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Journal of Lipid Research, Vol 30, 1735-1746, Copyright © 1989 by Lipid Research, Inc.
CC Luo, WH Li and L Chan
Dog apolipoprotein (apo) C-I, A-I, and E cDNA clones were identified in a
dog liver cDNA library in lambda gt10 by hybridization to synthetic
oligonucleotide probes with the corresponding human DNA sequences. The
longest clone for each apolipoprotein was completely sequenced. The apoC-I
cDNA sequence predicts a protein of 62 residue mature peptide preceded by a
26 amino acid signal peptide. The apoA-I cDNA sequence predicts a 242
residue mature peptide, a 6 residue pro-segment, and an 18 residue signal
peptide. The apoE cDNA, which lacks the signal peptide region, predicts a
mature peptide of 291 amino acid residues. Slot blot hybridization of total
RNA isolated from various dog tissues to dog apoC-I, A-I, and E cDNA probes
indicates that apoC-I mRNA is detectable in liver only, apoA-I mRNA is
present in liver and small intestine, though the concentration in the
latter tissue is only approximately 15% of that in the liver, and apoE mRNA
is present in multiple tissues including liver, jejunum, urinary bladder,
ileum, colon, brain, kidney, spleen, pancreas, and testis with relative
concentrations (%) of 100, 17.5, 7.5, 6.9, 5.9, 5.5, 5.0, 3.3, 1.0, and
1.0, respectively. These tissue distributions indicate that nascent
lipoprotein particles produced in the dog small intestine would contain
apoA-I and apoE but not apoC-I. The widespread tissue distribution of apoE
mRNA indicates that like other mammals, peripheral synthesis of apoE
contributes significantly to the total apoE pool in dog. We next compared
the cDNA sequences among different vertebrate species for apoC- I (human
and dog), A-I (human, rat, dog, rabbit and chicken), and E (human, rat, dog
and rabbit) and calculated the rate of nucleotide substitution for each
gene. Our results indicate that apoC-I has evolved rather rapidly and that
on the whole, apoA-I is more conservative than apoE, contradictory to an
earlier suggestion. ApoA-I is also more conservative than a region
(residues 4204-4536) at the carboxyl-terminal portion, but less
conservative than a region (residues 595-979) at the amino-terminal portion
of apoB-100. Some regions in each of the apolipoproteins studied are better
conserved than others and the rate of evolution of individual regions seems
to be related to the stringency of functional requirements. Finally, we
estimate that the human apoC-I pseudogene arose more than 35 million years
ago, becoming nonfunctional soon after its formation.
ARTICLES
Structure and expression of dog apolipoprotein A-I, E, and C-I mRNAs: implications for the evolution and functional constraints of apolipoprotein structure
Center for Demographic and Population Genetics, University of Texas, Houston 77030.
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