Rapid disappearance of translatable actin mRNA during cell differentiation in Naegleria

Actin, the major protein of Naegleria gruberi, is selectively not synthesized during the differentiation of amebae to flagellates. When RNA extracted from cells at intervals during differentiation is translated in the wheat germ cell-free system, a major translation product with the electrophoretic mobility of actin is seen to disappear with time during differentiation. This translation product is shown to be actin by its electrophoretic mobility, copolymerization with rabbit actin, peptide map, and immunoprecipitation by antibodies specific to Naegleria actin. Multiple isoforms of actin are synthesized in the cell-free system. Quantitative immunoprecipitation of translation products was employed to measure the relative amount of actin mRNA. Translatable actin mRNA begins to decrease in abundance within 7 min after the initiation of differentiation and thereafter decreases with a half-life of about 25 min. The selective disappearance of this major translatable mRNA provides a favorable opportunity to dissect the rules governing the half-life of a specific mRNA.     

Proteins of vesicular stomatitis virus. V. Identification of a precursor to the phosphoprotein of Piry virus.

A metabolic precursor to the major phosphoprotein of Piry virus (NSv) has been identified in extracts of Piry virus-infected L cells. The conversion of the precursor NSi to NSv occurs with a half-life of 20 min and is independent of continued protein synthesis. NSi has a greater electrophoretic mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis than does the product NSv, suggesting an increase in molecular weight during maturation. The conversion is unaffected by cyclic AMP, cyclic GMP, or by theophilline and cordycepin. No decrease in isoelectric point of NSv relative to NSi was observed on isoelectric focusing acrylamide gels. These latter observations suggest that NSi and NSv do not differ in extent of phosphorylation. We also report, without further characterization, the identification of another phosphoprotein in Piry virus-infected cells having an electrophoretic mobility in sodium dodecyl sulfate-polyacrylamide gel electrophoresis just slightly greater than the nucleocapsid N protein.     

Changes in neurodynamic parameters of the human brain during an individual annual cycle

Neurodynamic parameters of the human brain and their changes depending on the trimester of an individual annual cycle (IAC), which lasts from one birthday to the next, were studied. In the course of a year, fourfold examination (in February, April, July, and October) of 124 men and 242 women aged from 18 to 20 years was carried out. According to psychological characteristics, the examined subjects were divided into introverts and extroverts. The strength and mobility of nervous processes in extrovert men tended to decrease in the fourth trimester of the IAC, simultaneously with a decrease in the overall state of health. Introvert men exhibited a lower brain efficiency than extrovert men; changes in their brain functional mobility during an IAC were more pronounced than in the case of extrovert men; the lowest parameters were recorded in the second trimester. Annual changes in neurodynamic parameters in women were smaller than in men.     

Hyperthyreosis inhibits the ability of actin to form strong-binding with myosin

The effect of hyperthyreosis development induced by the increase in thyroid hormones in rats (during 2-4 weeks) on the orientation and mobility of fluorescent probe N-(iodoacetyl)-(1-naphtyl-5-sulpho-ethylenediamine) specifically bound to Cys 374 of actin in ghost muscle fibers isolated from fast (EDL) and slow (SOL) rat muscles was studied. It was found that the binding of myosin subfragment-1 (S1) to F-actin induced the typical for the formation of strong binding actomyosin decrease in mobility of actin subdomain 1 and its rotation towards thin filament periphery. Development of hyperthyreosis markedly inhibited these phenomena. The maximal effect was observed after 21 days of disease development. It is suggested that one of the reasons of the contractile deficit of muscle in hyperthyreosis is inhibition of the strong binding between actin and myosin during ATPase cycle.     

The methyl-accepting chemotaxis proteins of E. coli: a repellent-stimulated, covalent modification, distinct from methylation

The methyl-accepting chemotaxis proteins (MCPs) of Escherichia coli are integral membrane proteins that have been shown to undergo reversible methylation in response to the addition of attractants. We have shown that a second, rapid modification of MCPI and MCPII occurs, which is repellent-stimulated. This modification, which is not methylation, was detected because it causes a decrease in mobility of the MCPs on 7.5% SDS-polyacrylamide gels with a high acrylamide to bisacrylamide ratio. We have designated this modification as the CheB-modification, as it is dependent on the CheB gene product. The CheB-modification causes a decrease in the isoelectric point of MCPII by one or two charge groups. The CheB-modification is not necessary for the methylation, nor does it preclude methylation of the MCPs. Both the CheB-modified form and the unmodified, unmethylated forms of the MCPs are stable to treatment with base, which results in the hydrolysis of the methylesters (demethylation) of the MCPs. The potential role of CheB-modification in chemotaxis is discussed.     

