LPP-1 Infection of the Blue-Green Alga Plectonema boryanum: II. Viral Deoxyribonucleic Acid Synthesis and Host Deoxyribonucleic Acid Breakdown

Host and viral deoxyribonucleic acid (DNA) metabolism in LPP-1-infected Plectonema boryanum was studied by equilibrium centrifugation in CsCl gradients. Approximately 50% of the host DNA is degraded to acid-soluble material between 3 and 7 hr after infection. Most of the acid-soluble product is reincorporated into viral DNA. Incorporation of exogenous (3)H-adenine into viral DNA can be detected very early after infection (within the first 2 hr), but the bulk of viral DNA synthesis occurs between 6 and 8 hr. Both the breakdown of host DNA and the synthesis of viral DNA require protein synthesis during the first few hours of infection.     

LPP-1 Infection of the Blue-Green Alga Plectonema boryanum: I. Electron Microscopy

One-step growth and intracellular growth experiments were performed at high multiplicities of the virus LPP-1 during the infection of the blue-green alga Plectonema boryanum. The eclipse period lasts until 4 hr after infection, the latent period terminates at 6 hr, and the rise period continues until 14 to 16 hr after infection. The burst size was independent of multiplicity of infection over the ranges from 1 to 50. The burst size was 3,000 to 5,000 plaque-forming units (PFU) per infectious center or about 200 PFU per cell. Samples for electron microscopy were taken at characteristic times during the lytic cycle. The first sign of viral infection was the invagination of the photosynthetic lamellae at 3 hr after infection. Mature virions were visible at 4 hr. By 6 to 7 hr, many mature intracellular viral particles could be seen, with lysis beginning at 7 hr. By 10 hr after infection, all infected cells contained mature virions. No evidence for mass migration of performed viral precursors was obtained. The invagination of the lamellae could be prevented by the early addition of chloramphenicol, which implies that this process requires protein synthesis.     

Mice with transgenic overexpression of lipid phosphate phosphatase-1 display multiple organotypic deficits without alteration in circulating lysophosphatidate level

Lipid phosphate phosphatase 1 (LPP-1) is presumed to regulate the balance between lipid phosphates and their dephosphorylated counterparts. The currently prevailing hypothesis based on in vitro studies proposes that LPP-1 should regulate phospholipid lipid growth factors and second messengers, including lysophosphatidic acid (LPA), sphingosine 1-phosphate (S1P), diacylglycerol (DAG), and phosphatidic acid (PA). To evaluate the role of LPP-1 in vivo, three transgenic lines were established. RT-PCR, Western blotting, and enzymatic activity measurement confirmed a copy number-dependent ubiquitous overexpression of LPP-1. PMA-stimulated PA production in immortalized LPP-1 fibroblasts led to an elevation in the accumulation of DAG without major changes in the phospholipid classes isolated from the liver. The LPP-1 phenotype showed reduced body size, birth weight, and abnormalities in fur growth, whereas histological abnormalities included significantly decreased number of hair follicles, disrupted hair structure, and a severely impaired spermatogenesis. Implantation of LPP-1 or wild-type embryos into pseudopregnant LPP-1 mothers yielded a reduced litter size. The plasma level of alanine-leucine aminotransferase was significantly elevated. Unexpectedly, plasma concentrations of the five major acyl-species of LPA were indistinguishable between wild-type and LPP-1 animals. In contrast with previous studies using plasmid-mediated overexpression in vitro, transgenic overexpression of LPP-1 did not affect ERK1/2 activation elicited by LPA, S1P, thrombin, epidermal growth factor (EGF), and platelet-derived growth factor (PDGF), which was presumed to be a major signaling event regulated by LPP-1. Thus, transgenic overexpression of LPP-1 in mice elicited a number of unexpected phenotypic alterations without affecting several aspects of LPA signaling, which point to previously unappreciated mechanisms and roles of lipid phosphates in select organs.     

Functional development of sex accessory organs of the male rat. Use of oestradiol benzoate to identify the neonatal period as critical for development of normal protein-synthetic and secretory capabilities.

