Apolipoprotein B mRNA editing. Direct determination of the edited base and occurrence in non-apolipoprotein B-producing cell lines

In humans, apolipoprotein (apo) B48 is synthesized in the intestine as an obligatory constituent of chylomicrons. Apolipoprotein B48 is identical to the amino-terminal 2152 amino acids (240 kDa) of apoB100 and is translated from an edited apoB mRNA in which codon 2153 has been converted from glutamine (CAA) to what is recognized as a premature stop codon (UAA). To determine whether the apoB mRNA editing in fact converts cytosine 6666 in codon 2153 to uracil, we incubated a synthetic apoB RNA containing 32P-labeled cytosines in an in vitro editing system prepared from rabbit enterocytes. The in vitro edited RNA was purified and digested to nucleoside 5'-monophosphates, which were analyzed on two-dimensional thin-layer chromatography. We found that the edited base co-migrated with authentic uridine 5'-monophosphate. Thus, cytosine 6666 is converted to uracil, most likely by a nucleotide-specific cytosine deaminase. To determine whether apoB mRNA editing occurs in cell lines that do not synthesize apoB, we stably transfected a high expression vector containing 354 base pairs of apoB sequence into 18 different cell lines. We found apoB mRNA editing activity in five osteosarcoma cell lines and one epidermoid cell line, none of which synthesizes any detectable apoB. Thus, apoB mRNA editing occurs in cell lines that do not synthesize apoB, which suggests that mRNA editing may be a common biological phenomenon in eukaryotic cells.     

A 40 kilodalton rat liver nuclear protein binds specifically to apolipoprotein B mRNA around the RNA editing site.

Apolipoprotein (apo) B-48 mRNA is the product of RNA editing which consists of a C----U conversion changing a CAA codon encoding Gln-2153 in apoB-100 mRNA to a UAA stop codon in apoB-48 mRNA. In the adult rat, RNA editing occurs both in the small intestine and the liver. We have studied the ability of rat liver nuclear extracts to bind to synthetic apoB mRNA segments spanning the editing site. Using an RNA gel mobility shift assay, we found the sequence-specific binding of a protein(s) to a 65-nucleotide apoB-100 mRNA. UV crosslinking followed by T1 ribonuclease digestion and SDS-polyacrylamide gel electrophoresis demonstrated the formation of a 40 kDa protein-RNA complex when 32P-labeled apoB-100 mRNA was incubated with a rat liver nuclear extract but not with HeLa nuclear extract. Binding was specific for the sense strand of apoB mRNA, and was not demonstrated with single-stranded apoB DNA, or antisense apoB RNA. The complex also failed to form if SDS was present during the UV light exposure. Binding experiments using synthetic apoB mRNAs indicate that the 40 kDa protein would also bind to apoB-48 mRNA but not apoA-I, apoA-IV, apoC-II or apoE mRNA. Experiments using deletion mutants of apoB-100 mRNA indicate efficient binding of wildtype 65-nucleotide (W65), 40-nucleotide (W40) and 26-nucleotide (W26) apoB-100 mRNA segments, but not 10-nucleotide (or smaller) segments of apoB-100 mRNA to the 40 kDa protein. In contrast, two other regions of apoB-100 mRNA, B-5' (bases 1128-3003) and B-3' (bases 11310-11390), failed to bind to the protein. The 40 kDa sequence-specific binding protein in rat liver nuclear extract may play a role in apoB-100 mRNA editing.     

Detection of apolipoprotein B mRNA editing by peptide nucleic acid mediated PCR clamping.

Apolipoprotein B (apoB) mRNA editing leads to a single base change in its mRNA and the production of apoB-48. Currently, the degree of apoB mRNA editing is analyzed by the RT-PCR primer extension method. While this method is quantitative, it is labor intensive, utilizes radioactivity for labeling and may not be sensitive enough to discriminate between low levels of editing and inherent assay background levels. Peptide nucleic acid (PNA) oligonucletides have been used in single point mutation detection through PCR clamping. In the present work, we developed a PCR based assay which can detect the single base change responsible for the apoB-48 production. We found that as low as 0.5% of the edited form can be clearly detected by PNA mediated PCR clamping. When combined with the primer extension assay, an approximately 180-fold enrichment of the edited percentage is observed, reflecting selected PCR amplification of templates containing the edited base.     

Identification of a novel in-frame translational stop codon in human intestine apoB mRNA

Human apolipoprotein (apo) B exists in plasma as two isoproteins designated apoB-100 and apoB-48. ApoB-100 (512 kDa) and apoB-48 (250 kDa) are synthesized by the liver and intestine respectively. Analysis of apoB cDNA clones isolated from a human intestinal cDNA library revealed that the intestinal apoB mRNA contains a new in-frame translational stop codon. This premature stop codon is generated by a single base substitution of a 'C' to 'T' at nucleotide 6538 which converts the codon 'CAA' coding for the amino acid glutamine residue 2153 to an in-frame stop codon 'TAA'. The generation of a stop codon in the intestinal apoB mRNA appears to be tissue specific since it has not been reported in cDNA clones isolated from human liver cDNA libraries which code for the 4536 amino acid apoB-100. A potential polyadenylation signal sequence 'AATAAA' was also identified 390 bases downstream from the new stop codon. The new stop codon in the human intestinal apoB mRNA provides a potential mechanism for the biosynthesis of intestinal apoB-48.     

