Ubiquitin chains in the Dsk2 UBL domain mediate Dsk2 stability and protein degradation in yeast

Ubiquitin-like (UBL)–ubiquitin-associated (UBA) proteins, including Dsk2 and Rad23, act as delivery factors that target polyubiquitinated substrates to the proteasome. We report here that the Dsk2 UBL domain is ubiquitinated in yeast cells and that Dsk2 ubiquitination of the UBL domain is involved in Dsk2 stability, depending on the Dsk2 UBA domain. Also, Dsk2 lacking ubiquitin chains impaired ubiquitin-dependent protein degradation and decreased the interaction of Dsk2 with polyubiquitinated proteins in cells. Moreover, Dsk2 ubiquitination affected ability to restore the temperature-sensitive growth defect of dsk2Δ. These results indicate that ubiquitination in the UBL domain of Dsk2 has in vivo functions in the ubiquitin–proteasome pathway in yeast.     

Identification of a novel protein, PriB, in Klebsiella pneumoniae

PriB is a primosomal protein required for the reinitiation of replication in bacteria. Here, we report the identification and characterization of a novel PriB protein in Klebsiella pneumoniae (KPN_04595; KpPriB). Unlike the well-studied Escherichia coli PriB protein (EcPriB), which exists as a homodimer comprising 104-aa polypeptides, KpPriB forms a monomer of only 55 aa, due to the absence of the 49 aa N-terminus in KpPriB. Although this N-terminal region (1–49 aa) in EcPriB contains several important residues, such as K18, R34, and W47, which are crucial for ssDNA binding, we found that KpPriB binds ssDNA, but not ssRNA, with comparable affinity as that for EcPriB. Results from filter-binding assays demonstrate that the KpPriB–ssDNA interaction is cooperative and salt-sensitive. Substituting the residue K33 in KpPriB with alanine, the position corresponding to the classic ssDNA-binding residue K82 of EcPriB located in loop L₄₅, significantly reduced ssDNA-binding activity and cooperativity. These results reveal that the 1–49 aa region of the classical PriB protein is unnecessary for ssDNA binding. On the basis of these findings, the structure–function relationships of KpPriB are discussed.     

Extrusion of the C-terminal helix in navel orangeworm moth pheromone-binding protein (AtraPBP1) controls pheromone binding

The navel orangeworm, Amyelois transitella (Walker), is an agricultural insect pest that can be controlled by disrupting male–female communication with sex pheromones, a technique known as mating disruption. Insect pheromone-binding proteins (PBPs) provide fast transport of hydrophobic pheromones through aqueous sensillar lymph and promote sensitive delivery of pheromones to receptors. Here we present a mutational analysis on a PBP from A. transitella (AtraPBP1) to evaluate how the C-terminal helix in this protein controls pheromone binding as a function of pH. Pheromone binds tightly to AtraPBP1 at neutral pH, but the binding is much weaker at pH below 5. Deletion of the entire C-terminal helix (residues 129–142) causes more than 100-fold increase in pheromone-binding affinity at pH 5 and only a 1.5-fold increase at pH 7. A similar pH-dependent increase in pheromone binding is also seen for the H80A/H95A double mutant that promotes extrusion of the C-terminal helix by disabling salt bridges at each end of the helix. The single mutants (H80A and H95A) also exhibit pheromone binding at pH below 5, but with ∼2-fold weaker affinity. NMR and circular dichroism data demonstrate a large overall structural change in each of these mutants at pH 4.5, indicating an extrusion of the C-terminal helix that profoundly affects the overall structure of the low pH form. Our results confirm that sequestration of the C-terminal helix at low pH as seen in the recent NMR structure may serve to block pheromone binding. We propose that extrusion of these C-terminal residues at neutral pH (or by the mutations in this study) exposes a hydrophobic cleft that promotes high affinity pheromone binding.     

