The Archaeal Topoisomerase Reverse Gyrase Is a Helix-destabilizing Protein That Unwinds Four-way DNA Junctions

Four-way junctions are non-B DNA structures that originate as intermediates of recombination and repair (Holliday junctions) or from the intrastrand annealing of palindromic sequences (cruciforms). These structures have important functional roles but may also severely interfere with DNA replication and other genetic processes; therefore, they are targeted by regulatory and architectural proteins, and dedicated pathways exist for their removal. Although it is well known that resolution of Holliday junctions occurs either by recombinases or by specialized helicases, less is known on the mechanisms dealing with secondary structures in nucleic acids. Reverse gyrase is a DNA topoisomerase, specific to microorganisms living at high temperatures, which comprises a type IA topoisomerase fused to an SF2 helicase-like module and catalyzes ATP hydrolysis-dependent DNA positive supercoiling. Reverse gyrase is likely involved in regulation of DNA structure and stability and might also participate in the cell response to DNA damage. By applying FRET technology to multiplex fluorophore gel imaging, we show here that reverse gyrase induces unwinding of synthetic four-way junctions as well as forked DNA substrates, following a mechanism independent of both the ATPase and the strand-cutting activity of the enzyme. The reaction requires high temperature and saturating protein concentrations. Our results suggest that reverse gyrase works like an ATP-independent helix-destabilizing protein specific for branched DNA structures. The results are discussed in light of reverse gyrase function and their general relevance for protein-mediated unwinding of complex DNA structures.     

The Full-length Saccharomyces cerevisiae Sgs1 Protein Is a Vigorous DNA Helicase That Preferentially Unwinds Holliday Junctions

The highly conserved RecQ family of DNA helicases has multiple roles in the maintenance of genome stability. Sgs1, the single RecQ homologue in Saccharomyces cerevisiae, acts both early and late during homologous recombination. Here we present the expression, purification, and biochemical analysis of full-length Sgs1. Unlike the truncated form of Sgs1 characterized previously, full-length Sgs1 binds diverse single-stranded and double-stranded DNA substrates, including DNA duplexes with 5′- and 3′-single-stranded DNA overhangs. Similarly, Sgs1 unwinds a variety of DNA substrates, including blunt-ended duplex DNA. Significantly, a substrate containing a Holliday junction is unwound most efficiently. DNA unwinding is catalytic, requires ATP, and is stimulated by replication protein A. Unlike RecQ homologues from multicellular organisms, Sgs1 is remarkably active at picomolar concentrations and can efficiently unwind duplex DNA molecules as long as 23,000 base pairs. Our analysis shows that Sgs1 resembles Escherichia coli RecQ protein more than any of the human RecQ homologues with regard to its helicase activity. The full-length recombinant protein will be invaluable for further investigation of Sgs1 biochemistry.     

Identification of Proteassemblin,a Mammalian Homologue of the Yeast Protein,Ump1p,That Is Required for Normal Proteasome Assembly

We have identified a mammalian homologue of yeast Ump1p by searching for similar proteins in human and mouse expressed sequence tag (EST) databases. Ump1p is an accessory protein that is required for normal proteasome assembly in yeast (1). A mammalian homologue, which we refer to as “proteassemblin,” is a constituent of proteasome assembly intermediates (preproteasomes), but not fully assembled 20S proteasomes, as is Ump1p in yeast. We also provide evidence that proteassemblin is a constituent of pre-immunoproteasomes that contain the precursor of the interferon-γ-inducible subunit LMP2. By analogy with Ump1p, we hypothesize that proteassemblin is required for normal mammalian proteasome assembly.     

The Membrane Protein Alkaline Phosphatase Is Delivered to the Vacuole by a Route That Is Distinct from the VPS-dependent Pathway

Membrane trafficking intermediates involved in the transport of proteins between the TGN and the lysosome-like vacuole in the yeast Saccharomyces cerevisiae can be accumulated in various vps mutants. Loss of function of Vps45p, an Sec1p-like protein required for the fusion of Golgi-derived transport vesicles with the prevacuolar/endosomal compartment (PVC), results in an accumulation of post-Golgi transport vesicles. Similarly, loss of VPS27 function results in an accumulation of the PVC since this gene is required for traffic out of this compartment.

