. angustifolia megagametophyte.     

Effect of ovular receptivity on seed set and fruit development in cucumber (Cucumis sativus L.)

Summary Seed set and fruit development in cucumber (Cucumis sativus L.) were studied in relation to female flower receptivity from day — 2 before anthesis to day + 2 after anthesis. The female cucumber flower is protogynous. The pistil was receptive 2 days before anthesis. The iso-electric focusing (IEF) patterns of the stigma/style proteins, were identical from day -5 to day +2. In pollinated flowers in vivo germination and pollen-tube growth in the ovary were affected by pistil age from day -2 to day +2. In addition, differences in sectorial filling in full seeds were observed within the fruits. A negative correlation was observed between the frequency of fertilized ovules in the pedoncular part of the fruit and ovary length at the time of pollination. In the whole fruit, significant differences in the number of full seeds and fruit size at maturity were found, and these were observed to be correlated with the various stages of female flower maturation at pollination. The day -2 and day +2 stages yielded the smallest fruits with few full seeds compared to the day -1, day 0 and day +1 stages, which had the biggest fruits and a large number of full seeds. A strong positive correlation was found between total seed number (including full and empty seeds), fruit length and weight at maturity. All these results suggest that both seed set in the different parts of the fruit and fruit development are controlled by ovular receptivity rather than by stigma/style receptivity.     

Water limitation effect on seed development and germination in Trigonella coerulea (Fabaceae)

The annual garden spice legume Trigonella coerulea was subjected to controlled drought conditions to investigate the influence of resource limitation on flowering, seed production and germination. Limitations in water availability significantly reduced plant height and the number of fruits produced. However, treatments had no significant effect on seed set within the fruit. Fruit number per plant, rather than seed number per fruit was affected by resource limitation. Plants growing under water deficiency had higher flower abortion rates. Simultaneously, the size and germination rate of the seeds were decreased. In terms of reproductive success T. coerulea was not able to adapt reproduction to water shortage. Increase in moisture had no significant effect on seed quantity and quality when compared to the control.     

Embryo sac development is affected in Petunia inflata plants transformed with an antisense gene encoding the extracellular domain of receptor kinase PRK1

 In a previous study of the function of a pollen-expressed receptor kinase of Petunia inflata, PRK1, it was found that transgenic plants carrying an antisense-PRK1 gene were unable to transmit the transgene through either the male or, unexpectedly, the female. In this report, the nature of this female phenotype was studied using one of the transgenic plants, ASRK-13. Electron and light microscopic examination of the embryo sac and seed development of ASRK-13 and a wild-type plant revealed that embryo sac development of approximately half of the ovules of ASRK-13 was abnormal. The development of the affected embryo sacs was arrested at the late stages of megagametogenesis. The majority of the affected embryo sacs completed three rounds of mitosis normally, but failed to progress through the maturation stages when cell expansion, nuclear migration, and differentiation take place. The remaining small number of abnormal embryo sacs were arrested at either the four- or eight-nucleate stages. The ovules containing the defective embryo sacs apparently failed to be fertilized, resulting in degeneration of half of the seeds produced by ASRK-13. RNA gel blot analysis suggests that the PRK1 gene is expressed in the ovary, albeit at a much lower level than in the anther. The possibility that the antisense PRK1 gene is responsible for the abnormal embryo sac development is discussed. Received: 25 April 1997 / Revision accepted: 25 June 1997     

Identification and functional characterization of a leucine-rich repeat receptor-like kinase gene that is involved in regulation of soybean leaf senescence

We report here the cloning and characterization of a soybean receptor-like kinase (RLK) gene, designated GmSARK (Glycine max senescence-associated receptor-like kinase), which is involved in regulating leaf senescence. The conceptual protein product of GmSARK contains typical domains of LRR receptor-like kinases: a cytoplasmic domain with all the 11 kinase subdomains, a transmembrane domain and an extracelullar domain containing 9 Leucine-Rich Repeat (LRR) units that may act as a receptor. The expression of GmSARK in soybean leaves was up-regulated in all the three tested senescence systems: senescing cotyledons, dark-induced primary leaf senescence and the natural leaf senescence process after florescence. Furthermore, the RNA interference (RNAi)-mediated knocking-down of GmSARK dramatically retarded soybean leaf senescence. A more complex thylakoid membrane system, higher foliar level of chlorophyll content and a very remarkable delay of senescence-induced disintegration of chloroplast structure were observed in GmSARK-RNAi transgenic leaves. A homolog of maize lethal leaf-spot 1 gene, which has been suggested to encode a key enzyme catalyzing chlorophyll breakdown, was isolated and nominated Gmlls1. The expression level of Gmgtr1 gene, which encodes a key enzyme of chlorophyll synthesis, was also analyzed. It was found that Gmlls1 was up-regulated and Gmgtr1 was down-regulated during senescence in wild-type soybean leaves. However, both of the up-regulation of Gmlls1 and down-regulation of Gmgtr1 were retarded during senescence of GmSARK-RNAi transgenic leaves. In addition, over-expression of the GmSARK gene greatly accelerated the senescence progression of CaMV 35S:GmSARK transgenic plants. Taken together, these results strongly suggested the involvement of this LRR-RLK in regulation of soybean leaf senescence, maybe via regulating chloroplast development and chlorophyll accumulation. Multiple functions of GmSARK besides its regulation of leaf senescence were also discussed. Electronic Supplementary Material Supplementary material is available for this article at Rui Gan, Peng-Li Li and Yuan-Yuan Ma contributed equally to this work.     

