A domain distinct from nucleoplasmin's nuclear localization sequence influences its transport.

We constructed mutants of the prototypical, nuclear-accumulating protein nucleoplasmin and used them in both in vivo and in vitro nuclear transport assays to search for transport-influencing domains distinct from this protein's recognized nuclear localization sequence. We identified the polyglutamic acid tract on the amino flank of the nuclear localization sequence as being involved in two stages of nuclear transport. This poly-glu tract is required for the facilitated translocation of nucleoplasmin through the nuclear pore complex, and it also enhances the subsequent binding of nucleoplasmin within the nucleus.

Distinct phosphorylation sites differentially influence facilitated transport of an NLS-protein and its subsequent intranuclear binding.

We measured the nuclear transport of radiolabeled fusion proteins consisting of variants of the Simian Virus 40 large T antigen's nuclear localization sequence region linked to beta-galactosidase, itself a cytoplasmic protein. We microinjected the fusion protein variants into the cytoplasm of living Xenopus oocytes or supplied them to the surface of oil-isolated oocyte nuclei via paired beads or cytoplasm. Presence of the cdc2 kinase site (124T) on the amino flank of the nuclear localization sequence (126PKKKRKV132) greatly enhances facilitated transport through the nuclear pore complex; additional presence of the casein kinase II site (112S) enhances subsequent intranuclear binding.

Intranuclear binding of nucleoplasmin.

Many proteins--including not only structural proteins, but also enzymes, hormone receptors, and other transcription factors--accumulate to much higher nuclear than cytoplasmic concentrations. Nuclear localization sequences or signals (NLSs) within their primary structures entrain specific transport of these proteins through the nuclear pore complexes. This transport process is energy-dependent, but evidence for a true active transport mechanism is not conclusive. An alternative mechanism--facilitated transport of NLS proteins followed by their intranuclear binding--has been implicated by experiments with oil-isolated nuclei. However, there has been no agreement as to a role for binding in the in vivo nuclear accumulation of NLS-containing proteins. We demonstrate herein that a prototypical NLS protein, nucleoplasmin (Np), binds within the nucleus of the living Xenopus oocyte and that this binding accounts for its nuclear accumulation.

Nucleoplasmin associates with and is phosphorylated by casein kinase II.

Nucleoplasmin is a phosphorylated nuclear-accumulating protein. We report herein that the kinetics of its cytoplasm-->nucleus transport are affected by its degree of phosphorylation. Therefore, we sought to identify any protein kinase which specifically associates with nucleoplasmin. We discovered that nucleoplasmin co-isolates by two independent methods (immunoabsorption and chromatography) in a complex including a kinase which phosphorylates nucleoplasmin. The co-purifying kinase is casein kinase II-like because: (i) it phosphorylates casein; (ii) its phospho-transferase activity can be competed out by GTP; (iii) it is stimulated by polylysine; and (iv) it is inhibited by heparin. Moreover, a polyclonal antibody to the alpha (38 kDa) and alpha' (36 kDa) catalytic subunits of casein kinase II specifically recognizes 38 and 36 kDa polypeptides in the nucleoplasmin-complex, and a specific inhibitor of casein kinase II inhibits nucleoplasmin's nuclear transport. Additionally, we found that phosphorylation of nucleoplasmin by its associated casein kinase II is strongly inhibited by histones and that, in addition to nucleoplasmin, another protein (p100) in the nucleoplasmin-complex is phosphorylated by casein kinase II.

An NLS is sufficient to engage facilitated translocation by the nuclear pore complex and subsequent intranuclear binding.

We investigated the nuclear transport of a fusion protein consisting of a nuclear localization signal linked to beta-galactosidase, normally a cytoplasmic protein. We microinjected the radiolabeled fusion protein into the cytoplasm of living Xenopus oocytes or supplied it directly to the surface of the oil-isolated oocyte nucleus and measured its transport into the nucleus. Our data confirm that a nuclear localization signal is sufficient to entrain a protein's facilitated transport through the nuclear pore complex and its subsequent nuclear accumulation. Moreover, nuclear envelope micropuncture experiments determine that the fusion protein's accumulation results from its intranuclear binding, demonstrating that no specific region of a transported protein--other than the nuclear localization signal itself--is required for facilitated transport and intranuclear binding. Finally, we present evidence that the intranuclear binding of a transported protein requires not only its nuclear localization signal, but also its prior facilitated transport through the nuclear pore complex.

