Discriminating between homodimeric and monomeric proteins in the crystalline state.

Scores calculated from intermolecular contacts of proteins in the crystalline state are used to differentiate monomeric and homodimeric proteins, by classification into two categories separated by a cut-off score value. The generalized classification error is estimated by using bootstrap re-sampling on a nonredundant set of 172 water-soluble proteins whose prevalent quaternary state in solution is known to be either monomeric or homodimeric. A statistical potential, based on atom-pair frequencies across interfaces observed with homodimers, is found to yield an error rate of 12.5%. This indicates a small but significant improvement over the measure of solvent accessible surface area buried in the contact interface, which achieves an error rate of 15.4%. A further modification of the latter parameter relating the two most extensive contacts of the crystal results in an even lower error rate of 11.1%.

DelGEF, an RCC1-related protein encoded by a gene on chromosome 11p14 critical for two forms of hereditary deafness.

We have cloned a human cDNA, DELGEF (deafness locus associated putative guanine nucleotide exchange factor), derived from a 225 kb genomic sequence of chromosome 11p14, critical for the Usher 1C syndrome and for DFNB18, a locus for non-syndromic sensorineural deafness. The amino acid sequence of the protein hDelGEF1 is homologous to the nucleotide exchange factor RCCI for the small GTPase Ran. hDelGEF2 is derived from the same DELGEF gene by alternative splicing. In addition, we have identified a murine homologue, mDelGEF. The ubiquitously expressed soluble protein hDelGEF1 is found both in the cyytoplasm and in the nucleus. Overexpressed hDelGEF2 colocalizes with mitochondria.

Rapid measurement of scalar three-bond 1HN-1H alpha spin coupling constants in 15N-labelled proteins.

Two new 2D NMR experiments, CT-HMQC-HA and CT-HMQC-HN, are proposed for the rapid measurement of homonuclear 3JHNH alpha coupling constants of uniformly 15N-enriched proteins in solution. The experiments are based on the comparison of the signal intensities in a pair of constant-time [15N,1H]-HMQC spectra recorded with and without decoupling of the amide proton-alpha proton coupling. Experimental data recorded with the 78-residue N-terminal domain of the E. coli arginine repressor (ArgR-N) and with oxidized E. coli flavodoxin (176 residues) showed good agreement with 3JHNH alpha coupling constants obtained by fitting of the multiplet fine structure of the amide proton resonances or from a 3D HNHA-J experiment, respectively. Quantitative estimates for the effects from different relaxation rates of in-phase and antiphase magnetization are given.

Human RanBP3, a group of nuclear RanGTP binding proteins.

A group of novel human Ran-binding proteins, RanBP3, was identified using the yeast two-hybrid system via Ran-mediated interaction with the nucleotide exchange factor RCC1. Several open reading frames, representing putative alternatively spliced products, were established by cDNA cloning. Two of them, RanBP3-a and RanBP3-b, encode nuclear hydrophilic proteins of 499 and 562 amino acid residues. The sequences contain FXFG motifs, characteristic of a subgroup of nucleoporins, and a C-terminal domain showing similarity to the Ran-binding protein RanBP1. These proteins are localized in the nucleus, preferentially bind RanGTP and may be nuclear effectors of the Ran pathway.

Yrb4p, a yeast ran-GTP-binding protein involved in import of ribosomal protein L25 into the nucleus.

Gsp1p, the essential yeast Ran homologue, is a key regulator of transport across the nuclear pore complex (NPC). We report the identification of Yrb4p, a novel Gsp1p binding protein. The 123 kDa protein was isolated from Saccharomyces cerevisiae cells and found to be related to importin-beta, the mediator of nuclear localization signal (NLS)-dependent import into the nucleus, and to Pse1p. Like importin-beta, Yrb4p and Pse1p specifically bind to Gsp1p-GTP, protecting it from GTP hydrolysis and nucleotide exchange. The GTPase block of Gsp1p complexed to Yrb4p or Pse1p is released by Yrb1p, which contains a Gsp1p binding domain distinct from that of Yrb4p. This might reflect an in vivo function for Yrb1p. Cells disrupted for YRB4 are defective in nuclear import of ribosomal protein L25, but show no defect in the import of proteins containing classical NLSs. Expression of a Yrb4p mutant deficient in Gsp1p-binding is dominant-lethal and blocks bidirectional traffic across the NPC in wild-type cells. L25 binds to Yrb4p and Pse1p and is released by Gsp1p-GTP. Consistent with its putative role as an import receptor for L25-like proteins, Yrb4p localizes to the cytoplasm, the nucleoplasm and the NPC.

