The Human Plasma Proteome
We have merged four different views of the human plasma proteome, based on different methodologies, into a single nonredundant list of 1175 distinct gene products. The methodologies used were 1) literature search for proteins reported to occur in plasma or serum; 2) multidimensional chromatography o...
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| Veröffentlicht in: | Molecular & cellular proteomics 2004-04, Vol.3 (4), p.311-326 |
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| creator | Anderson, N. Leigh Polanski, Malu Pieper, Rembert Gatlin, Tina Tirumalai, Radhakrishna S. Conrads, Thomas P. Veenstra, Timothy D. Adkins, Joshua N. Pounds, Joel G. Fagan, Richard Lobley, Anna |
| description | We have merged four different views of the human plasma proteome, based on different methodologies, into a single nonredundant
list of 1175 distinct gene products. The methodologies used were 1) literature search for proteins reported to occur in plasma
or serum; 2) multidimensional chromatography of proteins followed by two-dimensional electrophoresis and mass spectroscopy
(MS) identification of resolved proteins; 3) tryptic digestion and multidimensional chromatography of peptides followed by
MS identification; and 4) tryptic digestion and multidimensional chromatography of peptides from low-molecular-mass plasma
components followed by MS identification. Of 1,175 nonredundant gene products, 195 were included in more than one of the four
input datasets. Only 46 appeared in all four. Predictions of signal sequence and transmembrane domain occurrence, as well
as Genome Ontology annotation assignments, allowed characterization of the nonredundant list and comparison of the data sources.
The ânonproteomicâ literature (468 input proteins) is strongly biased toward signal sequence-containing extracellular proteins,
while the three proteomics methods showed a much higher representation of cellular proteins, including nuclear, cytoplasmic,
and kinesin complex proteins. Cytokines and protein hormones were almost completely absent from the proteomics data (presumably
due to low abundance), while categories like DNA-binding proteins were almost entirely absent from the literature data (perhaps
unexpected and therefore not sought). Most major categories of proteins in the human proteome are represented in plasma, with
the distribution at successively deeper layers shifting from mostly extracellular to a distribution more like the whole (primarily
cellular) proteome. The resulting nonredundant list confirms the presence of a number of interesting candidate marker proteins
in plasma and serum. |
| doi_str_mv | 10.1074/mcp.M300127-MCP200 |
| format | Article |
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list of 1175 distinct gene products. The methodologies used were 1) literature search for proteins reported to occur in plasma
or serum; 2) multidimensional chromatography of proteins followed by two-dimensional electrophoresis and mass spectroscopy
(MS) identification of resolved proteins; 3) tryptic digestion and multidimensional chromatography of peptides followed by
MS identification; and 4) tryptic digestion and multidimensional chromatography of peptides from low-molecular-mass plasma
components followed by MS identification. Of 1,175 nonredundant gene products, 195 were included in more than one of the four
input datasets. Only 46 appeared in all four. Predictions of signal sequence and transmembrane domain occurrence, as well
as Genome Ontology annotation assignments, allowed characterization of the nonredundant list and comparison of the data sources.
The ânonproteomicâ literature (468 input proteins) is strongly biased toward signal sequence-containing extracellular proteins,
while the three proteomics methods showed a much higher representation of cellular proteins, including nuclear, cytoplasmic,
and kinesin complex proteins. Cytokines and protein hormones were almost completely absent from the proteomics data (presumably
due to low abundance), while categories like DNA-binding proteins were almost entirely absent from the literature data (perhaps
unexpected and therefore not sought). Most major categories of proteins in the human proteome are represented in plasma, with
the distribution at successively deeper layers shifting from mostly extracellular to a distribution more like the whole (primarily
cellular) proteome. The resulting nonredundant list confirms the presence of a number of interesting candidate marker proteins
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list of 1175 distinct gene products. The methodologies used were 1) literature search for proteins reported to occur in plasma
or serum; 2) multidimensional chromatography of proteins followed by two-dimensional electrophoresis and mass spectroscopy
(MS) identification of resolved proteins; 3) tryptic digestion and multidimensional chromatography of peptides followed by
MS identification; and 4) tryptic digestion and multidimensional chromatography of peptides from low-molecular-mass plasma
components followed by MS identification. Of 1,175 nonredundant gene products, 195 were included in more than one of the four
input datasets. Only 46 appeared in all four. Predictions of signal sequence and transmembrane domain occurrence, as well
as Genome Ontology annotation assignments, allowed characterization of the nonredundant list and comparison of the data sources.
The ânonproteomicâ literature (468 input proteins) is strongly biased toward signal sequence-containing extracellular proteins,
while the three proteomics methods showed a much higher representation of cellular proteins, including nuclear, cytoplasmic,
and kinesin complex proteins. Cytokines and protein hormones were almost completely absent from the proteomics data (presumably
due to low abundance), while categories like DNA-binding proteins were almost entirely absent from the literature data (perhaps
unexpected and therefore not sought). Most major categories of proteins in the human proteome are represented in plasma, with
the distribution at successively deeper layers shifting from mostly extracellular to a distribution more like the whole (primarily
cellular) proteome. The resulting nonredundant list confirms the presence of a number of interesting candidate marker proteins
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list of 1175 distinct gene products. The methodologies used were 1) literature search for proteins reported to occur in plasma
or serum; 2) multidimensional chromatography of proteins followed by two-dimensional electrophoresis and mass spectroscopy
(MS) identification of resolved proteins; 3) tryptic digestion and multidimensional chromatography of peptides followed by
MS identification; and 4) tryptic digestion and multidimensional chromatography of peptides from low-molecular-mass plasma
components followed by MS identification. Of 1,175 nonredundant gene products, 195 were included in more than one of the four
input datasets. Only 46 appeared in all four. Predictions of signal sequence and transmembrane domain occurrence, as well
as Genome Ontology annotation assignments, allowed characterization of the nonredundant list and comparison of the data sources.
The ânonproteomicâ literature (468 input proteins) is strongly biased toward signal sequence-containing extracellular proteins,
while the three proteomics methods showed a much higher representation of cellular proteins, including nuclear, cytoplasmic,
and kinesin complex proteins. Cytokines and protein hormones were almost completely absent from the proteomics data (presumably
due to low abundance), while categories like DNA-binding proteins were almost entirely absent from the literature data (perhaps
unexpected and therefore not sought). Most major categories of proteins in the human proteome are represented in plasma, with
the distribution at successively deeper layers shifting from mostly extracellular to a distribution more like the whole (primarily
cellular) proteome. The resulting nonredundant list confirms the presence of a number of interesting candidate marker proteins
in plasma and serum.</abstract><pub>American Society for Biochemistry and Molecular Biology</pub><pmid>14718574</pmid><doi>10.1074/mcp.M300127-MCP200</doi><tpages>16</tpages><oa>free_for_read</oa></addata></record> |
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| title | The Human Plasma Proteome |
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