Protein kinase CK2 both promotes robust proliferation and inhibits the proliferative fate in the C. elegans germ line

Stem cells are capable of both self-renewal (proliferation) and differentiation. Determining the regulatory mechanisms controlling the balance between stem cell proliferation and differentiation is not only an important biological question, but also holds the key for using stem cells as therapeutic agents. The Caenorhabditis elegans germ line has emerged as a valuable model to study the molecular mechanisms controlling stem cell behavior. In this study, we describe a large-scale RNAi screen that identified kin-10, which encodes the β subunit of protein kinase CK2, as a novel factor regulating stem cell proliferation in the C. elegans germ line. While a loss of kin-10 in an otherwise wild-type background results in a decrease in the number of proliferative cells, loss of kin-10 in sensitized genetic backgrounds results in a germline tumor. Therefore, kin-10 is not only necessary for robust proliferation, it also inhibits the proliferative fate. We found that kin-10’s regulatory role in inhibiting the proliferative fate is carried out through the CK2 holoenzyme, rather than through a holoenzyme-independent function, and that it functions downstream of GLP-1/Notch signaling. We propose that a loss of kin-10 leads to a defect in CK2 phosphorylation of its downstream targets, resulting in abnormal activity of target protein(s) that are involved in the proliferative fate vs. differentiation decision. This eventually causes a shift towards the proliferative fate in the stem cell fate decision.     

siRNA-mediated knockdown of a splice variant of the PK-A catalytic subunit gene causes adult-onset paralysis in C. elegans

In C. elegans, the PK-A catalytic subunit is encoded by kin-1, which has six 5' exons (N'1-N'6), any one of which may be alternatively spliced onto exon-2. Here we describe a novel siRNA-based strategy to knockdown the expression levels of the N'3 and N'4 splice variants. We show that this technique can effectively knockdown expression of the targeted isoforms without affecting expression of the other kin-1 splice variants. We suggest that this strategy could be widely used in C. elegans to investigate the function of genes with alternative first exons. Moreover, we report a novel role for the N'3 kin-1 variant. Whereas knockdown of the N'4 variant results in no obvious phenotype, loss of the N'3 variant leads to paralysis and an egg-laying defect in the adult, suggesting a deficit in the function of the neuromuscular junction. The function of the N'3 variant is discussed in relation to the known function of PK-A in regulation of the release of neurotransmitters from many presynaptic termini.     

kin-19/casein kinase Iα has dual functions in regulating asymmetric division and terminal differentiation in C. elegans epidermal stem cells

Casein Kinase I (CKI) is a conserved component of the Wnt signaling pathway that regulates cell fate determination in metazoans. We show that post-embryonic asymmetric division and fate specification of C. elegans epidermal stem cells are controlled by a non-canonical Wnt/β-catenin signaling pathway, involving the β-catenins WRM-1 and SYS-1, and that C. elegans kin-19/CKIα functions in this pathway. Furthermore, we find that kin-19 is the only member of the Wnt asymmetry pathway that functions with, or in parallel to, the heterochronic temporal patterning pathway to control withdrawal from self-renewal and subsequent terminal differentiation of epidermal stem cells. We show that, except in the case of kin-19, the Wnt asymmetry pathway and the heterochronic pathway function separately and in parallel to control different aspects of epidermal stem cell fate specification. However, given the function of kin-19/CKIα in both pathways, and that CKI, Wnt signaling pathway and heterochronic pathway genes are widely conserved in animals, our findings suggest that CKIα may function as a regulatory hub through which asymmetric division and terminal differentiation are coordinated in adult stem cells of vertebrates.Key words: C. elegans, kin-19, casein kinase Ialpha (CKIα), Wnt, stem cell, asymmetric cell division, heterochronic, temporal identity, terminal differentiation, self-renewal     

Mapping intersubunit interactions of the regulatory subunit (RIalpha) in the type I holoenzyme of protein kinase A by amide hydrogen/deuterium exchange mass spectrometry (DXMS)