Ferric ions inhibit proteolytic processing of progastrin

The gastrointestinal hormone gastrin is generated from an 80 amino acid precursor (progastrin) by cleavage after dibasic residues by prohormone convertase 1. Phosphorylation of Ser₇₅ has previously been suggested, on the basis of indirect evidence, to inhibit cleavage of progastrin after Arg₇₃Arg₇₄. Gastrins bind two ferric ions with high affinity, and iron binding is essential for the biological activity of non-amidated gastrins in vitro and in vivo. This study directly investigated the effect of iron binding and of serine phosphorylation on the cleavage of synthetic progastrin-derived peptides. The affinity of synthetic progastrin_55–80 for ferric ions, and the rate of cleavage by prohormone convertase 1, were not affected by phosphorylation of Ser₇₅. In contrast, in the presence of ferric ions the rate of cleavage of both progastrin_55–80 and phosphoSer₇₅progastrin_55–80 by prohormone convertase 1 was significantly reduced. Hence iron binding to progastrin may regulate processing and secretion in vivo, and regulation may be particularly important in diseases with altered iron homeostasis.     

Smad3 contributes to positioning of proliferating cells in colonic crypts by inducing EphB receptor protein expression

In prion diseases cellular prion protein (PrP^C) undergoes conformational transition into the β-sheet-rich form (PrP^Sc). PrP^C consists of the disordered N-terminal part and a C-terminal globular domain containing three α-helices (H1, H2, H3) and an antiparallel beta sheet (B1, B2). B2–H2 loop, which has a focal role in the species barrier, contains the highest density of asparagine (N) and glutamine (Q) residues in the whole sequence. Q/N-rich domains are essential for the conversion of yeast prions. We investigated the role of Q/N residues in the B2–H2 loop in PrP conversion. We prepared mouse PrP mutants with increasing number of consecutive Q/N residues in the B2–H2 loop. Stability of the mutants decreased with the increasing number of inserted glutamines. In vitro conversion of mutants yielded fibrils of similar morphology as the wild-type PrP. Q/N mutants accelerated fibrillization in comparison to the wild-type PrP, with mutant containing the most glutamines having the shortest lag phase. The effect of Q/N residues was specific for the B2–H2 loop and was not due to simple increase in flexibility as the introduction of Gly-Ser or Ala residues slowed the conversion despite their decreased stability. Our results thus suggest that Q/N residues in the B2–H2 loop of PrP promote protein conversion and may represent a link to conversion of Q/N-rich prions.     

Structural modeling of RNase P RNA of the hyperthermophilic archaeon Pyrococcus horikoshii OT3

Ribonuclease P (RNase P) is a ubiquitous trans-acting ribozyme that processes the 5′ leader sequence of precursor tRNA (pre-tRNA). The RNase P RNA (PhopRNA) of the hyperthermophilic archaeon Pyrococcus horikoshii OT3 is central to the catalytic process and binds five proteins (PhoPop5, PhoRpp21, PhoRpp29, PhoRpp30, and PhoRpp38) which contribute to the enzymatic activity of the holoenzyme. Despite significant progress in determining the crystal structure of the proteins, the structure of PhopRNA remains elusive. Comparative analysis of the RNase P RNA sequences and existing crystallographic structural information of the bacterial RNase P RNAs were combined to generate a phylogenetically supported three-dimensional (3-D) model of the PhopRNA. The model structure shows an essentially flat disk with 16 tightly packed helices and a conserved face suitable for the binding of pre-tRNA. Moreover, the structure in solution was investigated by enzymatic probing and small-angle X-ray scattering (SAXS) analysis. The low resolution model derived from SAXS and the comparative 3-D model have similar overall shapes. The 3-D model provides a framework for a better understanding of structure–function relationships of this multifaceted primordial ribozyme.     