The vacuolar ATPase subunit Vph1p transits to the vacuole in the Golgi-derived transport vesicles, as defined by mutations in VPS45, and through the PVC, as defined by mutations in VPS27. In this study we demonstrate that, whereas VPS45 and VPS27 are required for the vacuolar delivery of several membrane proteins, the vacuolar membrane protein alkaline phosphatase (ALP) reaches its final destination without the function of these two genes. Using a series of ALP derivatives, we find that the information to specify the entry of ALP into this alternative pathway to the vacuole is contained within its cytosolic tail, in the 13 residues adjacent to the transmembrane domain, and loss of this sorting determinant results in a protein that follows the VPS-dependent pathway to the vacuole.

Using a combination of immunofluorescence localization and pulse/chase immunoprecipitation analysis, we demonstrate that, in addition to ALP, the vacuolar syntaxin Vam3p also follows this VPS45/27-independent pathway to the vacuole. In addition, the function of Vam3p is required for membrane traffic along the VPS-independent pathway.

     

Bin2 Is a Membrane Sculpting N-BAR Protein That Influences Leucocyte Podosomes,Motility and Phagocytosis

Cell motility, adhesion and phagocytosis are controlled by actin and membrane remodelling processes. Bridging integrator-2 (Bin2) also called Breast cancer-associated protein 1 (BRAP1) is a predicted N-BAR domain containing protein with unknown function that is highly expressed in leucocytic cells. In the present study we solved the structure of Bin2 BAR domain and studied its membrane binding and bending properties in vitro and in vivo. Live-cell imaging experiments showed that Bin2 is associated with actin rich structures on the plasma membrane, where it was targeted through its N-BAR domain. Pull-down experiments and immunoprecipitations showed that Bin2 C-terminus bound SH3 domain containing proteins such as Endophilin A2 and α-PIX. siRNA of endogenous protein led to decreased cell migration, increased phagocytosis and reduced podosome density and dynamics. In contrast, overexpression of Bin2 led to decreased phagocytosis and increased podosome density and dynamics. We conclude that Bin2 is a membrane-sculpting protein that influences podosome formation, motility and phagocytosis in leucocytes. Further understanding of this protein may be key to understand the behaviour of leucocytes under physiological and pathological conditions.     

The 13-kD FK506 Binding Protein, FKBP13, Interacts with a Novel Homologue of the Erythrocyte Membrane Cytoskeletal Protein 4.1

We have identified a novel generally expressed homologue of the erythrocyte membrane cytoskeletal protein 4.1, named 4.1G, based on the interaction of its COOH-terminal domain (CTD) with the immunophilin FKBP13. The 129-amino acid peptide, designated 4.1G–CTD, is the first known physiologic binding target of FKBP13. FKBP13 is a 13-kD protein originally identified by its high affinity binding to the immunosuppressant drugs FK506 and rapamycin (Jin, Y., M.W. Albers, W.S. Lane, B.E. Bierer, and S.J. Burakoff. 1991. Proc. Natl. Acad. Sci. USA. 88:6677– 6681); it is a membrane-associated protein thought to function as an ER chaperone (Bush, K.T., B.A. Henrickson, and S.K. Nigam. 1994. Biochem. J. [Tokyo]. 303:705–708). We report the specific association of FKBP13 with 4.1G–CTD based on yeast two-hybrid, in vitro binding and coimmunoprecipitation experiments. The histidyl-proline moiety of 4.1G–CTD is required for FKBP13 binding, as indicated by yeast experiments with truncated and mutated 4.1G–CTD constructs. In situ hybridization studies reveal cellular colocalizations for FKBP13 and 4.1G–CTD throughout the body during development, supporting a physiologic role for the interaction. Interestingly, FKBP13 cofractionates with the red blood cell homologue of 4.1 (4.1R) in ghosts, inside-out vesicles, and Triton shell preparations. The identification of FKBP13 in erythrocytes, which lack ER, suggests that FKBP13 may additionally function as a component of membrane cytoskeletal scaffolds.     

