Origin and Evolution of GALA-LRR,a New Member of the CC-LRR Subfamily: From Plants to Bacteria?

The phytopathogenic bacterium Ralstonia solanacearum encodes type III effectors, called GALA proteins, which contain F-box and LRR domains. The GALA LRRs do not perfectly fit any of the previously described LRR subfamilies. By applying protein sequence analysis and structural prediction, we clarify this ambiguous case of LRR classification and assign GALA-LRRs to CC-LRR subfamily. We demonstrate that side-by-side packing of LRRs in the 3D structures may control the limits of repeat variability within the LRR subfamilies during evolution. The LRR packing can be used as a criterion, complementing the repeat sequences, to classify newly identified LRR domains. Our phylogenetic analysis of F-box domains proposes the lateral gene transfer of bacterial GALA proteins from host plants. We also present an evolutionary scenario which can explain the transformation of the original plant LRRs into slightly different bacterial LRRs. The examination of the selective evolutionary pressure acting on GALA proteins suggests that the convex side of their horse-shoe shaped LRR domains is more prone to positive selection than the concave side, and we therefore hypothesize that the convex surface might be the site of protein binding relevant to the adaptor function of the F-box GALA proteins. This conclusion provides a strong background for further functional studies aimed at determining the role of these type III effectors in the virulence of R. solanacearum.     

Isolation and characterization of a novel F-box protein Pof10 in fission yeast

The SCF complex is a type of ubiquitin-protein ligase (E3) that consists of invariable components, including Skp1, Cdc53/Cul1, and Rbx1, as well as variable components known as F-box proteins. Using a yeast two-hybrid system, we isolated six proteins that interact with Schizosaccharomyces pombe Skp1. Among them, Pof10 is a novel F-box protein consisting of 662 amino acids, harboring the F-box domain required for the binding to Skp1 and followed by four WD40 repeats. Overexpression of Pof10 in fission yeast resulted in loss of viability with marked morphological changes that are similar to those in pop1 mutant yeast. Coexpression of Skp1 with Pof10 prevented the lethality, suggesting that the lethality from Pof10 overexpression results from the sequestration of Skp1 from other F-box proteins including Pop1. Whereas most F-box proteins show rapid turnover, Pof10 has a remarkably long half-life in vivo and has been shown to be localized predominantly in cytoplasm. These results suggest that the stable F-box protein Pof10 might target abundant cytoplasmic proteins for degradation in fission yeast.     

A combination of the F-box motif and kelch repeats defines a large Arabidopsis family of F-box proteins

In the sequences released by the Arabidopsis Genome Initiative (AGI), we have discovered a new large gene family (48 genes as of July 2000). A detailed computational and biochemical analysis of the predicted gene products reveals a novel family of plant F-box proteins, where the amino (N)-terminal F-box motif is followed by four kelch repeats and a characteristic carboxy-terminal domain. F-box proteins are an expanding family of eukaryotic proteins, which have been shown in some cases to be critical for the controlled degradation of cellular regulatory proteins via the ubiquitin pathway. The F-box motif of the At5g48990 gene product, a member of the family, was shown to be functionally active by its ability to mediate the in vitro interaction between At5g48990 and ASK1 proteins. F-box proteins specifically recruit the targets to be ubiquitinated, mainly through protein-protein interaction modules such as WD-40 domains or leucine-rich repeats (LRRs). The kelch repeats of the family described here form a potential protein-protein interaction domain, as molecular modelling of the kelch repeats according to the galactose oxidase crystal structure (the only solved structure containing kelch repeats) predicts a -propeller. The identification of this family of F-box proteins greatly expands the field of plant F-box proteins and suggests that controlled degradation of cellular proteins via the ubiquitin pathway could play a critical role in multiple plant cellular processes.     

