We describe the construction and characterization of a human X-chromosome-specific yeast artificial chromosome (YAC) library. Starting with 60 micrograms of hybrid cell line genomic DNA, we generated over 150,000 recombinants, over 90% of which range from 150 to 500 kb. From these recombinants, 3300 human-positive YACs (representing coverage of 4.5 X chromosomes) were identified by genomic human DNA hybridization. Mapping of random clones revealed that they are derived from the X chromosome in a regionally unbiased fashion, and screening with single-copy X-chromosome probes has repeatedly produced YACs from the library. By determining the frequency of YAC clones containing both hamster and human repetitive sequences, we estimated that approximately 11% of clones contain discontiguous sequences. Taken together, the low cocloning rate, the unbiased coverage, and a consistent recovery of YACs using specific X-chromosome markers indicate that YAC technology can be used for extensive cloning and mapping purposes. Because a certain amount of genomic rearrangement is present in YAC libraries, chromosome walking must be undertaken with a degree of caution.
Construction and characterization of a yeast artificial chromosome library for Xpter-Xq27.3: a systematic determination of cocloning rate and X-chromosome representation.
MURGIA, ALESSANDRA;
1992
Abstract
We describe the construction and characterization of a human X-chromosome-specific yeast artificial chromosome (YAC) library. Starting with 60 micrograms of hybrid cell line genomic DNA, we generated over 150,000 recombinants, over 90% of which range from 150 to 500 kb. From these recombinants, 3300 human-positive YACs (representing coverage of 4.5 X chromosomes) were identified by genomic human DNA hybridization. Mapping of random clones revealed that they are derived from the X chromosome in a regionally unbiased fashion, and screening with single-copy X-chromosome probes has repeatedly produced YACs from the library. By determining the frequency of YAC clones containing both hamster and human repetitive sequences, we estimated that approximately 11% of clones contain discontiguous sequences. Taken together, the low cocloning rate, the unbiased coverage, and a consistent recovery of YACs using specific X-chromosome markers indicate that YAC technology can be used for extensive cloning and mapping purposes. Because a certain amount of genomic rearrangement is present in YAC libraries, chromosome walking must be undertaken with a degree of caution.Pubblicazioni consigliate
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