An abundant nucleolar phosphoprotein is associated with ribosomal DNA in Tetrahymena macronuclei.

An abundant 52-kDa phosphoprotein was identified and characterized from macronuclei of the ciliated protozoan Tetrahymena thermophila. Immunoblot analyses combined with light and electron microscopic immunocytochemistry demonstrate that this polypeptide, termed Nopp52, is enriched in the nucleoli of transcriptionally active macronuclei and missing altogether from transcriptionally inert micronuclei. The cDNA sequence encoding Nopp52 predicts a polypeptide whose amino-terminal half consists of multiple acidic/serine-rich regions alternating with basic/proline-rich regions. Multiple serines located in these acidic stretches lie within casein kinase II consensus motifs, and Nopp52 is an excellent substrate for casein kinase II in vitro. The carboxyl-terminal half of Nopp52 contains two RNA recognition motifs and an extreme carboxyl-terminal domain rich in glycine, arginine, and phenylalanine, motifs common in many RNA processing proteins. A similar combination and order of motifs is found in vertebrate nucleolin and yeast NSR1, suggesting that Nopp52 is a member of a family of related nucleolar proteins. NSR1 and nucleolin have been implicated in transcriptional regulation of rDNA and rRNA processing. Consistent with a role in ribosomal gene metabolism, rDNA and Nopp52 colocalize in situ, as well as by cross-linking and immunoprecipitation experiments, demonstrating an association between Nopp52 and rDNA in vivo.

Affinity purification of von Willebrand factor using ligands derived from peptide libraries.

The chromatographic purification of vWF (von Willebrand Factor) from human plasma represents a challenge because it consists of multimers with molecular weights ranging from 0.5 to 10 million Daltons. Phage peptide library screening yielded a lead peptide (RLRSFY) that interacts with vWF. Conservative substitutions of terminal residues of the lead peptide led to a second peptide, RVRSFY, which was more efficient in the affinity chromatographic purification of vWF from protein mixtures. Adsorption isotherm measurements indicated multiple interactions between vWF and the immobilized peptide RVRSFY. Increases in peptide density on the chromatographic supports resulted in stronger association constants and higher maximum protein binding capacities. When the peptide density was lower than 32 mg/mL, there was no measurable interaction between vWF and immobilized peptide RVRSFY in HEPES buffer containing 0.5 M NaCl at pH 7. An increase in peptide density from 32 to 60 mg/mL increased the association constants from 0.9 x 10(6) to 2 x 10(6) (M-1). Divalent salts (calcium and magnesium chloride) were used to elute the retained vWF with 82.5% of the activity recovered. The interactions between vWF and the immobilized peptide RVRSFY are dominated by ionic attractions and also involve hydrophobic interactions at close contact. Finally, the purification of vWF from crude material PEG filtrate of a cryoprecipitate of human plasma is demonstrated using affinity chromatography with immobilized N-acetyl-RVRSFYK.

Chemically derived peptide libraries: a new resin and methodology for lead identification.

We have developed a new resin for peptide synthesis that can be used to synthesize and evaluate directly combinatorial peptide libraries for binding target proteins. Fidelity of the peptide synthesis using this hydrophilic resin is comparable to polystyrene-based resins. Peptide libraries synthesized on this resin were probed by a two color PEptide Library Immunostaining Chromatographic ANalysis (PELICAN) technique for sequences binding the serine protease Factor IX zymogen. This PELICAN technique readily distinguishes between beads interacting with the reagents for target detection (blue beads) from those beads specific for the target protein itself (red beads). Validation of the PELICAN technique, as well as purification of Factor IX from plasma, is demonstrated utilizing this resin.

Phosphorylated and dephosphorylated linker histone H1 reside in distinct chromatin domains in Tetrahymena macronuclei.

