Ran/TC4: a small nuclear GTP-binding protein that regulates DNA synthesis.

Ran/TC4, first identified as a well-conserved gene distantly related to H-RAS, encodes a protein which has recently been shown in yeast and mammalian systems to interact with RCC1, a protein whose function is required for the normal coupling of the completion of DNA synthesis and the initiation of mitosis. Here, we present data indicating that the nuclear localization of Ran/TC4 requires the presence of RCC1. Transient expression of a Ran/TC4 protein with mutations expected to perturb GTP hydrolysis disrupts host cell DNA synthesis. These results suggest that Ran/TC4 and RCC1 are components of a GTPase switch that monitors the progress of DNA synthesis and couples the completion of DNA synthesis to the onset of mitosis.

Characterization of four novel ras-like genes expressed in a human teratocarcinoma cell line.

A mixed-oligonucleotide probe was used to identify four ras-like coding sequences in a human teratocarcinoma cDNA library. Two of these sequences resembled the rho genes, one was closely related to H-, K-, and N-ras, and one shared only the four sequence domains that define the ras gene superfamily. Homologs of the four genes were found in genomic DNA from a variety of mammals and from chicken. The genes were transcriptionally active in a range of human cell types.

Effects of mutant Ran/TC4 proteins on cell cycle progression.

Ran/TC4, a member of the RAS gene superfamily, encodes an abundant nuclear protein that binds and hydrolyzes GTP. Transient expression of a Ran/TC4 mutant protein deficient in GTP hydrolysis blocked DNA replication, suggesting a role for Ran/TC4 in the regulation of cell cycle progression. To test this possibility, we exploited an efficient transfection system, involving the introduction of cDNAs in the pMT2 vector into 293/Tag cells, to analyze phenotypes associated with mutant and wild-type Ran/TC4 expression. Expression of a Ran/TC4 mutant protein deficient in GTP hydrolysis inhibited proliferation of transfected cells by arresting them predominantly in the G2, but also in the G1, phase of the cell cycle. Deletion of an acidic carboxy-terminal hexapeptide from the Ran/TC4 mutant did not alter its nuclear localization but did block its inhibitory effect on cell cycle progression. These data suggest that normal progression of the cell cycle is coupled to the operation of a Ran/TC4 GTPase cycle. Mediators of this coupling are likely to include the nuclear regulator of chromosome condensation 1 protein and the mitosis-promoting factor complex.

Aberrant function of the Ras-related protein TC21/R-Ras2 triggers malignant transformation.

Although the human Ras proteins are members of a large superfamily of Ras-related proteins, to date, only the proteins encoded by the three mammalian ras genes have been found to possess oncogenic potential. Among the known Ras-related proteins, TC21/R-Ras2 exhibits the most significant amino acid identity (55%) to Ras proteins. We have generated mutant forms of TC21 that possess amino acid substitutions analogous to those that activate Ras oncogenic potential [designated TC21(22V) and TC21(71L)] and compared the biological properties of TC21 with those of Ras proteins in NIH 3T3 and Rat-1 transformation assays. Whereas wild-type TC21 did not show any transforming potential in vitro, both TC21(22V) and TC21(71L) displayed surprisingly potent transforming activities that were comparable to the strong transforming activity of oncogenic Ras proteins. Like Ras-transformed cells, NIH 3T3 cells expressing mutant TC21 proteins formed foci of morphologically transformed cells in monolayer cultures, proliferated in low serum, formed colonies in soft agar, and developed progressive tumors in nude mice. Thus, TC21 is the first Ras-related protein to exhibit potent transforming activity equivalent to that of Ras. Furthermore, mutant TC21 proteins also stimulated constitutive activation of mitogen-activated protein kinases as well as transcriptional activation from Ras-responsive promoter elements (Ets/AP-1 and NF-kappa B). We conclude that aberrant TC21 function may trigger cellular transformation via a signal transduction pathway similar to that of oncogenic Ras and suggest that deregulated TC21 activity may contribute significantly to human oncogenesis.

Separate domains of the Ran GTPase interact with different factors to regulate nuclear protein import and RNA processing.

