Giant viruses infecting algae.

Paramecium bursaria chlorella virus (PBCV-1) is the prototype of a family of large, icosahedral, plaque-forming, double-stranded-DNA-containing viruses that replicate in certain unicellular, eukaryotic chlorella-like green algae. DNA sequence analysis of its 330, 742-bp genome leads to the prediction that this phycodnavirus has 376 protein-encoding genes and 10 transfer RNA genes. The predicted gene products of approximately 40% of these genes resemble proteins of known function. The chlorella viruses have other features that distinguish them from most viruses, in addition to their large genome size. These features include the following: (a) The viruses encode multiple DNA methyltransferases and DNA site-specific endonucleases; (b) PBCV-1 encodes at least part, if not the entire machinery to glycosylate its proteins; (c) PBCV-1 has at least two types of introns--a self-splicing intron in a transcription factor-like gene and a splicesomal processed type of intron in its DNA polymerase gene. Unlike the chlorella viruses, large double-stranded-DNA-containing viruses that infect marine, filamentous brown algae have a circular genome and a lysogenic phase in their life cycle.

Repetitive DNA insertion in a protein kinase ORF of a latent FSV (Feldmannia sp. virus) genome.

We describe the structure of a Feldmannia sp. virus (FsV) genome integrated in the brown alga, Feldmannia. This integrated FsV genome appears to be permanently inactivated and lost its ability to excise and replicate. Unlike the replicated form of FsV, this integrated FsV genome contains a large (>50 kb) repeat region inserted in a protein kinase open reading frame. While related to the 173-bp repeats previously characterized in the FsV genome (Lee et al., 1995), Southern blot analysis indicates that the repeats in the inactive, integrated FsV genome are distinct from those previously characterized. Fine structural analysis of the repeat-insertion sites in the protein kinase gene indicates that there are 8- and 10-bp palindromic sequences present in multiple locations located near the repeat-insertion site. The translated protein kinase contains all of the catalytic motifs conserved in most serine/threonine protein kinases and a potential autophosphorylation site. This protein kinase gene is expressed as RNA in sporophyte plants where virus production is active but not in gametophyte plants where the virus genome is latent. The structure of the integrated virus genome is discussed.

A Feldmannia algal virus has two genome size-classes.

Persistent viruses occur intracellularly in brown algae, specifically the Ectocarpales, and as reported here in the genus Feldmannia. Feldmannia species are small (1 mm-several cm), filamentous forms with single-celled meiotic sporangia that normally produce haploid zoospores. In the isolate reported here, spores were not observed in the sporangia but rather numerous (approximately 10(6) per cell) polyhedral viruses are formed in their place. Two dsDNA genome classes of 158 and 178 kbp, with two restriction site variants of each, are described. The individual abundance of each genome in viral preparations is affected by culture temperature. A cosmid library was used to generate circular restriction enzyme (BamHi, Noti, and Psti) site maps.

A brown algal virus genome contains a "RING" zinc finger motif.

The brown filamentous alga Feldmannia sp. contains a large icosahedral dsDNA virus, FsV, of which there are multiple variants. A 4.5-kb SstI-HindIII fragment (SH4.5) that is conserved among all genome variants was sequenced. Three open reading frames (ORF-1, -2, and -3, containing 555, 2022, and 411 bp, respectively) were shown to be transcriptionally active by ribonuclease protection assay. A "RING" zinc finger motif and a nucleotide binding site motif were identified in ORF-2.

Characterization of a repetitive DNA element in a brown algal virus.

We describe a family of repetitive sequences found in viruses infecting the brown alga Feldmannia sp. Previously we have demonstrated that the dsDNA genomes of viruses infecting one Feldmannia sp. isolate exist as two size classes of 160 and 179 kb. Repetitive sequences within these genomes were first demonstrated based on the anomalous hybridization among five BamHI fragments from digested virus DNA. Sequence analysis of one of those fragments, B2.4, revealed the presence of 173-bp direct repeats. The restriction maps of the cross-hybridizing BamHI fragments in the two FsV (Feldmannia sp. virus) genome size classes show that these repeats are not widely dispersed, rather they are confined to a small region of each virus genome. We estimate the number of these repeats in the 179-kb genome to be about 109 and in the 169-kb genome to be about 41. In the 179-kb genome, the repeats are contained within a 22-kb region, about 12% of that virus genome, and in the 160-kb genome the repeats are contained within a 10-kb region, about 6% of the genome. The difference in repeat numbers can account for 62% of the size difference between the two size classes of the FsV genome.

Characterization of the major capsid protein and cloning of its gene from algal virus PBCV-1.

