Two members of the thioredoxin-h family interact with the kinase domain of a Brassica S locus receptor kinase.

To determine potential targets of the S locus receptor kinase (SRK) during the Brassica self-incompatibility response, a yeast two-hybrid library was screened with the SRK-910 protein kinase domain. Two thioredoxin-h-like clones, THL-1 and THL-2, were found to interact specifically with the SRK-910 protein kinase domain and not to interact with the protein kinase domains from the Arabidopsis receptor-like protein kinases (RLK) RLK4 and RLK5. The interaction between THL-1 and the SRK-910 protein kinase domain was confirmed using coimmunoprecipitation experiments with fusion proteins produced in Escherichia coli. THL-1 has thioredoxin activity based on an insulin reduction assay, and THL-1 is weakly phosphorylated by the SRK-910 protein kinase domain. THL-1 and THL-2 are both expressed in a variety of tissues but show some differences in steady state mRNA levels, with THL-2 being preferentially expressed in floral tissues. This indicates a more general biological function for these thioredoxins in addition to a potential role as effector molecules in the self-incompatibility signal cascade.     

Features of the extracellular domain of the S-locus receptor kinase from Brassica

An S-receptor kinase (SRK) gene associated with self-incompatibility in a Brassica napus subsp. oleifera line has been characterized. The SRK-A14 cDNA shows the highest levels of homology in the 5 end to the SLG-A14 cDNA present at the same locus. RNA blot analysis shows that the SRK-A14 gene is expressed predominantly in the pistil, and at lower levels in the anthers. The predicted amino acid sequences from the extracellular domain of the SRK-A14 gene and three other SRK genes were compared. The different SRK extracellular domains were for the most part very similar, with the exception of two variable regions containing a high level of amino acid alterations. These extracellular domains also contain a region of similarity to the immunoglobulin domains present in members of the immunoglobulin superfamily. These findings may define regions of the SRK protein that are necessary for interactions between SRK and other proteins.     

Antisense suppression of thioredoxin<Emphasis Type="Italic">h</Emphasis>mRNA in <Emphasis Type="Italic">Brassica napus cv.</Emphasis>

In Brassica, the thioredoxinhproteins, THL1 and THL2, were previously found to be potential inhibitors of the S receptor kinase (SRK) in the Brassica self-incompatibilty response. To investigate the biological roles of THL1 and THL2 in pollen–pistil interactions, the stigma-specific SLR1 promoter was used to drive antisense THL1/2 expression in Brassica napus cv. Westar. This cultivar is normally compatible, but antisense suppression of THL1/2 led to a low level constitutive rejection of all Brassica napus pollen tested. Fluorescence microscopy revealed that the pollen rejection was a typical Brassica self-incompatibility rejection response with reduced pollen adhesion, germination and pollen tube growth. In addition, Westar was found to express the SLG₁₅ and SRK₁₅ proteins which may be the target of regulation by THL1 and THL2. Thus, these results indicate that the THL1 and THL2 are required for full pollen acceptance in B. napus cv. Westar.     

Distribution of similar self-incompatibility (<Emphasis Type="Italic">S</Emphasis>) haplotypes in different genera,<Emphasis Type="Italic"> Raphanus</Emphasis> and<Emphasis Type="Italic"> Brassica</Emphasis>

The nucleotide sequences of ten SP11 and nine SRK alleles in Raphanus sativus were determined, and deduced amino acid sequences were compared with those of Brassica SP11 and SRK. The amino acid sequence identity of class-I SP11s in R. sativus was about 30% on average, the highest being 52.2%, while that of the S domain of class-I SRK was 77.0% on average and ranged from 70.8% to 83.9%. These values were comparable to those of SP11 and SRK in Brassica oleracea and B. rapa. SP11 of R. sativus S-21 was found to be highly similar to SP11 of B. rapa S-9 (89.5% amino acid identity), and SRK of R. sativus S-21 was similar to SRK of B. rapa S-9 (91.0%). SP11 and SRK of R. sativus S-19 were also similar to SP11 and SRK of B. oleracea S-20, respectively. These similarities of both SP11 and SRK alleles between R. sativus and Brassica suggest that these S haplotype pairs originated from the same ancestral S haplotypes.     