Phosphorylated and dephosphorylated isoforms of Tetrahymena macronuclear H1 were separated from each other by cation-exchange high performance liquid chromatography and used to generate a pairwise set of antisera that discriminate the phosphorylation state of this linker histone. Affinity-purified antibodies from each sera recognize appropriate H1 isoforms and stain macronuclei under appropriate physiological conditions. Immunogold localizations demonstrate that phosphorylated and dephosphorylated H1 localize nonrandomly in distinct subdomains of macronuclear chromatin. Dephosphorylated H1 is strongly enriched in the electron-dense chromatin bodies that punctuate macronuclear chromatin. In contrast, phosphorylated H1 isoforms, as well as an evolutionarily conserved H2A.F/Z-like variant (hv1) believed to function in the establishment of transcriptionally competent chromatin, are modestly enriched at the periphery of chromatin bodies and in the surrounding euchromatin. Using antibodies against TATA-binding protein, we show that transcriptionally active chromatin lies outside of the chromatin bodies in an area relatively devoid of H1. Antibodies against general core histones are more or less evenly distributed across these domains. Together, these data are consistent with a model in which phosphorylation of H1, perhaps in association with hv1, loosens the binding of H1 in chromatin leading to chromatin decondensation as part of a first-step mechanism in gene activation. In contrast, our data support the view that dephosphorylation of this linker histone facilitates or stabilizes condensed, transcriptionally silent chromatin.

Generation and characterization of novel antibodies highly selective for phosphorylated linker histone H1 in Tetrahymena and HeLa cells.

Phosphorylated forms of Tetrahymena macronuclear histone H1 were separated from each other and from dephosphorylated H1 by cation-exchange HPLC. A homogeneous fraction of hyperphosphorylated macronuclear H1 was then used to generate novel polyclonal antibodies highly selective for phosphorylated H1 in Tetrahymena and in human cells. These antibodies fail to recognize dephosphorylated forms of H1 in both organisms and are not reactive with most other nuclear or cytoplasmic phosphoproteins including those induced during mitosis. The selectivity of these antibodies for phosphorylated forms of H1 in Tetrahymena and in HeLa argues strongly that these antibodies recognize highly conserved phosphorylated epitopes found in most H1s and from this standpoint Tetrahymena H1 is not atypical. Using these antibodies in indirect immunofluorescence analyses, we find that a significant fraction of interphase mammalian cells display a strikingly punctate pattern of nuclear fluorescence. As cells enter S-phase, nuclear staining becomes more diffuse, increases significantly, and continues to increase as cells enter mitosis. As cells exit from mitosis, staining with the anti-phosphorylated H1 antibodies is rapidly lost presumably owing to the dephosphorylation of H1. These immunofluorescent data document precisely the cell cycle changes in the level of H1 phosphorylation determined by earlier biochemical studies and suggest that these antibodies represent a powerful new tool to probe the function(s) of H1 phosphorylation in a wide variety of eukaryotic systems.

Temporal and spatial association of histone H2A variant hv1 with transcriptionally competent chromatin during nuclear development in Tetrahymena thermophila.

Vegetative cells of the ciliated protozoan Tetrahymena thermophila contain a transcriptionally active macronucleus and a transcriptionally inactive micronucleus. Although structurally and functionally dissimilar, these nuclei are products of a single postzygotic division during conjugation, the sexual phase of the life cycle. Immunocytochemical analyses during growth, starvation, and conjugation were used to examine the nuclear deposition of hv1, a histone H2A variant that is found in macronuclei and thought to play a role in transcriptionally active chromatin. Polyclonal antisera were generated using whole hv1 protein and synthetic peptides from the amino and carboxyl domains of hv1. The transcriptionally active macronuclei stained at all stages of the life cycle. Micronuclei did not stain during growth or starvation but stained with two of the sera during early stages of conjugation, preceding the stage when micronuclei become transcriptionally active. Immunoblot analyses of fractionated macro- and micronuclei confirmed the micronuclear acquisition of hv1 early in conjugation. hv1 staining disappeared from developing micronuclei late in conjugation. Interestingly, the carboxy-peptide antiserum stained micronuclei only briefly, late in development. The detection of the previously sequestered carboxyl terminus of hv1 may be related to the elimination of hv1 during the dynamic restructing of micronuclear chromatin that occurs as the micronucleus enters a transcriptionally incompetent state that is maintained during vegetative growth. These studies demonstrate that the transcriptional differences between macro- and micronuclei are associated with the loss of a chromatin component from developing micronuclei rather than its de novo appearance in developing macronuclei and argue that hv1 functions in establishing a transcriptionally competent state of chromatin.