F-box proteins in rice. Genome-wide analysis, classification, temporal and spatial gene expression during panicle and seed development, and regulation by light and abiotic stress

F-box proteins constitute a large family in eukaryotes and are characterized by a conserved F-box motif (approximately 40 amino acids). As components of the Skp1p-cullin-F-box complex, F-box proteins are critical for the controlled degradation of cellular proteins. We have identified 687 potential F-box proteins in rice (Oryza sativa), the model monocotyledonous plant, by a reiterative database search. Computational analysis revealed the presence of several other functional domains, including leucine-rich repeats, kelch repeats, F-box associated domain, domain of unknown function, and tubby domain in F-box proteins. Based upon their domain composition, they have been classified into 10 subfamilies. Several putative novel conserved motifs have been identified in F-box proteins, which do not contain any other known functional domain. An analysis of a complete set of F-box proteins in rice is presented, including classification, chromosomal location, conserved motifs, and phylogenetic relationship. It appears that the expansion of F-box family in rice, in large part, might have occurred due to localized gene duplications. Furthermore, comprehensive digital expression analysis of F-box protein-encoding genes has been complemented with microarray analysis. The results reveal specific and/or overlapping expression of rice F-box protein-encoding genes during floral transition as well as panicle and seed development. At least 43 F-box protein-encoding genes have been found to be differentially expressed in rice seedlings subjected to different abiotic stress conditions. The expression of several F-box protein-encoding genes is also influenced by light. The structure and function of F-box proteins in plants is discussed in light of these results and the published information. These data will be useful for prioritization of F-box proteins for functional validation in rice.     

F-box proteins: the key to protein degradation

Summary The eukaryotic protein degradation pathway involves the ubiquitin (Ub) modification of substrates targeted for degradation by the 26S proteasome. The addition of Ub, a process called ubiquitination, is mediated by enzymes including the E3 Ub ligases which transfer the Ub to targeted substrates. A major type of E3 Ub ligases, the SCF (Skp–Cullin–F-box) complex, is composed of four major components: Skp1, Cul1/Cdc53, Roc1/Rbx1/Hrt1, and an F-box protein. The F-box component of the SCF machineries is responsible for recognizing different substrates for ubiquitination. Interaction with components of the SCF complex is mediated through the F-box motif of the F-box protein while it associates with phosphorylated substrates through its second protein–protein interaction motif such as Trp–Asp (WD) repeats or leucine-rich repeats (LRRs). By targeting diverse substrates, F-box proteins exert controls over stability of proteins and regulate the mechanisms for a wide-range of cellular processes. Here we discuss the importance of F-box proteins by providing a general overview and examples of how F-box proteins function in various cellular settings such as tissue development, cell proliferation, and cell death, in the modeling organism Drosophila.     

Role of extracytoplasmic leucine rich repeat proteins in plant defence mechanisms

Plant-pathogen interactions involve highly complex series of reactions in disease development. Plants are endowed with both, resistance and defence genes. The activation of defence genes after contact with avirulence gene products of pathogens depends on signals transduced by leucine-rich repeats (LRRs) contained in resistance genes. Additionally, LRRs play roles for various actions following ligand recognition. Polygalacturonase inhibiting proteins (PGIPs), the only plant LRR protein with known ligands, are pectinase inhibitors, bound by ionic interactions to the extracellular matrix (ECM) of plant cells. They have a high affinity for fungal endopolygalacturonases (endoPGs). PGIP genes are organised in families encoding proteins with similar physical characteristics but different specificities. They are induced by infection and stress related signals. The molecular basis of PG-PGIP interaction serves as a model to understand the evolution of plant LRR proteins in recognising non-self-molecules. Extensins form a different class of structural proteins with repetitive sequences. They are also regulated by wounding and pathogen infection. Linkage of extensins with LRR motifs is highly significant in defending host tissues against pathogen invasion. Overexpression of PGIPs or expression of several PGIPs in a plant tissue, and perhaps manipulation of extensin expression could be possible strategies for disease management.     

