Distribution and consensus of branch point signals in eukaryotic genes: a computerized statistical analysis.

An intermediate stage in the process of eukaryotic RNA splicing is the formation of a lariat structure. It is anchored at an adenosine residue in intron between 10 and 50 nucleotides upstream of the 3' splice site. A short conserved sequence (the branch point sequence) functions as the recognition signal for the site of lariat formation. It has been generally assumed that the branch point is recognized mainly by the presence of its unique sequence where the lariat is formed. However, the known branch point consensus sequence is found to be distributed nearly randomly throughout the gene sequence with only a slightly higher frequency in the expected lariat region. Further, the known consensus sequence is found to be clearly inadequate to specify branch points. These observations have implications for understanding the mechanism of branch point recognition in the process of splicing, and the possible evolution of the branch point signal.

Possible evolution of splice-junction signals in eukaryotic genes from stop codons.

Splice-junction sequence signals are strongly conserved structural components of eukaryotic genes. These sequences border exon/intron junctions and aid in the process of removing introns by the RNA splicing machinery. Although substantial research has been undertaken to understand the mechanism of splicing, little is known about the origin and evolution of these splice signal sequences. Based on the previously published theory that the primitive genes evolved in pieces from primordial genetic sequences to avoid the interfering stop codons, a "stop-codon walk" mechanism is proposed in this paper to have assisted in the evolution of coding genes. This mechanism predicts the presence of stop codons in splice-junction signals inside the introns. Evidence of the consistent presence of stop codons in the splice-junction signals, in a position where they are expected, is shown by the analysis of codon statistics in these signal sequences in the GenBank databank. The results suggest that the splice-junction signals may have evolved from stop codons as a consequence of a selective pressure to avoid stop codons during the original evolution of coding genes. They also suggest that other splice signals within the introns, such as the branch-point sequence, may have evolved from stop codons for similar reasons.

RNA splice junctions of different classes of eukaryotes: sequence statistics and functional implications in gene expression.

A systematic analysis of the RNA splice junction sequences of eukaryotic protein coding genes was carried out using the GENBANK databank. Nucleotide frequencies obtained for the highly conserved regions around the splice sites for different categories of organisms closely agree with each other. A striking similarity among the rare splice junctions which do not contain AG at the 3' splice site or GT at the 5' splice site indicates the existence of special mechanisms to recognize them, and that these unique signals may be involved in crucial gene-regulation events and in differentiation. A method was developed to predict potential exons in a bare sequence, using a scoring and ranking scheme based on nucleotide weight tables. This method was used to find a majority of the exons in selected known genes, and also predicted potential new exons which may be used in alternative splicing situations.

Origin of eukaryotic introns: a hypothesis, based on codon distribution statistics in genes, and its implications.

A hypothesis for the origin of introns in eukaryotic genes is developed. By computer simulation it was found that the reading-frame lengths in a random nucleotide sequence are distributed in a negative exponential manner and that there exists an upper limit of about 200 codons in the length of the reading frames (RFs). These characteristics suggest that, if primordial DNA contained a random nucleotide sequence, the most primitive cells would have been under selective pressure to eliminate interfering stop codons in order to increase the length of RFs. Further, they indicate that the only possible way that a coding sequence that is considerably longer than 600 nucleotides could be derived from the short coding sequences occurring in a random sequence would be to splice the short coding sequences and to eliminate the stretches of sequences containing clusters of inframe stop codons. Thus, introns are suggested to be those stretches of sequences containing interfering stop codons that were originally earmarked in the first primitive cells to be eliminated in order to enable the coding for long polypeptides. Because the statistical characteristics of codon distributions in today's eukaryotic DNA sequences resemble closely those of a random sequence and because the upper limit in the length of RFs (200 codons) in a random sequence corresponds precisely to the observed maximum length of exons in today's eukaryotic genes (600 nucleotides), it is suggested that introns originated in the most primitive unicellular eukaryotes when they evolved from primordial sequences. The data from the prokaryotic gene sequences indicate that prokaryotic genes may have been derived originally from primitive unicellular eukaryotic genes by losing introns from them.

Automated preparation of DNA sequences for publication.

A computer program which draws DNA sequences is described. A simple method is used which enables the user to highlight or annotate specific parts of a sequence. The sizes of the characters in the sequence to be drawn are specified by the user. In addition, vertical spacing between lines and horizontal spacing between characters can be specified. Sequences can be prepared and high quality output produced on a plotter in a short period of time, making the program advantageous to use over typing, computer printing, or preparation by a graphics department.

Mechanism of coupling periodate-oxidized nucleosides to proteins.