Functional development of the sex accessory tissues was studied in the male rat. Three potentially crucial developmental periods (neonatal, prepubertal and pubertal) were examined, and then the functional integrity of the accessory tissues was investigated in the adult, when the animals would have been expected to display normal function. Four accessory tissues (the seminal vesicles, ventral prostate and caput and cauda epididymides) were used because of their different embryological origins and responses to androgens in the adult. Synthesis and secretion of previously characterized tissue-specific androgen-dependent proteins were taken as indicators of normal function. Development was perturbed by using oestradiol benzoate, since this was known to affect gross development of the seminal vesicles and ventral prostate when given to neonatal rats. Treatment during the first 5 days after birth severely restricted development of the seminal vesicles and ventral prostate. Protein secreted by the former was only 1% of the normal amount, and in many cases several major secretory proteins were essentially missing. Prostatic protein secretion was less than 20% of normal, but all the major proteins were detectable. In both tissues overall protein synthesis per cell was quantitatively normal, but the proportion devoted to specific major secretory proteins was markedly depressed, i.e. the response is differential. In contrast, treatment during the prepubertal period was without noticeable effects. Development of the seminal vesicles and prostate was somewhat inhibited by treatment at puberty, but these changes were minor compared with those after neonatal exposure to oestradiol benzoate. No effects on epididymal protein synthesis or secretory proteins were observed, and epididymal weight and DNA content were only moderately decreased regardless of when oestradiol benzoate was administered during sexual maturation. Hence the neonatal period is not so critical for epididymal development. The substantial changes elicited by oestrogen treatment during neonatal life in seminal-vesicle and prostatic protein synthesis and secretion were compared with those evoked in sexually mature males by either oestrogen treatment or castration. Both these latter treatments resulted in a general decrease in seminal-vesicle protein synthesis and secretion, but the marked differential effects on major proteins after neonatal exposure were absent. Castration did, however, evoke a differential prostatic response, but this was not seen after oestrogen treatment of adults.     

Identification and biosynthesis of the bacteriophage T4 mot regulatory protein.

The T4 mot gene regulates middle mode RNA synthesis in phage-infected cells. The mot gene product has been identified in two ways. (i) Infections with amber and temperature-sensitive mot mutants both lead to the disappearance of a number of protein bands on SDS-polyacrylamide gels. These are middle mode proteins whose synthesis depends on mot function. The mot protein disappears from such gels after infection with a mot amber mutant, but not with the mot missense mutant. (ii) This same protein is the only one to have a charge alteration when proteins from wild-type phage and mot missense mutant infections are compared by two-dimensional gel electrophoresis. Mot protein is basic and has a mol. wt. of 24 000. It migrates between the positions of gp 1 and gp IPIII on 15% SDS-polyacrylamide gels. Mot protein synthesis begins immediately after infection and continues until 4 min after infection at 30 degrees C, after which time it is strongly inhibited. This inhibition depends neither on T4 DNA synthesis nor on ADP ribosylation of the alpha subunits of the Escherichia coli RNA polymerase. The mot protein does not regulate its own biosynthesis. It is stable throughout the course of infection.     

Evidence for photosynthetic independence of viral multiplication in cyanophage LPP-1 infected cyanobacterium Phormidium uncinatum

Abstract Pigment decomposition, oxygen evolution and CO₂ fixation were measured in the cyanobacterium Phormidium uncinatum after infection with cyanophage LPP-1, under light and dark conditions. A gradual decrease in para benzoquinone supported O₂ evolution, chlorophyll a and phycocyanin level were noticed after 6 h of infection. These results demonstrated decreased photosynthetic activity of the host P. uncinatum prior to the start of LPP-1 multiplication. Metabolic inhibitor investigations confirmed that the cyanophage LPP-1 multiplication was independent of host photosynthesis.     

Effect of cytosine arabinoside on viral-specific protein synthesis in cells infected with herpes simplex virus.