The ASB2β Ubiquitin-interacting motif is involved in its monoubiquitination

ASB2 proteins are E3 ubiquitin (Ub) ligases that ubiquitinate filamins. There are two ASB2 splice variants, ASB2α and ASB2β. ASB2β has a ubiquitin-binding motif (UIM) at the N-terminal region but ASB2α does not. Here, we provide the first evidence that ASB2β but not ASB2α is monoubiquitinated and that this monoubiquitination involves the UIM. Myc-tagged ASB2β and hemagglutinin (HA)-tagged Ub were co-expressed in HEK293 cells using the pCMV expression vector. Immunoprecipitation with an anti-Myc antibody followed by immunoblotting with anti-Myc and anti-HA antibodies showed an additional ASB2β protein band that had both a Myc and a HA tag. The molecular weight of this protein was larger than that of ASB2β, and the difference in molecular weight between these two proteins corresponded to the molecular weight of monoubiquitin, strongly implying that monoubiquitinated ASB2β is produced in cells. ASB2β with mutations in the UIM motif; either Glu·Asp·Glu27-29Ala·Ala·Ala mutations (ASB2β M1) or a Ser38Ala mutation, (ASB2β M2) were not monoubiquitinated, suggesting the importance of the UIM for ASB2β monoubiquitination. Furthermore, an ASB2β mutant that lacked a SOCS box (ASB2β ΔC) and did not show E3 Ub ligase activity was monoubiquitinated to the same extent as the wild-type ASB2β. In contrast, an ASB2β mutant that lacked the UIM-containing domain (ASB2β ΔN) was not monoubiquitinated. These results suggest that ASB2β but not ASB2α might be monoubiquitinated and that the ASB2β UIM motif, but not its E3 Ub ligase activity, plays a pivotal role in this monoubiquitination.     

Killer-toxin-resistantkre12 mutants ofSaccharomyces cerevisiae: genetic and biochemical evidence for a secondary K1 membrane receptor

TheSaccharomyces cerevisiae killer toxin K1 is a secreted α/β-heterodimeric protein toxin that kills sensitive yeast cells in a receptor-mediated two-stage process. The first step involves toxin binding to β-1,6-d-glucan-components of the outer yeast cell surface; this step is blocked in yeast mutants bearing nuclear mutations in any of theKRE genes whose products are involved in synthesis and/or assembly of cell wall β-d-glucans. After binding to the yeast cell wall, the killer toxin is transferred to the cytoplasmic membrane, subsequently leading to cell death by forming lethal ion channels. In an attempt to identify a secondary K1 toxin receptor at the plasma membrane level, we mutagenized sensitive yeast strains and isolated killer-resistant (kre) mutants that were resistant as spheroplasts. Classical yeast genetics and successive back-crossings to sensitive wild-type strain indicated that this toxin resistance is due to mutation(s) in a single chromosomal yeast gene (KRE12), renderingkrel2 mutants incapable of binding significant amounts of toxin to the membrane. Sincekrel2 mutants showed normal toxin binding to the cell wall, but markedly reduced membrane binding, we isolated and purified cytoplasmic membranes from akrel2 mutant and from an isogenicKre12+ strain and analyzed the membrane protein patterns by 2D-electrophoresis using a combination of isoelectric focusing and SDS-PAGE. Using this technique, three different proteins (or subunits of a single multimeric protein) were identified that were present in much lower amounts in thekre12 mutant. A model for K1 killer toxin action is presented in which the gene product ofKRE12 functions in vivo as a K1 docking protein, facilitating toxin binding to the membrane and subsequent ion channel formation.     

Importin β-type nuclear transport receptors have distinct binding affinities for Ran-GTP

Cargos destined to enter or leave the cell nucleus are typically transported by receptors of the importin β family to pass the nuclear pore complex. The yeast Saccharomyces cerevisiae comprises 14 members of this protein family, which can be divided in importins and exportins. The Ran GTPase regulates the association and dissociation of receptors and cargos as well as the transport direction through the nuclear pore. All receptors bind to Ran exclusively in its GTP-bound state and this event is restricted to the nuclear compartment. We determined the Ran–GTP binding properties of all yeast transport receptors by biosensor measurements and observed that the affinity of importins for Ran–GTP differs significantly. The dissociation constants range from 230 pM to 270 nM, which is mostly based on a variability of the off-rate constants. The divergent affinity of importins for Ran–GTP suggests the existence of a novel mode of nucleocytoplasmic transport regulation. Furthermore, the cellular concentration of β-receptors and of other Ran-binding proteins was determined. We found that the number of β-receptors altogether about equals the amounts of yeast Ran, but Ran–GTP is not limiting in the nucleus. The implications of our results for nucleocytoplasmic transport mechanisms are discussed.     