This paper describes a mechanism of coupling periodate-oxidized nucleosides to proteins. Each of the dialdehyde groups of a periodate-oxidized nucleoside is shown to couple to lysine residues on different protein molecules through Schiff bases, thereby cross-linking different protein molecules, forming a polymer. This is in contrast to the previous model in which nucleosides were suggested to couple to proteins through a morpholine structure. The cross-linked structure of the nucleoside-antigen, significantly different when compared to the native protein, may affect the specificity and the efficiency of antibody production.

Purification of antibodies for the cytokinin N6-(delta 2-isopentenyl) adenosine by affinity chromatography.

Isopentenyl adenosine antibodies useful in the investigations of the "cytokinin" functions of isopentenyl adenosine were purified by affinity chromatography. Using different affinity columns, the antibodies were purified to near complete purity. Analyses of the purified proteins revealed the presence of isopentenyl adenosine binding proteins in normal rabbit serum, which presence supports a suggested role for isopentenyl adenosine and its related compounds in animal cell division in vivo.

Replication of adeno-associated virus DNA. Complementation of naturally occurring rep- mutants by a wild-type genome or an ori- mutant and correction of terminal palindrome deletions.

When the entire adeno-associated virus (AAV) genome is inserted into a bacterial plasmid, infectious AAV genomes can be rescued and replicated when the recombinant AAV-plasmid DNA is transfected into human 293 cells together with helper adenovirus particles. We have taken advantage of this experimental system to analyze the effects of several classes of mutations on replication of AAV DNA. We obtained AAV mutants by molecular cloning in bacterial plasmids of naturally occurring AAV variant or defective-interfering genomes. Each of these mutants contains a single internal deletion of AAV coding sequences. Also, some of these mutant-AAV plasmids have additional deletions of one or both AAV terminal palindromes introduced during constructions in vitro. We show here that AAV mutants containing internal deletions were defective for replicative form DNA replication (rep-) but could be complemented by intact wild-type AAV. This indicates that an AAV replication function, Rep, is required for normal AAV replication. Mutants in which both terminal palindromes were deleted (ori-) were also replication defective but were not complementable by wild-type AAV. The cis-dominance of the ori- mutation shows that the replication origin is comprised in part of the terminal palindrome. Deletion of only one terminal palindrome was phenotypically wild-type and allowed rescue and replication of AAV genomes in which the deleted region was regenerated apparently by an intramolecular correction mechanism. One model for this correction mechanism is proposed. An AAV ori- mutant also complemented replication of AAV rep- mutants as efficiently as did wild-type AAV. These studies also revealed an unexpected additional property of the deletion mutants in that monomeric single-stranded single-stranded DNA accumulated very inefficiently even though monomeric single-stranded DNA from the complementing wild-type AAV did accumulate.

Molecular cloning of adeno-associated virus variant genomes and generation of infectious virus by recombination in mammalian cells.

Continued passage of the human parvovirus, adeno-associated virus (AAV), at high multiplicity of infection in human cells results in the accumulation of AAV particles containing variant genomes. We have analyzed the structure of individual variant AAV genomes by molecular cloning in the Escherichia coli plasmid, pBR328. Each of the AAV inserts in six individual recombinant plasmids contained a single internal deletion but in contrast to a previous model, the locations of the deletions were nonrandom. The molecular cloning protocol also generated recombinant plasmids containing the entire AAV2 DNA sequence which yielded infectious AAV particles when transfected into human 293 cells in the presence of helper adenovirus using a DEAE-transfection procedure. Infectious AAV genomes were also generated by recombination when cells were jointly transfected with a mixture of plasmids containing two different mutant AAV genomes. The efficiency of this recombination appear to be influenced by the degree of homology between the mutant AAV genomes.

Identification and purification of tRNAs containing N6-(delta 2-isopentenyl) adenosine using antibodies specific for N6-(delta-isopentenyl) adenosine.

Antibodies specific for the modified nucleoside N6-(delta 2-isopentenyl) adenosine (i6A) were employed to identify the tRNAs containing i6A from an unfractionated tRNA mixture by a nitrocellulose filter binding assay. When radioactive aminoacyl-tRNAs were incubated with i6A-specific antibodies and filtered through nitrocellulose membrane filters, the tRNAs possessing i6A (tRNAtyr and tRNAser) remained on the filters. tRNAarg and tRNAlys which do not contain i6A showed no binding. This finding will be useful as a very simple and rapid assay of such RNAs under a variety of conditions. Purification of i6A containing tRNAs from an unfractionated tRNA mixture was achieved by affinity chromatography of the tRNAs on an i6A antibody-Sepharose column. Nonspecific binding of tRNAs to the column was avoided by the use of purified antibodies.