DOI: 10.1073/pnas.83.20.7826. Random-clone strategy for genomic restriction mapping in yeast.

Random-clone strategy for genomic restriction mapping in yeast.

10.1073/pnas.83.20.7826

Crossref journal-article

Proceedings of the National Academy of Sciences

Proceedings of the National Academy of Sciences (341)

Abstract

An approach to global restriction mapping is described that is applicable to any complex source DNA. By analyzing a single restriction digest for each member of a redundant set of lambda clones, a data base is constructed that contains fragment-size lists for all the clones. The clones are then grouped into subsets, each member of which is related to at least one other member by a significant overlap. Finally, a tree-searching algorithm seeks restriction maps that are consistent with the fragment-size lists for all the clones in each subset. The feasibility of the approach has been demonstrated by collecting data on 5000 lambda clones containing random 15-kilobase inserts of yeast DNA. It is shown that these data can be analyzed to produce regional maps of the yeast genome, extending in some cases for over 100 kilobases. In combination with hybridization probes to previously cloned genes, these local maps are already useful for defining the physical arrangement of closely linked genes. They may in the future serve as building blocks for the construction of a continuous global map.

Bibliography

Olson, M. V., Dutchik, J. E., Graham, M. Y., Brodeur, G. M., Helms, C., Frank, M., MacCollin, M., Scheinman, R., & Frank, T. (1986). Random-clone strategy for genomic restriction mapping in yeast. Proceedings of the National Academy of Sciences, 83(20), 7826â7830.

Authors 9

M V Olson (first)
J E Dutchik (additional)
M Y Graham (additional)
G M Brodeur (additional)
C Helms (additional)
M Frank (additional)
M MacCollin (additional)
R Scheinman (additional)
T Frank (additional)

References 0 Referenced 245

None

Dates

Type	When
Created	19 years, 3 months ago (May 31, 2006, 6:09 a.m.)
Deposited	3 years, 4 months ago (April 13, 2022, 12:26 p.m.)
Indexed	5 days, 19 hours ago (Aug. 27, 2025, 11:58 a.m.)
Issued	38 years, 11 months ago (Oct. 1, 1986)
Published	38 years, 11 months ago (Oct. 1, 1986)
Published Online	38 years, 11 months ago (Oct. 1, 1986)
Published Print	38 years, 11 months ago (Oct. 1, 1986)

Funders 0

None

BibTeX

@article{Olson_1986, title={Random-clone strategy for genomic restriction mapping in yeast.}, volume={83}, ISSN={1091-6490}, url={http://dx.doi.org/10.1073/pnas.83.20.7826}, DOI={10.1073/pnas.83.20.7826}, number={20}, journal={Proceedings of the National Academy of Sciences}, publisher={Proceedings of the National Academy of Sciences}, author={Olson, M V and Dutchik, J E and Graham, M Y and Brodeur, G M and Helms, C and Frank, M and MacCollin, M and Scheinman, R and Frank, T}, year={1986}, month=oct, pages={7826–7830} }