The Vaccinia Virus Superoxide Dismutase-Like Protein (A45R) Is a Virion Component That Is Nonessential for Virus Replication

A characterization of the A45R gene from vaccinia virus (VV) strain Western Reserve is presented. The open reading frame is predicted to encode a 125-amino-acid protein (M(r), of 13,600) with 39% amino acid identity to copper-zinc superoxide dismutase (Cu-Zn SOD). Sequencing of the A45R gene from other orthopoxviruses, here and by others, showed that the protein is highly conserved in all viruses sequenced, including 16 strains of VV, 2 strains of cowpox virus, camelpox virus, and 4 strains of variola virus. In all cases the protein lacks key residues involved in metal ion binding that are important for the catalytic activity. The A45R protein was expressed in Escherichia coli, purified, and tested for SOD activity, but neither enzymatic nor inhibitory SOD activity was detected. Additionally, no virus-encoded SOD activity was detected in infected cells or purified virions. A monoclonal antibody raised against the A45R protein expressed in E. coli identified the A45R gene product as a 13.5-kDa protein that is expressed late during VV infection. Confocal microscopy of VV-infected cells indicated that the A45R protein accumulated predominantly in cytoplasmic viral factories. Electron microscopy and biochemical analyses showed that the A45R protein is incorporated into the virion core. A deletion mutant lacking the majority of the A45R gene and a revertant virus in which the deleted gene was restored were constructed and characterized. The growth properties of the deletion mutant virus were indistinguishable from those of wild-type and revertant viruses in all cell lines tested, including macrophages. Additionally, the virulence and pathogenicity of the three viruses were also comparable in murine and rabbit models of infection. A45R is unusual in being the first VV core protein described that affects neither virus replication nor virulence.     

Characterization of a Calcium-Dependent Protein Kinase of Tobacco Leaves That Is Associated with the Plasma Membrane and Is Inducible by Sucrose

The plasma membrane fraction from leaves of tobacco containsa 54-kDa protein with autophosphorylation activity, and thelevel of this protein increases after feeding of leaves withsucrose [Ohto and Nakamura (1995) Plant Physiol. 109: 973].The 54-kDa autophosphorylation protein could not be releasedfrom the plasma membrane by treatment with salt or alkali butcould be efficiently solubi-lized by 1% sodium deoxycholate(NaDOC). Ion-exchange chromatography of the NaDOC-solubilizedproteins in the presence of octylglucoside separated the 54-kDaautophosphorylation protein into three peaks. The autophosphorylationactivity of the 54-kDa protein in peaks I and II increased afterfeeding of leaves with sucrose. The 54-kDa protein in the peakII fraction was enriched about 125-fold starting from the microsomalmembrane fraction. The 54-kDa protein in this fraction phosphorylatedhistone HIS in a calcium-dependent manner and cross-reactedwith an antibody against a calcium-dependent protein kinase(CDPK) of Arabidopsis thaliana. These results suggest that the54-kDa protein in the peak II fraction is a novel isoform ofCDPK which is associated with the plasma membrane and is inducibleby sucrose. (Received September 29, 1997; Accepted September 1, 1998)     

The mdoC Gene of Escherichia coli Encodes a Membrane Protein That Is Required for Succinylation of Osmoregulated Periplasmic Glucans

Osmoregulated periplasmic glucans (OPGs) of Escherichia coli are anionic oligosaccharides that accumulate in the periplasmic space in response to low osmolarity of the medium. Their anionic character is provided by the substitution of the glucosidic backbone by phosphoglycerol originating from the membrane phospholipids and by succinyl residues from unknown origin. A phosphoglycerol-transferase-deficient mdoB mutant was subjected to Tn5 transposon mutagenesis, and putative mutant clones were screened for changes in the anionic character of OPGs by thin-layer chromatography. One mutant deficient in succinylation of OPGs was obtained, and the gene inactivated in this mutant was characterized and named mdoC. mdoC, which encodes a membrane-bound protein, is closely linked to the mdoGH operon necessary for the synthesis of the OPG backbone.     

Cag3 Is a Novel Essential Component of the Helicobacter pylori Cag Type IV Secretion System Outer Membrane Subcomplex