The major capsid protein (Vp54) from Chlorella virus PBCV-1 is a glycoprotein and the most abundant viral structural protein. The gene encoding Vp54 has been cloned and sequenced. Initially, a region of the gene was amplified using the polymerase chain reaction (PCR) primed with oligonucleotides derived from the N-terminal amino acid sequences of purified protein and cyanogen bromide cleavage fragments. The PCR product was used as a probe to map the location of the gene to PBCV-1 genomic Pstl restriction fragment P8. A 1314-bp open reading frame (ORF) was identified which contained the predicted coding regions from the derived amino acid sequences. The peptide encoded by this ORF had a predicted molecular weight of 48.2 kDa and contained six putative N-linked and 63 putative O-linked glycosylation sites. Primer extension analysis indicated that transcription started 14 bp 5' to the ATG. The gene for Vp54 was transcribed late in infection and this transcript was the most abundant viral RNA present in infected cells.

Characterization of the gene encoding the most abundant in vitro translation product from virus-infected Chlorella-like algae.

The gene (33kDa) encoding a 33-kDa peptide from Chlorella virus, PBCV-1, was cloned and sequenced. This gene encodes the most abundant in vitro translation product synthesized from viral mRNAs isolated beginning at 20 min post-infection. The message persisted throughout the remainder of the viral life cycle. An open reading frame (ORF) of 717 bp, which encodes a polypeptide of 238 amino acids with a predicted M(r) or 26,613, was found on a 2752-bp cloned fragment from PBCV-1 HindIII restriction fragment 9. Transcriptional analysis of this ORF indicated that it was expressed both early and late, and as the viral life cycle progressed, the mRNA increased in size and abundance. Three other ORFs were also found; the largest of which (741 bp) hybridized to a low-abundance transcript which would encode a polypeptide with a predicted M(r) of 27,854.

Viruses and viruslike particles of eukaryotic algae.

Until recently there was little interest or information on viruses and viruslike particles of eukaryotic algae. However, this situation is changing. In the past decade many large double-stranded DNA-containing viruses that infect two culturable, unicellular, eukaryotic green algae have been discovered. These viruses can be produced in large quantities, assayed by plaque formation, and analyzed by standard bacteriophage techniques. The viruses are structurally similar to animal iridoviruses, their genomes are similar to but larger (greater than 300 kbp) than that of poxviruses, and their infection process resembles that of bacteriophages. Some of the viruses have DNAs with low levels of methylated bases, whereas others have DNAs with high concentrations of 5-methylcytosine and N6-methyladenine. Virus-encoded DNA methyltransferases are associated with the methylation and are accompanied by virus-encoded DNA site-specific (restriction) endonucleases. Some of these enzymes have sequence specificities identical to those of known bacterial enzymes, and others have previously unrecognized specificities. A separate rod-shaped RNA-containing algal virus has structural and nucleotide sequence affinities to higher plant viruses. Quite recently, viruses have been associated with rapid changes in marine algal populations. In the next decade we envision the discovery of new algal viruses, clarification of their role in various ecosystems, discovery of commercially useful genes in these viruses, and exploitation of algal virus genetic elements in plant and algal biotechnology.

Transcription and sequence studies of a 4.3-kbp fragment from a ds-DNA eukaryotic algal virus.

A 4.3-kbp portion of the genome from the Chlorella virus, PBCV-1, has been cloned and sequenced. Minimally, five open reading frames (ORFs) were identified on this fragment. Transcriptional analysis indicates that each ORF encodes complex patterns of RNA. The total length of transcribed RNA exceeds that of the ORF indicating either post-transcriptional modification or multiple transcriptional start/stop sites. The sequence TTTTTNT, previously described as the transcriptional stop site for the early genes of vaccinia virus, is also found downstream of each of our ORFs. The regions 5' to each ORF were very A + T-rich (approx 80%) but distinct promoter sequences were not unambiguously identified.

The chloroplast genome of an exsymbiotic Chlorella-like green alga.

Chloroplast DNA was isolated and cloned from Chlorella, strain N1a, exsymbiotic with Paramecium bursaria. BamHI, SalI, KpnI and Xho I restriction fragments of the DNA were assembled into a circular map. The genome consists of approximately 120 kbp of DNA, has a G/C content of 38%, and contains only a single copy of the rRNA cistron. The rRNA cistron is small, 5000-8000 bp, and the 16S and 23S gene are separated by less than 2000 bp.

The mitochondrial genome of an exsymbiotic Chlorella-like green alga.

Mitochondrial (mt) DNA from the unicellular, exsymbiotic Chlorella-like green alga, strain Nla was isolated and cloned. The mtDNA has a buoyant density of 1.692 g/ml in CsCl and an apparent G/C base composition of 32.5%. The genome contains approximately 76 kbp of DNA based on restriction fragment summation and electron microscopic measurements. A map of restriction endonuclease sites using Sst I, Bam I, Sal I and Xho I was generated. The genome maps as a circular molecule and appears as such under the electron microscope. Eight genes were assigned to the map by hybridization to specific restriction fragments using heterologous mt-encoded specific probes. These include the genes for subunits 6, 9, and alpha of the F0-F1 ATPase complex, the large and small subunit rRNAs, cytochrome oxidase subunits I and II, and apocytochrome b.

A comparison of viruses infecting two different Chlorella-like green algae.