VHS domains of ESCRT‐0 cooperate in high‐avidity binding to polyubiquitinated cargo

VHS (Vps27, Hrs, and STAM) domains occur in ESCRT‐0 subunits Hrs and STAM, GGA adapters, and other trafficking proteins. The structure of the STAM VHS domain–ubiquitin complex was solved at 2.6 Å resolution, revealing that determinants for ubiquitin recognition are conserved in nearly all VHS domains. VHS domains from all classes of VHS‐domain containing proteins in yeast and humans, including both subunits of ESCRT‐0, bound ubiquitin in vitro. ESCRTs have been implicated in the sorting of Lys63‐linked polyubiquitinated cargo. Intact human ESCRT‐0 binds Lys63‐linked tetraubiquitin 50‐fold more tightly than monoubiquitin, though only 2‐fold more tightly than Lys48‐linked tetraubiquitin. The gain in affinity is attributed to the cooperation of flexibly connected VHS and UIM motifs of ESCRT‐0 in avid binding to the polyubiquitin chain. Mutational analysis of all the five ubiquitin‐binding sites in yeast ESCRT‐0 shows that cooperation between them is required for the sorting of the Lys63‐linked polyubiquitinated cargo Cps1 to the vacuole.     

Solution structure of UIM and interaction of tandem ubiquitin binding domains in STAM1 with ubiquitin

STAM1 and Hrs are the components of ESCRT-0 complex for lysosomal degradation of membrane proteins is composed of STAM1 Hrs and has multiple ubiquitin binding domains. Here, the solution structure of STAM1 UIM, one of the ubiquitin binding motif, was determined by NMR spectroscopy. The structure of UIM adopts an α-helix with amphipathic nature. The central hydrophobic residues in UIM provides the binding surface for ubiquitin binding and are flanked with positively and negatively charged residues on both sides. The docking model of STAM1 UIM-ubiquitin complex is suggested. In NMR and ITC experiments with the specifically designed mutant proteins, we investigated the ubiquitin interaction of tandem ubiquitin binding domains from STAM1. The ubiquitin binding affinity of the VHS domain and UIM in STAM1 was 52.4 and 94.9 μM, and 1.5 and 2.2 fold increased, respectively, than the value obtained from the isolated domain or peptide. The binding affinities here would be more physiologically relevant and provide more precise understanding in ESCRT pathway of lysosomal degradation.     

Purification and characterization of Plasmodium yoelii adenosine deaminase

Plasmodium lacks the de novo pathway for purine biosynthesis and relies exclusively on the salvage pathway. Adenosine deaminase (ADA), first enzyme of the pathway, was purified and characterized from Plasmodium yoelii, a rodent malarial species, using ion exchange and gel exclusion chromatography. The purified enzyme is a 41 kDa monomer. The enzyme showed K_m values of 41 μM and 34 μM for adenosine and 2′-deoxyadenosine, respectively. Erythro-9-(2-hydroxy-3-nonyl) adenine competitively inhibited P. yoelii ADA with K_i value of 0.5 μM. The enzyme was inhibited by DEPC and protein denaturing agents, urea and GdmCl. Purine analogues significantly inhibited ADA activity. Inhibition by p-chloromercuribenzoate (pCMB) and N-ethylmaleimide (NEM) indicated the presence of functional –SH groups. Tryptophan fluorescence maxima of ADA shifted from 339 nm to 357 nm in presence of GdmCl. Refolding studies showed that higher GdmCl concentration irreversibly denatured the purified ADA. Fluorescence quenchers (KI and acrylamide) quenched the ADA fluorescence intensity to the varied degree. The observed differences in kinetic properties of P. yoelii ADA as compared to the erythrocyte enzyme may facilitate in designing specific inhibitors against ADA.     

