Role of A kinase anchor proteins in the tissue-specific regulation of lipoprotein lipase

Activation of protein kinase A by catecholamines inhibits lipoprotein lipase (LPL) activity through the elaboration of an RNA binding complex, which inhibits LPL translation by binding to the 3'-untranslated region of the LPL mRNA. To better define this process, we reconstituted the inhibitory RNA binding complex in vitro and demonstrated that the K homology (KH) domain of A kinase anchor protein (AKAP) 121/149 plays a vital role in the inhibition of LPL translation. Inhibition of LPL translation occurred in vitro only when the Calpha subunit, R subunit, and AKAP 149 were present. Using different glutathione-S-transferase fusion proteins of AKAP 149, sequences containing the KH domain were required for inhibition of LPL translation, and the inhibition of AKAP 121 expression in 3T3-F442A adipocytes with short interfering RNA resulted in loss of epinephrine-mediated translation inhibition. After epinephrine injection into mice, LPL activity was inhibited in white adipose tissue but not in brown adipose tissue (BAT) or muscle. LPL activity and synthetic rate were inhibited in vitro by the addition of epinephrine to 3T3-F442A adipocytes, but there was no effect in L6 muscle cells and cultures of brown adipocytes. Corresponding with these differences in LPL translation, AKAP 121 protein and mRNA were abundantly expressed in mouse white adipose tissue, but was either very low or undetectable in BAT and muscle. Thus, AKAP 121/149 contains a KH region that is essential to the translation inhibition of LPL in response to epinephrine. BAT and muscle do not express significant AKAP 121/149, and this likely explains some of the tissue-specific differences in LPL regulation.     

Association of PP1 with its regulatory subunit AKAP149 is regulated by serine phosphorylation flanking the RVXF motif of AKAP149

Reformation of the nuclear envelope at the end of mitosis involves the recruitment of the B-type lamin phosphatase PP1 to nuclear membranes by A-kinase anchoring protein AKAP149. PP1 remains associated to AKAP149 throughout G1 but dissociates from AKAP149 when AKAP149 is phosphorylated at the G1/S transition. We examine here the role of phosphorylation of serines flanking the RVXF PP1-binding motif of AKAP149, on PP1 anchoring. The use of AKAP149 peptides encompassing the RVXF motif and five flanking serines, either wild type (wt) or bearing S-->A or S-->D mutations, specifically shows that phosphorylation of S151 or S159 abolishes PP1 binding to immobilized AKAP149. Peptides with S151 or S159 as the only wt serine residue trigger dissociation of PP1 from immunoprecipitated AKAP149, whereas S151/159D mutants are ineffective. Furthermore, immunoprecipitated AKAP149 from purified G1-phase nuclear envelopes binds PKA and PKC in overlay assays. PKA binding to AKAP149 in vitro is unaffected by the presence of PKC or PP1, and similarly, PKC binding is independent of PKA or PP1. The immunoprecipitated AKAP149 complex contains PKA and PKC activities. Both AKAP149-associated PKA and PKC serine-phosphorylate immunoprecipitated AKAP149 in vitro; however, only PKC-mediated phosphorylation promotes dissociation of PP1 from the AKAP. The results suggest a putative temporally and spatially controlled mechanism promoting release of PP1 from AKAP149. AKAP149 emerges as a scaffolding protein for multiple protein kinases and phosphatases that may be involved in the integration of intracellular signals that converge at the nuclear envelope.     

Role of dimerization in KH/RNA complexes: the example of Nova KH3

The K homology module, one of the most common RNA-binding motifs, is present in multiple copies in both prokaryotic and eukaryotic regulatory proteins. Increasing evidence suggests that self-aggregation of KH modules has a functional role. We have used a combination of techniques to characterize the behavior in solution of the third KH domain of Nova-1, a paradigmatic KH protein. The possibility of working on the isolated module allowed us to observe specifically the homodimerization and RNA-binding properties of KH domains. We provide conclusive evidence that self-association of Nova-1 KH3 occurs in solution even in the absence of RNA. Homodimerization involves a specific protein/protein interface. We also studied the dynamical behavior of Nova-1 KH3 in isolation and in complex with RNA. These data provide a model for the mechanism of KH/RNA recognition and suggest functional implications of dimerization in KH complexes. We discuss our findings in the context of the whole KH family and suggest a generalized mode of interaction.     