The relationship between viral DNA and protein synthesis during herpes simplex virus type 1 (HSV-1) replication in HeLa cells was examined. Treatment of infected cells with cytosine arabinoside (ara-C), which inhibited the synthesis of HSV-1 DNA beyond the level of detection, markedly affected the types and amounts of viral proteins made in the infected cell. Although early HSV-1 proteins were synthesized normally, there was a rapid decline in total viral protein synthesis beginning 3 to 4 h after infection. This is the time that viral DNA synthesis would normally have been initiated. ara-C also prevented the normal shift from early to late viral protein synthesis. Finally, it was shown that the effect of ara-C on late protein synthesis was dependent upon the time after infection that the drug was added. These results suggest that inhibition of progeny viral DNA synthesis by ara-C prevents the "turning on" of late HSV-1 protein synthesis but allows early translation to be "switched off."     

Analysis of globulin maturation in developing sunflower seeds

The synthesis of major storage globulin polypeptides has been examined in developing seeds of sunflower(Helianthus annuus L.). Analyses of total proteins and purified globulins, also called helianthinin, by gel electrophoresis and immunoelectrophoresis have shown that a burst of protein synthesis and accumulation occurs around 10 d after flowering. There is no mature globulin before that time and only small amounts of precursor forms can be detected. Thus, 10–12 d after flowering appears to be a transition period during which genetic information for the globulin becomes actively expressed. Immunoelectrophoresis has confirmed that globulin is the main storage protein, at seed maturation, accounting up to 70 % of total proteins per kernel. Pulse chase experiments have shown that synthesis initially involves the formation of high molecular mass precursors and that storage proteins are post-translationally processed. Intermediary products, with molecular mass higher than early translational products, can be detected, together with mature globulin polypeptides.     

Lipid phosphate phosphatase-1 dephosphorylates exogenous lysophosphatidate and thereby attenuates its effects on cell signalling

The serum-derived phospholipid growth factor, lysophosphatidate (LPA), activates cells through a family of G-protein-coupled EDG receptors. The present article examines the role of lipid phosphate phosphatase-1 (LPP-1, or phosphatidate phosphate 2A) in regulating cell activation by LPA. Over-expressing LPP-1 approximately doubled the rate of dephosphorylation of exogenous LPA by Rat2 fibroblasts. The amount of LPA dephosphorylation was restricted to less than 10% of the total exogenous LPA. Over-expression of LPP-1 attenuated cell activation as indicated by diminished responses including cAMP, Ca(2+), activation of phospholipase D and ERK, DNA synthesis and cell division. LPP-1 therefore provides a novel level of regulation for controlling cell signalling by exogenous LPA.     

Engineered serine protease inhibitor prevents furin-catalyzed activation of the fusion glycoprotein and production of infectious measles virus.

We have identified the major cellular endoprotease that activates the fusion (F) glycoprotein of measles virus (MV) and have engineered a serine protease inhibitor (serpin) to target the endoprotease and inhibit the production of infectious MV. The F-protein precursor of MV was not cleaved efficiently into the mature F protein in human colon carcinoma cells lacking functional furin, indicating that furin is the major enzyme responsible for activation of the MV F protein. A human serpin alpha 1-antitrypsin variant was engineered to specifically inhibit furin. When expressed from a recombinant vaccinia virus in primate cells infected by MV, the engineered serpin (alpha 1-PDX) specifically inhibited furin-catalyzed cleavage of the F-protein precursor without affecting synthesis of other MV proteins. We generated human glioma cells stably expressing alpha 1-PDX. MV infection in these cells did not result in syncytia. The infected cells produced all the MV proteins, but the F-protein precursor remained largely uncleaved. This did not prevent virus assembly. However, the released virions contained inactive F-protein precursor rather than mature F protein, and infectious-virus titers were reduced by 3 to 4 orders of magnitude. These results show that a mature F protein is not required for the assembly of MV but is crucial for virus infectivity. The engineered serpin may offer a novel molecular antiviral approach against MV.     