Comparative-physiological study of leukocyte participation in initiation of lipid peroxidation during nitrite intoxication in rats and muskrats

The study is carried out on Wistar white rats non-adapted to oxygen deficit and on semiaquatic rodents muskrats adapted to periodic arrest of respiration during diving under conditions of Nembutal narcosis. It has been revealed that 1 h after a subcutaneous injection of sodium nitrite (3 mg/100 g body mass), intensification of lipid peroxidation (LPO) in the muskrat brain is absent, the activity of the antioxidant enzyme catalase increasing 16 times (p < 0.01) as compared with control injected with equivalent saline volume. In heart and liver, there was a statistically significant decrease of the content of LPO products active in the test with 2-thiobarbituric acid; in the femoral muscle tissue, the LPO intensity did not change. In rats, unlike muskrats, after injection of sodium nitrite, an increase of LPO is recorded in brain, while a decrease of the LPO product content in the femoral muscle; in liver the LPO intensity did not change. In muskrats, the sodium nitrite administration led to a decrease of the leukocyte spontaneous mobility, of lymphocyte cytokine-producing activity, and of neutrophil bactericidal activity (by the content of cationic proteins in neutrophilic phagocytes), whereas in rats the leukocyte mobility did not change, only the blood neutrophil bactericidal activity decreased. The ability of neutrophils to produce the superoxide anion during the nitrite intoxication did not change both in rats and in muskrats. The obtained data allow concluding that under conditions of Nembutal narcosis the leukocyte functional activity on the background of nitrite intoxication is suppressed to the greater degree in the muskrats genotypically adapted to oxygen deficit than in immunocompetent cells of the rodents not adapted to hypoxia.     

Effect of Long-Term Storage on Water Status and Physicochemical Properties of Nutritionally Enhanced Tortillas

The effect of functional ingredients (carrot juice, whole soy flour, and whole kamut flour) and storage (180 days) on physicochemical properties (texture and amylopectin recrystallization) and water status (moisture content, water activity, ice melting peak thermal properties, and proton nuclear magnetic resonance (¹H NMR) mobility) of tortillas has been studied. Different formulations significantly changed the parameters studied during storage resulting in larger changes than in the standard formulation (STD) that, therefore, may be considered the most stable product. The properties of whole kamut tortillas were very similar to those of standard sample while the formulation that contained carrot juice lead to an increased system rigidity observable both at macroscopic (textural properties), macromolecular (significantly reduced), and molecular (¹H FID) levels. A decrease of moisture content, water activity, endothermic transition ~0 °C, and an increase of ¹H NMR mobility (¹H T₂ pop A and C) were observed in soy-containing products [(soy enriched (SOY) and carrot, soy, and kamut (CSK)]. SOY and CSK had very low water activity, presented the highest ¹H NMR molecular mobility and underwent the most marked changes during storage suggesting that water activity cannot be taken as a sole indicator of food stability as very important modifications occurred in tortillas at molecular level.     

A study by polyacrylamide-gel electrophoresis of the effect of proteolysis on Micrococcus lysodeikticus polynucleotide phosphorylase

1. Trypsin digestion of Micrococcus lysodeikticus polynucleotide phosphorylase (nucleoside diphosphate-polynucleotide nucleotidyltransferase) causes a progressive increase in electrophoretic mobility in polyacrylamide gels of the single active degradation product. 2. A marked increase in primer requirement for CDP polymerization occurs before a more mobile product is formed. 3. alpha-Chymotrypsin digestion yields a product that separates into several active species on polyacrylamide-gel electrophoretograms. 4. No separation of ADP-and CDP-polymerization activities occurs during electrophoresis after either trypsin or alpha-chymotrypsin treatment.     