Domain-Specific Positive Selection Contributes to the Evolution of Arabidopsis Leucine-Rich Repeat Receptor-Like Kinase (LRR RLK) Genes

Leucine-rich repeat receptor-like kinases (LRR RLKs) comprise the largest group within the plant receptor-like kinase (RLK) superfamily, and the Arabidopsis genome alone contains over 200 LRR RLK genes. Although there is clear evidence for diverse roles played by individual LRR RLK genes in Arabidopsis growth and development, the evolutionary mechanism for this functional diversification is currently unclear. In this study, we focused on the LRRII RLK subfamily to investigate the molecular mechanisms that might have led to the functional differentiation of Arabidopsis LRR RLK genes. Phylogenetic analysis of 14 genes in this subfamily revealed three well-supported groups (I, II, and III). RT-PCR analysis did not find many qualitative differences in expression among these 14 genes in various Arabidopsis tissues, suggesting that evolution of regulatory sequences did not play a major role in their functional divergence. We analyzed substitution patterns in the predicted ligand-binding regions of these genes to examine if positive selection has acted to produce novel ligand-binding specificities, using the nonsynonymous/synonymous rate ratio (d _N/d _S) as an indicator of selective pressure. Estimates of d _N/d _S ratios from multiple methods indicate that nonsynonymous substitutions accumulated during divergence of the three lineages. Positive selection is likely to have occurred along the lineages ancestral to groups II and III. We suggest that positive selection on the ligand-binding sites of LRRII RLKs promoted diversification of ligand-binding specificities and thus contributed to the functional differentiation of Arabidopsis LRRII RLK genes during evolution. [Reviewing Editor: Dr. Martin Kreitman]     

Transformation of Arabidopsis with a Brassica SLG/SRK region and ARC1 gene is not sufficient to transfer the self-incompatibility phenotype

Self-incompatibility (SI) promotes outbreeding in flowering plants, and in Brassica SI is genetically controlled by the S locus. Self-incompatible Brassica and self-fertile Arabidopsis belong to the same crucifer family. In addition, a comparative analysis reveals a high degree of microsynteny between the B. campestris S locus and its homologous region in Arabidopsis– with the notable exception that the Brassica SI genes, SLG and SRK, are missing. Brassica ARC1 encodes a component of the SRK signal transduction pathway leading to self-pollen rejection, and no closely related ARC1 homolog has been identified in Arabidopsis. The purpose of the research reported here was to introduce Brassica SI components into Arabidopsis in an attempt to compensate for the missing genes and to investigate whether the SI phenotype can be transferred. Inserts of approximately 40 kb from the fosmid clones F20 and F22, which span the B. napus W1 SLG-SRK region, were cloned into the plant transformation vector pBIBAC2. Transgenic plants were generated that expressed the Brassica SI genes in the flower buds. In addition, the endogenous, SLG-like, gene AtS1 was not co-suppressed by the Brassica SLG transgene. No SI phenotype was observed among the T1 BIBAC2-F20 and BIBAC2-F22 transgenic plants. When the ARC1 gene was transformed into BIBAC2-F20 or BIBAC2-F22 plants, the resulting BIBAC2-F20-ARC1 and BIBAC2-F22-ARC1 plants still set seeds normally, and no rejection response was observed when self-incompatible B. napus W1 pollen was placed on BIBAC2-F20-ARC1 or BIBAC2-F22-ARC1 Arabidopsis stigmas. Taken together, our results suggest that complementing Arabidopsis genome with Brassica SLG, SRK and ARC1 genes is unlikely to be sufficient to transfer the SI phenotype. Received: 11 November 1999 / Accepted: 14 February 2000     

Members of the<Emphasis Type="Italic"> S</Emphasis>-receptor kinase multigene family in<Emphasis Type="Italic"> Senecio squalidus</Emphasis> L. (Asteraceae), a species with sporophytic self-incompatibility

