Bottleneck sequencing

We claim: 1. A method for sequencing DNA, comprising: a) fragmenting a double-stranded DNA population from an initial sample to form a library of double-stranded fragments, wherein said initial sample comprises a plurality of cells such that said library of double-stranded fragments are from a plurality of genomes from different cells; b) ligating adaptors to ends of at least a portion of the double-stranded fragments to form a library of double-stranded adaptor-ligated fragments; c) diluting at least a portion of the library of double-stranded adaptor-ligated fragments to form a diluted sample of double-stranded adaptor-ligated fragments; d) amplifying at least a portion of the double-stranded adaptor-ligated fragments in said diluted sample, to form a plurality of members from each single strand of the two strands of said double-stranded adaptor-ligated fragments that are amplified, such that a plurality of Watson families are formed from amplicons of one strand and a plurality of corresponding Crick families are formed from amplicons from the other strand, wherein the number of double-stranded adaptor-ligated fragments present in said diluted sample is such that, during said amplifying, less than 10 Watson families and corresponding Crick families are formed from said double-stranded adaptor-ligated fragments; e) sequencing at least two family members from one of said Watson families and at least two family members from one of said corresponding Crick families to obtain a nucleotide sequence for the sequenced members of the one Watson family and the one Crick family; f) sequencing at least a portion of said double-stranded adaptor-ligated fragments from b) above, or sequencing at least a portion of said double-stranded fragments from a) above, thereby generating sequencing data comprising sequence information for germline and/or clonal mutations present in said plurality of genomes; and g) performing the following in silico with data analysis software: i) aligning the nucleotide sequence of said at least two members of said one Watson family to a reference sequence; ii) identifying a difference between at least 90% of the at least two members of said one Watson family and the reference sequence, wherein said difference is a single base difference, a two-base difference, a small insertion or deletion of 1 to 6 bases, or a substitution mutation; iii) identifying the difference as a potential rare or potential non-clonal somatic mutation if it is found in at least 90% of said nucleotide sequences of said at least two members of said one corresponding Crick family; and iv) performing either A) or B) below: A) identifying said potential rare or potential non-clonal somatic mutation as a rare or non-clonal somatic mutation when it is not present as a clonal and/or germline mutation in said sequencing data from said plurality of genomes, or B) identifying said potential rare or potential non-clonal somatic mutation as a clonal or germline mutation when it is present as a clonal and/or germline mutation in said sequencing data from said plurality of genomes. 2. The method of claim 1 , wherein the difference is a single base difference. 3. The method of claim 1 , wherein said at least two members of said one Watson family are at least 4 members of said one Watson family, and said at least two members of said one corresponding Crick family are at least 4 members of said one corresponding Crick family. 4. The method of claim 1 , wherein the double-stranded DNA population comprises mitochondrial and/or nuclear DNA. 5. The method of claim 4 , wherein the reference sequence comprises mitochondrial sequences. 6. The method of claim 1 , wherein the adaptors are Y-shaped adaptors, having one end with complementary sequences and one end with non-complementary sequences. 7. The method of claim 1 , wherein the adaptors are U-shaped or hairpin adaptors. 8. The method of claim 1 , wherein the library of double-stranded adaptor-ligated fragments comprises fragments in which 5′ and 3′ ends are ligated to different adaptors. 9. The method of claim 1 , wherein said at least two family members from said one Watson family are at least 10 members from said one Watson family, and said at least two members of said one corresponding Crick family are at least 10 family members from said one corresponding Crick family. 10. The method of claim 1 , wherein the adaptors comprise random barcode sequences, and wherein the barcode sequences indicate a particular fragment among the double stranded adaptor-ligated fragments. 11. The method of claim 1 , wherein said initial sample is from a human and is a sample selected from the group consisting of: plasma, stool, urine, and saliva.