A rice lectin receptor‐like kinase that is involved in innate immune responses also contributes to seed germination

Seed germination and innate immunity both have significant effects on plant life spans because they control the plant's entry into the ecosystem and provide defenses against various external stresses, respectively. Much ecological evidence has shown that seeds with high vigor are generally more tolerant of various environmental stimuli in the field than those with low vigor. However, there is little genetic evidence linking germination and immunity in plants. Here, we show that the rice lectin receptor‐like kinase OslecRK contributes to both seed germination and plant innate immunity. We demonstrate that knocking down the OslecRK gene depresses the expression of α–amylase genes, reducing seed viability and thereby decreasing the rate of seed germination. Moreover, it also inhibits the expression of defense genes, and so reduces the resistance of rice plants to fungal and bacterial pathogens as well as herbivorous insects. Yeast two‐hybrid and co‐immunoprecipitation experiments revealed that OslecRK interacts with an actin‐depolymerizing factor (ADF) in vivo via its kinase domain. Moreover, the rice adf mutant exhibited a reduced seed germination rate due to the suppression of α–amylase gene expression. This mutant also exhibited depressed immune responses and reduced resistance to biotic stresses. Our results thus provide direct genetic evidence for a common physiological pathway connecting germination and immunity in plants. They also partially explain the common observation that high‐vigor seeds often perform well in the field. The dual effects of OslecRK may be indicative of progressive adaptive evolution in rice.     

AtAPOSTART1, an Arabidopsis thaliana PH-START domain protein involved in seed germination

The seed in the mature and dry state is metabolically inactive (quiescent) and is thus able to withstand extreme environmental conditions, such as drought and cold. Germination commences when the dry seed, shed from its parent plant, takes up water (imbibition) and ends when the root emerges through the seed coat. During seedling establishment, the reserves stored in the seed are metabolized, whereas the subsequent vegetative and reproductive growth is supported by photosynthesis. Here, we describe the functional characterization of the PH-START protein AtAPO1 (Arabidopsis thaliana APOSTART1), the putative homologue of PpAPO1 (Poa pratensis APOSTART1) in Arabidopsis thaliana. By using translational fusion of the AtAPO1 promoter to the uiaD gene and in situ hybridization analyses, we show that AtAPO1 is expressed in mature embryo sacs and developing embryos. The functional analysis of two at-apostart mutant alleles suggests that AtAPO1 is involved in the control of seed germination.     

An atypical soybean leucine-rich repeat receptor-like kinase, GmLRK1, may be involved in the regulation of cell elongation

A leucine-rich repeat receptor-like kinase (LRR-RLK) encoded by one of the genes highly expressed in a specific stage of soybean seed development, referred to as GmLRK1, was identified and characterized. Examination of its kinase domain indicated that GmLRK1 may be a catalytically inactive atypical receptor kinase. An autophosphorylation assay confirmed that GmLRK1 is incapable of autophosphorylation in vitro. However, the phosphorylation of GmRLK1 could be induced after incubation with plant protein extracts, suggesting that some plant proteins may interact with GmLRK1 and phosphorylate the protein in vivo. Analyses of the expression profiles of GmLRK1 and its Arabidopsis ortholog At2g36570 revealed that they may be involved in regulation of more fundamental metabolic and/or developmental pathways, rather than a specialized developmental program such as seed development. Our results further indicate that the GmLRK1 and At2g36570 may play a role in the regulation of certain cellular processes that lead to cell elongation and expansion. S. Kim and S.-J. Kim have contributed equally to this work.     

An S-locus receptor-like kinase plays a role as a negative regulator in plant defense responses

Plant cells often use cell surface receptors to sense environmental changes and then transduce external signals via activated signaling pathways to trigger adaptive responses. In Arabidopsis, the receptor-like protein kinase (RLK) gene family contains more than 600 members, and some of these are induced by pathogen infection, suggesting a possible role in plant defense responses. We previously characterized an S-locus RLK (CBRLK1) at the biochemical level. In this study, we examined the physiological function of CBRLK1 in defense responses. CBRLK1 mutant and CBRLK1-overexpressing transgenic plants showed enhanced and reduced resistance against a virulent bacterial pathogen, respectively. The altered pathogen resistances of the mutant and overexpressing transgenic plants were associated with increased and reduced induction of the pathogenesis-related gene PR1, respectively. These results suggest that CBRLK1 plays a negative role in the disease resistance signaling pathway in Arabidopsis.