Self-association of the single-KH-domain family members Sam68, GRP33, GLD-1, and Qk1: role of the KH domain.

Sam68 is a member of a growing family of proteins that contain a single KH domain embedded in a larger conserved domain of approximately 170 amino acids. Loops 1 and 4 of this KH domain family are longer than the corresponding loops in other KH domains and contain conserved residues. KH domains are protein motifs that are involved in RNA binding and are often present in multiple copies. Here we demonstrate by coimmunoprecipitation studies that Sam68 self-associated and that cellular RNA was required for the association. Deletion studies demonstrated that the Sam68 KH domain loops 1 and 4 were required for self-association. The Sam68 interaction was also observed in Saccharomyces cerevisiae by the two-hybrid system. In situ chemical cross-linking studies in mammalian cells demonstrated that Sam68 oligomerized in vivo. These Sam68 complexes bound homopolymeric RNA and the SH3 domains of p59fyn and phospholipase Cgamma1 in vitro, demonstrating that Sam68 associates with RNA and signaling molecules as a multimer. The formation of the Sam68 complex was inhibited by p59fyn, suggesting that tyrosine phosphorylation regulates Sam68 oligomerization. Other Sam68 family members including Artemia salina GRP33, Caenorhabditis elegans GLD-1, and mouse Qk1 also oligomerized. In addition, Sam68, GRP33, GLD-1, and Qk1 associated with other KH domain proteins such as Bicaudal C. These observations indicate that the single KH domain found in the Sam68 family, in addition to mediating protein-RNA interactions, mediates protein-protein interactions.     

Recruitment of protein phosphatase 1 to the nuclear envelope by A-kinase anchoring protein AKAP149 is a prerequisite for nuclear lamina assembly

Subcellular targeting of cAMP-dependent protein kinase (protein kinase A [PKA]) and of type 1 protein phosphatase (PP1) is believed to enhance the specificity of these enzymes. We report that in addition to anchoring PKA, A-kinase anchoring protein AKAP149 recruits PP1 at the nuclear envelope (NE) upon somatic nuclear reformation in vitro, and that PP1 targeting to the NE is a prerequisite for assembly of B-type lamins. AKAP149 is an integral membrane protein of the endoplasmic reticulum/NE network. The PP1-binding domain of AKAP149 was identified as K(153)GVLF(157). PP1 binds immobilized AKAP149 in vitro and coprecipitates with AKAP149 from purified NE extracts. Affinity isolation of PP1 from solubilized NEs copurifies AKAP149. Upon reassembly of somatic nuclei in interphase extract, PP1 is targeted to the NE. Targeting is inhibited by a peptide containing the PP1-binding domain of AKAP149, abolished in nuclei assembled with membranes immunodepleted of AKAP149, and restored after reincorporation of AKAP149 into nuclear membranes. B-type lamins do not assemble into a lamina when NE targeting of PP1 is abolished, and is rescued upon recruitment of PP1 to the NE. We propose that kinase and phosphatase anchoring at the NE by AKAP149 plays in a role in modulating nuclear reassembly at the end of mitosis.     

The KH domains of Xenopus Vg1RBP mediate RNA binding and self-association

Xenopus Vg1 mRNA is localized to the vegetal cortex during oogenesis in a process involving microtubules and microfilaments and proteins that specifically recognize the vegetal localization element (VLE) within the 3' untranslated region. One of the best characterized VLE-binding proteins is Vg1RBP or Vera. Primary sequence analysis of Vg1RBP and its homologs suggests that most of its open reading frame is occupied by RNA-binding modules, including two RRMs and four KH domains, arranged as three pairs of didomains. In the first detailed domain analysis of Vg1RBP, we show that the interaction of Vg1RBP with the VLE requires both KH didomains, but not the RRM didomain, and moreover that the KH didomains contribute cooperatively to RNA binding. In the full-length protein, individual KH domains display significant redundancy, and their relative importance appears to vary with the RNA target. We also demonstrate that the KH34 didomain mediates Vg1RBP self-association, which is stabilized by RNA, and occurs in vivo as well as in vitro. Altogether, our findings highlight the importance of multiple KH domains in mediating RNA-protein and protein-protein interactions in the formation of a stable complex of Vg1RBP and Vg1 mRNA.     