Five plaque-forming viruses (Pbi viruses) of the unicellular, eukaryotic, exsymbiotic Chlorella-like green alga strain Pbi were isolated from fresh water collected in Germany. The viruses were compared to two previously characterized plaque-forming viruses (NC64A viruses) of Chlorella strain NC64A. The Pbi viruses do not infect Chlorella NC64A and vice versa. Like the NC64A viruses the Pbi viruses are large polyhedron with a diameter of 140 to 150 nm, are chloroform sensitive, have many structural proteins, and have large dsDNA genomes of at least 300 kb. However, the Pbi viruses are serologically distinct from the NC64A viruses. The five Pbi virus genomes contain 5-methylcytosine, which varied from 14.2 to 43.1% of the cytosine, and two of them also contained N6-methyladenine. DNAs from the Pbi viruses hybridized poorly with the two NC64A virus DNAs and they have a higher guanine plus cytosine content (ca. 46%) than the NC64A virus DNAs (ca. 40%).

Properties of the Chlorella receptor for the virus PBCV-1.

The virus PBCV-1 attached rapidly, specifically, and irreversibly to the external surface of cell walls of its host, a unicellular, eukaryotic Chlorella-like green alga. Attachment was pH and salt dependent. Each cell contained at least 5 X 10(4) PBCV-1 binding sites and Scatchard analysis indicated that each cell could adsorb 5000 PBCV-1 particles. The PBCV-1 receptor was unaffected by extraction with organic solvents, detergents, high salts, or treatment with several proteases as well as the polysaccharide degrading enzymes, cellulase and pectinase. In contrast, acid and alkali treatments of walls at high temperatures and treatment with an enzyme preparation from PBCV-1 lysates destroyed the virus receptor. We suspect that the receptor is a carbohydrate.

Characterization of viruses infecting a eukaryotic Chlorella-like green alga.

Nineteen plaque-forming viruses of the unicellular, eukaryotic Chlorella-like green alga, strain NC64A, were isolated from various geographic regions in the United States and characterized. Like the previously described virus, PBCV-1, all of the new viruses were large polyhedrons, sensitive to chloroform, and contained large dsDNA genomes of ca. 300 kbp. All of the viral DNAs contained 5-methyldeoxycytidine which varied from 0.1 to 47% of the deoxycytidine. In addition, 10 of the viral DNAs contained N6-methyldeoxyadenosine which varied from 8.1 to 37% of the deoxyadenosine. These viruses, along with 11 previously described viruses which replicate in the same Chlorella host, were grouped into 11 classes based on at least one of the following properties: plaque size, reaction with PBCV-1 antiserum, or the nature and abundance of methylated bases in their genomic DNA.

Replication of the algal virus PBCV-1 in UV-irradiated Chlorella.

The large dsDNA algal virus, PBCV-1, replicates in UV-irradiated Chlorella, albeit more slowly and with a smaller burst size than in untreated Chlorella. Irradiated cells are unable to form colonies, and endogenous RNA and DNA synthesis are reduced to background levels. Thus a fully function host nucleus is not required for PBCV-1 replication.

Lytic viruses infecting a Chlorella-like alga.

A number of viruses which form plaques on the unicellular, eukaryotic, Chlorella-like green alga, strain NC64A, were isolated from fresh water ponds and rivers in Illinois, North Carolina, and South Carolina. The viruses were large polyhedrons (160 to 190 nm in diameter) and contained dsDNA genomes of ca. 300 kbp. All of the viral DNAs hybridized with DNA from the previously described PBCV-1 virus. However, the viruses, even many of those isolated from the same water sample, could be distinguished from one another by DNA restriction endonuclease digestion. The viruses, including PBCV-1, were grouped into five classes by their resistance to certain DNA restriction endonucleases. Presumably the DNAs in the five classes contain different types or amounts of modified bases.

Infection of a Chlorella-like alga with the virus, PBCV-1: ultrastructural studies.

Ultrastructural studies revealed that the virus, PBCV-1, adsorbs to the surface of the Chlorella-like green alga NC64A and enzymatically digests a portion of the host cell wall. The viral DNA is then released into the interior of the cell leaving an empty capsid on the surface. Thus uncoating of the viral genome occurs at the surface of its host. PBCV-1 also adsorbs to and digests the host wall of either heat-killed, methanol-extracted, or purified cell wall fragments.

Structural proteins and lipids in a virus, PBCV-1, which replicates in a Chlorella-like alga.

PBCV-1, a large dsDNA-containing virus which replicates in a Chlorella-like green alga, is composed of approximately 64% protein, 25% DNA, and 5-10% lipid on a weight basis. Polyacrylamide gel electrophoresis of the dissociated virus particle resolves 50 to 60 proteins which range in apparent molecular weight from 10,000 to 135,000. Two of these proteins are glycoproteins and at least four are located on the viral surface. The major lipids are phosphatidyl choline, phosphatidyl ethanolamine, and an unidentified component. The effect of organic solvents, surfactants, and chelating and reducing agents on viral infectivity and ultrastructure are reported. Inhibitor studies established that PBCV-1 protein synthesis occurs on cytoplasmic ribosomes.