Ran-binding protein 5 (RanBP5) is related to the nuclear transport factor importin-beta but interacts differently with RanBP1.

We report the identification and characterization of a novel 124-kDa Ran binding protein, RanBP5. This protein is related to importin-beta, the key mediator of nuclear localization signal (NLS)-dependent nuclear transport. RanBP5 was identified by two independent methods: it was isolated from HeLa cells by using its interaction with RanGTP in an overlay assay to monitor enrichment, and it was also found by the yeast two-hybrid selection method with RanBP1 as bait. RanBP5 binds to RanBP1 as part of a trimeric RanBP1-Ran-RanBP5 complex. Like importin-beta, RanBP5 strongly binds the GTP-bound form of Ran, stabilizing it against both intrinsic and RanGAP1-induced GTP hydrolysis and also against nucleotide exchange. The GAP resistance of the RanBP5-RanGTP complex can be relieved by RanBP1, which might reflect an in vivo role for RanBP1. RanBP5 is a predominantly cytoplasmic protein that can bind to nuclear pore complexes. We propose that RanBP5 is a mediator of a nucleocytoplasmic transport pathway that is distinct from the importin-alpha-dependent import of proteins with a classical NLS.

The human gene ZFP161 on 18p11.21-pter encodes a putative c-myc repressor and is homologous to murine Zfp161 (Chr 17) and Zfp161-rs1 (X Chr)

A clone from a lambda gt11 cDNA expression library of HeLa cells was isolated, sequenced, and shown to encode a new human zinc finger protein. The cDNA of the gene termed ZFP161 has an open reading frame of 1347 bp. The predicted protein comprises 449 amino acid residues and contains five zinc finger motifs of the Krüppel type near the C-terminus and a BTB/POZ domain in the N-terminal region. The protein is 98% homologous to a murine zinc finger protein, ZF5 (M. Numoto et al., 1993, Nucleic Acids Res. 21: 3767-3775), which is a putative transcriptional repressor of c-myc and exhibits growth-suppressive activity in mouse cell lines. Through the use of a panel of somatic cell hybrids for chromosomal assignment and DNAs of somatic cell hybrids containing a deleted chromosome 18 for fine mapping, the human gene ZFP161 was localized to 18p11.21-pter. Therefore, ZFP161 is a candidate gene by position for the holoprosencephaly type 4 gene, HPE4, which is involved in congenital malformations. With DNAs from an interspecific backcross, two homologous mouse genes, Zfp161 and Zfp161-rs1, were mapped to chromosome 17 and the X chromosome, respectively. Mapping of Zfp161 confirms and extends a region of homology between distal mouse chromosome 17 and human 18p.

Human Supt5h protein, a putative modulator of chromatin structure, is reversibly phosphorylated in mitosis.

The Saccharomyces cerevisiae proteins Spt4p, Spt5p and Spt6p are involved in transcriptional repression by modulating the structure of chromatin. From HeLa cells we have purified a human homologue of Spt5p, Supt5hp, and show here that the protein is reversibly phosphorylated in mitosis. The cloned cDNA predicts a protein of 1087 residues with 31% identity to yeast Spt5p. It includes an acidic N-terminus, a putative nuclear localization signal and a C-terminal region containing two different repeated motifs. One of them, with the consensus sequence P-T/S-P-S-P-Q/A-S/G-Y, is similar to the C-terminal domain in the largest subunit of RNA polymerase II.

NMR assignments, secondary structure and hydration of oxidized Escherichia coli flavodoxin.