Plant F-box Proteins – Judges between Life and Death

Selective protein degradation through the ubiquitin–26S proteasome system is a key mechanism for post-translational control of regulatory proteins in all eukaryotes. The pivotal components in this system are the multi-subunit E3 Ub-ligase enzymes responsible for specific recognition and ubiquitination of degradation targets. In this review, we focus on plant F-box proteins which confer specificity to the SCF-type E3 enzyme complexes. F-box proteins represent one of the largest and most heterogeneous superfamilies in plants, with hundreds of different representatives exposing an extensive variability of C-terminal target-binding domains, and as such, modulating almost every aspect of plant growth and development. Since the first reports on plant F-box proteins over a decade ago, a lot of progress has been made in our understanding of their relevance for plant physiology. In this review, we combine well-established knowledge with the most recent advances related to plant F-box proteins and their role in plant development, hormone signaling and defense pathways. We also elaborate on the yet poorly described carbohydrate-binding plant F-box proteins presumably targeting glycoproteins for proteasomal degradation.     

The F-box: a new motif for ubiquitin dependent proteolysis in cell cycle regulation and signal transduction

The ubiquitin system of intracellular protein degradation controls the abundance of many critical regulatory proteins. Specificity in the ubiquitin system is determined largely at the level of substrate recognition, a step that is mediated by E3 ubiquitin ligases. Analysis of the mechanisms of phosphorylation directed proteolysis in cell cycle regulation has uncovered a new class of E3 ubiquitin ligases called SCF complexes, which are composed of the subunits Skp1, Rbx1, Cdc53 and any one of a large number of different F-box proteins. The substrate specificity of SCF complexes is determined by the interchangeable F-box protein subunit, which recruits a specific set of substrates for ubiquitination to the core complex composed of Skp1, Rbx1, Cdc53 and the E2 enzyme Cdc34. F-box proteins have a bipartite structure--the shared F-box motif links F-box proteins to Skp1 and the core complex, whereas divergent protein-protein interaction motifs selectively bind their cognate substrates. To date all known SCF substrates are recognised in a strictly phosphorylation dependent manner, thus linking intracellular signalling networks to the ubiquitin system. The plethora of different F-box proteins in databases suggests that many pathways will be governed by SCF-dependent proteolysis. Indeed, genetic analysis has uncovered roles for F-box proteins in a variety of signalling pathways, ranging from nutrient sensing in yeast to conserved developmental pathways in plants and animals. Moreover, structural analysis has revealed ancestral relationships between SCF complexes and two other E3 ubiquitin ligases, suggesting that the combinatorial use of substrate specific adaptor proteins has evolved to allow the regulation of many cellular processes. Here, we review the known signalling pathways that are regulated by SCF complexes and highlight current issues in phosphorylation dependent protein degradation.     

A mutation within the leucine-rich repeat domain of the Arabidopsis disease resistance gene RPS5 partially suppresses multiple bacterial and downy mildew resistance genes.

Recognition of pathogens by plants is mediated by several distinct families of functionally variable but structurally related disease resistance (R) genes. The largest family is defined by the presence of a putative nucleotide binding domain and 12 to 21 leucine-rich repeats (LRRs). The function of these LRRs has not been defined, but they are speculated to bind pathogen-derived ligands. We have isolated a mutation in the Arabidopsis RPS5 gene that indicates that the LRR region may interact with other plant proteins. The rps5-1 mutation causes a glutamate-to-lysine substitution in the third LRR and partially compromises the function of several R genes that confer bacterial and downy mildew resistance. The third LRR is relatively well conserved, and we speculate that it may interact with a signal transduction component shared by multiple R gene pathways.     

The abundance of Met30p limits SCF(Met30p) complex activity and is regulated by methionine availability

Ubiquitin-mediated degradation plays a crucial role in many fundamental biological pathways, including the mediation of cellular responses to changes in environmental conditions. A family of ubiquitin ligase complexes, called SCF complexes, found throughout eukaryotes, is involved in a variety of biological pathways. In Saccharomyces cerevisiae, an SCF complex contains a common set of components, namely, Cdc53p, Skp1p, and Hrt1p. Substrate specificity is defined by a variable component called an F-box protein. The F- box is a approximately 40-amino-acid motif that allows the F-box protein to bind Skp1p. Each SCF complex recognizes different substrates according to which F-box protein is associated with the complex. In yeasts, three SCF complexes have been demonstrated to associate with the ubiquitin-conjugating enzyme Cdc34p and have ubiquitin ligase activity. F-box proteins are not abundant and are unstable. As part of the SCF(Met30p) complex, the F-box protein Met30p represses methionine biosynthetic gene expression when availability of L-methionine is high. Here we demonstrate that in vivo SCF(Met30p) complex activity can be regulated by the abundance of Met30p. Furthermore, we provide evidence that Met30p abundance is regulated by the availability of L-methionine. We propose that the cellular responses mediated by an SCF complex are directly regulated by environmental conditions through the control of F-box protein stability.     