Protein kinase A (PKA), a central locus for cAMP signaling in the cell, is composed of regulatory (R) and catalytic (C) subunits. The C-subunits are maintained in an inactive state by binding to the R-subunit dimer in a tetrameric holoenzyme complex (R(2)C(2)). PKA is activated by cAMP binding to the R-subunits which induces a conformational change leading to release of the active C-subunit. Enzymatic activity of the C-subunit is thus regulated by cAMP via the R-subunit, which toggles between cAMP and C-subunit bound states. The R-subunit is composed of a dimerization/docking (D/D) domain connected to two cAMP-binding domains (cAMP:A and cAMP:B). While crystal structures of the free C-subunit and cAMP-bound states of a deletion mutant of the R-subunit are known, there is no structure of the holoenzyme complex or of the cAMP-free state of the R-subunit. An important step in understanding the cAMP-dependent activation of PKA is to map the R-C interface and characterize the mutually exclusive interactions of the R-subunit with cAMP and C-subunit. Amide hydrogen/deuterium exchange mass spectrometry is a suitable method that has provided insights into the different states of the R-subunit in solution, thereby allowing mapping of the effects of cAMP and C-subunit on different regions of the R-subunit. Our study has localized interactions with the C-subunit to a small contiguous surface on the cAMP:A domain and the linker region. In addition, C-subunit binding causes increased amide hydrogen exchange within both cAMP-domains, suggesting that these regions become more flexible in the holoenzyme and are primed to bind cAMP. Furthermore, the difference in the protection patterns between RIalpha and the previously studied RIIbeta upon cAMP-binding suggests isoform-specific differences in cAMP-dependent regulation of PKA activity.     

Sensing Domain Dynamics in Protein Kinase A-I�� Complexes by Solution X-ray Scattering

The catalytic (C) and regulatory (R) subunits of protein kinase A are exceptionally dynamic proteins. Interactions between the R- and C-subunits are regulated by cAMP binding to the two cyclic nucleotide-binding domains in the R-subunit. Mammalian cells express four different isoforms of the R-subunit (RIα, RIβ, RIIα, and RIIβ) that all interact with the C-subunit in different ways. Here, we investigate the dynamic behavior of protein complexes between RIα and C-subunits using small angle x-ray scattering. We show that a single point mutation in RIα, R333K (which alters the cAMP-binding properties of Domain B) results in a compact shape compared with the extended shape of the wild-type R·C complex. A double mutant complex that disrupts the interaction site between the C-subunit and Domain B in RIα, RIα_ABR333K·C(K285P), results in a broader P(r) curve that more closely resembles the P(r) profiles of wild-type complexes. These results together suggest that interactions between RIα Domain B and the C-subunit in the RIα·C complex involve large scale dynamics that can be disrupted by single point mutations in both proteins. In contrast to RIα·C complexes. Domain B in the RIIβ·C heterodimer is not dynamic and is critical for both inhibition and complex formation. Our study highlights the functional differences of domain dynamics between protein kinase A isoforms, providing a framework for elucidating the global organization of each holoenzyme and the cross-talk between the R- and C-subunits.     

Realizing the allosteric potential of the tetrameric protein kinase A RIα holoenzyme

PKA holoenzymes containing two catalytic (C) subunits and a regulatory (R) subunit dimer are activated cooperatively by cAMP. While cooperativity involves the two tandem cAMP binding domains in each R-subunit, additional cooperativity is associated with the tetramer. Of critical importance is the flexible linker in R that contains an inhibitor site (IS). While the IS becomes ordered in the R:C heterodimer, the overall conformation of the tetramer is mediated largely by the N-Linker that connects the?D/D domain to the IS. To understand how the N-Linker contributes to assembly of tetrameric holoenzymes, we engineered a monomeric RIα that contains most of the N-Linker, RIα(73-244), and crystallized a holoenzyme complex. Part of the N-linker is now ordered by interactions with a symmetry-related dimer. This complex of two symmetry-related dimers forms a tetramer that reveals novel mechanisms for allosteric regulation and has many features associated with full-length holoenzyme. A model of the tetrameric holoenzyme, based on this structure, is consistent with previous small angle X-ray and neutron scattering data, and is validated with new SAXS data and with an RIα mutation localized to a novel interface unique to the tetramer.     