Oxygen-17 NMR relaxation studies on gelatinization temperature and water mobility in maize starches

The effects of starch/water ratio, amylose content, degree of phosphorylation, and added KI on water mobility in maize starch-water dispersions were studied by oxygen-17 spin-spin relaxation time measurements over a range of temperatures. The results demonstrate that: (i) the changes in spin-spin relaxation time (ΔT₂) reflect the degree of starch-water interaction at different stages of the heating process; (ii) the amount of added water affects the initial T₂ and ΔT₂ during gelatinization; (iii) higher amylose contents result in lower water mobility in starch-water systems; (iv) higher degrees of phosphorylation lead to a decrease in water mobility, accompanied by a decrease in gelatinization temperature; and (v) added KI effectively decreases water mobility and gelatinization temperature in the starch-water systems studied.     

Gephyrin-independent GABA(A)R mobility and clustering during plasticity

The activity-dependent modulation of GABA-A receptor (GABA(A)R) clustering at synapses controls inhibitory synaptic transmission. Several lines of evidence suggest that gephyrin, an inhibitory synaptic scaffold protein, is a critical factor in the regulation of GABA(A)R clustering during inhibitory synaptic plasticity induced by neuronal excitation. In this study, we tested this hypothesis by studying relative gephyrin dynamics and GABA(A)R declustering during excitatory activity. Surprisingly, we found that gephyrin dispersal is not essential for GABA(A)R declustering during excitatory activity. In cultured hippocampal neurons, quantitative immunocytochemistry showed that the dispersal of synaptic GABA(A)Rs accompanied with neuronal excitation evoked by 4-aminopyridine (4AP) or N-methyl-D-aspartic acid (NMDA) precedes that of gephyrin. Single-particle tracking of quantum dot labeled-GABA(A)Rs revealed that excitation-induced enhancement of GABA(A)R lateral mobility also occurred before the shrinkage of gephyrin clusters. Physical inhibition of GABA(A)R lateral diffusion on the cell surface and inhibition of a Ca(2+) dependent phosphatase, calcineurin, completely eliminated the 4AP-induced decrease in gephyrin cluster size, but not the NMDA-induced decrease in cluster size, suggesting the existence of two different mechanisms of gephyrin declustering during activity-dependent plasticity, a GABA(A)R-dependent regulatory mechanism and a GABA(A)R-independent one. Our results also indicate that GABA(A)R mobility and clustering after sustained excitatory activity is independent of gephyrin.     

Surface changes in irradiated thymocytes studied by partition in 2-phase systems and electrophoresis

A study was made of thymocyte surface changes 1-6 hour after the irradiation in a dose of 4 Gy by means of two phase partition in dextran-polyethylenglycole systems and of electrophoretic mobility registration. A decrease in the two phase partition coefficient (by 20% per cent in one hour after irradiation) was registered. The electrophoretic mobility of irradiated cells did not change.     

HMGA1a is involved in specific splice site regulation of human immunodeficiency virus type 1

Human immunodeficiency virus type 1 (HIV-1) utilizes a highly complex splice site regulation system, taking advantage of host proteins, to express its own viral protein in an orderly way. We show here that one of the host proteins, high mobility group A protein 1a (HMGA1a), is involved in splice site regulation of 3′ splice site 2 (A2) and 5′splice site 3 (D3) of HIV-1 genomic RNA. shRNA knockdown of HMGA1 in HeLa cells resulting in a decrease of HMGA1 showed a significant decrease of Vpr mRNA. RNA electophoretic mobility shift assays showed HMGA1a specifically binds to a sequence adjacently upstream D3. In vitro splicing using heterologous pre-mRNA with A2 and D3, showed HMGA1a induced a splicing intermediate which decreased when an RNA decoy of the HMGA1a binding site was added. RT-PCR of in vitro splicing products revealed that HMGA1a induced an incomplete splicing product resulting from usage of A2 but inhibition of D3, which is reminiscent of the splicing pattern necessary for Vpr mRNA formation. HMGA1a interacted with hnRNPA1 shown by coimmunoprecipitation and supershifted U1 snRNP in an RNA electophoretic mobility shift assay. We conclude that HMGA1a anchors U1 snRNP to inhibit D3 function, and that HMGA1a inhibits hnRNPA1 function on exon splicing silencer of Vpr (ESSV) to activate A2 function. We show here for the first time that HMGA1a is involved in specific splice site regulation of HIV-1.     