Distinct contributions of KH domains to substrate binding affinity of Drosophila P-element somatic inhibitor protein

Drosophila P-element somatic inhibitor protein (PSI) regulates splicing of the P-element transposase pre-mRNA by binding a pseudo-splice site upstream of the authentic splice site using four tandem KH-type RNA binding motifs. While the binding domains and specificity of PSI have been established, little is known about the contributions of each PSI KH domain to overall protein stability and RNA binding affinity. Using a construct containing only the RNA binding domain of PSI (PSI-KH03), we introduced a physiologically relevant point mutation into each KH domain of PSI individually and measured stability and RNA binding affinity of the resulting mutant proteins. Although secondary structure, as measured by circular dichroism spectroscopy, is only subtly changed for each mutant protein relative to wild type, RNA binding affinity is reduced in each case. Mutations in the second or third KH domains of the protein are significantly more deleterious to substrate recognition than mutation of the outer (first and fourth) domains. These results show that despite the ability of a single KH domain to bind RNA in some systems, PSI requires multiple tandem KH domains for specific and high-affinity recognition of substrate RNA.     

Specific recognition of the C-rich strand of human telomeric DNA and the RNA template of human telomerase by the first KH domain of human poly(C)-binding protein-2

Poly(C)-binding proteins (PCBPs) constitute a family of nucleic acid-binding proteins that play important roles in a wide spectrum of regulatory mechanisms. The diverse functions of PCBPs are dependent on the ability of the PCBPs to recognize poly(C) sequences with high affinity and specificity. PCBPs contain three copies of KH (hnRNP K homology) domains, which are responsible for binding nucleic acids. We have determined the NMR structure of the first KH domain (KH1) from PCBP2. The PCBP2 KH1 domain adopts a structure with three alpha-helices packed against one side of a three-stranded antiparallel beta-sheet. Specific binding of PCBP2 KH1 to a number of poly(C) RNA and DNA sequences, including the C-rich strand of the human telomeric DNA repeat, the RNA template region of human telomerase, and regulatory recognition motifs in the poliovirus-1 5'-untranslated region, was established by monitoring chemical shift changes in protein (15)N-HSQC spectra. The nucleic acid binding groove was further mapped by chemical shift perturbation upon binding to a six-nucleotide human telomeric DNA. The binding groove is an alpha/beta platform formed by the juxtaposition of two alpha-helices, one beta-strand, and two flanking loops. Whereas there is a groove in common with all of the DNA and RNA binders with a hydrophobic floor accommodating a three-residue stretch of C residues, nuances in recognizing flanking residues are provided by hydrogen bonding partners in the KH domain. Specific interactions of PCBP2 KH1 with telomeric DNA and telomerase RNA suggest that PCBPs may participate in mechanisms involved in the regulation of telomere/telomerase functions.     

The RNA binding domains of the nuclear poly(A)-binding protein

The nuclear poly(A)-binding protein (PABPN1) is involved in the synthesis of the mRNA poly(A) tails in most eukaryotes. We report that the protein contains two RNA binding domains, a ribonucleoprotein-type RNA binding domain (RNP domain) located approximately in the middle of the protein sequence and an arginine-rich C-terminal domain. The C-terminal domain also promotes self-association of PABPN1 and moderately cooperative binding to RNA. Whereas the isolated RNP domain binds specifically to poly(A), the isolated C-terminal domain binds non-specifically to RNA and other polyanions. Despite this nonspecific RNA binding by the C-terminal domain, selection experiments show that adenosine residues throughout the entire minimal binding site of approximately 11 nucleotides are recognized specifically. UV-induced cross-links with oligo(A) carrying photoactivatable nucleotides at different positions all map to the RNP domain, suggesting that most or all of the base-specific contacts are made by the RNP domain, whereas the C-terminal domain may contribute nonspecific contacts, conceivably to the same nucleotides. Asymmetric dimethylation of 13 arginine residues in the C-terminal domain has no detectable influence on the interaction of the protein with RNA. The N-terminal domain of PABPN1 is not required for RNA binding but is essential for the stimulation of poly(A) polymerase.     

