Testis-specific linker histone H1t is multiply phosphorylated during spermatogenesis. Identification of phosphorylation sites.

During normal spermatogenesis, the testis-specific linker histone H1t appears at pachytene stage becomes phosphorylated in early spermatids and disappears in late spermatids. Using reversed-phase and hydrophilic interaction liquid chromatography, H1t from rat and mouse testes was isolated, subjected to enzymatic digestion, and analyzed by mass spectrometry. We observed different phosphorylated states of H1t (mono-, di-, and triphosphorylated) as well as the unphosphorylated protein. Tandem mass spectrometry and immobilized metal ion affinity chromatography experiments with MS/MS/MS and multistage activation were utilized to identify five phosphorylation sites on H1t from rats. Phosphorylation occurs on both serine and threonine residues, whereas only two of these sites were located on peptides containing the CDK consensus motif (S/T)PXZ. Rat H1t phosphorylation starts first by phosphorylation of the nonconsensus motif SPKS in the COOH-terminal domain, namely at Ser-140 and to a smaller degree at a further nonconsensus motif at Ser-186. This is followed by phosphorylation of Ser-177 and Thr-155, both located in CDK consensus motifs. A single phosphorylation site at Ser-8 in the NH2-terminal tail was also found. Mouse H1t lacks Ser-186 and is phosphorylated at up to four sites. In contrast to somatic linker histones, no strict order of increasing phosphorylation could be detected in H1t. Thus, it appears that not the order of up-phosphorylation but the number of the phosphate groups is necessary for regulated chromatin decondensation, thus facilitating the substitution of H1t by transition proteins and protamines.

Glucose induces anion conductance and cytosol-to-membrane transposition of ICln in INS-1E rat insulinoma cells.

The metabolic coupling of insulin secretion by pancreatic beta cells is mediated by membrane depolarization due to increased glucose-driven ATP production and closure of K(ATP) channels. Alternative pathways may involve the activation of anion channels by cell swelling upon glucose uptake. In INS-1E insulinoma cells superfusion with an isotonic solution containing 20 mM glucose or a 30% hypotonic solution leads to the activation of a chloride conductance with biophysical and pharmacological properties of anion currents activated in many other cell types during regulatory volume decrease (RVD), i.e. outward rectification, inactivation at positive membrane potentials and block by anion channel inhibitors like NPPB, DIDS, 4-hydroxytamoxifen and extracellular ATP. The current is not inhibited by tolbutamide and remains activated for at least 10 min when reducing the extracellular glucose concentration from 20 mM to 5 mM, but inactivates back to control levels when cells are exposed to a 20% hypertonic extracellular solution containing 20 mM glucose. This chloride current can likewise be induced by 20 mM 3-Omethylglucose, which is taken up but not metabolized by the cells, suggesting that cellular sugar uptake is involved in current activation. Fluorescence resonance energy transfer (FRET) experiments show that chloride current activation by 20 mM glucose and glucose-induced cell swelling are accompanied by a significant, transient redistribution of the membrane associated fraction of ICln, a multifunctional 'connector hub' protein involved in cell volume regulation and generation of RVD currents.

Afamin is a novel human vitamin E-binding glycoprotein characterization and in vitro expression.

Hydrophobic vitamins are transported in human plasma and extravascular fluids by carrier proteins. No specific protein has been described so far for vitamin E, which plays a crucial role in protecting against oxidative damage and disease. We report here the purification of a 75-kDa glycoprotein with vitamin E-binding properties by stepwise chromatography of lipoprotein-depleted human plasma and monitoring of vitamin E (alpha-tocopherol)-binding activity. Partial sequencing identified this protein as afamin, a previously described member of the albumin gene family with four or five potential N-glycosylation sites. Glycosylation analysis indicated that >90% of the glycans were sialylated biantennary complex structures. The vitamin E-binding properties were confirmed using recombinantly expressed afamin. Qualitative and quantitative analysis of plasma and extravascular fluids revealed an abundant presence of this protein not only in plasma (59.8+/-13.3 microg/mL) but also in extravascular fluids such as follicular (34.4+/-12.7 microg/mL) and cerebrospinal (0.28+/-0.16 microg/mL) fluids, suggesting potential roles for afamin in fertility and neuroprotection. Afamin is partly (13%) bound to plasma lipoproteins. Afamin and vitamin E concentrations significantly correlate in follicular and cerebrospinal fluids but not in plasma. The vitamin E association of afamin in follicular fluid was directly demonstrated by gel filtration chromatography and immunoprecipitation which complements the in vitro findings for purified native and recombinant afamin.

A new gene-finding tool: using the Caenorhabditis elegans operons for identifying functional partner proteins in human cells.