While the molecular basis of sporophytic self-incompatibility (SSI) has been investigated extensively in the Brassicaceae, almost nothing is known about the molecular regulation of SSI in other families, such as the Asteraceae. In species of Brassica and in Arabidopsis lyrata, a stigma-specific serine-threonine receptor kinase (SRK) and its cognate ligand, a pollen coating-borne cysteine-rich protein (SCR/SP11), determine the female and male sides of the SSI response, respectively. Here we have used RT-PCR with degenerate primers to conserved regions of SRK to amplify three SRK-like gene fragments expressed in stigmas of Senecio squalidus (Asteraceae). The Senecio S-receptor-like kinase (SSRLK) sequences share ~43% amino acid sequence identity with Brassica SRK₃ but higher amino acid sequence identity (~50%) with two Solanum bulbocastanum receptor-like kinase genes of unknown function. Despite expression in stigmas, all three SSRLKs were expressed at varying levels in floral and vegetative tissues. No allelic polymorphism was detected for the three SSRLKs in two S homozygous lines of S. squalidus or three other lines of S. squalidus carrying different S alleles. A full-length cDNA clone was obtained for SSRLK1 and its predicted amino acid sequence revealed significant structural differences to Brassica SRKs, most notably a major N-terminal truncation of 169 amino acids and the presence of just 8 conserved cysteine residues within the putative receptor domain instead of 12. Together, the sequence characteristics and expression characteristics of SSRLKs suggest that they are unlikely to be directly involved in the SSI response of S. squalidus. These findings are discussed in terms of the evolution of the SRK multigene family and the molecular basis of SSI in S. squalidus and the Asteraceae.     

Interaction of the maize and Arabidopsis kinase interaction domains with a subset of receptor-like protein kinases: implications for transmembrane signaling in plants

The kinase interaction (KI) domain of kinase-associated protein phosphatase (KAPP) interacts with the phosphorylated form of an Arabidopsis thaliana receptor-like protein kinase (RLK). The KI domain may recruit KAPP into an RLK-initiated signaling complex. To examine additional roles that this domain may play in plant signal transduction, a search was conducted for other KI domain-containing proteins. One gene was isolated which encodes a KI domain, the maize homolog of KAPP. To test whether the maize KI domain associates with other maize proteins, it was used as a probe in a protein–protein interaction cloning strategy. A new maize RLK, K I domain i nteracting k inase 1 (KIK1), was identified by its interaction with the maize KI domain. The maize KI domain and the KIK1 kinase domain association required phosphorylation of the kinase. This work establishes that the KI domain phosphorylation-dependent signaling mechanism is present in both monocots and dicots. Additionally, it was determined that both the maize and Arabidopsis KI domains interact with several but not all of the active RLKs assayed. These multiple associations imply that KAPP may function in a number of RLK-initiated signaling pathways.     

Exploring the role of a stigma-expressed plant U-box gene in the pollination responses of transgenic self-incompatible Arabidopsis thaliana

Recognition of “self” pollen in the self-incompatibility (SI) response of the Brassicaceae is determined by allele-specific interaction between the S-locus receptor kinase (SRK), a transmembrane protein of the stigma epidermis, and its ligand, the pollen coat-localized S-locus cysteine-rich (SCR) protein. The current model for SRK-mediated signaling proposes a central role for the plant U-box (PUB) Armadillo repeat-containing protein ARC1, an E3 ligase that interacts with, and is phosphorylated by, the kinase domain of SRK. According to the model, activated ARC1 causes the degradation of factors required for successful pollen tube growth. However, Arabidopsis thaliana plants transformed with functional SRK and SCR genes isolated from self-incompatible A. lyrata can express an intense SI response despite lacking a functional ARC1 gene. Here, we tested the possibility that a different member of the A. thaliana PUB protein family might have assumed the role of ARC1 in SI. Toward this end, we analyzed the AtPUB2 gene, which is annotated as being highly expressed in stigmas. Our functional analysis of a T-DNA insertion pub2 allele, together with yeast two-hybrid interaction assays and reporter analysis of AtPUB2 promoter activity, demonstrates that AtPUB2 does not function in SI. The results leave open the question of whether the proposed model of ARC1-mediated signaling applies to transgenic SRK–SCR self-incompatible A. thaliana plants.     

In Planta Assessment of the Role of Thioredoxin h Proteins in the Regulation of S-Locus Receptor Kinase Signaling in Transgenic Arabidopsis

