Susan E. Wellman

Effects of anti-C23 (Nucleolin) antibody on transcription of ribosomal DNA in Chironomus salivary gland cells☆

Protein C23 (also called nucleolin or 100-kDa nucleolar protein) is a major nucleolar phosphoprotein involved in ribosome biogenesis. To determine the effects of protein C23 on preribosomal RNA (pre-rRNA) synthesis anti-C23 antiserum was microinjected into nuclei of Chironomus tentans salivary glands. Transcription was measured by incubation of the glands with 32P-labeled RNA precorsors followed by microdissection of nucleoli, RNA extraction, and electrophoretic analyses. Injection of the anti-C23 antibody caused a 2- to 3.5-fold stimulation of 32P incorporation into 38S pre-rRNA. No stimulation was observed in salivary glands injected with preimmune serum or antiserum preabsorbed with protein C23. The stimulatory effect was selective for pre-rRNA as indicated by the lack of stimulation of 32P incorporation into extranucleolar RNA. Injection of the antiserum produced little or no effect on pre-RNA processing as measured by the relative amounts of 32P-labeled intermediate cleavage products of pre-rRNA in stimulated versus control glands. When protein extracts of Chironomus tentans salivary gland nuclei were probed on Western blots with anti-C23 antibody the predominant cross-reacting species was a 110-kDa polypeptide which had an electrophoretic mobility similar to that of protein C23. These results suggest that protein C23 not only is involved in ribosome assembly but also plays a role in regulating the transcription of the preribosomal RNA.

Histone H1 variants differentially inhibit DNA replication through an affinity for chromatin mediated by their carboxyl-terminal domains.

Multiple forms of histone H1 are found in most mammalian tissues, and diversity in their temporal and spatial expression likely corresponds to diversity in function. Here, using Xenopus egg extracts, we show that while the somatic H1s significantly inhibit DNA replication in Xenopus sperm nuclei, little or no inhibition is seen in the case of the testes-specific variant, H1t. We suggest that differences in H1-chromatin interactions might explain some of the diversity in H1 function. To demonstrate this, we show that the somatic H1 variants preferentially assemble into chromatin relative to H1t. Differences in chromatin structure are seen depending on whether chromatin assembly occurs in the presence of somatic H1s or H1t. These data suggest that the mechanistic basis for some of the functional differences of H1 variants lies in their relative affinity for chromatin. Using a series of domain-switch mutants of H1(0) and H1t we identify the H1 carboxyl-terminal domains as the domains responsible for the differential affinity for chromatin and, concurrently, for the differential effects of H1 variants upon DNA replication.

A novel quantitative receptor autoradiography and in situ hybridization histochemistry technique using storage phosphor screen imaging

A new technique of image acquisition for quantitative receptor autoradiography and in situ hybridization histochemistry was developed using storage phosphor screen imaging. This method was at least 4-5 times faster than conventional film densitometry. Two of the advantages of the phosphor screen method are high sensitivity and wide linear range of response. Other aspects of this method were compared with those of conventional densitometry. Use of storage phosphor screen imaging will allow greatly increased speed of pharmacological screening procedures that utilize quantitative autoradiography.

Differential effects on GABAA receptor γ2-subunit messenger RNA by tolerance to and withdrawal from pentobarbital — an in situ hybridization study

The heterogeneity of the GABAA receptors has been confirmed structurally and functionally. The present study demonstrates the pharmacological heterogeneity of the GABAA receptors. Rats were rendered tolerant to pentobarbital by continuous intracerebroventricular infusion via osmotic minipumps and abruptly withdrawn from pentobarbital. In situ hybridization of mRNA coding for the GABAA receptor gamma 2-subunit showed decreases of mRNA levels in superior and inferior colliculus in pentobarbital tolerant rats compared to rats in withdrawal. In rats 24-hr after withdrawal from pentobarbital, increases of mRNA levels in neocortex, piriform cortex and in granular and Purkinje cell layers of the cerebellum were observed. These results indicate the fast adaptation of GABA synapses in response to abrupt withdrawal from chronic pentobarbital treatment. The differential responsiveness seen in different areas further confirms the pharmacological heterogeneity of the GABAA receptors. The observed increases and decreases of mRNA may underlie, at least in part, the previously reported changes in Bmax of GABAA receptor ligand binding sites.

