Hi everyone,

I have a few questions about the distribution of disease-SNPs on the genome. I apology in advance if some of them are very banal to you. I'm not a bioinformatician but a statistician. I've tried to obtain answers on my own, by searching on the web and on this forum but I'm still unsure if I got them right and I didn't find all I was looking for.

Therefore your help will be very much appreciated...!

So, if my sources are correct, each genome has approx. 3.3mio SNPs among which about 1.3mio are in intragenic regions. Among the latter, 25'000 to 40'000 SNPs are in protein-coding regions.

Q1: if I understood correctly, a gene is not wholly considered as a protein-coding region. What is exactly the difference between a gene and its protein-coding part? And what about exons? Are they a synonym for protein-coding regions or for genes or...?

Q2: Are the boundaries of the protein-coding region considered as a known information or have they to be inferred (how, in that case?)?

Q3: Is it ok to believe that the proportion of SNPs associated with a given phenotype will be much higher in the protein-coding region than in the rest of the genome? Can we say the same for SNPs in intragenic regions when compared with those in intergenic regions?

Q4: Given that the number of SNPs in non-coding regions is much higher than in coding-regions, I guess that most GWAS will mark much more SNPs as "significantly associated with the phenotype" in the non-coding regions. Is this guess correct? But still, in terms of proportions with respect to these to regions, a SNP in coding-regions is more likely to be associated with the phenotype, is that right?

Q5: In the common Illumina chips (for instance with 500k SNPs) is the proportion of SNPs found in protein coding region favoured with respect to SNPs in intergenic regions? If yes, what is the typical proportion of such SNPs on these chips? The proportion of SNPs found significant in GWAS would also depend on these choices made by the chip constructed then.

I thank you very much in advance....

Q1: Genes have exons and introns... Exons are usually coding for proteins, introns not... However in some transcripts (and later proteins) exon can be skipped.

Q2: Boundaries of exons are known. Typically by software or by RNA sequencing. Also open reading frames and splice site sequences are known so from this proteins can be predicted.

Q3: I don't completely understand the question. Variants are present in coding and non coding part of the genome. However more variation is allowed in non coding parts of the genome since in general they are less crucial. Keep in mind that there are several types of coding variants: Loss of function variants (splice sites, frameshifts), missense and synonymous mutations. Where loss of function variants have likely a damaging effect to the protein, but not necessarily are disease causing. Missense mutations can be disease causing but only in vital parts of proteins in vital proteins. For example in APP or PSEN1 in Alzheimers. Even some synonymous mutations can be disease causing...

Q4: Yes, that is correct, but not necessarily following your hypothesis. GWAS are usually risk factors and not disease causing mutations. So GWAS non coding variants are for example often eQTLs or in the neighborhood of a regulatory element. So in general: no SNPs in coding regions are not more likely to be associated with disease, GWAS are usually risk factors and more regulatory variants in my view.

Q5: Usually Illumina chips are designed based on tagging SNPs and followed by an imputation step to end up with 5 million variants. Because in general "common" coding variants don't cause diseases, it are the rare coding variants that are more prone to be disease causing and especially in the Mendelian diseases..