On the decrease in lateral mobility of phospholipids by sugars

Upon cold and drought stress, sucrose and trehalose protect membrane structures from fusion and leakage. Similarly, these sugars protect membrane proteins from inactivation during dehydration. We studied the interactions between sugars and phospholipid membranes in giant unilamellar vesicles with the fluorescent lipid analog 3,3′-dioctadecyloxacarbocyanine perchlorate incorporated. Using fluorescence correlation spectroscopy, it was found that sucrose decreased the lateral mobility of phospholipids in the fully rehydrated, liquid crystalline membrane more than other sugars did, including trehalose. To describe the nature of the difference in the interaction of phospholipids with sucrose and trehalose, atomistic molecular dynamics studies were performed. Simulations up to 100 ns showed that sucrose interacted with more phospholipid headgroups simultaneously than trehalose, resulting in a larger decrease of the lateral mobility. Using coarse-grained molecular dynamics, we show that this increase in interactions can lead to a relatively large decrease in lateral phospholipid mobility.     

Some properties of the chloroplast envelope as revealed by electrophoretic mobility studies of intact chloroplasts

The electrophoretic mobility of mature spinach (Spinacia oleracea L. var. Americana) chloroplasts sampled over a 7-month period was between −2.03 and −2.45 micrometers per second per volt per centimeter when suspended in a solution containing 1 millimolar CaCl₂. The surface charge density of EDTA-treated chloroplasts was calculated to be −7,400 electrostatic units per square centimeter representing, on the average, one electronic charge per 645 square Angstroms. Electrophoretic mobility increases during plastid maturation. Calcium, but not magnesium, generally stabilized the envelope of isolated plastids against small increases in surface charge that occur with time in the absence of calcium. Pronase caused a sharp, but temporary, decrease in the electrophoretic mobility of chloroplasts. This was interpreted as representing a transient binding of pronase to the envelope surface during proteolysis. No −SH groups were detected on the surface of the plastid envelope. Inasmuch as the isoelectric point of intact chloroplasts was found to be at pH 4.5, it is likely that the major part of the total surface charge results from the presence of exposed carboxyl groups of intrinsic envelope proteins that are not readily hydrolyzed by mild pronase treatment.     

Equine fetal kinetics: Presentation and location

The extent and nature of fetal mobility (presentation and location changes) were studied in 10 pony mares by ultrasonic examinations each week during the fetal stage (Day 40 to term). The percentage of examinations with cranial fetal presentation was 35 to 43% during Months 2 to 5 (no significant differences among months); a significant increase occurred between Months 5 and 6 reaching 100% at Month 7. With only 3 transient exceptions, the fetus was in cranial presentation during all examinations from Month 7 to term. The frequency of presentation changes between successive examinations decreased (P<0.05) between Months 4 and 5 and further decreased between Months 6 and 7. A significant and progressive decrease in the proportion of examinations in which at least part of the fetus was located in the umbilical-cord horn occurred over Months 2 to 4. During the same months, an increase occurred in the frequency of location of at least part of the fetus in the noncord horn and in the frequency of location of all of the fetus in the uterine body. The fetus was equally distributed among the 3 parts of the uterus during Month 4. Thereafter, locations decreased (P<0.05) in the noncord horn, increased (P<0.05) in the uterine body, and maintained a plateau (no significant differences) in the cord horn until Month 7 and then increased (P<0.05). The frequency of location changes between successive examinations increased (P<0.01) progressively during Months 2 to 4 followed by a decrease between Months 4 and 10. With one exception, the fetus was located in both the cord horn and uterine body for all examinations during Month 9 to term. In conclusion, a gradual decrease in fetal mobility occurred after Month 4; with only a few transient exceptions, final selection of cranial presentation occurred by Month 7, and final selection of partial location in the cord horn occurred by Month 9.     

Changes in electronegativity of the cell surface during the development of the cell surface during the development of the cellular slime mold, Dictyostelium discoideum

A microelectrophoretic method was applied to determine electrophoretic mobility of the amoebae of the cellular slime molds at various stages of development. The vegetative amoebae were negatively charged and their electrophoretic mobility remained unchanged as long as they fed. After the cessation of feeding mobility of the amoebae decreased gradually in the interphase. Proteolytic enzymes and EDTA had no effect on mobility of the amoebae right after finishing feeding. On the contrary, mobility of the amoebae in the middle interphase was increased by treatment with proteolytic enzymes, lipase, and EDTA. EDTA and pronase showed an additive effect on the increase in mobility, and the increased mobility was almost the same as that of the vegetative a-moebae. These results indicate that the decrease in mobility during the interphase is due to the accumulation of a substance(s) (probably lipoprotein) on the cell surface. The cells disaggregated from the migrating slugs showed lower mobility than the cells obtained from the aggregation centers. The latter had still lower mobility than the interphase amoebae. These changes in electrophoretic mobility were discussed in relation to corresponding changes in adhesiveness.     