Genome-wide Analysis of Kelch Repeat-containing F-box Family

The ubiquitin-dependent protein degradation pathway plays diverse roles in eukaryotes. Previous studies indicate that both F-box and Kelch motifs are common in a variety of organisms. F-box proteins are subunits of E3 ubiquitin ligase complexes called SCFs （SKP1, Cullinl, F-box protein, and Rbxl）; they have an N-terminal F-box motif that binds to SKP1 （S-phase kinase associated protein）, and often have C-terminal protein-protein interaction domains, which specify the protein substrates for degradation via the ubiquitin pathway. One of the most frequently found protein interaction domains in F-box proteins is the Kelch repeat domain. Although both the F-box and Kelch repeats are ancient motifs, Kelch repeats-containing F-box proteins （KFB） have only been reported for human and Arabidopsis previously. The recent sequencing of the rice genome and other plant genomes provides an opportunity to examine the possible evolution history of KFB. We carried out extensive BLAST searches to identify putative KFBs in selected organisms, and analyzed their relationships phylogenetically. We also carried out the analysis of both gene duplication and gene expression of the KFBs in rice and Arabidopsis. Our study indicates that the origin of KFBs occurs before the divergence of animals and plants, and plant KFBs underwent rapid gene duplications.     

Identification of a ubiquitin-binding structure in the S-locus F-box protein controlling S-RNase-based self-incompatibility

In flowering plants,self-incompatibility(SI) serves as an important intraspecific reproductive barrier to promote outbreeding.In species from the Solanaceae,Plantaginaceae and Rosaceae,S-RNase and SLF(S-locus F-box) proteins have been shown to control the female and male specificity of SI,respectively.However,little is known about structure features of the SLF protein apart from its conserved F-box domain.Here we show that the SLF C-terminal region possesses a novel ubiquitin-binding domain(UBD) structure conserved among the SLF protein family.By using an ex vivo system of Nicotiana benthamiana,we found that the UBD mediates the SLF protein turnover by the ubiquitin—proteasome pathway.Furthermore,we detected that the SLF protein was directly involved in S-RNase degradation.Taken together,our results provide a novel insight into the SLF structure and highlight a potential role of SLF protein stability and degradation in S-RNase-based self-incompatibility.     

ARABIDILLO gene homologues in basal land plants: species-specific gene duplication and likely functional redundancy

ARABIDILLO proteins regulate multicellular root development in Arabidopsis thaliana. Conserved ARABIDILLO homologues are present throughout land plants, even in early-evolving plants that do not possess complex root architecture, suggesting that ARABIDILLO genes have additional functions. Here, we have cloned and characterised ARABIDILLO gene homologues from two early-evolving land plants, the bryophyte Physcomitrella patens and the lycophyte Selaginella moellendorffii. We show that two of the PHYSCODILLO genes (PHYSCODILLO1A and -1B) exist as a tail-to-tail tandem array of two almost identical 12?kb sequences, while a third related gene (PHYSCODILLO2) is located elsewhere in the Physcomitrella genome. Physcomitrella possesses a very low percentage of tandemly arrayed genes compared with the later-evolving plants whose genomes have been sequenced to date. Thus, PHYSCODILLO1A and -1B genes represent a relatively unusual gene arrangement. PHYSCODILLO promoters are active largely in the haploid gametophyte, with additional activity at the foot of the sporophyte. The pattern of promoter activity is uniform in filamentous and leafy tissues, suggesting pleiotropic gene functions and likely functional redundancy: the latter possibility is confirmed by the lack of discernible phenotype in a physcodillo2 deletion mutant. Interestingly, the pattern of PHYSCODILLO promoter activity in female reproductive organs is strikingly similar to that of an Arabidopsis homologue, suggesting co-option of some PHYSCODILLO functions or regulation into both the sporophyte and gametophyte. In conclusion, our work identifies and characterises some of the earliest-evolving land plant ARABIDILLO homologues. We confirm that all land plant ARABIDILLO genes arose from a single common ancestor and suggest that PHYSCODILLO proteins have novel and pleiotropic functions, some of which may be conserved in later-evolving plants.     