The small Ras-related GTP binding and hydrolyzing protein Ran has been implicated in a variety of processes, including cell cycle progression, DNA synthesis, RNA processing, and nuclear-cytosolic trafficking of both RNA and proteins. Like other small GTPases, Ran appears to function as a switch: Ran-GTP and Ran-GDP levels are regulated both by guanine nucleotide exchange factors and GTPase activating proteins, and Ran-GTP and Ran-GDP interact differentially with one or more effectors. One such putative effector, Ran-binding protein 1 (RanBP1), interacts selectively with Ran-GTP. Ran proteins contain a diagnostic short, acidic, carboxyl-terminal domain, DEDDDL, which, at least in the case of human Ran, is required for its role in cell cycle regulation. We show here that this domain is required for the interaction between Ran and RanBP1 but not for the interaction between Ran and a Ran guanine nucleotide exchange factor or between Ran and a Ran GTPase activating protein. In addition, Ran lacking this carboxyl-terminal domain functions normally in an in vitro nuclear protein import assay. We also show that RanBP1 interacts with the mammalian homolog of yeast protein RNA1, a protein involved in RNA transport and processing. These results are consistent with the hypothesis that Ran functions directly in at least two pathways, one, dependent on RanBP1, that affects cell cycle progression and RNA export, and another, independent of RanBP1, that affects nuclear protein import.

Isolated mammalian and Schizosaccharomyces pombe ran-binding domains rescue S. pombe sbp1 (RanBP1) genomic mutants.

Mammalian Ran-binding protein-1 (RanBP1) and its fission yeast homologue, sbp1p, are cytosolic proteins that interact with the GTP-charged form of Ran GTPase through a conserved Ran-binding domain (RBD). In vitro, this interaction can accelerate the Ran GTPase-activating protein-mediated hydrolysis of GTP on Ran and the turnover of nuclear import and export complexes. To analyze RanBP1 function in vivo, we expressed exogenous RanBP1, sbp1p, and the RBD of each in mammalian cells, in wild-type fission yeast, and in yeast whose endogenous sbp1 gene was disrupted. Mammalian cells and wild-type yeast expressing moderate levels of each protein were viable and displayed normal nuclear protein import. sbp1(-) yeast were inviable but could be rescued by all four exogenous proteins. Two RBDs of the mammalian nucleoporin RanBP2 also rescued sbp1(-) yeast. In mammalian cells, wild-type yeast, and rescued mutant yeast, exogenous full-length RanBP1 and sbp1p localized predominantly to the cytosol, whereas exogenous RBDs localized predominantly to the cell nucleus. These results suggest that only the RBD of sbp1p is required for its function in fission yeast, and that this function may not require confinement of the RBD to the cytosol. The results also indicate that the polar amino-terminal portion of sbp1p mediates cytosolic localization of the protein in both yeast and mammalian cells.

A T42A Ran mutation: differential interactions with effectors and regulators, and defect in nuclear protein import.

Ran, the small, predominantly nuclear GTPase, has been implicated in the regulation of a variety of cellular processes including cell cycle progression, nuclear-cytoplasmic trafficking of RNA and protein, nuclear structure, and DNA synthesis. It is not known whether Ran functions directly in each process or whether many of its roles may be secondary to a direct role in only one, for example, nuclear protein import. To identify biochemical links between Ran and its functional target(s), we have generated and examined the properties of a putative Ran effector mutation, T42A-Ran. T42A-Ran binds guanine nucleotides as well as wild-type Ran and responds as well as wild-type Ran to GTP or GDP exchange stimulated by the Ran-specific guanine nucleotide exchange factor, RCC1. T42A-Ran.GDP also retains the ability to bind p10/NTF2, a component of the nuclear import pathway. In contrast to wild-type Ran, T42A-Ran.GTP binds very weakly or not detectably to three proposed Ran effectors, Ran-binding protein 1 (RanBP1), Ran-binding protein 2 (RanBP2, a nucleoporin), and karyopherin beta (a component of the nuclear protein import pathway), and is not stimulated to hydrolyze bound GTP by Ran GTPase-activating protein, RanGAP1. Also in contrast to wild-type Ran, T42A-Ran does not stimulate nuclear protein import in a digitonin permeabilized cell assay and also inhibits wild-type Ran function in this system. However, the T42A mutation does not block the docking of karyophilic substrates at the nuclear pore. These properties of T42A-Ran are consistent with its classification as an effector mutant and define the exposed region of Ran containing the mutation as a probable effector loop.

Identification and characterization of a human homolog of the Schizosaccharomyces pombe ras-like gene YPT-3.

The Polymerase Chain Reaction was used to amplify ras and ras-like sequences from two human cDNA libraries. Members corresponding to each of the three major ras-subfamilies (ras, rho, and rab/YPT) were identified. The one homologous to rab/YPT, referred to here as YL8, appears to be the human homolog of the recently reported Schizosaccharomyces pombe YPT3 gene. The YL8 gene could encode a guanine nucleotide binding protein of 216 amino acids with about 70% amino acid sequence identity to S. pombe YPT3, and is transcriptionally active in a variety of human cell lines.

Cellular functions of TC10, a Rho family GTPase: regulation of morphology, signal transduction and cell growth.

