Conformational states of the nuclear GTP-binding protein Ran and its complexes with the exchange factor RCC1 and the effector protein RanBP1.

It has been shown before by (31)P NMR that Ras bound to the nonhydrolyzable GTP analogue guanosine 5'-O-(beta, gamma-imidotriphosphate) (GppNHp) exists in two conformations which are rapidly interconverting with a rate constant of 3200 s-1 at 30 degrees C [Geyer, M., et al. (1996) Biochemistry 35, 10308-10320]. Here we show that Ran complexed with GTP also exists in two conformational states, 1 and 2, which can be directly inferred from the occurrence of two (31)P NMR resonance lines for the gamma-phosphate group of bound GTP. The exchange between the two states is slow on the NMR time scale with a value of <200 s-1 at 5 degrees C for the corresponding first-order rate constants. In wild-type Ran, the equilibrium constant K' between the two states is 0.7 at 278 K, is different for various mutants, and is strongly dependent on the temperature. The standard enthalpy DeltaH degrees and the standard entropy DeltaS degrees for the conformational transitions determined from the NMR spectra are as follows: DeltaH degrees = 37 kJ mol-1 and DeltaS degrees = 130 J mol-1 K-1 for wild-type Ran.GTP. In complex with the Ran-binding protein RanBP1, one of the Ran.GTP conformations (state 2) is stabilized. The interaction of Ran with the guanine nucleotide exchange factor protein RCC1 was also studied by (31)P NMR spectroscopy. In the presence of nucleotide, the ternary complex of Ran.nucleotide.RCC1, an intermediate in the guanine nucleotide exchange reaction, could be observed. A model for the conformational transition of Ran.GTP is proposed where the two states observed are caused by the structural flexibility of the effector loop of Ran; in solution, state 2 resembles the GTP-bound form found in the crystal structure of the Ran-RanBP complex.

The 1.7 A crystal structure of the regulator of chromosome condensation (RCC1) reveals a seven-bladed propeller.

The gene encoding the regulator of chromosome condensation (RCC1) was cloned by virtue of its ability to complement the temperature-sensitive phenotype of the hamster cell line tsBN2, which undergoes premature chromosome condensation or arrest in the G1 phase of the cell cycle at non-permissive temperatures. RCC1 homologues have been identified in many eukaryotes, including budding and fission yeast. Mutations in the gene affect pre-messenger RNA processing and transport, mating, initiation of mitosis and chromatin decondensation, suggesting that RCC1 is important in the control of nucleo-cytoplasmic transport and the cell cycle. Biochemically, RCC1 is a guanine-nucleotide-exchange factor for the nuclear Ras homologue Ran; it increases the dissociation of Ran-bound GDP by 10(5)-fold. It may also bind to DNAvia a protein-protein complex. Here we show that the structure of human RCC1, solved to 1.7-A resolution by X-ray crystallography, consists of a seven-bladed propeller formed from internal repeats of 51-68 residues per blade. The sequence and structure of the repeats differ from those of WD40-domain proteins, which also form seven-bladed propellers and include the beta-subunits of G proteins. The nature of the structure explains the consequences of a wide range of known mutations. The region of the protein that is involved in guanine-nucleotide exchange is located opposite the region that is thought to be involved in chromosome binding.

Conserved histidine residues of RCC1 are essential for nucleotide exchange on Ran.

Charged amino acid residues of human RCC1 were converted to alanine and mutants which were unable to complement tsBN2 cells (a temperature-sensitive rcc1- mutant of the hamster BHK21 cell line) were selected. These RCC1 mutants were analyzed for the ability to inhibit premature chromatin condensation by microinjection into tsBN2 cells, and their steady-state kinetic parameters for guanine nucleotide exchange reaction were measured. Examined RCC1 mutants were unstable in tsBN2 cells at the restrictive temperature, yet they significantly inhibited premature chromatin condensation. Mutants located on the N-terminus of the RCC1 repeat showed an increased K(m), while their kcat values were comparable to that of wild-type RCC1. In contrast, mutants containing the conserved histidine residues in the C-terminus of the RCC1 repeat showed a value of K(m) similar to that of wild-type RCC1, while the kcat values of these mutants were reduced, depending upon the RCC1 repeats on which the mutation was located. These steady-state kinetic parameters of mutants indicate that the N-terminus and the C-terminus of RCC1 repeats play different roles in guanine nucleotide exchange on Ran. The comparison of kcat among the histidine mutants suggests that those histidine residues which are conserved in the RCC1 repeats and also through evolution comprise the catalytic site for the guanine nucleotide exchange reaction.