Regulatory subunit of cAMP-dependent protein kinase inhibits phosphoprotein phosphatase

The activity of a purified high molecular weight phosphoprotein phosphatase was inhibited by purified type II cAMP-dependent protein kinase. This effect required cAMP and was obtained in the absence of ATP. The isolated type II regulatory subunits (R-subunits) from several species also inhibited the phosphatase activity in both crude extracts and purified preparations. Half maximal inhibition was observed at 0.06-0.25 microM, well within the physiological range of R-subunit concentrations. The inhibitory potency of R-subunit was greater using the thiophosphorylated form. Limited trypsinization of the R-subunit abolished the inhibitory activity. The C-subunit released the bound cAMP when combined with R-subunit, but the phosphatase did not, implying that the inhibited species is a R.cAMP-phosphatase complex. The results suggest that the R-subunit might have at least one physiological role in addition to inhibition of the C-subunit, i.e., inhibition of phosphatase. The latter would occur only when cAMP is elevated.     

kin-19/casein kinase Iα has dual functions in regulating asymmetric division and terminal differentiation in C. elegans epidermal stem cells

Casein Kinase I (CKI) is a conserved component of the Wnt signaling pathway, which regulates cell fate determination in metazoans. We show that post-embryonic asymmetric division and fate specification of C. elegans epidermal stem cells are controlled by a non-canonical Wnt/b-catenin signaling pathway, involving the b-catenins WRM-1 and SYS-1, and that C. elegans kin-19/CKIa functions in this pathway. Furthermore, we find that kin-19 is the only member of the Wnt asymmetry pathway that functions with, or in parallel to, the heterochronic temporal patterning pathway to control withdrawal from self-renewal and subsequent terminal differentiation of epidermal stem cells. We show that, except in the case of kin-19, the Wnt asymmetry pathway and the heterochronic pathway function separately and in parallel to control different aspects of epidermal stem cell fate specification. However, given the function of kin-19/CKIa in both pathways, and that CKI, Wnt signaling pathway and heterochronic pathway genes are widely conserved in animals, our findings suggest that CKIa may function as a regulatory hub through which asymmetric division and terminal differentiation are coordinated in adult stem cells of vertebrates.     

The type I restriction endonuclease EcoR124I, couples ATP hydrolysis to bidirectional DNA translocation

Type I restriction endonuclease holoenzymes contain methylase (M), restriction (R) and specificity (S) subunits, present in an M2:R2:S1 stoichiometry. These enzymes bind to specific DNA sequences and translocate dsDNA in an ATP-dependent manner toward the holoenzyme anchored at the recognition sequence. Once translocation is impeded, DNA restriction, which functions to protect the host cell from invading DNA, takes place. Translocation and DNA cleavage are afforded by the two diametrically opposed R-subunits. To gain insight into the mechanism of translocation, a detailed characterization of the ATPase activity of EcoR124I was done. Results show that following recognition sequence binding, ATP hydrolysis-coupled, bidirectional DNA translocation by EcoR124I ensues, with the R-subunits transiently disengaging, on average, every 515 bp. Macroscopic processivity of 2031(+/-184)bp is maintained, as the R-subunits remain in close proximity to the DNA through association with the methyltransferase. Transient uncoupling of ATP hydrolysis from translocation results in 3.1(+/-0.4) ATP molecules being hydrolyzed per base-pair translocated per R-subunit. This is the first clear demonstration of the coupling of ATP hydrolysis to dsDNA translocation, albeit inefficient. Once translocation is impeded on supercoiled DNA, the DNA is cleaved. DNA cleavage inactivates the EcoR124I holoenzyme partially and reversibly, which explains the stoichiometric behaviour of type I restriction enzymes. Inactivated holoenzyme remains bound to the DNA at the recognition sequence and immediately releases the nascent ends. The release of nascent ends was demonstrated using a novel, fluorescence-based, real-time assay that takes advantage of the ability of the Escherichia coli RecBCD enzyme to unwind restricted dsDNA. The resulting unwinding of EcoR124I-restricted DNA by RecBCD reveals coordination between the restriction-modification and recombination systems that functions to destroy invading DNA efficiently. In addition, we demonstrate the displacement of EcoR124I following DNA cleavage by the translocating RecBCD enzyme, resulting in the restoration of catalytic function to EcoR124I.     

The DH-PH region of the giant protein UNC-89 activates RHO-1 GTPase in Caenorhabditis elegans body wall muscle

Mutation of the Caenorhabditis elegans gene unc-89 results in disorganization of muscle A-bands. unc-89 encodes a giant polypeptide (900 kDa) containing a DH domain followed by a PH domain at its N terminus, which is characteristic of guanine nucleotide exchange factor proteins for Rho GTPases. To obtain evidence that the DH-PH region has activity toward specific Rho family small GTPases, we conducted an experiment using the yeast three-hybrid system. The DH-PH region of UNC-89 has exchange activity for RHO-1 (C. elegans RhoA), but not for CED-10 (C. elegans Rac), MIG-2 (C. elegans RhoG), or CDC-42 (C. elegans Cdc42). The DH domain alone has similar activity for RHO-1. An in vitro binding assay demonstrates interaction between the DH-PH region of UNC-89 and each of the C. elegans Rho GTPases. Partial knockdown of rho-1 in C. elegans adults showed a pattern of disorganization of myosin thick filaments similar to the phenotype caused by unc-89 (su75), a mutant allele in which all of the isoforms containing the DH-PH region are missing. Taken together, we propose a model in which the DH-PH region of UNC-89 activates RHO-1 GTPase for organization of myosin filaments in C. elegans muscle cells.     