A systematic phenotypic screen of F-box genes through a tissue-specific RNAi-based approach in Drosophila

F-box proteins are components of the SCF(SkpA-Cullin 1-F-box) E3 ligase complexes,acting as the specificity-determinants in targeting substrate proteins for ubiquitination and degradation.In humans,at least 22 out of 75 F-box proteins have experimentally documented substrates,whereas in Drosophila 12 F-box proteins have been characterized with known substrates.To systematically investigate the genetic and molecular functions of F-box proteins in Drosophila,we performed a survey of the literature and databases.We identified 45 Drosophila genes that encode proteins containing at least one F-box domain.We collected publically available RNAi lines against these genes and used them in a tissue-specific RNAi-based phenotypic screen.Here,we present our systematic phenotypic dataset from the eye,the wing and the notum.This dataset is the first of its kind and represents a useful resource for future studies of the molecular and genetic functions of F-box genes in Drosophila.Our results show that,as expected,F-box genes in Drosophila have regulatory roles in a diverse array of processes including cell proliferation,cell growth,signal transduction,and cellular and animal survival.     

F-box proteins and protein degradation: An emerging theme in cellular regulation

Selective protein degradation by the ubiquitin-proteosome pathway has recently emerged as a powerful regulatory mechanism in a wide variety of cellular processes. Ubiquitin conjugation requires the sequential activity of three enzymes or protein complexes called the ubiquitin-activating enzyme (E1), the ubiquitin-conjugating enzyme (E2), and the ubiquitin-protein ligase (E3). In most eukaryotes, there are a small number of similar E1 isoforms without apparent functional specificity. The specific selection of target proteins is accomplished by the E2 and E3 proteins. One of the best-characterized families of E3s are the SCF complexes. The SCF is composed of a cullin (Cdc53), SKP1, RBX1 and one member of a large family of proteins called F-box proteins. The function of the F-box protein is to interact with target proteins. In some cases, the stability of the F-box protein may regulate activity of the SCF complex. In addition, post-translational modification of the cullin subunit by the ubiquitin-like protein RUB/NEDD8 appears to regulate SCF function. In plants, the SCF has so far been implicated in floral development, circadian clock, and response to the plant growth regulators auxin and jasmonic acid.     

GmCOI1, a soybean F-box protein gene, shows ability to mediate jasmonate-regulated plant defense and fertility in Arabidopsis

The F-box protein gene COI1 from Arabidopsis plays a fundamental role in response to jasmonates, which regulate plant root growth, pollen fertility, wounding and healing, and defense against pathogens and insects. Null mutations in COI1 were previously found to abolish all the jasmonate responses, and the Arabidopsis coil-1 mutant is male sterile and susceptible to pathogen infection. In this study, we isolated an F-box protein gene from soybean, which shares significant homology with the Arabidopsis COI1 and similarly contains an F-box motif and leucine rich repeats (LRR), here designated GmCOI1 (Glycine max L. (Merr.) COI1). To test whether the sequence homology and structural similarity are indicative of functional conservation, we expressed GmCOI1 in the Arabidopsis coil-1 mutant. The transgenic coil-1 plants with expression of the GmCOI1 gene were found to exhibit normal jasmonate responses, including jasmonate-regulated plant defense and fertility. In addition, the chimerical proteins with swapped domain of the F-box motif or LRR between GmCOI1 and COI1 were shown to functionally complement the coil-1 mutation. Furthermore, GmCOI1 was found to assemble into the Skpl-Cullin-F-box (SCF) complexes, similar to the formation of the Arabidopsis SCF(COO1). These data demonstrate the soybean F-box protein gene GmCOI1 is able to mediate jasmonate-regulated plant defense and fertility in Arabidopsis, which implies a generic jasmonate pathway with conserved signal components in different plant species.