Regulation of the xylanase gene, cgxA, from Chaetomium gracile by transcriptional factors, XlnR and AnRP

The roles of XlnR and AnRP in regulating the expression of the xylanase gene, cgxA, from Chaetomium gracile were investigated using Aspergillus nidulansas an intermediate host. The XlnR consensus binding sequence –GGCTAA– in the promoter region was functional in vivo. The cgxA gene was induced when xylan was used as a carbon source but this inducibility was abolished when the XlnR binding sequence was mutated. Furthermore, the induction by xylan was increased when the AnRP binding sequence –TTGACAAAT– was mutated. Electrophoretic mobility shift assays using partially purified AnRP and an Aspergillus oryzae XlnR fusion protein, MalE-AoXlnR, provided evidence that the binding of the two proteins to their respective sites in the cgxA promoter region was mutually exclusive.     

Characterization of the CaMKKβ-AMPK signaling complex

The AMP-activated protein kinase (AMPK) is a critical regulator of energy homeostasis, and is a potential target for treatment of metabolic diseases as well as cancer. AMPK can be phosphorylated and activated by the tumor suppressor LKB1 or the Ca²⁺/CaM-dependent protein kinase kinase β (CaMKKβ). We previously identified a physical complex between CaMKKβ and AMPK (Anderson, K. A., Ribar, T. J., Lin, F., Noeldner, P. K., Green, M. F., Muehlbauer, M. J., Witters, L. A., Kemp, B. E., and Means, A. R. (2008) Cell Metabolism 7, 377–388). Here we expand our analysis of the CaMKKβ–AMPK signaling complex and show that whereas CaMKKβ can form a complex with and activate AMPK, CaMKKα cannot. In addition, we show that CaMKKβ and AMPK associate through their kinase domains, and CaMKKβ must be in an active conformation in order to bind AMPK but not to associate with an alternative substrate, Ca²⁺/Calmodulin-dependent protein kinase IV (CaMKIV). Our results demonstrate that CaMKKβ and AMPK form a unique signaling complex. This raises the possibility that the CaMKKβ–AMPK complex can be specifically targeted by small molecule drugs to treat disease.     

ASB proteins interact with Cullin5 and Rbx2 to form E3 ubiquitin ligase complexes

The ankyrin repeat and SOCS box (ASB) family is composed of 18 proteins from ASB1 to ASB18 and belongs to the suppressor of cytokine signaling (SOCS) box protein superfamily. ASB2 was recently shown to interact with a certain Cul-Rbx module to form an E3 ubiquitin (Ub) ligase complex, but the functional composition of the ASB-containing E3 Ub ligase complexes remains to be characterized. Here, we show that ASB proteins interact with Cul5-Rbx2 but neither Cul2 nor Rbx1 in cells. Mutational analysis revealed that the highly conserved amino acid sequences of the BC box and Cul5 box in the SOCS box of ASB proteins were essential for the interaction with Cul5-Rbx2. Although ASB proteins show slight divergences from the consensus sequences of the BC box and Cul5 box, all five tested ASB proteins bound to Cul5-Rbx2. Furthermore, all three tested ASB complexes containing Cul5-Rbx2 were found to have E3 Ub ligase activity. These findings suggest that the ASB family proteins interact with Cul5-Rbx2 to form E3 Ub ligases and play significant roles via a ubiquitination-mediated pathway.     