Lipid phosphate phosphatase-1 dephosphorylates exogenous lysophosphatidate and thereby attenuates its effects on cell signalling

The serum-derived phospholipid growth factor, lysophosphatidate (LPA), activates cells through a family of G-protein-coupled EDG receptors. The present article examines the role of lipid phosphate phosphatase-1 (LPP-1, or phosphatidate phosphate 2A) in regulating cell activation by LPA. Overexpressing LPP-1 approximately doubled the rate of dephosphorylation of exogenous LPA by Rat2 fibroblasts. The amount of LPA dephosphorylation was restricted to less than 10% of the total exogenous LPA. Over-expression of LPP-1 attenuated cell activation as indicated by diminished responses including cAMP, Ca2+, activation of phospholipase D and ERK, DNA synthesis and cell division. LPP-1 therefore provides a novel level of regulation for controlling cell signalling by exogenous LPA.     

Lipid phosphate phosphatase-1 and Ca2+ control lysophosphatidate signaling through EDG-2 receptors

The serum-derived phospholipid growth factor, lysophosphatidate (LPA), activates cells through the EDG family of G protein-coupled receptors. The present study investigated mechanisms by which dephosphorylation of exogenous LPA by lipid phosphate phosphatase-1 (LPP-1) controls cell signaling. Overexpressing LPP-1 decreased the net specific cell association of LPA with Rat2 fibroblasts by approximately 50% at 37 degrees C when less than 10% of LPA was dephosphorylated. This attenuated cell activation as indicated by diminished responses, including cAMP, Ca(2+), activation of phospholipase D and ERK, DNA synthesis, and cell division. Conversely, decreasing LPP-1 expression increased net LPA association, ERK stimulation, and DNA synthesis. Whereas changing LPP-1 expression did not alter the apparent K(d) and B(max) for LPA binding at 4 degrees C, increasing Ca(2+) from 0 to 50 micrometer increased the K(d) from 40 to 900 nm. Decreasing extracellular Ca(2+) from 1.8 mm to 10 micrometer increased LPA binding by 20-fold, shifting the threshold for ERK activation to the nanomolar range. Hence the Ca(2+) dependence of the apparent K(d) values explains the long-standing discrepancy of why micromolar LPA is often needed to activate cells at physiological Ca(2+) levels. In addition, the work demonstrates that LPP-1 can regulate specific LPA association with cells without significantly depleting bulk LPA concentrations in the extracellular medium. This identifies a novel mechanism for controlling EDG-2 receptor activation.     

Sequential Formation of Vaccinia Virus Proteins and Viral Deoxyribonucleic Acid Replication

In vaccinia virus-infected cell cultures, cellular protein synthesis was inhibited 50% at 2 hr postinfection (PI) and 80 to 90% by 4 hr PI. Input virus was responsible for this inhibition. Five early proteins, coded for by the viral genome, could be detected at 2 to 3 hr PI. Normally, their synthesis did not continue beyond 6 hr PI, at which time synthesis of a different set of proteins began. When DNA replication was blocked, synthesis of these early proteins continued until 9 to 12 hr PI. The bulk of the proteins which were incorporated into mature virus were synthesized at 8 hr PI and thereafter. The time of their formation was close to the time at which virus maturation occurred. However, 15% of the protein found in mature virus was synthesized early in the infectious cycle. The quantity of “early viral protein” which was not incorporated into mature virus was almost as large as the quantity of viral protein which did appear in mature virus. The “early” and “late” proteins could be shown to have separate and distinct immunological properties. The role of this large quantity of “early” protein is discussed.     

Viral Protein Synthesis in Bacteriophage φ29-Infected Bacillus subtilis

Twenty-three (14)C-labeled phage phi29-specific proteins in lysates of UV-irradiated Bacillus subtilis have been resolved by sodium dodecyl sulfate polyacrylamide gel electrophoresis and identified by autoradiography. Included in this group of proteins are the six major structural proteins of the virion. Analysis of the temporal sequence of viral protein synthesis indicates that three groups of proteins can be identified by time of appearance, beginning at 2 to 4, 4 to 6, or 8 to 10 min after infection, respectively. These proteins account for approximately 90% of the coding capacity of the phi29 genome.     