Elimination of apolipoprotein B48 formation in rat hepatoma cell lines transfected with mutant human apolipoprotein B cDNA constructs.

Rat hepatoma McA-RH7777 cell lines transfected with full-length human apolipoprotein (apo) B constructs produce mostly human apoB48 and only small amounts of apoB100, as a result of mRNA editing at codon 2153 (C to U conversion at nucleotide 6666). To abolish the formation of apoB48 and increase the yield of apoB100 and other forms of apoB longer than apoB48, site-specific mutations were introduced at or near the site of apoB mRNA editing. Among four mutations examined, only that in which codon 2153 was converted from CAA (Gln) to CTA (Leu) effectively precluded the formation of apoB48. In this mutant, a stop codon would not be generated even if the C to U conversion occurred. The three other mutations were introduced to disrupt the proposed stem-loop structure encompassing the editing site. Changes made in the third positions of five codons on the 5' side of the edited base or of four codons 3' of the edited base failed to eliminate the production of a protein with the approximate size of apoB48. A construct in which codon 2153 was changed from CAA to GAT (Asp) also failed to eliminate the production of a protein the size of apoB48. Analysis of the region between nucleotides 6200 and 6900 of the cDNA did not detect any prevalent alternate editing sites. Immunoblot analysis using polyclonal antibodies raised against synthetic peptides of human apoB100 indicated that the carboxyl terminus of the apoB48-like proteins probably resides between amino acid residues 2068 and 2129 of apoB100. These results provide some insight into the mechanism of apoB mRNA editing and will facilitate further studies on apoB-containing lipoproteins.     

Three distinct RNA sequence elements are required for efficient apolipoprotein B (apoB) RNA editing in vitro.

Apolipoprotein B (apoB) mRNA is edited in rat liver and intestine to convert a CAA glutamine codon to a UAA translational stop codon by the direct conversion of cytidine to uridine at nucleotide 6666. We have proposed the 'mooring sequence' model for apoB RNA editing, in which editing complexes (editosomes) assemble on specific apoB mRNA flanking sequences to direct this site-specific editing event. One sequence element (approx. nts 6671-81, the presumed 'mooring sequence') has been previously identified as necessary for editing. We have identified two additional sequence elements which are necessary for efficient editing: (1) a 5' 'Regulator' region which modulates editing efficiency and (2) a 'Spacer' region between the editing site and the 3' mooring sequence, whose distance is critical for efficient editing. Utilizing this data, we have induced editing at a cryptic site and have defined a 22 nucleotide 'cassette' of specific apoB sequence which is sufficient to support wild-type levels of editing in vitro in a background of distal apoB RNA sequence.     

Sequence requirements for apolipoprotein B RNA editing in transfected rat hepatoma cells

Apolipoprotein (apo) B mRNA undergoes a novel tissue-specific editing reaction, which replaces a genomically templated cytidine with uridine. This substitution converts codon 2153 from glutamine (CAA) in apo B100 mRNA to a stop codon (UAA) in apoB48 mRNA (Powell, L. M., Wallis, S. C., Pease, R. J., Edwards, Y. H., Knott, T. J., and Scott, J. (1987) Cell 50, 831-840). To examine sequences in the human apoB mRNA required for the editing reaction, a series of deletion mutants around the cytidine conversion site was prepared and transfected into a rat hepatoma cell line (McArdle 7777). This cell makes both apoB100 and apoB48. Editing was detected by a primer extension assay on cDNA that had been amplified by the polymerase chain reaction. RNAs of between 2385 and 26 nucleotides spanning the conversion site underwent similar levels of conversion. Editing was confirmed by cloning and sequencing of cDNA corresponding to the transfected RNAs. Conversion did not occur in transfected human hepatoblastoma (HepG2) or epithelial carcinoma (HeLa) cell lines, which do not make apoB48. These results verify that apoB48 is generated by a genuine tissue-specific RNA editing reaction and show that 26 nucleotides of apoB mRNA are sufficient for editing.     

Single base substitution between human intestinal and hepatic apolipoprotein B mRNA detected by ribonuclease cleavage analysis

The molecular mechanism of human intestinal apolipoprotein (apo) B-48 synthesis has been elucidated by a combination of sequencing of cloned complementary DNAs and RNase cleavage analysis of RNA heteroduplex. All intestinal cDNA clones contained a single C to T base substitution in the codon CAA encoding Gln2153 in apoB-100 cDNA, resulting in a translational stop. One of the our intestinal apoB cDNA clones was polyadenylated 106 bases downstream from the stop codon, possibly producing a 7-kb apoB message in the intestine. RNase cleavage analysis of the RNA heteroduplex between hepatic or intestinal RNA and apoB cDNA-directed anti-sense RNA showed that this single C to U substitution may occur in most of intestinal apoB mRNA. These results suggested that human apoB-48 is mostly produced by apoB mRNA with an in-frame stop codon in the intestine.