How can a large number of different phenotypes be generated by a limited number of genotypes? Promiscuity between different, structurally related and/or unrelated proteins seems to provide a plausible explanation to this pertinent question. Strategies able to predict such functional interrelations between different proteins are important to restrict the number of putative candidate proteins, which can then be subjected to time-consuming functional tests. Here we describe the use of the operon structure of the nematode genome to identify partner proteins in human cells. In this work we focus on ion channels proteins, which build an interface between the cell and the outside world and are responsible for a growing number of diseases in humans. However, the proposed strategy for the partner protein quest is not restricted to this scientific area but can be adopted in virtually every field of human biology where protein-protein interactions are assumed.

Cell swelling stimulates cytosol to membrane transposition of ICln.

ICln is a multifunctional protein that is essential for cell volume regulation. It can be found in the cytosol and is associated with the cell membrane. Besides its role in the splicing process, ICln is critically involved in the generation of ion currents activated during regulatory volume decrease after cell swelling (RVDC). If reconstituted in artificial bilayers, ICln can form ion channels with biophysical properties related to RVDC. We investigated (i) the cytosol versus cell membrane distribution of ICln in rat kidney tubules, NIH 3T3 fibroblasts, Madin-Darby canine kidney (MDCK) cells, and LLC-PK1 epithelial cells, (ii) fluorescence resonance energy transfer (FRET) in living fibroblasts between fluorescently tagged ICln and fluorochromes in the cell membrane, and (iii) possible functional consequences of an enhanced ICln presence at the cell membrane. We demonstrate that ICln distribution in rat kidneys depends on the parenchymal localization and functional state of the tubules and that cell swelling causes ICln redistribution from the cytosol to the cell membrane in NIH 3T3 fibroblasts and LLC-PK1 cells. The addition of purified ICln protein to the extracellular solution or overexpression of farnesylated ICln leads to an increased anion permeability in NIH 3T3 fibroblasts. The swelling-induced redistribution of ICln correlates to altered kinetics of RVDC in NIH 3T3 fibroblasts, LLC-PK1 cells, and MDCK cells. In these cells, RVDC develops more rapidly, and in MDCK cells the rate of swelling-induced depolarization is accelerated if cells are swollen for a second time. This coincides with an enhanced ICln association with the cell membrane.

Mechanisms sensing and modulating signals arising from cell swelling.

Cell volume alterations are involved in numerous cellular events like epithelial transport, metabolic processes, hormone secretion, cell migration, proliferation and apoptosis. Above all it is a need for every cell to counteract osmotic cell swelling in order to avoid cell damage. The defence against excess cell swelling is accomplished by a reduction of the intracellular osmolarity by release of organic- or inorganic osmolytes from the cell or by synthesis of osmotically less active macromolecules from their specific subunits. De-spite the large amount of experimental data that has accumulated, the intracellular mechanisms underlying the sensing of cell volume perturbations and the activation of volume compensatory processes, commonly summarized as regulatory volume decrease (RVD), are still only partly revealed. Moving into this field opens a complex scenario of molecular rearrangements and interactions involving intracellular messengers such as calcium, phosphoinositides and inositolphosphates as well as phosphoryla-tion/dephosphorylation processes and cytoskeletal reorganization with marked cell type- and tissue specific variations. Even in one and the same cell type significant differences regarding the activated pathways during RVD may be evident. This makes it virtually im-possible to unambigously define common sensing- and sinaling pathways used by differ-ent cells to readjust their celll volume, even if all these pathways converge to the activa-tion of comparatively few sets of effectors serving for osmolyte extrusion, including ion channels and transporters. This review is aimed at providing an insight into the manifold cellular mechanisms and alterations occuring during cell swelling and RVD.

Simvastatin inhibits malignant transformation following expression of the Ha-ras oncogene in NIH 3T3 fibroblasts.

In previous studies we have shown that the expression of the transforming Ha-ras oncogene in NIH 3T3 fibroblasts stimulates cellular calcium entry, which triggers oscillatory calcium induced calcium release from internal stores. The intracellular calcium oscillations lead to cytoskeletal remodeling by actin stress fiber depolymerization and activation of the Na(+)/H(+) exchanger thus mediating cell swelling and intracellular alkalosis, both important mitogenic signals. This is evidenced by abrogation of Ha-ras induced growth factor independent cell proliferation by interference with any of these events, i.e. by inhibition of cellular calcium entry or inhibition of the Na(+)/H(+) exchanger. As shown in this study, simvastatin, an inhibitor of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, the key enzyme for cholesterol biosynthesis, is able to prevent these events following the expression of the transforming Ha-ras oncogene. We show, that simvastatin inhibits farnesylation dependent membrane translocation of a CAAX motive bearing yellow fluorescent protein and suppresses Ha-ras stimulated cellular calcium influx, which can be identified as capacitative calcium entry. In addition simvastatin is able to block regulatory volume decrease channels and to suppress the cytoskeletal remodeling, intracellular alkalinization, increase in cell volume and growth factor independent cell proliferation induced by the oncogene. Thus simvastatin is able to prevent crucial cellular events following expression of the transforming Ha-ras oncogene.