Replication of mengovirus. I. Effect on synthesis of macromolecules by host cell

Plagemann, Peter G. W. (Western Reserve University, Cleveland, Ohio), and H. Earle Swim. Replication of mengovirus. I. Effect on synthesis of macromolecules by host cell. J. Bacteriol. 91:2317-2326. 1966.-The replication of mengovirus was studied in two strains of Novikoff (rat) hepatoma cells propagated in vitro. The replicative cycle in both strains required 6.5 to 7 hr. Infection resulted in a marked depression of ribonucleic acid (RNA) and protein synthesis by strain N1S1-63. Inhibition of RNA synthesis was reflected by a decrease in the deoxyribonucleic acid (DNA)-dependent RNA polymerase activity of isolated nuclei. Mengovirus had no effect on either protein or RNA synthesis or on the DNA-dependent RNA polymerase activity of a second strain, N1S1-67. The time course of viral-induced synthesis of RNA by cells was studied in cells treated with actinomycin D. It was first detectable between 2.5 and 3 hr after infection and continued until 6.5 to 7 hr. The formation of mature virus was estimated biochemically by measuring the amount of RNA synthesized as a result of viral infection which was resistant to degradation by ribonuclease in the presence of deoxycholate. Approximately 70% of the deoxycholate-ribonuclease-resistant RNA was located in mature virus, and the remainder was double-stranded. The formation of mature virus began about 45 min after viral-directed (actinomycin-resistant) synthesis of RNA was detectable in the cell, and only about 18 to 20% of the total RNA synthesized was incorporated into virus. Release of virus from cells began about 1 hr after maturation was first detectable. Release of virus from cells was accompanied by a loss of a large proportion of their cytoplasmic RNA and protein.     

Identification of the gene controlling the synthesis of the major bacteriophage T5 membrane protein.

After infection of Escherichia coli B by bacteriophage T5, a major new protein species, as indicated by polyacrylamide gel electrophoresis, appears in the cells' membranes. Phage mutants with amber mutations in the first-step-transfer portion of their DNA have been tested for their ability to induce membrane protein synthesis after they infect E. coli B. We have found that phage with mutations in the Al gene of T5 do not induce the synthesis of the T5-specific major membrane protein, whereas phage that are mutant in the A2 gene do induce its synthesis. We conclude that gene Al must function normally for T5-specific membrane protein biosynthesis to occur and that only the first 8% (first-step-transfer piece) of the DNA need be present in the cell for synthesis to occur.     

The developmental profiles of two major haemolymph proteins from Drosophila melanogaster.

There are four major protein species in the haemolymph of the late 3rd instar of Drosophila. Two of these, LSP-1 and LSP-2, have been studied in detail. Larvae, pupae, and flies of different ages were measured for wet weight, total extractable protein and using an immunoassay, the amounts of LSP-1 and LSP-2. The synthesis of both proteins begins after the 2nd larval ecdysis and at puparium formation they represent 9% and 1.5% of total extractable protein. This value remains constant during the first part of metamorphosis, then falls rapidly. The function of these proteins and their suitability as systems for the study of gene control and protein synthesis in Drosophila are discussed.     