RAN/TC4 mutants identify a common requirement for snRNP and protein import into the nucleus.

Kinetic competition experiments have demonstrated that at least some factors required for the nuclear import of proteins and U snRNPs are distinct. Both import processes require energy, and in the case of protein import, the energy requirement is known to be at least partly met by GTP hydrolysis by the Ran GTPase. We have compared the effects of nonhydrolyzable GTP analogues and two mutant Ran proteins on the nuclear import of proteins and U snRNPs in vitro. The mutant Ran proteins have different defects; Q69L (glutamine 69 changed to leucine) is defective in GTP hydrolysis while T24N (threonine 24 changed to asparagine) is defective in binding GTP. Both protein and snRNP import are sensitive either to the presence of the two mutant Ran proteins, which act as dominant negative inhibitors of nuclear import, or to incubation with nonhydrolyzable GTP analogues. This demonstrates that there is a requirement for a GTPase activity for the import of U snRNPs, as well as proteins, into the nucleus. The dominant negative effects of the two mutant Ran proteins indicate that the pathways of protein and snRNP import share at lease one common component.

The kinetic mechanism of Ran--nucleotide exchange catalyzed by RCC1.

The interaction of Ran, a Ras-related nuclear GTP-binding protein, with its guanine nucleotide exchange factor RCC1 has been studied by equilibrium and transient kinetic measurements using fluorescent nucleotides. The four-step mechanism of catalyzed nucleotide exchange involves the formation of ternary complexes consisting of Ran, RCC1, and GXP as well as a nucleotide-free dimeric Ran.RCC1 complex. This model is sufficient to describe all experimental data obtained, so that no additional reaction steps must be assumed. All the rate and equilibrium constants for the four-step mechanism have been determined either experimentally or from a simultaneous theoretical fit to all experimental data sets. The affinities of RCC1 to Ran.GDP and Ran.GTP are similar (1.3 x 10(5) and 1.8 x 10(5) M-1, respectively) and are high enough to allow formation of the ternary complex under appropriate concentration conditions. In the absence of excess nucleotide and at low Ran concentrations, GDP (or GTP) can be efficiently displaced by excess RCC1 and the ternary complex can be produced. The affinities of both nucleotides (GDP or GTP) to Ran in the corresponding ternary complexes are reduced by orders of magnitude in comparison with the respective binary complexes. The reduction of affinity of both nucleotides in the ternary complexes leads to a dramatic increase in the dissociation rate constants by similar orders of magnitude (from 1.5 x 10(-5) s(-1) to 21 s(-1) for GDP) and thus to facilitated nucleotide exchange. The quantitative results of the kinetic analysis suggest that the exchange reaction does not per se favor the formation of the Ran.GTP complex, but rather accelerates the formation of the equilibrium dictated by the relative affinities of Ran for GDP/GTP and the respective concentrations of the nucleotide in the cell. The extent of Ran.GTP formation in vivo can be calculated using the constants derived.

Regulation of Cdc2/cyclin B activation by Ran, a Ras-related GTPase.

During the cell cycle, a checkpoint prevents the initiation of mitosis until S-phase is completed. The molecular mechanism may involve the RCC1 protein, which catalyses guanine nucleotide exchange on the Ras-related nuclear protein, Ran (or TC4). Genetic studies have suggested that RCC1 may be involved in sensing the replication state of DNA and controlling the activation of Cdc2/cyclin B protein kinase through Ran. In this report, we present direct biochemical evidence for the post-translational control of Cdc2/cyclin B activation by Ran. In a cell-free system of concentrated Xenopus egg extracts supplemented with nuclei, a mutant form of Ran (T24N) analogous to dominant inactive mutants of other Ras-related GTPases inhibits Cdc2/cyclin B activation in the presence of replicating nuclear DNA. This role for Ran is mediated through control of the tyrosine phosphorylation state of Cdc2 and appears to be distinct from other effects on nuclear import, nuclear formation and DNA replication. When extracts were supplemented with RCC1 protein prior to addition of Ran T24N, inhibition of Cdc2/cyclin B by Ran T24N was relieved. This suggests that Ran T24N may act in a dominant manner by sequestering RCC1 in an inactive form. In contrast to Ran T24N, a mutant of Ran (Q69L) defective in GTPase activity and hence locked in the GTP-bound state has no inhibitory effect on Cdc2/cyclin B activation. In the light of these results, we propose that generation of the GTP-bound form of Ran is required for Cdc2/cyclin B activation and entry into mitosis when this process is coupled to the progression of S-phase.