JSON

{
  "indexed": {
    "date-parts": [
      [
        2025,
        8,
        27
      ]
    ],
    "date-time": "2025-08-27T15:58:53Z",
    "timestamp": 1756310333071
  },
  "reference-count": 0,
  "publisher": "Proceedings of the National Academy of Sciences",
  "issue": "20",
  "content-domain": {
    "domain": [
      "www.pnas.org"
    ],
    "crossmark-restriction": true
  },
  "published-print": {
    "date-parts": [
      [
        1986,
        10
      ]
    ]
  },
  "abstract": "<jats:p>An approach to global restriction mapping is described that is applicable to any complex source DNA. By analyzing a single restriction digest for each member of a redundant set of lambda clones, a data base is constructed that contains fragment-size lists for all the clones. The clones are then grouped into subsets, each member of which is related to at least one other member by a significant overlap. Finally, a tree-searching algorithm seeks restriction maps that are consistent with the fragment-size lists for all the clones in each subset. The feasibility of the approach has been demonstrated by collecting data on 5000 lambda clones containing random 15-kilobase inserts of yeast DNA. It is shown that these data can be analyzed to produce regional maps of the yeast genome, extending in some cases for over 100 kilobases. In combination with hybridization probes to previously cloned genes, these local maps are already useful for defining the physical arrangement of closely linked genes. They may in the future serve as building blocks for the construction of a continuous global map.</jats:p>",
  "DOI": "10.1073/pnas.83.20.7826",
  "type": "journal-article",
  "created": {
    "date-parts": [
      [
        2006,
        5,
        31
      ]
    ],
    "date-time": "2006-05-31T10:09:14Z",
    "timestamp": 1149070154000
  },
  "page": "7826-7830",
  "update-policy": "http://dx.doi.org/10.1073/pnas.cm10313",
  "source": "Crossref",
  "is-referenced-by-count": 245,
  "title": "Random-clone strategy for genomic restriction mapping in yeast.",
  "prefix": "10.1073",
  "volume": "83",
  "author": [
    {
      "given": "M V",
      "family": "Olson",
      "sequence": "first",
      "affiliation": []
    },
    {
      "given": "J E",
      "family": "Dutchik",
      "sequence": "additional",
      "affiliation": []
    },
    {
      "given": "M Y",
      "family": "Graham",
      "sequence": "additional",
      "affiliation": []
    },
    {
      "given": "G M",
      "family": "Brodeur",
      "sequence": "additional",
      "affiliation": []
    },
    {
      "given": "C",
      "family": "Helms",
      "sequence": "additional",
      "affiliation": []
    },
    {
      "given": "M",
      "family": "Frank",
      "sequence": "additional",
      "affiliation": []
    },
    {
      "given": "M",
      "family": "MacCollin",
      "sequence": "additional",
      "affiliation": []
    },
    {
      "given": "R",
      "family": "Scheinman",
      "sequence": "additional",
      "affiliation": []
    },
    {
      "given": "T",
      "family": "Frank",
      "sequence": "additional",
      "affiliation": []
    }
  ],
  "member": "341",
  "published-online": {
    "date-parts": [
      [
        1986,
        10
      ]
    ]
  },
  "container-title": "Proceedings of the National Academy of Sciences",
  "original-title": [],
  "language": "en",
  "link": [
    {
      "URL": "https://pnas.org/doi/pdf/10.1073/pnas.83.20.7826",
      "content-type": "unspecified",
      "content-version": "vor",
      "intended-application": "similarity-checking"
    }
  ],
  "deposited": {
    "date-parts": [
      [
        2022,
        4,
        13
      ]
    ],
    "date-time": "2022-04-13T16:26:57Z",
    "timestamp": 1649867217000
  },
  "score": 1,
  "resource": {
    "primary": {
      "URL": "https://pnas.org/doi/full/10.1073/pnas.83.20.7826"
    }
  },
  "subtitle": [],
  "short-title": [],
  "issued": {
    "date-parts": [
      [
        1986,
        10
      ]
    ]
  },
  "references-count": 0,
  "journal-issue": {
    "issue": "20",
    "published-print": {
      "date-parts": [
        [
          1986,
          10
        ]
      ]
    }
  },
  "alternative-id": [
    "10.1073/pnas.83.20.7826"
  ],
  "URL": "http://dx.doi.org/10.1073/pnas.83.20.7826",
  "relation": {},
  "ISSN": [
    "0027-8424",
    "1091-6490"
  ],
  "subject": [],
  "container-title-short": "Proc. Natl. Acad. Sci. U.S.A.",
  "published": {
    "date-parts": [
      [
        1986,
        10
      ]
    ]
  },
  "assertion": [
    {
      "value": "1986-10-01",
      "order": 2,
      "name": "published",
      "label": "Published",
      "group": {
        "name": "publication_history",
        "label": "Publication History"
      }
    }
  ]
}