Chi-Cheng Luo

Nonrandomness of point mutation as reflected in nucleotide substitutions in pseudogenes and its evolutionary implications.

SummaryWe have obtained a revised estimate of the pattern of point mutation by considering more pseudogene sequences. Compared with our previous estimate, it agrees better with expectations based on the double-strand structure of DNA. The revised pattern, like the previous one, indicates that mutation occurs nonrandomly among the four nucleotides. In particular, the proportion of transitional mutations (59%) is almost twice as high as the value (33%) expected under random mutation. The same high proportion of transitions is observed in synonymous substitutions in genes. The proportion of transitional changes observed among electrophoretic variants of human hemoglobin is about the same as that predicted by the revised pattern of mutation. We also show that nonrandom mutation increases, by about 15%, the proportion of synonymous mutations due to single-nucleotide changes in the codon table, and increases, from 10% to 50%, the rate of synonymous mutation in the seven genes studied. However, nonrandom mutation reduces (by about 10%) the proportion of polar changes among nonsynonymous mutations in a gene. As far as single-nucleotide changes (in the codon table) are concerned, nonrandom mutation only slightly favors relatively conservative amino acid interchanges, and has virtually no effect on the proportions of radical changes and nonsense mutations.

Structure and evolution of the apolipoprotein multigene family

We present the complementary DNA and deduced amino acid sequence of rat apolipoprotein A-II (apoA-II), and the results of a detailed statistical analysis of the nucleotide and amino acid sequences of all the apolipoprotein gene sequences published to date: namely, those of human and rat apoA-I, apoA-II and apoE, rat apoA-IV, and human apoC-I, C-II and C-III. Our results indicate that the apolipoprotein genes have very similar genomic structures, each having a total of three introns at the same locations. Using the exon/intron junctions as reference points, we have obtained an alignment of the coding regions of all the genes studied. It appears that the mature peptide regions of these genes are almost completely made up of tandem repeats of 11 codons. The part of mature peptide region encoded by exon 3 contains a common block of 33 codons, whereas the part encoded by exon 4 contains a much more variable number of internal repeats of 11 codons. These genes have apparently evolved from a primordial gene through multiple partial (internal) and complete gene duplications. On the basis of the degree of homology of the various sequences, and the pattern of the internal repeats in these genes, we propose an evolutionary tree for the apolipoprotein genes and give rough estimates of the divergence times between these genes. Our results show that apoA-II has evolved extremely rapidly and that apoA-I and apoE also have evolved at high rates but some regions are better conserved than the others. The rate of evolution of individual regions seems to be related to the stringency of their functional requirements.

Chicken apolipoprotein A-I: cDNA sequence, tissue expression and evolution.

Using an antibody against chicken apolipoprotein (apo) A-I, we identified multiple cDNA clones for the protein in two intestinal cDNA libraries in lambda gt11. The complete nucleotide sequence of chicken apoA-I cDNA was determined. The sequence predicts a mature protein of 240 amino acids, a 6-amino acid propeptide and an 18-amino acid signal peptide. Using a 32P-cDNA probe, we detected the presence of apoA-I mRNA in 21 day old chicken intestine, liver, kidney, spleen, breast muscle and brain. The primary sequence of apoA-I contains numerous tandem repeats of 11 and 22 residues in a manner similar to the mammalian proteins. Our analysis of apoA-I sequences from human, rabbit, dog, rat, and chicken indicates that the rate of amino acid substitution is considerably faster in the rat lineage than in other mammalian lineages.

Genetic basis of apolipoprotein disorders

The protein components of plasma lipoproteins are known as apolipoproteins. The major function of apolipoproteins is lipid transport in the intravascular and extravascular compartments. Many apolipoproteins have, in addition, acquired highly specialized functions. For example, apolipoprotein B (apoB) is an important determinant in the binding of LDL to the LDL receptor [1]. ApoE also appears to confer receptor binding capability to lipoprotein particles to both the LDL receptor [2] and a specific apoE receptor [3]. ApoC-II activates lipoprotein lipase and is important in chylomicron and VLDL metabolism [4,5]. Conversely, apoC-III seems to inhibit the apoC-II activation of lipoprotein lipase [6]. It also modulates the uptake of apoE-containing lipoproteins by liver cells. ApoA-I [7] and possibly apoC-I [8], apoE [9] and apoA-IV [10] are thought to activate lecithin-cholesterol acyltransferase.