D‐AKAP2:PKA RII:PDZK1 ternary complex structure: Insights from the nucleation of a polyvalent scaffold

A‐kinase anchoring proteins (AKAPs) regulate cAMP‐dependent protein kinase (PKA) signaling in space and time. Dual‐specific AKAP2 (D‐AKAP2/AKAP10) binds with high affinity to both RI and RII regulatory subunits of PKA and is anchored to transporters through PDZ domain proteins. Here, we describe a structure of D‐AKAP2 in complex with two interacting partners and the exact mechanism by which a segment that on its own is disordered presents an α‐helix to PKA and a β‐strand to PDZK1. These two motifs nucleate a polyvalent scaffold and show how PKA signaling is linked to the regulation of transporters. Formation of the D‐AKAP2: PKA binary complex is an important first step for high affinity interaction with PDZK1, and the structure reveals important clues toward understanding this phenomenon. In contrast to many other AKAPs, D‐AKAP2 does not interact directly with the membrane protein. Instead, the interaction is facilitated by the C‐terminus of D‐AKAP2, which contains two binding motifs—the D‐AKAP2_AKB and the PDZ motif—that are joined by a short linker and only become ordered upon binding to their respective partner signaling proteins. The D‐AKAP2_AKB binds to the D/D domain of the R‐subunit and the C‐terminal PDZ motif binds to a PDZ domain (from PDZK1) that serves as a bridging protein to the transporter. This structure also provides insights into the fundamental question of why D‐AKAP2 would exhibit a differential mode of binding to the two PKA isoforms.     

An analysis of the substrate specificity of insulin-stimulated protein kinase-1, a mammalian homologue of S6 kinase-II

The specificity determinants for insulin-stimulated protein kinase-I (ISPK-1) have been investigated with synthetic peptides based on naturally-occurring protein phosphoacceptor sequences. Peptides (Arg-Arg-Xaa-Ser-Xaa) that fulfill the consensus sequence for cyclic-AMP-dependent protein kinase (PK-A) are also phosphorylated readily by ISPK-1. The phosphorylation efficiency is improved by increasing the number of N-terminal arginine residues and by moving the arginyl cluster one residue further away from the serine, the nonapeptide (Arg)₄-Ala-Ala-Ser-Val-Ala being the best substrate among all the short peptides tested (K_m = 15 μM). Conversely, the substitution of either Thr for Ser or Lys for Arg is detrimental. Likewise, two flanking Pro residues and an Arg immediately N-terminal to the Ser act as negative specificity determinants. While the specificity of ISPK-1 shows several similarities to that of PK-A, including an absolute requirement for basic residues on the N-terminal side of the target Ser, it differs in several other respects including (1), the detrimental effect of a Lys for Arg substitution which is still compatible with some phosphorylation by ISPK-1, but not PK-A; (2), the presence of C-terminal acidic residues which are tolerated very well by ISPK-1, but are detrimental to PK-A; (3), the effect of substituting Phe for Val in the peptide Arg-Arg-Ala-Ser-Val-Ala, which improves the efficiency of phosphorylation by PK-A (lowering the K_m 4-fold), but has no effect on phosphorylation by ISPK-1. These differences in peptide substrate specificity may account in part for the different rates of phosphorylation of physiological substrates for ISPK-1 and PK-A, such as the G subunit of protein phosphatase-1.     

Purification and chacterization of acid-type phosphatases from a heavy-metal-accumulating Citrobacter sp.