Chronic pentobarbital administration alters γ‐aminobutyric acidA receptor α6‐subunit mRNA levels and diazepam‐insensitive [3H]Ro15‐4513 binding

In order to study the chronic effects of pentobarbital, a positive GABAA receptor modulator, on the inverse agonist binding of the benzodiazepine site, binding of [3H]Ro15‐4513 and levels of GABAA receptor α6‐subunit mRNA were investigated in the brains of pentobarbital‐tolerant/dependent animals, using receptor autoradiography and in situ hybridization histochemistry in consecutive brain sections. Pentobarbital was administered to rats either 60 mg/kg, i.p., once, for acute treatment, or 300 μg/10μl/h i.c.v. continuously for 6 days via osmotic minipumps to render rats tolerant to pentobarbital. Rats assigned to the dependent group were sacrificed 24 h after discontinuance of pentobarbital infusion, while those assigned to the tolerant group were sacrificed at the end of infusion. The α6 subunit mRNA was increased in the tolerant group only. Diazepam‐insensitive [3H]Ro15‐4513 binding was increased in the cerebellar granule layer of pentobarbital‐tolerant and ‐dependent rats. No alterations in these parameters were observed in acutely treated animals. These data suggest that chronic pentobarbital treatment induced expression of α6‐subunit mRNA. This was in contrast to α1‐ and γ2‐subunit mRNA, which in tolerant animals are unchanged, but for which withdrawal triggers a surge in levels. Because the α6‐subunit is a major component of the diazepam‐insensitive [3H]Ro15‐4513 binding site, the increased diazepam‐insensitive [3H]Ro15‐4513 binding implied de novo synthesis of the receptor subunit protein.

Pharmacokinetics of methyl parathion: A comparison following single intravenous, oral or dermal administration

Assessment of the risks posed by the residential use of methyl parathion requires an understanding of its pharmacokinetics after different routes of exposure. Thus, studies were performed using adult female rats to define the pharmacokinetic parameters for methyl parathion after intravenous injection and to apply the described model to an examination of its pharmacokinetics after single oral or dermal exposure. The pharmacokinetics of methyl parathion after intravenous administration (1.5 mg/kg) were best described by a three-compartment model; the apparent volume of the central compartment was 1.45 liters/kg, clearance was 1.85 liters/h/kg and the terminal half-life was 6.6 h with an elimination constant of 0.50 h(-1). The apparent oral absorption coefficient for methyl parathion (1.5 mg/kg) was 1.24 h(-1), and its oral bioavailability was approximately 20%. The latter likely includes a significant first pass effect. Concentrations of methyl parathion increased during the initial 10-60 min and then declined during the next 15-36 h. After dermal administration (6.25-25 mg/kg), methyl parathion concentrations peaked within 12-26 h and then declined dose dependently. The apparent dermal absorption coefficient was approximately 0.41 h(-1), and only two pharmacokinetic compartments could be distinguished. In conclusion, the pharmacokinetics of methyl parathion are complex and route dependent. Also, dermal exposure, because of sustained methyl parathion concentrations, may pose the greatest risk.

A comparison of cholinesterase activity after intravenous, oral or dermal administration of methyl parathion

Time-dependent changes in blood cholinesterase activity caused by single intravenous, oral or dermal administration of methyl parathion to adult female rats were defined. Intravenous and oral administration of 2.5 mg/kg methyl parathion resulted in rapid (<60 min) decreases in cholinesterase activity which recovered fully in vivo within 30–48 h. In contrast, spontaneous reactivation of cholinesterase in vitro was complete within 6 h at 37°C. Dermal administration of methyl parathion caused dose-dependent inhibition of cholinesterase activity which developed slowly (≧6 h) and was prolonged (≧48 h). Time- and route-dependent effects of methyl parathion on cholinesterase activity in brain and other tissues generally paralleled its effects on activity in blood. In conclusion, pharmacodynamics of methyl parathion differ substantially with route of exposure. Recovery of cholinesterase in vivo after intravenous or oral exposure may partially reflect spontaneous reactivation and suggests a rapid clearance of methyl parathion or its active metabolite methyl paraoxon. The more gradual and prolonged inhibition of cholinesterase caused by dermal administration is consistent with disposition of methyl parathion at a site from which it or methyl paraoxon is only slowly distributed. Thus, dermal exposure to methyl parathion may pose the greatest risk for long-term adverse effects.

