# How much memory would be required to store human DNA?

I'm looking for amount of memory in bytes (MB, GB, TB, whatever) required to store a single human DNA. I read a few articles on Wikipedia about DNA, Chromosomes, Base pairs, Genes, and have some rough guess, but before disclosing anything I'd like to see how others would approach this issue.

Alternative question would be how many atoms are there in human DNA, but that would be off topic for this site.

I understand that this will be an approximation, so I'm looking for minimal value that would be able to store DNA of any human.

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As for the number of atoms, this depends on the composition. A and T are smaller molecules than G and C. The structure of the molecule is the beef, though, not its atomic composition, so this isn't really a very useful calculation. (For what it's worth, e.g. the A molecule aka deoxyadenosine is C10H13N5O3 so 31 atoms.) – tripleee Aug 30 at 9:28

If you trust such things, here is what Wikipedia claims (from http://en.wikipedia.org/wiki/Human_genome#Information_content):

The 2.9 billion base pairs of the haploid human genome correspond to a maximum of about 725 megabytes of data, since every base pair can be coded by 2 bits. Since individual genomes vary by less than 1% from each other, they can be losslessly compressed to roughly 4 megabytes.

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Just to add some biological commentary, "haploid" here means only one copy of each chromosome. The human reference assembly is haploid (and a mosaic of multiple people). An actual individual genome will be diploid (2 copies of each chromosome, except X and Y) but again only variant between the two copies at a small subset of sites. – Alex Stoddard Jan 23 '12 at 19:58
I wonder if it can be compressed... – Costa May 21 at 18:35
Thought about it for a day, and realized this: If you stored some base case human DNA, any subsequent human's DNA would only need to be stored as the diff between it and the base case. For same sex examples DNA is 99.9% the same. And across sexes it's like 98.5%. – Costa May 22 at 15:14

You do not store the whole dna in one stream ... most the time it is store by chromosome

A large chromosome take about 300 MB a small one about 50 MB

Edit:

I think the first reason why it is not saved in 2 bit per base pair is that it would cause an hurdle to work with the data. Most of the people would not know how to convert it. And even when a program for conversion would be given, a lot of people in large companies or research institutes are not allowed to/need to ask or do not know how to install programs ...

1GB Storage costs nothing .. even the download of 3 GB takes only 4 minutes with 100 MBit and most of the companies have a faster connection.

Another point is that the data isn't that simple as you always get told.

e.g. The method for sequencing invented by Craig_Venter was a great break through but also has its down sites. It could not separate long chains of the same base pair so it is not always 100% clear if there are 8 A's or 9 A's. Things you had to take care of later on ..

Another example is the DNA methylation. Such Information you can't store in a 2-bit representation.

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thx for the down vote... instead of the wikipedia/google knowledge of the other guys I have worked with the data .... – rauschen Jan 22 '12 at 5:48
+1 from me. However, I have no clue what does "large" or "small" chromosome mean? – Milan Babuškov Jan 23 '12 at 9:54
These numbers don't tally with what Wikipedia says (see the table at en.wikipedia.org/wiki/Human_genome#Information_content); I'm not saying you're wrong, but can you explain the discrepancy? – Oliver Charlesworth Jan 23 '12 at 11:25
It looks like he is quoting Mbp (million of base-pairs, each base-pair being a single position in the genome) rather than MB which can assume a 2-bit encoding of each position – Alex Stoddard Jan 23 '12 at 20:02

Basically, each base pair takes 2 bits (you can use 00, 01, 10, 11 for T, G, C, and A). Since there are about 2.9 billion base pairs in the human genome, (2 * 2.9 billion) bits ~= 691 megabytes.

I'm no expert, however, the Human Genome page on Wikipedia states the following:

Raw MB:

• Male (XY): 770MB
• Female (XX): 756MB

I'm not sure where their variance comes from, but I'm sure you can figure it out.

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Realistically, more than 2 bits are required, as there are other bases stored in sequence information (`N`, for example, where data is not mappable and therefore unknown). The IUPAC nucleotide codes include more than the standard four, and this can increase storage overhead. ebi.ac.uk/2can/tutorials/aa.html – Alex Reynolds Jan 30 '12 at 8:37
@AlexReynolds broken link :/ – o0'. May 1 at 13:13

The human genome contains 2.9 billion base pairs. So if you represented each base pair as a byte then it would take 2.9 billion bytes or 2.9 GB. You could probably come up with a more creative way of storing base pairs as each base pair only requires 2 bits. So you could probably store 4 base pairs per byte bringing down the total of less than a GB.

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bits ~= bytes. 2.9 billion bits is around 350 MB – SDGuero Apr 22 '14 at 23:01
@SDGuero, base-pairs are base 4 not base 2, so you need at least 2 bits to represent a base pair. – slayton Apr 24 '14 at 13:41

Yes, the minimum RAM needed for whole human DNA is about 770 MB. However, the 2-bit representation is in-practical. It is hard to search through or do some computations on it. Therefore some mathematicians designed more effective way to store those sequencies of bases ... and use them in searching and comparation algorithms such as for example GARLI (www.bio.utexas.edu/faculty/antisense/garli/garli.html ). This application runs on my PC right now, so I can say to You... that it practically has the DNA stored in about: 1 563 MB.

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There are 4 nucleotide bases that make up our DNA these are A,C,G,T therefore for each base in the DNA takes up 2bits. There are around 2.9billion bases so thats around 700 megabytes. The weird thing is that would fill a normal data cd! coincidence?!?

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just did it too. the raw sequence is ~700 MB. if one uses a fixed storage sequence or a fixed sequence storage algoritm - and the fact that the changes are 1% i calcuated ~120 MB with a perchromosome-sequenceoffset-statedelta storage. that's it for the storage.

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