Evolution of influenza A and B viruses: conservation of structural features in the hemagglutinin genes.

The complete nucleotide sequence of the hemagglutinin (HA) gene of a type B influenza virus (B/Lee/40) was obtained by using cloned cDNA derived from the RNA segment. The gene is 1,882 nucleotides long and can code for a protein precursor of 584 amino acids. Structural features common to type A virus HAs are also conserved in the B virus HA. These include a hydrophobic signal peptide, hydrophobic NH2 and COOH termini of the HA2 subunit, and a HA1/HA2 cleavage site involving an arginine residue. The sequence of the B HA gene and its deduced amino acid sequence were compared to those of a type A influenza virus (A/PR/8/34). When these two genes were aligned, it was found that 24% of the amino acids in the HA1 subunits and 39% of the amino acids in the HA2 subunits are conserved. This degree of relatedness between type B virus and type A virus HAs (intertypic comparison) is similar to the homologies observed among certain type A virus HAs (intratypic comparison). A close evolutionary relationship is therefore suggested between the HAs of type A and type B influenza viruses.

Moloney murine sarcoma proviral DNA is a transcriptional unit.

A portion of Moloney murine sarcoma virus DNA which is repeated at both ends of the provirus has been sequences. The nucleotide sequence, together with hybridization data obtained with in vitro pulse-labelled nascent viral RNA, indicate that initiation and termination of RNA synthesis occur within that region of the proviral DNA. A model for transcriptional readthrough of termination signals during RNA synthesis in this system is suggested.

Initiation of DNA replication by the dnaG protein.

Highly purified preparations of dnaG protein from Escherichia coli prime minus strand synthesis of phage alpha 3 DNA in vitro. This protein synthesizes primer oligonucleotides which may be composed of ribonucleotide or deoxyribonucleotide moieties or both. The presence of deoxyribonucleotide moieties in the chain limits primer chain length; this effect occurs even when ribonucleoside triphosphates are included in the priming reaction. The dnaG protein can use ADP in place of ATP. Primer formation by dnaG protein is strictly stoiochiometric in vitro; one molecule of dnaG protein is required to prime one molecule of alpha 3 DNA. All of these primers are equally efficient in the subsequent elongation reaction with DNA elongation factors I and III, dnaZ gene product, and DNA polymerase III to form RFII. The site recognized by dnaG protein on alpha 3 DNA in vitro is within the same region of the alpha 3 chromosome as the origin of replication in vivo. Structural properties of this site are crucial to dnaG action in vitro. No other enzymatic activity for dnaG protein has been detected.

Initiation of DNA replication by the Escherichia coli dnaG protein: evidence that tertiary structure is involved.

The dnaG protein of Escherichia coli initiates DNA replication by synthesizing primer oligonucleotides for elongation by DNA polymerae. The experiments reported here probe the nature of the nucleic acid element recognized by the dnaG protein. Three well-separated groups of nucleotides within the negative-strand origin of the single-stranded phage phi K are protected by the dnaG protein against nuclease digestion. DNA as far as 115 bases from the start site of primer synthesis is involved in binding of the dnaG protein to the replication origin. One molecule of dnaG protein could protect all of these nucleotides if the DNA were folded into a higher-order tertiary structure. Protection of the phi K origin by dnaG protein requires DNA binding protein, and it does not occur if the group of protected nucleotides most distant from the start site is removed from the template. There is no binding of dnaG protein to the complementary strand of the phi K origin-region DNA. The observed protection of the positive strand is due to a functional nucleic acid-protein complex.

Structure of murine sarcoma virus DNA replicative intermediates synthesized in vitro.

Moloney murine sarcoma virions synthesize discrete DNA products in vitro which closely resemble those found in vivo shortly after infection. These in vitro products have been isolated by electrophoresis and mapped with restriction endonucleases. In addition to the full-genome-length 6-kilobase pair linear DNA, a 5.4-kilobase pair circular DNA molecule, an incomplete linear DNA molecule, and a 600-base pair molecule were detected. The 6-kilobase pair DNA contained a 600-base pair direct terminal repeat which was missing from the circular form and was partially represented on the incomplete linear DNA molecule. The 600-base pair DNA contained sequences which were present in the 600-base pair direct repeat on the 6-kilobase pair DNA. The order of synthesis and the structure of these molecules detected in the in vitro reaction suggest that they are crucial intermediates in the formation of the final product of in vitro reverse transcription. A model which accounts for the synthesis of all of these molecules during the initial stages of viral replication is suggested.

Moloney murine sarcoma virions synthesize full-genome-length double-stranded DNA in vitro.

Moloney murine sarcoma virus (MSV) virions incubated under optimal conditions were shown to support extensive synthesis of double-stranded DNA. The major product, a 5950-base-pair (6-kilobase-pair DNA) double-stranded DNA, was characterized by cleavage with restriction endonucleases and shown to contain a 600-nucleotide-long direct repeat at both ends of the MSV genome. Linear DNA molecules made in vivo shortly after infection were compared to the linear double-stranded DNA synthesized in vitro. The restriction maps of both viral DNA products were indistinguishable. The 600-base-pair repeat results in a progeny DNA molecule that is longer than the parental MSV genomic RNA. The generation of this repeat must involve a mechanism that allows the viral reverse transcriptase (RNA-dependent DNA nucleotidyltransferase) to copy 5'- and 3'-terminal genomic (+) strand sequences twice.

Effect of cell proliferation on levels and diversity of poly(A)-containing mRNA.

The relationship between cell proliferation and the amount and diversity of polyribosome-associated poly(A)-containing messenger RNA [poly(A)+mRNA]has been investigated using a cloned AKR-mouse embryo cell culture system. The following results were obtained. First, an early response to the stimulation of proliferation of AKR-2B cells in culture is a rapid increase in the rate of accumulation of polyribosomal poly(A)+ mRNA. This results in a large increase in the total poly(A)+ mRNA content of rapidly proliferating cells compared to that found in resting cells. Second, the total amount of unique DNA sequence contributing to the poly(A)+ mRNA populations of both growing and resting cells is not detectably different. This corresponds to 9000-11,000 diverse gene equivalents of DNA and represents the transcription of 0.8-0.9% of the haploid mouse genome. Third, most of the increased poly(A)+ mRNA content of growing cells (greater than 90%) reflects an increased rate of production of polysomal mRNA species which are also found in resting cells. Fourth, growing cells appear to contain some species of poly(A)+ mRNA which are either absent or present in very low concentrations in non-growing cells. Within the limits of detection, however, all species of poly(A)+ mRNA present in non-growing cells are also present in growing cells.