Recombinant flavodoxin from Escherichia coli was uniformly enriched with 15N and 13C isotopes and its oxidized form in aqueous solution investigated by three-dimensional NMR spectroscopy. Nearly complete 1H, 15N and 13C resonance assignments were obtained. The secondary structure was determined from chemical shift, NOE and 3J(HNH alpha) coupling constant data. Like homologous long-chain flavodoxins, E. coli flavodoxin contains a five-stranded parallel beta-sheet and five helices. The beta-strands were found to comprise the residues 3-8, 29-34, 48-56, 80-89, 114-116 and 141-145. The helices comprise residues 12-25, 40-45, 62-73, 98-108 and 152-166. The FMN-binding site was determined by intermolecular NOEs and low-field shifted amide proton resonances induced by the phosphoester group of the cofactor. The data are in good agreement with a previously predicted model of E. coli flavodoxin [Havel, T. F. (1993) Mol. Sim. 10, 175-210]. The analysis of of water-flavodoxin NOEs revealed the presence of two, possibly three, buried hydration water molecules which are located at sites, where homologous flavodoxins from Anacystis nidulans and Anabena 7120 contain conserved hydration water molecules. One of these water molecules mediates hydrogen bonds between the protein backbone and the ribityl chain of the FMN cofactor.

The novel human protein serine/threonine phosphatase 6 is a functional homologue of budding yeast Sit4p and fission yeast ppe1, which are involved in cell cycle regulation.

We identified a novel human protein serine/threonine phosphatase cDNA, designated protein phosphatase 6 (PP6) by using a homology-based polymerase chain reaction. The predicted amino acid sequence indicates a 35 kDa protein showing high homology to other protein phosphatases including human PP2A (57%), human PP4 (59%), rat PPV (98%), Drosophila PPV (74%), Schizosaccharomyces pombe ppe1 (68%) and Saccharomyces cerevisiae Sit4p (61%). In human cells, three forms of PP6 mRNA were found with highest levels of expression in testis, heart and skeletal muscle. The PP6 protein was detected in lysates of human heart muscle and in bull testis. Complementation studies using a temperature sensitive mutant strain of S. cerevisiae SIT4, which is required for the G1 to S transition of the cell cycle, showed that PP6 can rescue the mutant growth arrest. In addition, a loss of function mutant of S. pombe ppe1, described as a gene interacting with the pim1/spi1 mitotic checkpoint and involved in cell shape control, can be complemented by expression of human PP6. These data indicate that human PP6 is a functional homologue of budding yeast Sit4p and fission yeast ppe1, implying a function of PP6 in cell cycle regulation.

Ubiquitous expression and testis-specific alternative polyadenylation of mRNA for the human Ran GTPase activator RanGAP1.

RanGAP1 is the activator of the Ras-related nuclear GTPase Ran, which is involved in the nucleo-cytoplasmic transport of both, proteins and mRNAs, and also in cell cycle regulation. Here, we report a 2970-bp cDNA clone of RanGAP1 isolated from a HeLa lambda gt11 cDNA library. It contains a 215-bp 5' untranslated region (UTR) with a G + C-content of 68%, followed by a 1764-bp open reading frame and a 989-bp 3' UTR preceding a 77-bp poly(A)+ tail. RanGAP1 shows differential patterns of expression in human tissues. In addition to the 3.5-kb transcript present in all tissues and highly expressed in brain, thymus and testis, we found a second transcript of 2.8 kb in testis. In order to analyze this shorter transcript, we screened a human testis lambda gt10 cDNA library and cloned an alternatively polyadenylated RanGAP1 transcript. Taking the 3' UTR of RanGAP1, which lies downstream of the first polyadenylation signal, as a probe in Northern blot analysis, we confirmed that this second transcript found in testis results from a distinct 3' UTR.

The thermolability of nuclear protein import in tsBN2 cells is suppressed by microinjected Ran-GTP or Ran-GDP, but not by RanQ69L or RanT24N.