Synthesis and Cleavage of Influenza Virus Proteins

The NWS strain of influenza virus grows rapidly in and kills the MDCK dog kidney cell strain. Within 1 to 2 hr, the virus inhibits host cell protein synthesis and for 3 to 4 hr more it directs the synthesis of influenza virus proteins at a rate about twice that of uninfected cell synthesis. The rates of virus ribonucleic acid (RNA) and protein synthesis reach a maximum within the first few hours after infection and then drop. Plaque assays exhibit a linear dose-response, indicating that only one virion is necessary for productive infection. We have confirmed earlier reports regarding the fragmented nature of the RNA genome of purified influenza virions. However, high resolution gel electrophoresis indicated that each size class of viral RNA is heterogenous, so that there are at least 10 and probably more fragment sizes of RNA in these virions. Repeated attempts to detect infectivity in preparations of extracted viral RNA were completely negative (over a 10(8)-fold loss of infectivity after extraction). Even infection of the "infectious" RNA-treated cells with intact, related, influenza viruses failed to support infectivity of the isolated RNA or to rescue a host range genetic marker of the RNA. Purified influenza virions exhibit only three major protein peaks based on separation according to molecular weights. These three major virion proteins are the only major virion proteins synthesized in infected cells. This is true throughout the infectious cycle from several hours after infection until the cells are dying. However, the molecular weight of these virion proteins differs slightly depending upon the cell type in which the virus is grown. No host membrane proteins are incorporated into the virions as they bud through the cell membrane. Pulse-chase labeling early after infection or prolonged chase experiments indicate that influenza virus proteins are cleaved from one or more precursor polypeptides. In fact, each of the three major peaks seems to be a heterogeneous mixture of polypeptides in various stages of cleavage. Peptide analysis confirms that the three major peaks share common peptides, but the exact precursor product relationships are not clear. There may be one or several precursor proteins. Also there could be overlapping messenger RNA molecules of varying length giving rise to polypeptides of various sizes and overlapping sequences. Late in infection, amino acid labeling shows a preponderance of internal nucleocapsid protein synthesis, indicating that either this protein is much more stable to cleavage in infection or it is made from a more stable messenger. There is no obvious relationship between virion RNA fragments and viral protein sizes, so these fragments may be artifacts.     

The rapid intranuclear accumulation of preexisting proteins in response to high plasmodial density in Physarum polycephalum

When actively growing microplasmodia of the lower eukaryote Physarum polycephalum are gently pelleted and allowed to stand at high plasmodial densities for 45 min, three specific nuclear acidic proteins undergo dramatic quantitative changes. Two major proteins of molecular weight 46 000 and 94 000 increase 110 and 320%, respectively. The increase in these two proteins is not markedly attenuated during periods when 88% total protein synthesis is blocked by cycloheximide, and the specific radioactivities of these proteins from prelabeled and continuously labeled control and pelleted plasmodia are essentially identical. A third protein of molecular weight 34 000 decreases by 51 % during the 45 min period and when cycloheximide is present, a 36% decrease in this protein still occurs. The rapid changes which occur in these three proteins in response to high plasmodial density also develop, together with many other changes, during plasmodial differentiation, but only after about 6 h of starvation. It is concluded that the rapid increase in the 46 000 and 94 000 mol. wt proteins results from protein transfer phenomena rather than de novo synthesis and that these proteins perhaps function in the early reorganization of cell metabolism rather than in structural differentiation. In further comparative studies it has been observed that mature spherules of P. polycephalum contain a major acidic protein not present in growing or differentiating plasmodia and also that the complement of residual acidic proteins differs in starvation-induced vs cold-induced spherules.     

Human papillomavirus L1 protein expressed in tobacco chloroplasts self-assembles into virus-like particles that are highly immunogenic

Cervical cancer is the second most prevalent cancer in women worldwide. It is linked to infection with human papillomavirus (HPV). As the virus cannot be propagated in culture, vaccines based on virus-like particles have been developed and recently marketed. However, their high costs constitute an important drawback for widespread use in developing countries, where the incidence of cervical cancer is highest. In a search for alternative production systems, the major structural protein of the HPV-16 capsid, L1, was expressed in tobacco chloroplasts. A very high yield of production was achieved in mature plants (approximately 3 mg L1/g fresh weight; equivalent to 24% of total soluble protein). This is the highest expression level of HPV L1 protein reported in plants. A single mature plant synthesized approximately 240 mg of L1. The chloroplast-derived L1 protein displayed conformation-specific epitopes and assembled into virus-like particles, visible by transmission electron microscopy. Furthermore, leaf protein extracts from L1 transgenic plants were highly immunogenic in mice after intraperitoneal injection, and neutralizing antibodies were detected. Taken together, these results predict a promising future for the development of a plant-based vaccine against HPV.