Analysis of nucleosome assembly and histone exchange using antibodies specific for acetylated H4.

Using antibodies that specifically recognize the acetylated forms of histone H4, we show that it is possible to immunoprecipitate newly assembled (acetylated) nucleosomes. Newly replicated HeLa cell chromatin was labeled for 5-30 min with [3H]thymidine in the presence of sodium butyrate (thus inhibiting the deacetylation of newly deposited H4); bulk chromatin DNA was labeled for 24 h with [14C]thymidine. When soluble nucleosomes were incubated with immobilized antibodies, a comparison of the bound and unbound fractions showed up to a 65-fold enrichment for new chromatin DNA in the immunoprecipitate (bound), relative to the supernatant (unbound). No enrichment for new DNA was observed when preimmune control serum was used in a similar fashion. The enrichment for new DNA in the immunopellet was paralleled by a similar enrichment for all four newly synthesized histones. Acetylation was required for antibody recognition: When chromatin was replicated in the absence of butyrate (permitting histone deacetylation and chromatin maturation), equally low levels of new and old chromatin were immunoprecipitated, and no enrichment for new DNA was observed. Competition experiments confirmed these results. Analyses of histone deposition during the inhibition of DNA replication established that acetylated chromatin is the preferential target for H2A/H2B exchange. These experiments provide evidence for the highly selective assembly of newly synthesized H3, H2A, and H2B with acetylated H4, and for the involvement of histone acetylation in dynamic chromatin remodeling. In addition, immunoprecipitations of radiolabeled cytosolic extracts identified a possible somatic chromatin preassembly complex, containing newly synthesized H3 and new (acetylated) H4.

Fractionation of small tryptic phosphopeptides by alkaline PAGE followed by amino acid sequencing.

A novel two-step approach for localizing the site(s) of phosphorylation within intact proteins is described. Phosphorylated (32P-labeled) tryptic peptides are first resolved in a high-percentage polyacrylamide gel that has been optimized for the enrichment and separation of small, negatively charged peptides. Then the resolved peptides are located by autoradiography, excised, eluted and immobilized on a positively charged membrane, Immobilon -N, where they can be sequenced directly. The methods have been developed using a small, basic phosphoprotein (histone H1 from Tetrahymena); however, the approach is probably applicable to a wide variety of phosphoproteins.

Synthesis of soluble and insoluble elastins in cultures of chick aortic cells.

Aortic cells were isolated from 9- and 12-day embryonic chick aortas and cultured for varying periods after first passage. Cells obtained from 9-day tissue remained indefinitely as monolayers and possessed a relatively low rate of tropoelastin synthesis. Cells obtained from 12-day tissue remained monolayers for 4 to 8 days, after which time portions of the culture contracted into matrix containing chemically definable insoluble elastin and forming desmosine cross-links. The rate of tropoelastin synthesis was significantly higher in the 12-day derived cells suggesting that these cells had been committed to elastogenesis in vivo and retained this commitment in vitro. A chick tropoelastin cDNA was obtained and partially characterized from a lambda gt11 expression cDNA library. Using the tropoelastin cDNA probe, measurement of the steady-state level of tropoelastin revealed that the increased rate of tropoelastin synthesis in the 12-day cells was accompanied by a significant increase in the level of tropoelastin mRNA steady-state levels. The aortic cell cultures present an important model system for extending studies of chick aortic elastogenesis. The aortic cell cultures synthesize tropoelastin at a rate 10% less than the corresponding organ culture. Significantly, the production of tropoelastin is productive in formation of insoluble, chemically definable elastin. The definition of insoluble includes both amino acid composition and desmosine formation.