Nucleoplasmin uptake by facilitated transport and intranuclear binding.

Specific proteins are selectively translocated into the cell nucleus and accumulated therein, but the molecular mechanisms underlying this fundamental eukaryotic transport process remain obscure. We have employed a new experimental system with notable advantages for resolving protein translocation and accumulation mechanisms. Individual nuclei are isolated from oocytes under mineral oil and conjoined under the oil with either an aqueous bead or a similar volume of oocyte cytoplasm to form closed transport pairs. Using these pairs one can (i) present transportant proteins via the bead or cytoplasm to a minimally disturbed nucleus, (ii) monitor the intactness of the nuclear envelope, and (iii) separate pairs at various times after formation and measure the amount of transportant in each compartment. In addition, it is uniquely possible with these pairs to determine whether or not a transportant's concentration gradient constitutes a chemical activity gradient. This is done by puncturing the envelope, thus eliminating its normal sieving restrictions on diffusion, and measuring the effect on the transportant distributions. We demonstrate that a prototypical nuclear-accumulating protein, nucleoplasmin (Np), is translocated through the nuclear pore complex by a mechanism of facilitated transport, rather than active transport. We further show that Np's high accumulation results from subsequent intranuclear binding. Np's facilitated transport and intranuclear binding are both ATP-dependent, and the latter requires cytoplasmic protein(s).

Nuclear protein accumulation by facilitated transport and intranuclear binding.

Nuclear proteins are transported from the cytoplasm into the nucleus via nuclear envelope pore complexes (NPCs). At the molecular level, the mechanisms responsible for this transport remain obscure. However, it is known that, for many proteins, the process requires ATP and proceeds against formidable nucleocytoplasmic concentration gradients. Therefore, the NPC is often thought of as an active transport site. In this article, Philip Paine presents the alternative hypothesis that, on current evidence, protein translocation across the nuclear envelope and accumulation in the nucleus can equally well be explained by facilitated transport through the NPC and subsequent intranuclear binding.

The oocyte nucleus isolated in oil retains in vivo structure and functions.

We describe a technique for isolating the nucleus of the giant amphibian oocyte under paraffin oil. The method precludes the losses of small solutes and proteins that accompany isolation of nuclei into aqueous media. An individual oocyte is blotted, placed under oil, punctured near the animal pole and then squeezed to gently extrude the nucleus into the oil, thereby avoiding exposure to any aqueous environment. Light and electron microscopy of the oil-isolated nucleus demonstrate that its in vivo morphology is preserved. We also describe techniques that facilitate the study of nuclear functions under oil. Oil-isolated oocyte nuclei retain many in vivo functions for several hours, including size-selective envelope permeability, RNA synthesis and the ability to break down in response to cdc2/cyclin meiotic maturation promoting factor.

Polypeptide composition of normal and neoplastic human breast tissues and cells analyzed by two-dimensional gel electrophoresis.

The protein populations of epithelial cells cultured from two neoplastic and five non-neoplastic human breast tissues were resolved and displayed by two-dimensional polyacrylamide gel electrophoresis and silver-staining. With a computer-based image analysis system, we identified eight polypeptides which are present in both of the neoplastic cell lines, but absent from all five of the cultures of non-neoplastic breast cells. The eight polypeptides are not unique to cells cultured from neoplastic breast, because they are also found in cells cultured from non-breast tissues, both neoplastic and non-neoplastic. Two of the eight polypeptides (approximately Mr 25,000/pI 4.4 and approximately Mr 31,000/pI 5.5) are present in the patterns of whole tissue samples from infiltrating ductal carcinomas and absent in most normal breast tissue.

Nuclear protein synthesis in animal and vegetal hemispheres of Xenopus oocytes.

Experiments were conducted to determine if nuclear proteins are preferentially synthesized in the vicinity of the nucleus, a factor which could facilitate nucleocytoplasmic exchange. Using Xenopus oocytes, animal and vegetal hemispheres were separated by bisecting the cells in paraffin oil. It was initially established that protein synthesis is not affected by the bisecting procedure. To determine if nuclear protein synthesis is restricted to the animal hemisphere (which contains the nucleus), vegetal halves and enucleated animal halves were injected with [3H]leucine and incubated in oil for 90 min. The labeled cell halves were then fused with unlabeled, nucleated animal hemispheres that had been previously injected with puromycin in amounts sufficient to prevent further protein synthesis. Thus, labeled polypeptides which subsequently entered the nuclei were synthesized before fusion. Three hours after fusion, the nuclei were isolated, run on two-dimensional gels, and fluorographed. Approximately 200 labeled nuclear polypeptides were compared, and only 2 were synthesized in significantly different amounts in the animal and vegetal hemispheres. The results indicate that nuclear protein synthesis is not restricted to the cytoplasm adjacent to the nucleus.