The self-incompatibility (SI) response of the Brassicaceae is mediated by allele-specific interaction between the stigma-localized S-locus receptor kinase (SRK) and its ligand, the pollen coat-localized S-locus cysteine-rich protein (SCR). Based on work in Brassica spp., the thioredoxin h-like proteins THL1 and THL2, which interact with SRK, have been proposed to function as oxidoreductases that negatively regulate SRK catalytic activity. By preventing the spontaneous activation of SRK in the absence of SCR ligand, these thioredoxins are thought to be essential for the success of cross pollinations in self-incompatible plants. However, the in planta role of thioredoxins in the regulation of SI signaling has not been conclusively demonstrated. Here, we addressed this issue using Arabidopsis thaliana plants transformed with the SRKb-SCRb gene pair isolated from self-incompatible Arabidopsis lyrata. These plants express an intense SI response, allowing us to exploit the extensive tools and resources available in A. thaliana for analysis of SI signaling. To test the hypothesis that SRK is redox regulated by thioredoxin h, we expressed a mutant form of SRKb lacking a transmembrane-localized cysteine residue thought to be essential for the SRK-thioredoxin h interaction. We also analyzed transfer DNA insertion mutants in the A. thaliana orthologs of THL1 and THL2. In neither case did we observe an effect on the pollination responses of SRKb-expressing stigmas toward incompatible or compatible pollen. Our results are consistent with the conclusion that, contrary to their proposed role, thioredoxin h proteins are not required to prevent the spontaneous activation of SRK in the A. thaliana stigma.Many flowering plants possess self-incompatibility (SI), a genetic system that promotes outcrossing by preventing self-fertilization. In the Brassicaceae family, the SI response is controlled by haplotypes of the S locus, each of which contains two genes that encode highly polymorphic proteins, the S-locus receptor kinase (SRK), which is a plasma membrane resident single-pass transmembrane Ser/Thr receptor kinase displayed at the surface of stigma epidermal cells (Stein et al., 1991; Takasaki et al., 2000), and the S-locus Cys-rich protein (SCR), which is the pollen coat-localized ligand for SRK (Schopfer et al., 1999; Kachroo et al., 2001; Takayama et al., 2001). SRK and SCR exhibit allele-specific interactions, whereby only SRK and SCR encoded by the same S-locus haplotype interact. In a self-pollination, the binding of this “self” pollen-borne SCR to the extracellular domain of SRK activates the SRK kinase, thereby triggering a cellular response in stigma epidermal cells that causes inhibition of pollen germination and tube penetration into the stigma epidermal cell wall (for review, see Tantikanjana et al., 2010).Tight regulation of SRK kinase activity and its signaling cascade is critical for productive pollen-stigma interactions because constitutive (i.e. SCR-independent) activity of the receptor is expected to result in sterile stigmas that reject both compatible and incompatible pollen. In the classical view of ligand-activated receptor kinases, the receptor occurs as catalytically inactive monomers in the absence of ligand and only becomes activated upon ligand-induced dimerization (for review, see Lemmon and Schlessinger, 2010). However, some receptor kinases in both animals (Chan et al., 2000; Ehrlich et al., 2011) and plants (Giranton et al., 2000; Wang et al., 2005, 2008; Shimizu et al., 2010; Bücherl et al., 2013) form catalytically inactive dimers or oligomers in the absence of ligand, with receptor activation presumably resulting from ligand-induced higher order oligomerization or conformational changes (Lemmon and Schlessinger, 2010). Similar to the latter receptors, SRK forms oligomers in unpollinated stigmas, i.e. in the absence of SCR (Giranton et al., 2000), at least partly via ligand-independent dimerization domains located within the SRK extracellular domain (Naithani et al., 2007). It has been proposed that these ligand-independent SRK oligomers are maintained in an inactive state by thioredoxins, the ubiquitous small oxidoreductases that reduce disulfide bridges in proteins (Buchanan and Balmer, 2005). This hypothesis is supported by the following observations: (1) two Brassica napus thioredoxins, the Thioredoxin H-Like proteins THL1 and THL2, were identified as SRK interactors in a yeast (Saccharomyces cerevisiae) two-hybrid screen that used the B. napus SRK₉₁₀ kinase domain as bait (Bower et al., 1996); (2) when purified from pistils or insect cells, the Brassica oleracea SRK₃ variant was found to exhibit constitutive autophosphorylation activity in vitro, and this activity was inhibited by Escherichia coli-expressed THL1 proteins and was restored by addition of pollen coat proteins containing self but not of pollen coat proteins containing nonself SCR (Cabrillac et al., 2001); (3) the catalytic activity of THL1 was required for its inhibition of SRK₃ autophosphorylation activity in vitro (Cabrillac et al., 2001); and (4) antisense suppression of THL1/THL2 gene expression in the stigmas of a self-compatible B. napus strain reportedly produced a low-level constitutive incompatibility (Haffani et al., 2004), as might be expected if the THL1/THL2 proteins prevent the spontaneous activation of SRK-mediated signaling in stigmas.These observations notwithstanding, the in planta role of thioredoxin h proteins as negative regulators of SRK activity has not been conclusively demonstrated. To date, this proposed function has only been evaluated in a self-compatible strain of B. napus (Haffani et al., 2004). Consequently, it is not known if the proposed inhibitory effect of these thioredoxins on SRK catalytic activity is manifested in self-incompatible stigmas and if it applies to all SRK variants, be they derived from Brassica spp. or other self-incompatible species of the Brassicaceae such as Arabidopsis lyrata.In this study, we tested the in planta role of thioredoxin h proteins in the regulation of SI signaling using a transgenic self-incompatible Arabidopsis thaliana model that we generated by transforming A. thaliana with the SRKb-SCRb gene pair isolated from the Sb haplotype of self-incompatible A. lyrata (Kusaba et al., 2001; Nasrallah et al., 2002, 2004). We had previously shown that the stigmas of A. thaliana SRKb-SCRb transformants can exhibit an SI response that is as robust as the SI response observed in naturally self-incompatible A. lyrata, demonstrating that A. thaliana, which harbors nonfunctional S-locus haplotypes (Kusaba et al., 2001; Sherman-Broyles et al., 2007; Shimizu et al., 2008; Boggs et al., 2009c), has nevertheless retained all other factors required for SI. In view of the availability in A. thaliana of a highly efficient transformation method and numerous genetic resources, the A. thaliana SRK-SCR transgenic model has enabled the use of experimental approaches that are difficult or impossible to implement in Brassica species and has thus proven to be an invaluable platform for in planta analysis of SRK and SI signaling (Liu et al., 2007; Boggs et al., 2009a, 2009b; Tantikanjana et al., 2009; Tantikanjana and Nasrallah, 2012).We therefore used this transgenic A. thaliana self-incompatible model to determine if abolishing the proposed SRK-thioredoxin h interaction or eliminating expression of the major thioredoxin h proteins expressed in stigmas would affect the outcome of self- or cross pollination. To this end, we expressed a mutant form of SRKb that lacked the Cys residue previously shown to be required for the interaction of SRK with THLs (Mazzurco et al., 2001), and we analyzed plants carrying knockout insertional mutations in thioredoxin h genes. Our results are inconsistent with the proposed role of thioredoxin h proteins as negative regulators of SRK catalytic activity and SI signaling.     