High mannose-specific lectin (KAA-2) from the red alga Kappaphycus alvarezii potently inhibits influenza virus infection in a strain-independent manner

The carbohydrate binding profile of the red algal lectin KAA-2 from Kappaphycus alvarezii was evaluated by a centrifugal ultrafiltration–HPLC method using pyridylaminated oligosaccharides. KAA-2 bound exclusively to high mannose type N-glycans, but not to other glycans such as complex type, hybrid type, or the pentasaccharide core of N-glycans. This lectin exhibited a preference for an exposed α1–3 Man on a D2 arm in a similar manner to Eucheuma serra agglutinin (ESA-2), which shows various biological activities, such as anti-HIV and anti-carcinogenic activity. We tested the anti-influenza virus activity of KAA-2 against various strains including the recent pandemic H1N1-2009 influenza virus. KAA-2 inhibited infection of various influenza strains with EC₅₀s of low nanomolar levels. Immunofluorescence microscopy using an anti-influenza antibody demonstrated that the antiviral activity of KAA-2 was exerted by interference with virus entry into host cells. This mechanism was further confirmed by the evidence of direct binding of KAA-2 to a viral envelope protein, hemagglutinin (HA), using an ELISA assay. These results indicate that this lectin would be useful as a novel antiviral reagent for the prevention of infection.     

Structural basis for specific recognition of Lys 63‐linked polyubiquitin chains by tandem UIMs of RAP80

RAP80 has a key role in the recruitment of the Abraxas–BRCC36–BRCA1–BARD1 complex to DNA‐damage foci for DNA repair through specific recognition of Lys 63‐linked polyubiquitinated proteins by its tandem ubiquitin‐interacting motifs (UIMs). Here, we report the crystal structure of the RAP80 tandem UIMs (RAP80‐UIM1‐UIM2) in complex with Lys 63‐linked di‐ubiquitin at 2.2 Å resolution. The two UIMs, UIM1 and UIM2, and the α‐helical inter‐UIM region together form a continuous 60 Å‐long α‐helix. UIM1 and UIM2 bind to the proximal and distal ubiquitin moieties, respectively. Both UIM1 and UIM2 of RAP80 recognize an Ile 44‐centered hydrophobic patch on ubiquitin but neither UIM interacts with the Lys 63‐linked isopeptide bond. Our structure suggests that the inter‐UIM region forms a 12 Å‐long α‐helix that ensures that the UIMs are arranged to enable specific binding of Lys 63‐linked di‐ubiquitin. This was confirmed by pull‐down analyses using RAP80‐UIM1‐UIM2 mutants of various length inter‐UIM regions. Further, we show that the Epsin1 tandem UIM, which has an inter‐UIM region similar to that of RAP80‐UIM1‐UIM2, also selectively binds Lys 63‐linked di‐ubiquitin.     

DNA sequence analysis of the lamB gene from Klebsiella pneumoniae: implications for the topology and the pore functions in maltoporin.

Summary We have determined the sequence of the lamB gene from Klebsiella pneumoniae. It encodes the precursor to the LamB protein, a 429 amino acid polypeptide with maltoporin function. Comparison with the Escherichia coli LamB protein reveals a high degree of homology, with 325 residues strictly identical. The N-terminal third of the protein is the most conserved part of the molecule (1 change in the signal sequence, and 13 changes up to residue 146 of the mature protein). Differences between the two mature proteins are clustered mainly in six regions comprising residues 145–167, 173–187, 197–226, 237–300, 311–329, and 367–387 (K. pneumoniae LamB sequence). The most important changes were found in regions predicted by the two-dimensional model of LamB folding to form loops on the cell surface. In vivo maltose and maltodextrin transport properties of E. coli K 12 and K. pneumoniae strains were identical. However, none of the E. coli K12 LamB-specific phages was able to plaque onto K. pneumoniae. Native K. pneumoniae LamB protein forms highly stable trimers. The protein could be purified by affinity chromatography on starch-Sepharose as efficiently as the E. coli K12 LamB protein, indicating a conservation of the binding site for dextrins. However, none of the monoclonal antibodies directed against native E. coli K12 LamB protein recognized native purified K. pneumoniae LamB protein. These data indicate that most of the variability occurs within exposed regions of the protein and provide additional support for the proposed model of LamB folding. The fact that the N-terminal third of the protein is highly conserved is in agreement with the idea that it is part of, or constitutes, the pore domain located within the transmembranous channel and that it is not accessible from the cell surface.