Helicobacter pylori strains harboring the cag pathogenicity island (PAI) have been associated with more severe gastric disease in infected humans. The cag PAI encodes a type IV secretion (T4S) system required for CagA translocation into host cells as well as induction of proinflammatory cytokines, such as interleukin-8 (IL-8). cag PAI genes sharing sequence similarity with T4S components from other bacteria are essential for Cag T4S function. Other cag PAI-encoded genes are also essential for Cag T4S, but lack of sequence-based or structural similarity with genes in existing databases has precluded a functional assignment for the encoded proteins. We have studied the role of one such protein, Cag3 (HP0522), in Cag T4S and determined Cag3 subcellular localization and protein interactions. Cag3 is membrane associated and copurifies with predicted inner and outer membrane Cag T4S components that are essential for Cag T4S as well as putative accessory factors. Coimmunoprecipitation and cross-linking experiments revealed specific interactions with HpVirB7 and CagM, suggesting Cag3 is a new component of the Cag T4S outer membrane subcomplex. Finally, lack of Cag3 lowers HpVirB7 steady-state levels, further indicating Cag3 makes a subcomplex with this protein.Helicobacter pylori infects 50% of the world population. Stomach infection with this bacterium is associated with the development of several gastric diseases, including chronic active gastritis, peptic ulcers, gastric cancer, and mucosa-associated lymphoid tissue lymphoma. Factors influencing disease outcomes are not completely understood, but bacterial, host, and environmental factors have been identified that affect the dynamics of this bacterium-host interaction (30). A hallmark of H. pylori infection is the induction of mucosal inflammation, which is a risk factor for developing more severe pathology (27).Epidemiological studies have established that infection with strains harboring the cag pathogenicity island (PAI) leads to a higher risk for development of severe disease (27). The cag PAI size varies between 35 and 40 kb and encodes 27 putative proteins (1, 13). Several of the encoded proteins share sequence similarities with components of the prototypical type IV secretion (T4S) system VirB/D4 of Agrobacterium tumefaciens (15, 16). Based on research done in A. tumefaciens, the components of the molecular machinery have been divided into channel or core complex components (VirB6, VirB7, VirB8, VirB9, and VirB10), energetic components (VirB11, VirB4, and VirD4), and extracellular appendage components (VirB2 and VirB5). VirB6, VirB8, and VirB10 are components anchored at the inner membrane with domains spanning the periplasm, while VirB7 and VirB9 are located at the outer membrane. Energetic components are located at the inner membrane, and pilus components include the main subunit VirB2 and accessory components, such as VirB5, which functions as an adhesin (15, 16). The VirB/D4 T4S is thought to be energized by the inner membrane ATPases, and this energy is transduced to VirB10 and the outer membrane complex for protein translocation (11). The lipoprotein VirB7 is critical for the stability of HpVirB9 at the outer membrane (19).While the extent of homology of the H. pylori cag T4S components is often limited, sequence analysis has allowed the identification of the VirB11 (HP0525 and HpVirB11), VirB10 (HP0527 and HpVirB10), VirB9 (HP0528 and HpVirB9), and VirD4 (HP0524 and HpVirD4) homologues as summarized in Table S1 of the supplemental material (1, 13, 28). HpVirB9 and HpVirB10 homologies are not distributed along the entire length of the protein. For example, HpVirB10 is a very large protein with only a short domain similar to VirB10. HpVirB10 is also reported to localize on the external surface of the pilus (31), while VirB10 is tethered in the inner membrane. HP0529 (HpVirB6) and HP0530 (HpVirB8) have been assigned as homologs of VirB6 and VirB8, respectively (28). HP0523 (HpVirB1) has lytic transglycosylase activity, supporting its designation as a VirB1 homolog (38). HP0532 (HpVirB7) has a lipoprotein attachment site, suggesting a role as a VirB7 homolog (1, 28), and has been suggested to stabilize a Cag T4S outer membrane subcomplex containing CagM, HpVirB9, and HpVirB10 (28).The activity of the cag PAI-encoded T4S system is responsible for the translocation of the effector protein CagA and induction of proinflammatory chemokine and cytokine secretion, including the chemokine interleukin-8 (IL-8) (7). CagA T4S-mediated translocation into host cells is followed by tyrosine phosphorylation on specific tyrosine phosphorylation motifs (EPIYA motifs) at the C-terminal region of the protein and both phosphorylation-dependent and -independent interference with host cellular pathways. The induction of proinflammatory chemokine production is mediated by a still-uncharacterized Cag T4S-mediated delivery of peptidoglycan into host cells and subsequent activation of Nod receptors (37), and it has also been reported that CagA itself has proinflammatory properties (9). The molecular mechanisms responsible for Cag T4S system assembly and activity remain unclear.Null alleles of the genes with homology to T4S components (HpVirB11, HpVirB4, HpVirB6, HpVirB7, HpVirB8, HpVirB9, and HpVirB10) abolish both CagA translocation and IL-8 induction, with the exception of HpVirD4, which affects CagA translocation but not IL-8 induction (20). Other genes of the island also essential for Cag T4S function do not share sequence or structural homology with known T4S components. More detailed analysis of these Cag T4S essential genes allowed the recent assignment of several proteins as functional homologs of additional VirB components. HP0546 was suggested as a VirB2 homolog, the main subunit of other T4S system pili (3). Ultrastructural work suggested that HpVirB10 is also a major subunit of the Cag T4S system pilus (31, 35), but clear evidence that either HpVirB2 or HpVirB10 is the main pilus subunit is still lacking. CagL (HP0539) has been identified (29) as an adhesin (functionally similar to VirB5) whose binding to host cell receptors is required for activation of the secretion process, and CagF (HP0543) has been characterized as a CagA chaperone (17). CagD (HP0545) has been recently reported as a multifunctional Cag T4S component essential for CagA translocation and full IL-8 secretion induction (12).We have characterized the biochemical role of an additional essential H. pylori-specific gene, HP0522/cag3, in Cag T4S. A previous yeast two-hybrid screen that investigated interactions among cag PAI proteins suggested Cag3 could interact with HpVirB8, HpVirB7, CagM (HP0537), and CagG (HP0542) (10). To begin to understand the molecular basis of Cag3 function in T4S we investigated the subcellular localization of the Cag3 protein and the protein-protein interactions this protein establishes in H. pylori cells. We found evidence suggesting that Cag3 is an integral part of the Cag T4S outer membrane subcomplex required to maintain HpVirB7 levels.     