An acid phosphatase from a heavy-metal-accumulating strain of a Citrobacter sp. was resolved into two forms on the basis of their nonbinding (phosphatase I) or binding (phosphatase II) behaviour on the cation-exchange resin SP-Sephadex C50. Both holoenzymes had a molecular mass of 103–108 kDa as determined by Superose Q-6 column chromatography in the presence of 150 mM KCl and a subunit molecular mass of 27 kDa as determined by SDS-PAGE; the enzyme was tetrameric. Both enzymes had a pI ≈ 9.0 and were immunologically cross-reactive. There were minor differences in amino acid composition and in peptide maps following tryptic digest. The pH optimum for phosphatases I and II was 5.5 and 6.25, respectively; phosphatase II alone retained activity at pH values up to 9.0. Phosphatase I was more resistant to mechanical shear, γ-irradiation, high temperature, and toxins (F^– and formaldehyde). Glycerol increased the thermostability of both enzymes, particularly the more thermosensitive phosphatase II. Phosphatase II had a lower K _m and a lower V _max for glycerol 2-phosphate hydrolysis. The production of enzyme isoforms is a phenomenon similar to that described previously for the alkaline phosphatase of Escherichia coli, where the isoforms relate to precursive and final processed forms of the enzyme. Acid phosphatase is physiologically distinct, with a role that is still obscure but that may relate to cellular stress responses. Revision received: 22 August 1997 / Accepted: 16 September 1997     

Cytochrome P450-dependent metabolism of eicosapentaenoic acid in the nematode Caenorhabditis elegans

The genome of Caenorhabditis elegans contains 75 full length cytochrome P450 (CYP) genes whose individual functions are largely unknown yet. We tested the hypothesis that some of them may be involved in the metabolism of eicosapentaenoic acid (EPA), the predominant polyunsaturated fatty acid of this nematode. Microsomes isolated from adult worms contained spectrally active CYP proteins and showed NADPH-CYP reductase (CPR) activities. They metabolized EPA and with lower activity also arachidonic acid (AA) to specific sets of regioisomeric epoxy- and ω-/(ω-1)-hydroxy-derivatives. 17(R),18(S)-epoxyeicosatetraenoic acid was produced as the main EPA metabolite with an enantiomeric purity of 72%. The epoxygenase and hydroxylase reactions were NADPH-dependent, required the functional expression of the CPR-encoding emb-8 gene, and were inhibited by 17-ODYA and PPOH, two compounds known to inactivate mammalian AA-metabolizing CYP isoforms. Multiple followed by single RNAi gene silencing experiments identified CYP-29A3 and CYP-33E2 as the major isoforms contributing to EPA metabolism in C. elegans. Liquid chromatography/mass spectrometry revealed that regioisomeric epoxy- and hydroxy-derivatives of EPA and AA are endogenous constituents of C. elegans. The endogenous EPA metabolite levels were increased by treating the worms with fenofibrate, which also induced the microsomal epoxygenase and hydroxylase activities. These results demonstrate for the first time that C. elegans shares with mammals the capacity to produce CYP-dependent eicosanoids and may thus facilitate future studies on the mechanisms of action of this important class of signaling molecules.     

Glucose 6-phosphate dehydrogenase deficiency enhances germ cell apoptosis and causes defective embryogenesis in Caenorhabditis elegans

Glucose 6-phosphate dehydrogenase (G6PD) deficiency, known as favism, is classically manifested by hemolytic anemia in human. More recently, it has been shown that mild G6PD deficiency moderately affects cardiac function, whereas severe G6PD deficiency leads to embryonic lethality in mice. How G6PD deficiency affects organisms has not been fully elucidated due to the lack of a suitable animal model. In this study, G6PD-deficient Caenorhabditis elegans was established by RNA interference (RNAi) knockdown to delineate the role of G6PD in animal physiology. Upon G6PD RNAi knockdown, G6PD activity was significantly hampered in C. elegans in parallel with increased oxidative stress and DNA oxidative damage. Phenotypically, G6PD-knockdown enhanced germ cell apoptosis (2-fold increase), reduced egg production (65% of mock), and hatching (10% of mock). To determine whether oxidative stress is associated with G6PD knockdown-induced reproduction defects, C. elegans was challenged with a short-term hydrogen peroxide (H₂O₂). The early phase egg production of both mock and G6PD-knockdown C. elegans were significantly affected by H₂O₂. However, H₂O₂-induced germ cell apoptosis was more dramatic in mock than that in G6PD-deficient C. elegans. To investigate the signaling pathways involved in defective oogenesis and embryogenesis caused by G6PD knockdown, mutants of p53 and mitogen-activated protein kinase (MAPK) pathways were examined. Despite the upregulation of CEP-1 (p53), cep-1 mutation did not affect egg production and hatching in G6PD-deficient C. elegans. Neither pmk-1 nor mek-1 mutation significantly affected egg production, whereas sek-1 mutation further decreased egg production in G6PD-deficient C. elegans. Intriguingly, loss of function of sek-1 or mek-1 dramatically rescued defective hatching (8.3- and 9.6-fold increase, respectively) induced by G6PD knockdown. Taken together, these findings show that G6PD knockdown reduces egg production and hatching in C. elegans, which are possibly associated with enhanced oxidative stress and altered MAPK pathways, respectively.     