The translational regulation of lipoprotein lipase by epinephrine involves an RNA binding complex including the catalytic subunit of protein kinase A

The balance of lipid flux in adipocytes is controlled by the opposing actions of lipolysis and lipogenesis, which are controlled primarily by hormone-sensitive lipase and lipoprotein lipase (LPL), respectively. Catecholamines stimulate adipocyte lipolysis through reversible phosphorylation of hormone-sensitive lipase, and simultaneously inhibit LPL activity. However, LPL regulation is complex and previous studies have described translational regulation of LPL in response to catecholamines because of an RNA-binding protein that interacts with the 3'-untranslated region of LPL mRNA. In this study, we identified several protein components of an LPL RNA binding complex. Using an LPL RNA affinity column, we identified two of the RNA-binding proteins as the catalytic (C) subunit of cAMP-dependent protein kinase (PKA), and A kinase anchoring protein (AKAP) 121/149, one of the PKA anchoring proteins, which has known RNA binding activity. To determine whether the C subunit was involved in LPL translation inhibition, the C subunit was depleted from the cytoplasmic extract of epinephrine-stimulated adipocytes by immunoprecipitation. This resulted in the loss of LPL translation inhibition activity of the extract, along with decreased RNA binding activity in a gel shift assay. To demonstrate the importance of the AKAPs, inhibition of PKA-AKAP binding with a peptide competitor (HT31) prevented epinephrine-mediated inhibition of LPL translation. C subunit kinase activity was necessary for LPL RNA binding and translation inhibition, suggesting that the phosphorylation of AKAP121/149 or other proteins was an important part of RNA binding complex formation. The hormonal activation of PKA results in the reversible phosphorylation of hormone-sensitive lipase, which is the primary mediator of adipocyte lipolysis. These studies demonstrate a dual role for PKA to simultaneously inhibit LPL-mediated lipogenesis through inhibition of LPL translation.     

Domain architecture of a Caenorhabditis elegans AKAP suggests a novel AKAP function

A-kinase anchoring proteins (AKAPs) are adapter proteins that are involved in directing cAMP-dependent protein kinase and some other signaling enzymes to certain intracellular locations. In this study, we investigate the domain architecture of an AKAP from Caenorhabditis elegans (AKAP(CE)). We show that AKAP(CE) shares two domains with the Smad anchor for receptor activation, a FYVE-finger and a transforming growth factor beta (TGFbeta) receptor binding domain, suggesting that AKAP(CE) may interact with a receptor belonging to the TGFbeta receptor family. This predicted novel AKAP function supports the recent view of AKAPs as adapter proteins that can be involved in various signaling pathways.     

The structure of the C-terminal KH domains of KSRP reveals a noncanonical motif important for mRNA degradation

The AU-rich element (ARE) RNA-binding protein KSRP (K-homology splicing regulator protein) contains four KH domains and promotes the degradation of specific mRNAs that encode proteins with functions in cellular proliferation and inflammatory response. The fourth KH domain (KH4) is essential for mRNA recognition and decay but requires the third KH domain (KH3) for its function. We show that KH3 and KH4 behave as independent binding modules and can interact with different regions of the AU-rich RNA targets of KSRP. This provides KSRP with the structural flexibility needed to recognize a set of different targets in the context of their 3'UTR structural settings. Surprisingly, we find that KH4 binds to its target AREs with lower affinity than KH3 and that KSRP's mRNA binding, and mRNA degradation activities are closely associated with a conserved structural element of KH4.     