CARBOXYL-TERMINAL PEPTIDES FROM HISTONE H1 VARIANTS : DNA BINDING CHARACTERISTICS AND SOLUTION CONFORMATION

The carboxyl-terminal domains of the histone H1 proteins bind to DNA and are important in condensation of DNA. Little is known about the details of the interactions between H1 histones and DNA, and in particular, there is little known about differences among variant H1 histones in their interactions with DNA. Questions concerning H1 histone-DNA affinity and H1 conformation were investigated using peptide fragments from the carboxyl terminal domains of four nonallelic histone H1 variant proteins (mouse H1-1, H1-4 and H1(0), and rat H1t). Three of the four peptides showed a slight preference for binding to a GC-rich region of a 214-base-pair DNA fragment, rather than to an AT-rich region. The fourth peptide, H1t, appeared to bind preferentially to the AT-rich region of the 214-base-pair fragment. The results show that these small peptides bind preferentially to a subset of DNA sequences: such sequence preference might be exhibited by the intact H1 histones themselves. CD spectra of the peptides, which are from regions of the proteins that are not compactly folded, showed that the alpha-helical content of the peptides was minimal if the peptides were in 10 mM phosphate buffer, but increased if the peptides were in 1M NaClO4 and 50% trifluoroethanol, conditions that are postulated to approximate certain aspects of binding to DNA. H1-4 peptide, which was predicted to be 70% alpha-helix, but was not alpha-helical in 10 mM phosphate buffer, appeared from difference CD spectra to be more alpha-helical when it was bound to DNA. The regions of the proteins from which these peptides are derived, which are extended in solution, may fold, forming alpha-helices, upon binding to DNA.

Secondary structure of synthetic peptides derived from the repeating unit of a giant secretory protein from Chironomus tentans

The secretory proteins of Chironomus tentans larvae, which are used to construct underwater feeding and pupation tubes, assemble into complexes in vitro. Members of a family of 1000 kDa proteins, the spIs, appear to form the fibrous backbone of the assembled complexes. The spIs consist of a core of tandemly repeating units of 60 to 90 amino acids that can be subdivided into two regions: the subrepeat region, made up of short internal repeats, and the constant region, which lacks simple subrepeats. We have synthesized peptides representative of the constant and subrepeat regions of one of the spIs, and have examined their secondary structure using Fourier transform IR and CD spectroscopy. The IR spectrum of the constant peptide indicates that this peptide has alpha-helical regions and beta-turns. The CD spectrum confirms this. The IR spectrum of the subrepeat peptide is similar to that of the poly(Gly)II helix, and also may indicate the presence of beta-turns. The CD spectrum is consistent with this helical structure. Extrapolation of these results to intact spIs is in agreement with secondary structure prediction and modeling studies. Our results indicate that the alpha-helices and poly(Gly)II-like helices are not arranged as coiled-coils, which are often found in fibrous proteins. We suggest that these structural elements may be in an unusual arrangement in the spIs, organized as alternating alpha-helices and poly(Gly)II or collagen-like helices, interspersed with beta-turns.

Spectroscopic studies of Manduca sexta and Sesamia nonagrioides chorion protein structure

The secondary structure of Manduca sexta and Sesamia nonagrioides chorion proteins has been studied in intact chorions using laser-Raman and Fourier transform infra-red (FTIR) spectroscopy and in a solution containing extracted and reassembled chorion proteins using circular dichroism (CD) spectroscopy. Laser-Raman and IR spectra suggest the predominance of antiparallel beta-pleated sheet structure in intact chorion proteins of both Lepidoptera species. The bands at 1673, 1674 cm-1 (amide I) and 1234-1238 cm-1 (amide III) in the laser-Raman spectra can best be interpreted as resulting from abundant antiparallel beta-pleated sheet structure. Analysis of the amide I band suggests that chorion proteins consist of 60-70% antiparallel beta-pleated sheet and 30-40% beta-turns. Supporting evidence for the prevalence of antiparallel beta-pleated sheet in chorion proteins was supplied using FTIR spectroscopy by the observation of a very intense absorption band at 1635 cm-1 (amide I) and of a weak band at 1530, 1525 cm-1 (amide II) from chorions of both species. Surprisingly, analysis of the CD spectra of extracted and reassembled chorion proteins suggests that, in solution, they retain a regular secondary structure most probably dominated by beta-pleated sheet. We therefore suggest that the prominent regular beta-sheet structure of chorion proteins may exist in solution and dictate the aggregation and polymerization process in vivo.