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Comparative Study
.2005 May 3;102(18):6368-72.
doi: 10.1073/pnas.0502288102. Epub 2005 Apr 19.

Synonymous mutations in CFTR exon 12 affect splicing and are not neutral in evolution

Affiliations
Comparative Study

Synonymous mutations in CFTR exon 12 affect splicing and are not neutral in evolution

Franco Pagani et al. Proc Natl Acad Sci U S A..

Abstract

It is well established that exonic sequences contain regulatory elements of splicing that overlap with coding capacity. However, the conflict between ensuring splicing efficiency and preserving the coding capacity for an optimal protein during evolution has not been specifically analyzed. In fact, studies on genomic variability in fields as diverse as clinical genetics and molecular evolution mainly focus on the effect of mutations on protein function. Synonymous variations, in particular, are assumed to be functionally neutral both in clinical diagnosis and when measuring evolutionary distances between species. Using the cystic fibrosis transmembrane conductance regulator (CFTR) exon 12 splicing as a model, we have established that about one quarter of synonymous variations result in exon skipping and, hence, in an inactive CFTR protein. Furthermore, comparative splicing evaluation of mammalian sequence divergences showed that artificial combinations of CFTR exon 12 synonymous and nonsynonymous substitutions are incompatible with normal RNA processing. In particular, the combination of the mouse synonymous with the human missense variations causes exon skipping. It follows that there are two sequential levels at which evolutionary selection of genomic variants take place: splicing control and protein function optimization.

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Figures

Fig. 1.
Fig. 1.
Comparative analysis of human and mouse CFTR exon 12 sequences evaluated for splicing efficiency. (a) Comparison of human (hCF12) and mouse (mCF12) CFTR exon 12 nucleotide sequences and amino acids (in one letter code). Synonymous (green for human and yellow for mouse) and nonsynonymous (in red or black for human and mouse, respectively) differences are highlighted. h-m1 and h-m2 are human-mouse hybrid exons: h-m1 contains the human-specific synonymous along with and the mouse-specific nonsynonymous substitutions; h-m2 contains the mouse-specific synonymous along with and the human-specific nonsynonymous substitutions. (b) Schematic representation of the hybrid minigene used in transient transfection splicing assays. Minigene exons and introns are indicated as black boxes and lines, respectively. Exon 12 sequences (white box) were tested for splicing efficiency by using specific primers (arrows). Dotted lines show the two CFTR exon 12 alternative splicing possibilities. (c) RT-PCR products from transfection experiments. RNA splicing variants corresponding to exon 12 inclusion and exclusion are shown. M is the 1-kb marker. Numbers at the bottom indicate the percentage of exon inclusion. Transfection experiments in NIH 3T3 mouse cells lines showed comparable changes in the splicing efficiency.
Fig. 2.
Fig. 2.
Synonymous mutations in human CFTR exon 12 induce exon skipping. (Upper) The nucleotide and amino acid composition (in one letter code) of part of the human CFTR exon 12 (hCF). Third nucleotide positions are numbered according to their location in the exon. (Lower) RT-PCR products from splicing assay from 19 of 22 possible single synonymous changes between position 13 and 52 of the human CFTR exon 12. The position and the nucleotide substitution analyzed are indicated above each lane. The percentages of exon inclusion are reported at the bottom of each lane. The six synonymous substitutions that induce significant exon skipping are boxed.
Fig. 3.
Fig. 3.
Comparative analysis of mammalian CFTR exon 12 sequences evaluated for splicing efficiency. (a) Mammalian CFTR exon 12 sequences grouped into primates, (human, baboon, chimpanzee, and lemur), perissodactyla (horse), certiodactyla (pig, cow, and sheep), rodents (mouse and rat), and carnivora (cat, dog, and ferret). Compared to human sequences, synonymous (black) and nonsynonymous (white) differences are highlighted and numbered according to their position in the exon. Sequence comparison shows some degree of lineage-specific conservation in the exon. Nonsynonymous sites are specific for rodents. Among the synonymous changes, T28/T29 is a recent acquisition of the human/Pan/gorilla group, T37, C40, and T67 are rodent-specific, and A25 and G55 are exclusive for carnivores. The remaining synonymous changes at positions 10, 31, and 52 occur in more than one lineage, C43 and C46 are only present in rat, and only G7 is present in cat. Numbers on the right indicate the percentage of CFTR exon 12 inclusionin vivo. ND, not done. (b) Splicing efficiency of mammalian exons analyzed by RT-PCR products from transfection experiments. RNA splicing variants correspond to exon 12 inclusion and exclusion. M is the 1-kb marker. Percentage of exon inclusion is indicated at the bottom.
Fig. 4.
Fig. 4.
Synonymous substitutions affect the splicing efficiency according to the mammalian exonic context. (a) Sequences of CFTR exon 12 highlighting the artificial composition of synonymous substitutions introduced in hybrid minigenes by site-directed mutagenesis. The three synonymous changes that in the human context induce exon skipping (25A, 40C, and 52T) are boxed. Numbers on the right of each sequence indicate the percentage of exon inclusion as determined by minigene splicing assay. For clarity, these percentages are also reported under the image inb that shows corresponding RT-PCR products from splicing assay. The RNA splicing variants that correspond to exon 12 inclusion and exclusion are indicated. M is the 1-kb marker.
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References

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