Turning publicly available genome data into proteins

Question

I'm a computer scientist who is starting to dabble with biology. My eventual goal is to model different kinds of cells with a computer program. As of right now, I'm just trying to take some smaller steps.

First, I downloaded a complete human genome from http://hgdownload.cse.ucsc.edu/downloads.html#human There is a FASTA file for each chromosome.

Then, I wrote a java program which can convert FASTA DNA sequences into the appropriate amino acid chain.

Next, I made my program look for the "start" code (ATG) and "stop" codes (TAA, TAG, TGA).

So, now I have sequences of amino acids which might theoretically end up folding into proteins. But, before I start diving into protein folding, I wanted to try to verify that the steps I took so far were done correctly. I looked up some important human genes in an online database and found their amino acid sequences. I then searched through my program's data for those sequences and confirmed that they were there. However, the gene was in a different base-pair location than the database said that it should be in.

This led me to some questions, which, so far I have been unable to answer and hopefully people here will be able to help shed some light.

1. I know there are a lot of different publicly available genomes. Maybe the UCSC one that I downloaded is different from the one used by the gene database. How much does each genome vary from each other genome and in what ways do they vary?

2. In attempting to answer that first question, I was going to download a bunch of genomes from the 1000genomes website and do some comparisons, but I wasn't sure which files to download. Each of the files begins with either ERR or SRR and I'm not sure what that means. This is the folder I'm currently looking in ftp://ftp-trace.ncbi.nih.gov/1000genomes/ftp/data/HG00239/sequence_read/

3. Lets say I'm trying to model a white blood cell. How do I know which parts of the genome get turned into proteins for that type of cell?

Sorry if anything I said doesn't make sense. As I said, my expertise lies in programming, not biology/genetics.

Answer 1

No, your approach will not work, you are taking a very simplistic view of an extremely complex system. Some of the problems you are ignoring are:

• Genes (eukaryotic genes anyway) are spliced to produce mRNA, a process that removes introns and leaves only the exons. If you just translate the entire chromosome file you will get noise.

• Splicing also changes the frame a gene is read in, you don't mention frames at all in your question but you can't work with sequences unless you deal with them.

• Many genes (most even, in some species) are alternatively spliced. One gene can give rise to multiple protein sequences. Which one is produced at any one time can depend on a multitude of factors ranging from pure chance, through environmental conditions to the cell type where the gene is expressed.

• Genes can be present on both strands of DNA and a gene on the + strand can overlap with a gene on the - strand. In some cases they can even overlap on the same strand (nested genes). You need to check both strands for coding sequences.

• You're assuming that all coding sequences start with ATG (most do, not all) and you seem to be assuming that an ATG always starts a coding sequence. A given gene can have dozens or hundreds of ATG codons, how can you know which one is used as a START codon?

The process of identifying the parts of the genome that get translated into protein is not trivial. It is the subject of countless PhD theses, mine for example. There are many programs (gene predictors) that are designed specifically to detect genes in genomic sequences. Having spent many years working with them I can assure you that they're not something you can just whip up one afternoon. They tend to involve very complex models of coding vs. non-coding sequences and are way more sophisticated than simply looking for START and STOP codons. Trying to write one without knowing a lot more about biology than you seem to is just a waste of time.

Your specific questions are basically irrelevant because of the points mentioned above. Nevertheless, the answers are:

1. They vary but not much. For well annotated genomes like the human one, the differences will be negligible. That is not why you have strange results though as I explained above.

2. All public FTP sites tend to have a README file that explains what the files provided are. You should read the relevant README from ftp://ftp-trace.ncbi.nih.gov/1000genomes/ftp/

3. Answering that question will get you a Nobel prize. There simply is no way of predicting what genes will be activated in a particular cell. We're not even close to that level of understanding of how a cell works but I can tell you that it will not depend on the sequence, you will never be able to predict whether a gene is active in a particular cell based on its DNA sequence alone. It will depend on various things including the gene's methylation state and is largely an emergent quality of the cell's complexity (think of various proteins interacting with one another, leading to the activation of a gene). The best you can do is get a list of genes that are known to be active from the literature.

In summary, if you want to do something as complex as modelling a cell I suggest you first take the time and study some basic biology so you can understand the system you are trying to model a bit better. The cell is not only an extremely complex system that we don't fully understand yet, it is also not wholly deterministic and contains a lot of stochasticity that you seem to be ignoring completely.

Answer 2

Why bother predicting proteins badly from DNA sequence when you could have just as well downloaded the manually curated human proteome?

As to your questions:

1. Are you asking about human genomes or genomes in general? The vast majority of the variance in human genomes is in non-coding sequence. As to genomes in general, they vary in pretty much every imaginable way.

2. I think those files are quality filtered Illumina reads. SRA = Sequence Read Achieve. SRR = SRA RUN accession. ERA = EMBL SRA. ERR = ERA RUN accession.

3. You should look into transcriptomics data. Predicting such stuff in silico is currently pretty much undoable.