The small Ras-related GTPase, TC10, has been classified on the basis of sequence homology to be a member of the Rho family. This family, which includes the Rho, Rac and CDC42 subfamilies, has been shown to regulate a variety of apparently diverse cellular processes such as actin cytoskeletal organization, mitogen-activated protein kinase (MAPK) cascades, cell cycle progression and transformation. In order to begin a study of TC10 biological function, we expressed wild type and various mutant forms of this protein in mammalian cells and investigated both the intracellular localization of the expressed proteins and their abilities to stimulate known Rho family-associated processes. Wild type TC10 was located predominantly in the cell membrane (apparently in the same regions as actin filaments), GTPase defective (75L) and GTP-binding defective (31N) mutants were located predominantly in cytoplasmic perinuclear regions, and a deletion mutant lacking the carboxyl terminal residues required for post-translational prenylation was located predominantly in the nucleus. The GTPase defective (constitutively active) TC10 mutant: (1) stimulated the formation of long filopodia; (2) activated c-Jun amino terminal kinase (JNK); (3) activated serum response factor (SRF)-dependent transcription; (4) activated NF-kappaB-dependent transcription; and (5) synergized with an activated Raf-kinase (Raf-CAAX) to transform NIH3T3 cells. In addition, wild type TC10 function is required for full H-Ras transforming potential. We demonstrate that an intact effector domain and carboxyl terminal prenylation signal are required for proper TC10 function and that TC10 signals to at least two separable downstream target pathways. In addition, TC10 interacted with the actin-binding and filament-forming protein, profilin, in both a two-hybrid cDNA library screen, and an in vitro binding assay. Taken together, these data support a classification of TC10 as a member of the Rho family, and in particular, suggest that TC10 functions to regulate cellular signaling to the actin cytoskeleton and processes associated with cell growth.

Preparation of radioiodinated simian virus 40 DNA for use in DNA - DNA reassociation kinetics experiments.

A method is described for the preparation of 125I-labelled SV40 DNA. Using this method, SV40 DNA can be routinely labelled to 15 - 10(6) dpm per mug; much higher specific activities are easily obtained by minor modifications of the method. Once incorporated, the radioactive label dissociates from DNA exceedingly slowly at 4 degrees C or at 68 degrees C. Iodinated SV40 DNA is shown to be useful in the quantitation of viral nucleic acid sequences in SV40-transformed 3T3 cells by DNA - DNA reassociation kinetics.

The KpnI family of long interspersed nucleotide sequences is present on discrete sizes of circular DNA in monkey (BSC-1) cells.

Discretely sized molecules of small circular DNAs in African green monkey kidney (BSC-1) cells contain nucleotide sequences homologous to the KpnI family of long interspersed repetitive nucleotide sequences. The size distribution of these KpnI family-containing circular DNAs differs markedly from those of BSC-1 cell circular DNAs containing either the Alu family of short interspersed nucleotide sequences or the alpha-satellite family of tandemly repeated sequences. The structures of several cloned, apparently whole, KpnI family-related circular DNAs of varying sizes were analyzed and compared with a compilation of chromosomal KpnI sequences. In general, it was found that the cloned DNAs all contained only KpnI sequences, and that the recombination events given rise to them did not involve any noticeable gain of nucleotides.

Some extrachromosomal circular DNAs containing the Alu family of dispersed repetitive sequences may be reverse transcripts.

A 300 base-pair (bp) size class of small polydisperse circular DNA (spcDNA) isolated from the BSC-1 line of African Green monkey kidney cells was cleaved with the restriction endonuclease Sau3A, and the resulting fragments (100 to 200 bp) were cloned in bacteriophage M13 mp7. The nucleotide sequence of each of 24 clones containing DNA sequences homologous to the Alu family of mobile, dispersed, repetitive elements was then determined. Analysis of these sequences revealed that many, and perhaps all, of the 300 bp Alu-containing spcDNAs had regions in which the 5' and 3' ends of the normal Alu element were juxtaposed and covalently joined. Although more than one model can explain the generation of such circular molecules, the most attractive one at this time involves their generation from reverse transcripts of Alu-specific RNAs.

Structure of extrachromosomal circular DNAs containing both the Alu family of dispersed repetitive sequences and other regions of chromosomal DNA.

Small polydisperse circular DNA (spcDNA) isolated from the BSC-1 line of African Green monkey kidney cells was digested with the restriction endonuclease BamHI and cloned in bacteriophage lambda. The resulting library of 25,000 phage was then screened for the presence of the Alu family of short interspersed nucleotide sequences, and four of the 100 Alu-positive clones were characterized. In summary: (1) all four clones contained regions other than Alu that were homologous to the BSC-1 chromosome. Two contained Alu plus unique chromosomal DNA, one contained Alu plus an uncharacterized repetitive chromosomal DNA, and one contained Alu plus both unique and a specific tandemly repeated chromosomal DNA (alpha-satellite); (2) all four clones were derived from extrachromosomal circular DNAs and not from the accidental cloning of a very small amount of contaminating chromosomal material assumed to be present in spcDNA preparations; and (3) one clone represented an intact circular DNA with a restriction endonuclease cleavage map that was a circularly permuted version of its chromosomal homologue.