Dissociating the centrosomal matrix protein AKAP450 from centrioles impairs centriole duplication and cell cycle progression

Centrosomes provide docking sites for regulatory molecules involved in the control of the cell division cycle. The centrosomal matrix contains several proteins, which anchor kinases and phosphatases. The large A-Kinase Anchoring Protein AKAP450 is acting as a scaffolding protein for other components of the cell signaling machinery. We selectively perturbed the centrosome by modifying the cellular localization of AKAP450. We report that the expression in HeLa cells of the C terminus of AKAP450, which contains the centrosome-targeting domain of AKAP450 but not its coiled-coil domains or binding sites for signaling molecules, leads to the displacement of the endogenous centrosomal AKAP450 without removing centriolar or pericentrosomal components such as centrin, gamma-tubulin, or pericentrin. The centrosomal protein kinase A type II alpha was delocalized. We further show that this expression impairs cytokinesis and increases ploidy in HeLa cells, whereas it arrests diploid RPE1 fibroblasts in G1, thus further establishing a role of the centrosome in the regulation of the cell division cycle. Moreover, centriole duplication is interrupted. Our data show that the association between centrioles and the centrosomal matrix protein AKAP450 is critical for the integrity of the centrosome and for its reproduction.     

Dissecting FMR1, the protein responsible for fragile X syndrome, in its structural and functional domains.

FMR1 is an RNA-binding protein that is either absent or mutated in patients affected by the fragile X syndrome, the most common inherited cause of mental retardation in humans. Sequence analysis of the FMR1 protein has suggested that RNA binding is related to the presence of two K-homologous (KH) modules and an RGG box. However, no attempt has been so far made to map the RNA-binding sites along the protein sequence and to identify possible differential RNA-sequence specificity. In the present article, we describe work done to dissect FMR1 into regions with structurally and functionally distinct properties. A semirational approach was followed to identify four regions: an N-terminal stretch of 200 amino acids, the two KH regions, and a C-terminal stretch. Each region was produced as a recombinant protein, purified, and probed for its state of folding by spectroscopical techniques. Circular dichroism and NMR spectra of the N-terminus show formation of secondary structure with a strong tendency to aggregate. Of the two homologous KH motifs, only the first one is folded whereas the second remains unfolded even when it is extended both N- and C-terminally. The C-terminus is, as expected from its amino acid composition, nonglobular. Binding assays were then performed using the 4-nt homopolymers. Our results show that only the first KH domain but not the second binds to RNA, and provide the first direct evidence for RNA binding of both the N-terminal and the C-terminal regions. RNA binding for the N-terminus could not be predicted from sequence analysis because no known RNA-binding motif is identifiable in this region. Different sequence specificity was observed for the fragments: both the N-terminus of the protein and KH1 bind preferentially to poly-(rG). The C-terminal region, which contains the RGG box, is nonspecific, as it recognizes the bases with comparable affinity. We therefore conclude that FMR1 is a protein with multiple sites of interaction with RNA: sequence specificity is most likely achieved by the whole block that comprises the first approximately 400 residues, whereas the C-terminus provides a nonspecific binding surface.     

The Tudor tandem of 53BP1: a new structural motif involved in DNA and RG-rich peptide binding

53BP1 is a key transducer of the DNA damage checkpoint signal, which is required for phosphorylation of a subset of ATM substrates and p53 accumulation. After cell irradiation, the 53BP1 N-terminal region is phosphorylated. Its two C-terminal BRCT motifs interact with p53. Its central region is required and sufficient for 53BP1 foci formation at DNA strand breaks and for 53BP1 binding to the kinetochore. It contains an RG-rich segment and interacts with DNA in vitro. Here we show that the major globular domain of the 53BP1 central region adopts a new structural motif composed of two tightly packed Tudor domains and a C-terminal alpha helix. A unique surface essentially located on the first Tudor domain is involved in the binding to 53BP1 RG-rich sequence and to DNA, suggesting that the Tudor tandem can act as an adaptor mediating intramolecular as well as intermolecular protein-protein interactions and protein-nucleic acid associations.