Deletion of Thioredoxin Reductase and Effects of Selenite and Selenate Toxicity in Caenorhabditis elegans

Thioredoxin reductase-1 (TRXR-1) is the sole selenoprotein in C. elegans, and selenite is a substrate for thioredoxin reductase, so TRXR-1 may play a role in metabolism of selenium (Se) to toxic forms. To study the role of TRXR in Se toxicity, we cultured C. elegans with deletions of trxr-1, trxr-2, and both in axenic media with increasing concentrations of inorganic Se. Wild-type C. elegans cultured for 12 days in Se-deficient axenic media grow and reproduce equivalent to Se-supplemented media. Supplementation with 0–2 mM Se as selenite results in inverse, sigmoidal response curves with an LC₅₀ of 0.20 mM Se, due to impaired growth rather than reproduction. Deletion of trxr-1, trxr-2 or both does not modulate growth or Se toxicity in C. elegans grown axenically, and ⁷⁵Se labeling showed that TRXR-1 arises from the trxr-1 gene and not from bacterial genes. Se response curves for selenide (LC₅₀ 0.23 mM Se) were identical to selenite, but selenate was 1/4^th as toxic (LC₅₀ 0.95 mM Se) as selenite and not modulated by TRXR deletion. These nutritional and genetic studies in axenic media show that Se and TRXR are not essential for C. elegans, and that TRXR alone is not essential for metabolism of inorganic Se to toxic species.     

Cytochrome P450-dependent metabolism of PCB52 in the nematode Caenorhabditis elegans

There are 75 full length cytochrome P450 (CYP) genes known in the genome of the nematode Caenorhabditis elegans. The individual biological functions of the vast majority are mostly as yet unknown. Here the impact of cytochrome P450 isoforms on the metabolism of PCB52, an ortho-substituted, non-coplanar 2,2′,5,5′-tetrachlorbiphenyl, as a model PCB of these worldwide distributed pollutants is investigated. Organic extracts, isolated from treated worms and analyzed by GC/MS, contained two obvious PCB52-derived products which have been identified as C3-, C4- and/or C6-hydroxy-PCB52. Moreover, these hydroxylase reactions strictly required the functional expression of the NADPH-dependent cytochrome P450 reductase (CPR) encoding emb-8 gene, which was recently shown to be essential also for several other cytochrome P450-dependent enzymatic reactions. Multiple and subsequent single RNAi-gene silencing experiments, as well as the use of cyp-mutant strains, identified members of the CYP-14A subfamily and CYP-34A6 as the major isoforms contributing to PCB52 metabolism in C. elegans. In the gene-silenced worms and mutants, the reduction in formation of hydroxylated products ranged from 55% to 78%. These results demonstrate for the first time that C. elegans shares with mammals the capacity to produce CYP-dependent PCB metabolites and may thus facilitate future studies on biotransformation.     

Structure of yeast regulatory subunit: a glimpse into the evolution of PKA signaling

The major cAMP receptors in eukaryotes are the regulatory (R) subunits of PKA, an allosteric enzyme conserved in fungi through mammals. While mammals have four R-subunit genes, Saccharomyces cerevisiae has only one, Bcy1. To achieve a molecular understanding of PKA activation in yeast and to explore the evolution of cyclic-nucleotide binding (CNB) domains, we solved the structure of cAMP-bound Bcy1(168-416). Surprisingly, the relative orientation of the two CNB domains in Bcy1 is very different from mammalian R-subunits. This quaternary structure is defined primarily by a fungi-specific sequence in the hinge between the αB/αC helices of the CNB-A domain. The unique interface between the two CNB domains in Bcy1 defines the allosteric mechanism for cooperative activation of PKA by cAMP. Some interface motifs are isoform-specific while others, although conserved, play surprisingly different roles in each R-subunit. Phylogenetic analysis shows that structural differences in Bcy1 are shared by fungi of the subphylum Saccharomycotina.