Opposing effects of retinoic acid and dexamethasone on cellular retinol-binding protein ribonucleic acid levels in the rat.

Cellular retinol-binding protein (CRBP) is a potential mediator of vitamin A action. To determine whether retinoic acid and dexamethasone administration, alone and in combination, influence CRBP gene expression, adult female vitamin A-sufficient Sprague-Dawley rats randomly received 1) all-trans retinoic acid (100 micrograms) by intragastric intubation, 2) dexamethasone (2 micrograms/g BW) by ip injection, or 3) both all-trans retinoic acid and dexamethasone in the same doses. Control animals received either cottonseed oil by intragastric intubation or saline by ip injection. Six hours after treatment, lung and liver tissue were collected for Northern blot analysis with the radiolabeled cDNA specific for rat CRBP. Retinoic acid administration increased the amount of lung CRBP mRNA only, whereas dexamethasone decreased both lung and liver CRBP mRNA abundance. In animals treated with both retinoic acid and dexamethasone, CRBP mRNA abundance was also reduced. We conclude that CRBP gene expression can be modulated by both retinoic acid and dexamethasone in the vitamin A-sufficient animal. In the whole animal, our findings indicate that dexamethasone not only represses CRBP gene expression, but also opposes the effect of retinoic acid.

Current therapy of bronchopulmonary dysplasia.

In summary, little progress has been made in the past several years with respect to the treatment of the baby with BPD. The conduct of convincing clinical research seems to be a casualty of budget cuts and a rush to learn the tools of molecular biology. To date, there are no clinical trials that have convincingly demonstrated that long-term diuretic, bronchodilator, vasodilator, or antioxidant therapy is effective in the treatment of chronic BPD. Short-term corticosteroid therapy hastens extubation, but long-term outcome is unaffected and serious questions remain about its safety. Multicenter clinical trials should be carefully designed and implemented to address the values of these therapies. In the design of these trials, care should be taken to stratify treatment groups for known risk factors for BPD. What are the future directions for the treatment of BPD? It is hoped that new BPD treatment strategies will be based on an improved understanding of mechanisms of lung repair and inflammation. Enzyme, gene, cytokine, antioxidant, and antiprotease therapies are being developed in animal models of lung injury. In addition, the use of lung transplantation has begun to be explored for severe cases of BPD. It is also possible, as has occurred in many chronic idiopathic diseases, that nonspecific treatment may prove beneficial. Perhaps it is only a matter of time before intravenous immunoglobulin, cyclosporine, methotrexate, or "biological response modifiers" will be administered to infants with severe BPD. For example, there is anecdotal evidence that recombinant human growth hormone may improve respiratory muscle function in adults with chronic obstructive pulmonary diseases. In the absence of convincing clinical trials, the clinician should reserve existing therapies for the ventilator-dependent infant or infants whose high oxygen requirement is prohibiting discharge or resulting in complex home care or frequent rehospitalizations. It should be emphasized that continuous oxygen therapy combined with avoidance of environmental inhalant and infectious hazards have the strongest rationale and widest margin of safety for treatment of the infant with BPD. Ironically, oxygen therapy is frequently underutilized and discontinued too rapidly. Early discontinuation of oxygen therapy with alveolar hypoxia results in feeding difficulty, slow growth, nutrient malabsorption, bronchoconstriction, and pulmonary hypertension. Oxygen therapy, although more cumbersome and certainly less glamorous than other pharmacologic agents, remains the essential element of BPD care.

Change in quantity and size distribution of small circular DNAs during development of chicken bursa.

Small circular DNAs ranging in contour length from 0.06 to 3.5 micrometers have been isolated from bursas of 19-day chicken embryos and 4- to 5-week-old chickens. Small circular DNA is present in bursas of 19-day embryos at approximately 0.2 molecules per cell and is very heterogeneous, lacking distinct size classes; most molecules have contour lengths of less than 0.04 micrometers. In contrast, small circular DNA is present in bursas of 4- to 5-week old chickens at about 4 molecules per cell, and although this DNA is still heterogeneous, it contains a major distinct class of molecules 0.8 micrometers in size. These small circular DNAs may be products of developmental gene rearrangements occurring in the chromosomal DNA of lymphocytes in the bursa.