Sequence complexity of the S receptor kinase gene family in Brassica

A genomic library from an S ₂₉/S ₂₉ self-incompatible genotype of Brassica oleracea was screened with a probe carrying part of the catalytic domain of a Brassica S-receptor kinase (SRK)-like gene. Six positive phage clones with varying hybridisation intensities (K1 to K6) were purified and characterised. A 650–700 by region corresponding to the probe was excised from each clone and sequenced. DNA and predicted protein sequence comparisons based on a multiple alignment identified K5 as a pseudogene, whereas the others could encode functional proteins. K3 was found to have lost an intron from its genomic sequence. The six genes display different degrees of sequence similarity and form two distinct clusters in a dendrogram. The 98% similarity between K4 and K6, which extends across intron sequences, suggests that these might be very recently diverged alleles or daughters of a duplication. In addition, K2 showed a comparably high similarity to the probe. Clones K1, K3 and K5 cross-hybridised with an SLG ₂₉ cDNA probe, indicating the presence of upstream receptor domains homologous to the Brassica SLG gene. This suggests that the previously reported S sequence complexity may be ascribed to a large receptor kinase gene family.     

The tomato early fruit specific gene <Emphasis Type="Italic">Lefsm1</Emphasis> defines a novel class of plant-specific SANT/MYB domain proteins

We describe here a novel plant-specific gene, Lefsm1 (fruit SANT/MYB-like 1) harboring a single SANT/MYB domain. The expression of Lefsm1 is specific to the very early stages of tomato (Lycopersicon esculentum) fruit development. Ectopic expression of Lefsm1 results in severe developmental alterations manifested in retarded growth, and reduced apical dominance during tomato and Arabidopsis seedling development. A promoter sequence residing 1.0 kb upstream to the translation initiation codon confers the organ-specific expression of the gene. Lefsm1 belongs to a novel small gene family consisting of five to six members in tomato, Arabidopsis and rice. The SANT/MYB domain of LeFSM1 and its orthologs in Arabidopsis and rice differs from that of all other plant or animal MYB proteins and from the SANT domains found in part of the chromatin remodeling proteins. Together, our results indicate that Lefsm1 is a founding member of a small family of proteins containing a novel MYB/SANT domain which is likely to participate in the regulation of a plant-specific developmental program.     