Crystal structure of the nuclear Ras-related protein Ran in its GDP-bound form.

The Ran proteins constitute a distinct branch of the superfamily of Ras-related GTP-binding proteins which function as molecular switches cycling between GTP-bound 'on' and GDP-bound 'off' states. Ran is located predominantly in the nucleus of eukaryotic cells and is involved in the nuclear import of proteins as well as in control of DNA synthesis and of cell-cycle progression. We report here the crystal structure at 2.3 A resolution of human Ran (Mr 24K) complexed with GDP and Mg2+. This structure reveals a similarity with the Ras core (G-domain) but with significant variations in regions involved in GDP and Mg2+ coordination (switch I and switch II regions in Ras), suggesting that there could be major conformational changes upon GTP binding. In addition to the G-domain, an extended chain and an alpha-helix were identified at the carboxy terminus. The amino-terminal (amino-acid residues MAAQGEP) stretch and the acidic tail (DEDDDL) appear to be flexible in the crystal structure.

Interaction of the nuclear GTP-binding protein Ran with its regulatory proteins RCC1 and RanGAP1.

The guanine nucleotide dissociation and GTPase reactions of Ran, a Ras-related nuclear protein, have been investigated using different fluorescence techniques to determine how these reactions are stimulated by the guanine nucleotide exchange factor RCC1 and the other regulatory protein, RanGAP1 (GTPase-activating protein). The intrinsic GTPase of Ran is one-tenth of the rate of p21ras and is even lower in the Ran(Q69L) mutant. Under saturating conditions the rate constant for the RanGAP1 stimulated GTPase reaction is 2.1 s-1 at 25 degrees C, which is a 10(5)-fold stimulation, whereas RanGAP1 has no effect on Ran(Q69L). The intrinsic guanine nucleotide dissociation rates of Ran are also very low and are likewise increased 10(5)-fold by the exchange factor RCC1. Methods to describe the reaction kinetically are presented. The Ran(T24N) mutant, which is analogous to the S17N mutant of p21ras, has decreased relative affinities for both GDP/GTP and favors GDP binding. However, it was found to interact almost normally with RCC1. The combination of these properties leads to stabilization of the Ran(T24N)-RCC1 complex and may result in vivo in depletion of RCC1 available for stimulating guanine nucleotide exchange.

RanGAP1 induces GTPase activity of nuclear Ras-related Ran.

The nuclear Ras-related protein Ran binds guanine nucleotide and is involved in cell cycle regulation. Models of the signal pathway predict Ran to be active as Ran.GTP at the initiation of S phase upon activation by the nucleotide exchange factor RCC1 and to be inactivated for the onset of mitosis by hydrolysis of bound GTP. Here a nuclear homodimeric 65-kDa protein, RanGAP1, is described, which we believe to be the immediate antagonist of RCC1. It was purified from HeLa cell lysates and induces GTPase activity of Ran, but not Ras, by more than 3 orders of magnitude. The Ran mutant Q69L, modeled after RasQ61L, which is unable to hydrolyze bound GTP, is insensitive to RanGAP1.

Functional expression in Escherichia coli of the mitotic regulator proteins p24ran and p45rcc1 and fluorescence measurements of their interaction.

The gene products for the mitotic regulator genes RCC1 and Ran, p45rcc1 and p24ran, were expressed in Escherichia coli, purified in large amounts, and characterized for their biochemical properties. p24ran binds guanine nucleotide as a 1:1 complex, which is only slowly released from the protein. p45rcc1 catalyzes the exchange of nucleotide bound to the guanine nucleotide binding protein p24ran in the same way as the protein purified from HeLa cells. Likewise, the nucleotide dissociation from HeLa cell-derived p24ran protein is equally efficient with recombinant and nonrecombinant proteins. The recombinant proteins form a strong complex which contains no bound nucleotide. The kinetics of nucleotide exchange on p24ran in the presence or absence of p45rcc1 can be conveniently monitored either by the direct tryptophan fluorescence of p24ran or by fluorescence energy transfer measurements involving fluorescent nucleotides.