Expression of the Axonal Membrane Glycoprotein M6a Is Regulated by Chronic Stress

It has been repeatedly shown that chronic stress changes dendrites, spines and modulates expression of synaptic molecules. These effects all may impair information transfer between neurons. The present study shows that chronic stress also regulates expression of M6a, a glycoprotein which is localised in axonal membranes. We have previously demonstrated that M6a is a component of glutamatergic axons. The present data reveal that it is the splice variant M6a-Ib, not M6a-Ia, which is strongly expressed in the brain. Chronic stress in male rats (3 weeks daily restraint) has regional effects: quantitative in situ hybridization demonstrated that M6a-Ib mRNA in dentate gyrus granule neurons and in CA3 pyramidal neurons is downregulated, whereas M6a-Ib mRNA in the medial prefrontal cortex is upregulated by chronic stress. This is the first study showing that expression of an axonal membrane molecule is differentially affected by stress in a region-dependent manner. Therefore, one may speculate that diminished expression of the glycoprotein in the hippocampus leads to altered output in the corresponding cortical projection areas. Enhanced M6a-Ib expression in the medial prefrontal cortex (in areas prelimbic and infralimbic cortex) might be interpreted as a compensatory mechanism in response to changes in axonal projections from the hippocampus. Our findings provide evidence that in addition to alterations in dendrites and spines chronic stress also changes the integrity of axons and may thus impair information transfer even between distant brain regions.     

Tim23, a Protein Import Component of the Mitochondrial Inner Membrane, Is Required for Normal Activity of the Multiple Conductance Channel, MCC

We previously showed that the conductance of a mitochondrial inner membrane channel, called MCC, was specifically blocked by peptides corresponding to mitochondrial import signals. To determine if MCC plays a role in protein import, we examined the relationship between MCC and Tim23p, a component of the protein import complex of the mitochondrial inner membrane. We find that antibodies against Tim23p, previously shown to inhibit mitochondrial protein import, inhibit MCC activity. We also find that MCC activity is altered in mitochondria isolated from yeast carrying the tim23-1 mutation. In contrast to wild-type MCC, we find that the conductance of MCC from the tim23-1 mutant is not significantly blocked by mitochondrial presequence peptides. Tim23 antibodies and the tim23-1 mutation do not, however, alter the activity of PSC, a presequence-peptide sensitive channel in the mitochondrial outer membrane. Our results show that Tim23p is required for normal MCC activity and raise the possibility that precursors are translocated across the inner membrane through the pore of MCC.     

Cloning of a Novel Rat Gene, DB83, That Encodes a Putative Membrane Protein

Using a partial cDNA sequence and a 5'-RACE technique, we isolateda novel cDNA from rat liver referred to as DB83. DB83 had fourhydrophobic trans-membrane domains and one N-myristoylationsite as well as multiple possible phosphorylation sites. Thedb83 gene was highly expressed in the liver and significantlyin brain, lungs and kidneys. We suggest that DB83 is a tissue-specificputative membrane protein.     