The nuclear protein regulator of chromosome condensation 1 (RCC1) stimulates guanine nucleotide exchange on a protein, Ran, that is required for nuclear protein import. In the present report, we confirm that RCC1 is also required for nuclear protein import in tsBN2 hamster cells in vivo. The thermolability of nuclear protein import in tsBN2 cells was suppressed by microinjection of purified Ran-GTP into the cytoplasm, but Ran-GDP also relieved the import deficiency, suggesting either that both forms of Ran are active in import in vivo or that tsBN2 cells at restrictive temperature retain a mechanism to convert Ran-GDP to Ran-GTP. To distinguish between these possibilities, nuclear protein import in tsBN2 cells was tested in the presence of Ran mutants, one deficient in GTP hydrolysis (RanQ69L), and one with weak binding to GDP and little or no binding to GTP (RanT24N). Microinjection of the mutant RanQ69L inhibited import in vivo in either the GTP- or GDP-bound form at both the permissive and nonpermissive temperatures. RanT24N-GDP inhibited import in vivo at the permissive temperature and failed to stimulate nuclear protein import at the nonpermissive temperature. The implications of these results for the roles of RCC1 and Ran in nuclear protein import in vivo are discussed.

In vitro and in vivo evidence that protein and U1 snRNP nuclear import in somatic cells differ in their requirement for GTP-hydrolysis, Ran/TC4 and RCC1.

GTP-hydrolysis, the small ras-related GTP-binding protein Ran and its cognate guanosine nucleotide exchange factor, the RCC1 gene product, have recently been identified as essential components of the protein nuclear import pathway. In this report we use three independent approaches to investigate the role of these components in U1 snRNP nuclear import in somatic cells. (i) Using a somatic cell based in vitro nuclear import system we show that U1 snRNP nuclear import, in marked contrast to protein transport, is not significantly inhibited by non-hydrolyzable GTP-analogs and is therefore unlikely to require GTP-hydrolysis. (ii) Using the dominant negative Ran mutant RanQ69L, which is defective in GTP-hydrolysis, we show that Ran-mediated GTP-hydrolysis is not essential for the nuclear import of U1 snRNP in microinjected cultured cells. (iii) Using a cell line expressing a thermolabile RCC1 gene product, we show that the nuclear accumulation of microinjected U1 snRNP is not significantly affected by RCC1 depletion at the non-permissive temperature, indicating that RCC1 function is not essential for U-snRNP nuclear import. Based on these observations we conclude that protein and U-snRNP nuclear import in somatic cells differ in their requirements for GTP-hydrolysis, and Ran or RCC1 function. Based on these results, the substrates for nucleocytoplasmic exchange across the NPC can be divided into two classes, those absolutely requiring Ran, including protein import and mRNA export, and those for which Ran is not essential, including U-snRNP nuclear import, together with tRNA and U1 snRNA nuclear export.

Glutaredoxin-3 from Escherichia coli. Amino acid sequence, 1H AND 15N NMR assignments, and structural analysis.

The primary and secondary structure of glutaredoxin-3 (Grx3), a glutathione-disulfide oxidoreductase from Escherichia coli, has been determined. The amino acid sequence of Grx3 consists of 82 residues and contains a redox-active motif, Cys-Pro-Tyr-Cys, typical of the glutaredoxin family. Sequence comparison reveals a homology (33% identity) to that of glutaredoxin-1 (Grx1) from E. coli as well as to other members of the thioredoxin superfamily. In addition to the active site cysteine residues, Grx3 contains one additional cysteine (Cys65) corresponding to one of the two non-active site (or structural) cysteine residues present in mammalian glutaredoxins. The sequence-specific 1H and 15N nuclear magnetic resonance assignments of reduced Grx3 have been obtained. From a combined analysis of chemical shifts, 3JHNalpha coupling constants, sequential and medium range NOEs, and amide proton exchange rates, the secondary structure of reduced Grx3 was determined and found to be very similar to that inferred from amino acid sequence comparison to homologous proteins. The consequences of the proposed structural similarity to Grx1 are that Grx3, while possessing a largely intact GSH binding cleft, would have a very different spatial distribution of charged residues, most notably surrounding the active site cysteine residues and occurring in the proposed hydrophobic protein-protein interaction area. These differences may contribute to the observed very low Kcat of Grx3 as a reductant of insulin disulfides or as a hydrogen donor for ribonucleotide reductase. Thus, despite an identical active site disulfide motif and a similar secondary structure and tertiary fold, Grx3 and Grx1 display large functional differences in in vitro protein disulfide oxido-reduction reactions.