Expression of the Hypersensitive Response-assisting Protein in <Emphasis Type="Italic">Arabidopsis</Emphasis> Results in Harpin-dependent Hypersensitive Cell Death in Response to <Emphasis Type="Italic">Erwinia carotovora</Emphasis>

Active defense mechanisms of plants against pathogens often include a rapid plant cell death known as the hypersensitive cell death (HCD). Hypersensitive response-assisting protein (HRAP) isolated from sweet pepper intensifies the harpin_Pss-mediated HCD. Here we demonstrate that constitutive expression of the hrap gene in Arabidopsis results in an enhanced disease resistance towards soft rot pathogen, E. carotovora subsp. carotovora. This resistance was due to the induction of HCD since different HCD markers viz. Athsr3, Athsr4, ion leakage, H₂O₂ and protein kinase were induced. One of the elicitor harpin proteins, HrpN, from Erwinia carotovora subsp. carotovora was able to induce a stronger HCD in hrap-Arabidopsis than non-transgenic controls. To elucidate the role of HrpN, we used E. carotovora subsp. carotovora defective in HrpN production. The hrpN⁻ mutant did not induce disease resistance or HCD markers in hrap-Arabidopsis. These results imply that the disease resistance of hrap-Arabidopsis against a virulent pathogen is harpin dependent.     

Physical linkage of the SLG and SRK genes at the self-incompatibility locus of Brassica oleracea

Summary In Brassica oleracea, the pollen-stigma interaction of self-incompatibility is controlled by a single genetically defined locus designated S. Molecular studies have identified two genes that are tightly linked to the classically defined S locus: The S-Locus Glycoprotein (SLG) gene and the S-Receptor Kinase (SRK) gene. In previous RFLP linkage analyses with probes specific for SLG and SRK, we were unable to identify any recombination events between SLG, SRK, and self-incompatibility phenotype. In this paper, we use pulsed-field gel electrophoresis (PFGE) in conjunction with DNA blot analysis to characterize the S-locus region from two highly divergent self-incompatibility genotypes, S ₂ and S ₆. We establish the physical linkage of SLG and SRK in each genotype, and demonstrate that the two genes are separated by a maximum distance of 220 kb in the S ₆ genotype and 350 kb in the S ₂ genotype. Furthermore, a comparison of the data from the two genotypes reveals that a high level of polymorphism exists across the entire S-locus region.     

Activation of hypersensitive cell death by pathogen-induced receptor-like protein kinases from <Emphasis Type="Italic">Arabidopsis</Emphasis>

In Arabidopsis, there is a family of receptor-like protein kinases (RLKs) containing novel cysteine-rich repeats in their extracellular domains. Genes encoding many of these cysteine-rich RLKs (CRKs) are induced by pathogen infection, suggesting a possible role in plant defense responses. We have previously generated Arabidopsis plants expressing four pathogen-regulated CRK genes (CRK5, 6, 10 and 11) under control of a steroid-inducible promoter and found that induced expression of CRK5, but not the other three CRK genes, triggered hypersensitive response-like cell death in transgenic plants. In the present study, we have analyzed the structural relationship of the CRK family and identified three CRKs (CRK4, 19 and 20) that are structurally closely related to CRK5. Genes encoding these three CRKs are all induced by salicylic acid and pathogen infection. Furthermore, induced expression of CRK4, 19and 20 all activates rapid cell death in transgenic plants. Thus, the activity of inducing rapid cell death is shared by these structurally closely related CRKs. We have also performed yeast two-hybrid screens and identified proteins that interact with the kinase domains of CRKs. One of the identified CRK-interacting proteins is the kinase-associated type 2C protein phospohatase known to interact with a number of other RLKs through its kinase-interacting FHA domain. Other CRK-interacting proteins include a second protein with a FHA domain and another type 2C protein phosphatase. Interactions of CRKs with these three proteins in vivo were demonstrated through co-immunoprecipitation. These CRK-interacting proteins may play roles in the regulation and signaling of CRKs.