Disabled Is a Putative Adaptor Protein That Functions during Signaling by the Sevenless Receptor Tyrosine Kinase

DRK, the Drosophila homolog of the SH2-SH3 domain adaptor protein Grb2, is required during signaling by the sevenless receptor tyrosine kinase (SEV). One role of DRK is to provide a link between activated SEV and the Ras1 activator SOS. We have investigated the possibility that DRK performs other functions by identifying additional DRK-binding proteins. We show that the phosphotyrosine-binding (PTB) domain-containing protein Disabled (DAB) binds to the DRK SH3 domains. DAB is expressed in the ommatidial clusters, and loss of DAB function disrupts ommatidial development. Moreover, reduction of DAB function attenuates signaling by a constitutively activated SEV. Our biochemical analysis suggests that DAB binds SEV directly via its PTB domain, becomes tyrosine phosphorylated upon SEV activation, and then serves as an adaptor protein for SH2 domain-containing proteins. Taken together, these results indicate that DAB is a novel component of the SEV signaling pathway.     

C11ORF24 Is a Novel Type I Membrane Protein That Cycles between the Golgi Apparatus and the Plasma Membrane in Rab6-Positive Vesicles

The Golgi apparatus is an intracellular compartment necessary for post-translational modification, sorting and transport of proteins. It plays a key role in mitotic entry through the Golgi mitotic checkpoint. In order to identify new proteins involved in the Golgi mitotic checkpoint, we combine the results of a knockdown screen for mitotic phenotypes and a localization screen. Using this approach, we identify a new Golgi protein C11ORF24 (NP_071733.1). We show that C11ORF24 has a signal peptide at the N-terminus and a transmembrane domain in the C-terminal region. C11ORF24 is localized on the Golgi apparatus and on the trans-Golgi network. A large part of the protein is present in the lumen of the Golgi apparatus whereas only a short tail extends into the cytosol. This cytosolic tail is well conserved in evolution. By FRAP experiments we show that the dynamics of C11ORF24 in the Golgi membrane are coherent with the presence of a transmembrane domain in the protein. C11ORF24 is not only present on the Golgi apparatus but also cycles to the plasma membrane via endosomes in a pH sensitive manner. Moreover, via video-microscopy studies we show that C11ORF24 is found on transport intermediates and is colocalized with the small GTPase RAB6, a GTPase involved in anterograde transport from the Golgi to the plasma membrane. Knocking down C11ORF24 does not lead to a mitotic phenotype or an intracellular transport defect in our hands. All together, these data suggest that C11ORF24 is present on the Golgi apparatus, transported to the plasma membrane and cycles back through the endosomes by way of RAB6 positive carriers.     

The Inner Nuclear Membrane Protein Nemp1 Is a New Type of RanGTP-Binding Protein in Eukaryotes

The inner nuclear membrane (INM) protein Nemp1/TMEM194A has previously been suggested to be involved in eye development in Xenopus, and contains two evolutionarily conserved sequences in the transmembrane domains (TMs) and the C-terminal region, named region A and region B, respectively. To elucidate the molecular nature of Nemp1, we analyzed its interacting proteins through those conserved regions. First, we found that Nemp1 interacts with itself and lamin through the TMs and region A, respectively. Colocalization of Nemp1 and lamin at the INM suggests that the interaction with lamin participates in the INM localization of Nemp1. Secondly, through yeast two-hybrid screening using region B as bait, we identified the small GTPase Ran as a probable Nemp1-binding partner. GST pulldown and co-immunoprecipitation assays using region B and Ran mutants revealed that region B binds directly to the GTP-bound Ran through its effector domain. Immunostaining experiments using transfected COS-7 cells revealed that full-length Nemp1 recruits Ran near the nuclear envelope, suggesting a role for Nemp1 in the accumulation of RanGTP at the nuclear periphery. At the neurula-to-tailbud stages of Xenopus embryos, nemp1 expression overlapped with ran in several regions including the eye vesicles. Co-knockdown using antisense morpholino oligos for nemp1 and ran caused reduction of cell densities and severe eye defects more strongly than either single knockdown alone, suggesting their functional interaction. Finally we show that Arabidopsis thaliana Nemp1-orthologous proteins interact with A. thaliana Ran, suggesting their evolutionally conserved physical and functional interactions possibly in basic cellular functions including nuclear transportation. Taken together, we conclude that Nemp1 represents a new type of RanGTP-binding protein.