Evidence for restricted oligosaccharide mobility at the erythrocyte membrane surface: A fluorescence study

The glycophorins of whole, human erythrocytes were labeled at their sialic acid residues with one of three fluorescent probes. After preparation of the erythrocyte ghosts, the mobility of each fluorescent probe on the intact membrane was compared with its mobility on the isolated, labeled glycopeptides dissolved in aqueous buffer. A four- to ninefold decrease in the rotational relaxation time, as defined by the Perrin equation, accompanied the proteolytic removal of the labeled glycopeptides from the membrane. This suggests that the fluorescent probes, and by extrapolation, the sugars to which they are immediately attached, are restricted in their mobility at the membrane surface. A crude model of the carbohydrate layer of the erythrocyte surface was constructed by incorporating the labeled, tryptic glycopeptides into agarose gels of different agarose content. A decrease in the probe's mobility was observed as agarose content was raised. This indicates that the high oligosaccharide density at the erythrocyte membrane surface may contribute to the observed immobilization of the fluorescent probes in situ.     

Effect of Canavanine on Murine Retrovirus Polypeptide Formation

Canavanine is an arginine analog which is widely used to inhibit proteolytic processing of viral polyproteins. Certain results obtained with canavanine have suggested that it may have other effects. Therefore, we examined the effects of canavanine on the cell-free synthesis of murine retrovirus proteins. It was found that the electrophoretic mobility of the major gag-related cell-free product of both Rauscher murine leukemia virus (R-MuLV) and Moloney murine sarcoma virus 124 (Mo-MuSV-124) RNA was dependent on the concentration of canavanine used during translation. As the canavanine concentration was increased up to 4 mM, the apparent size of the major gag-related polypeptide also increased from 65,000 (R-MuLV RNA) or 63,000 (Mo-MuSV-124 RNA) to approximately 80,000 daltons. Additional increases in the canavanine concentration up to 12 mM did not increase the size of the gag gene product beyond 80,000 daltons. This change in electrophoretic mobility appeared to be due to a substitution of canavanine for arginine residues in the polypeptides, not to a change in their actual size. If amber suppressor tRNA and canavanine were used together during translation of Mo-MuSV-124 RNA and Mo-MuLV RNA, the results were also in agreement with this proposal. Translation experiments done with ovalbumin mRNA and mengovirus 35S RNA indicated that canavanine incorporation caused a shift in the electrophoretic mobility of ovalbumin from 43,000 to 45,000 daltons and caused the appearance of two slightly larger polypeptides in the 155,000- and 115,000- dalton regions of the mengovirus RNA cell-free product.     

The sites on calmodulin cross-linked to myosin light chain kinase and troponin I with water-soluble carbodiimide

To elucidate the interaction of calmodulin with calmodulin binding proteins, we studied the location of the interaction sites on calmodulin by using a chemical cross-linking reagent. Calmodulin prepared from wheat germ was cross-linked to myosin light chain kinase and troponin-I with 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide. The cross-linked products were cleaved partially with cyanogen bromide and cross-linked sites were determined by peptide mapping analysis using SDS-urea polyacrylamide gel electrophoresis. Peptides which contain the cross-linked site were displaced from their position because of the attached fragments of myosin light chain kinase or troponin I. The peptide of calmodulin from the N-terminal to Met-73 in the cross-linked product with myosin light chain kinase had the same mobility as that of uncross-linked calmodulin on the map though the amount of the peptide was decreased in the cross-linked product. The peptide from the N-terminal to Met-110 in the cross-linked product was displaced from its position. Similar change in the mobility of the calmodulin peptides was also observed in the cross-linked products with troponin I. It was concluded, therefore, that at least one cross-linked site for myosin light chain kinase and one for troponin I were located between Met-73 and Met-110 of the wheat germ calmodulin.