No worries.

Firstly, you don't need to align the Sanger sequencing to the whole human genome or view it in the same program along with the BAM files. From your pooled Illumina sequencing, you should have a VCF (or some other format) file with the SNP locations. Just extract the sequence for the region that should be covered by the Sanger sequencing and align (in Sequencher, or whatever you prefer) to that. You know it's coordinates, so you'll know that if that region covers chr1 1000-1500 and the SNP is at position 1200 that you should look at position 200 in the Sanger alignment. There's no reason to then go back to the Illumina reads, you're already done with them. You're confirming the Illumina findings with Sanger sequencing, not the other way around (if someone tells you otherwise then you should ignore them, they don't have a clue what they're doing).

Yes, as I said in one of my comments, that's an example with 3 copies of A and one of T (it's alfalfa DNA, so it's tetraploid).

His name is Devon, but not Demon :)

One usually doesn't use BAM files or NGS-specific tools with Sanger sequencing. You can't view a BAM file as a meaningful chromatogram in most cases (at least unless the second most likely base and the associated scores were stored as auxiliary tags (this would be atypical)).

Yes, Sanger is the gold standard for variant calling. It's just slow and expensive, which is why we all prefer NGS.

Thanks Joe.

I already searched to find SNPs using Sanger but its a little difficult since my individuals are tetraploid and I can not recognize if I have double heterozygous graph it means that from 4 allele 2 of them are differet ?

What you end up doing is comparing peak heights. In that example, it's 3 copies of A and one copy of T. This method isn't perfect, but neither is the NGS variant (though to be far, this is why one uses NGS with pooled data, it's easier to deal with their). I suspect that tetraploid is about the highest ploidy one would want to use Sanger sequencing for (I'm sure someone's tried it with even higher ploidy, so perhaps it still works OK and I've just never seen it).

What is the size of your PCR products? I assume you must be talking about PCR-ing cDNAs, since splicing of the genomic DNA would be something, well, not typical?

In short, if your 2 reads from the opposite sides of the PCR-product overlap significantly, you would be able to detect indels on the genomic level in a diploid organism. With tetraploid, plus splicing, I would at least try to separately sequence differently sized PCR bands cut from the gel. But if you want to publish this then either you go with subcloning of the PCR bands, or switch to NGS RNAseq, preferably with 2x100 (or longer) reads.

re splicing and function:

no idea. Or rather: too complex to answer in few lines.

Just keep in mind that not everything you get from PCR-ing RNA from the cell is "real". You can have pre-mRNA with not spliced introns, splicing errors etc. Unless the thing is dominant and consistent between experiments, it may be an artifact.

There are specific tools for viewing Sanger chromatograms and it makes no sense try to load these chromatogram files into programs which simply can not handle this (like IGV). If you can not see the chromatogram, and use simple fasta you can not make any calls as what is going on regarding SNPs/indels. Sometimes sequencing run is longer than your insert or gets killed for other reasons, and you get random noise base calls.

In case you have a lot of Sanger sequences plus FASTQ from NGS, and simply refuse to use i.e. Staden package listed above, then you have to have some genome sequence from your species, even if it is a toy "genome" in a form of contigs of interest, convert your Sanger files to FASTQ (i.e by using BioPython: http://biopython.org/wiki/SeqIO), or to FASTA, then map it to your toy genome and load into IGV. You are still out of luck if instead of clear homozygote different from reference you will get "N" base in your fasta/fastq file, but not just one but multiple reads. Which will bring you to square one: look at your Sanger chromatograms.