Protein loss during nuclear isolation.

Cryomicrodissection makes possible the measurement of the entire in vivo protein content of the amphibian oocyte nucleus and provides a heretofore missing baseline for estimating protein loss during nuclear isolation by other methods. When oocyte nuclei are isolated into an aqueous medium, they lose 95% of their protein with a half-time of 250 s. This result implies an even more rapid loss of protein from aqueously isolated nuclei of ordinary-size cells.

In vivo distribution of proteins within a single cell.

Using the oocyte of Xenopus laevis, we present an experimental system, involving two-dimensional gel electrophoresis, for measuring unambiguously the nucleocytoplasmic distribution of proteins within a living cell.

Reference phase analysis of free and bound intracellular solutes. I. Sodium and potassium in amphibian oocytes.

A method is described for the quantitative determination of free and bound solute concentrations in the cytoplasm of intact cells. The method includes (a) introduction of a gelatin gel reference phase (RP) into the cytoplasm; (b) diffusion of dissolved substances between cytoplasm and RP, (c) cell quenching to - 196 degrees C to prevent subsequent solute redistributions, (d) ultra-low temperature microdissection to isolate RP and cytoplasm samples, and (e) analysis of isolates for solute and water content. In normal oocytes of the salamander, Desmognathus ochrophaeus, free or RP Na+ and K+ are 21.0 +/- 1.1 and 128.8 +/- 2.4 mu eq/ml, respectively, and vary stoichiometrically in altered oocytes. Overall cytoplasmic concentrations are 75.2 +/- 2.7 mu eq Na+/ml and 88.6 +/- 1.5 mu eq K+/ml. Cytoplasmic chemical activities are 16.2 mu eq Na+/ml and 99.2 mu eq K+/ml, corresponding to activity coefficients of 0.22 and 1.12, respectively. The results demonstrate unambiguously that (a) oocytes actively transport Na+ and K+, and (b) cytoplasm has important binding properties which differentiate it from an ordinary aqueous solution. These cytoplasmic properties are investigated in the following paper.

Reference phase analysis of free and bound intracellular solutes. II. Isothermal and isotopic studies of cytoplasmic sodium, potassium, and water.

The intracellular reference phase (RP) method and ultra-low temperature micro-dissection were used for isothermal and isotopic phase distribution studies of Na(+), K(+), and water in amphibian oocyte cytoplasm. One-third of the cytoplasmic water is available as solvent for [(3)H]sucrose. This fraction, designated c1, quantitatively coincides with the water volume in which Na(+) and K(+) are freely diffusible. Two-thirds of the cytoplasmic water is inaccessible to sucrose and is designated c2. The Na(+) and K(+) associated with c2 are extremely slowly exchanging (bound) and at different concentrations than in c1. The cations in c1 are in mass-action equilibria with those in c2, each described by an equation of the formC(c) (i) = C(c) (1) (i) + C(c) (2) (i) = q(i).C(RP) (i) + (max)C(c) (2) (i).f(C(RP) (i)in which C(c) (i) is the cytoplasmic Na(+) or K(+) concentration, C(c) (1) (i) is the free, and C(c) (2) (i) the bound cation concentration averaged over the cytoplasmic water. q(i) is the fractional free solute space, C(RP) (i) the RP concentration, (max)C(c) (2) (i) the concentration of binding sites, and the function f is satisfied by the Langmuir isotherm. Numerical values for the variables of the isotherm are determined. Activity coefficients are calculated from RP data and provide a basis for generalizing the oocyte results to other cells. The conclusion is drawn that both c1 and c2 are widely distributed in cells, and that cellular ionic activities involve two distinct systems: the cell-membrane system and an adsorbed water ion-exchange-like buffering system. Alternative explanations for the two-component cytoplasm are considered. A model is proposed in which c1 is a normal intracellular aqueous phase controlled by the plasma membrane, whereas c2 consists of water and ions adsorbed in hydrate crystalline structures. In oocytes these structures are identified with yolk platelets.