Resonance assignment and structural analysis of acid denatured E. coli [U-15N]-glutaredoxin 3: use of 3D 15N-HSQC-(TOCSY-NOESY)-15N-HSQC.

Virtually complete sequence specific 1H and 15N resonance assignments are presented for acid denatured reduced E. coli glutaredoxin 3. The sequential resonance assignments of the backbone rely on the combined use of 3D F1-decoupled ROESY-15N-HSQC and 3D 15N-HSQC-(TOCSY-NOESY)-15N-HSQC using a single uniformly 15N labelled protein sample. The sidechain resonances were assigned from a 3D TOCSY-15N-HSQC and a homonuclear TOCSY spectrum. The presented assignment strategy works in the absence of chemical exchange peaks with signals from the native conformation and without 13C/15N double labelling. Chemical shifts, 3J(alpha H, NH) coupling constants and NOEs indicate extensive conformational averaging of both backbone and side chains in agreement with a random coil conformation. The only secondary structure element persisting at pH 3.5 appears to be a short helical segment comprising residues 37 to 40.

RNA1 encodes a GTPase-activating protein specific for Gsp1p, the Ran/TC4 homologue of Saccharomyces cerevisiae.

Ran/TC4 is a ras-related GTP-binding protein predominantly located in the nucleus. Ran/TC4 is essential for nuclear transport and is involved in mitotic control. In Saccharomyces cerevisiae a gene highly homologous to Ran/TC4 has been identified and named GSP1. Like all ras-related GTP-binding proteins, Gsp1p undergoes cycles of GTP hydrolysis and GDP/GTP exchange. The switching between the two different nucleotide bound states regulates the function of these GTP-binding proteins. Here we identify the product of the yeast RNA1 gene as the GTPase-activating protein (GAP) of Gsp1p. RNA1 belongs to a group of genes which are conserved in a variety of different organisms. We have expressed and purified recombinant Gsp1p and Rna1p from Escherichia coli. The GTPase activity of Gsp1p is stimulated 10(7)-fold by Rna1p. In addition, we find that the previously identified human RanGAP1 and rna1p from Schizosaccharomyces pombe are also able to induce GTPase activity of Gsp1p. The GTP hydrolysis of Ran is induced by RanGAP1 and rna1p but not by Rna1p. Implications for the suggested functions of Ran/TC4/Gsp1p in nuclear transport and mitotic control are discussed.

Human RanGTPase-activating protein RanGAP1 is a homologue of yeast Rna1p involved in mRNA processing and transport.

RanGAP1 is the GTPase activator for the nuclear Ras-related regulatory protein Ran, converting it to the putatively inactive GDP-bound state. Here, we report the amino acid sequence of RanGAP1, derived from cDNA and peptide sequences. We found it to be homologous to murine Fug1, implicated in early embryonic development, and to Rna1p from Saccharomyces cerevisiae and Schizosaccharomyces pombe. Mutations of budding yeast RNA1 are known to result in defects in RNA processing and nucleocytoplasmic mRNA transport. Concurrently, we have isolated Rna1p as the major RanGAP activity from Sc. pombe. Both this protein and recombinant Rna1p were found to stimulate RanGTPase activity to an extent almost identical to that of human RanGAP1, indicating the functional significance of the sequence homology. The Ran-specific guanine nucleotide exchange factor RCC1 and its yeast homologues are restricted to the nucleus, while Rna1p is reported to be localized to the cytoplasm. We suggest a model in which both activities, nuclear GDP-to-GTP exchange on Ran and cytoplasmic hydrolysis of Ran-bound GTP, are essential for shuttling of Ran between the two cellular compartments. Thus, a defect in either of the two antagonistic regulators of Ran would result in a shutdown of Ran-dependent transport processes, in agreement with the almost identical phenotypes described for such defects in budding yeast.