MouseMine: Keyword Search

Protein Domain

Type:

Family

Description:

This entry represents the epsilon subunit of the coatomer complex, which is involved in the regulation of intracellular protein trafficking between the endoplasmic reticulum and the Golgi complex [].Proteins synthesised on the ribosome and processed in the endoplasmic reticulum are transported from the Golgi apparatus to the trans-Golgi network (TGN), and from there via small carrier vesicles to their final destination compartment. This traffic is bidirectional, to ensure that proteins required to form vesicles are recycled. Vesicles have specific coat proteins (such as clathrin or coatomer) that are important for cargo selection and direction of transfer []. While clathrin mediates endocytic protein transport, and transport from ER to Golgi, coatomers primarily mediate intra-Golgi transport, as well as the reverse Golgi to ER transport of dilysine-tagged proteins []. For example, the coatomer COP1 (coat protein complex 1) is responsible for reverse transport of recycled proteins from Golgi and pre-Golgi compartments back to the ER, while COPII buds vesicles from the ER to the Golgi []. Coatomers reversibly associate with Golgi (non-clathrin-coated) vesicles to mediate protein transport and for budding from Golgi membranes []. Activated small guanine triphosphatases (GTPases) attract coat proteins to specific membrane export sites, thereby linking coatomers to export cargos. As coat proteins polymerise, vesicles are formed and budded from membrane-bound organelles. Coatomer complexes also influence Golgi structural integrity, as well as the processing, activity, and endocytic recycling of LDL receptors. In mammals, coatomer complexes can only be recruited by membranes associated to ADP-ribosylation factors (ARFs), which are small GTP-binding proteins. Coatomer complexes are hetero-oligomers composed of at least an alpha, beta, beta', gamma, delta, epsilon and zeta subunits.

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Protein Domain

IPR010714 | Coatomer_asu_C

Type:

Domain

Description:

Proteins synthesised on the ribosome and processed in the endoplasmic reticulum are transported from the Golgi apparatus to the trans-Golgi network (TGN), and from there via small carrier vesicles to their final destination compartment. This traffic is bidirectional, to ensure that proteins required to form vesicles are recycled. Vesicles have specific coat proteins (such as clathrin or coatomer) that are important for cargo selection and direction of transfer []. While clathrin mediates endocytic protein transport, and transport from ER to Golgi, coatomers primarily mediate intra-Golgi transport, as well as the reverse Golgi to ER transport of dilysine-tagged proteins []. For example, the coatomer COP1 (coat protein complex 1) is responsible for reverse transport of recycled proteins from Golgi and pre-Golgi compartments back to the ER, while COPII buds vesicles from the ER to the Golgi []. Coatomers reversibly associate with Golgi (non-clathrin-coated) vesicles to mediate protein transport and for budding from Golgi membranes []. Activated small guanine triphosphatases (GTPases) attract coat proteins to specific membrane export sites, thereby linking coatomers to export cargos. As coat proteins polymerise, vesicles are formed and budded from membrane-bound organelles. Coatomer complexes also influence Golgi structural integrity, as well as the processing, activity, and endocytic recycling of LDL receptors. In mammals, coatomer complexes can only be recruited by membranes associated to ADP-ribosylation factors (ARFs), which are small GTP-binding proteins. Coatomer complexes are hetero-oligomers composed of at least an alpha, beta, beta', gamma, delta, epsilon and zeta subunits. This entry represents the C terminus (approximately 500 residues) of the eukaryotic coatomer alpha subunit [, ]. This domain is found along with the domain.

•

Protein Domain

IPR029446 | COPB1_appendage_platform_dom

Type:

Domain

Description:

This entry represents a domain found in the C-terminal of the coatamer beta subunit proteins (Beta-coat proteins). It is a platform domain on the appendage that carries a highly conserved tryptophan [, ].Proteins synthesised on the ribosome and processed in the endoplasmic reticulum are transported from the Golgi apparatus to the trans-Golgi network (TGN), and from there via small carrier vesicles to their final destination compartment. This traffic is bidirectional, to ensure that proteins required to form vesicles are recycled. Vesicles have specific coat proteins (such as clathrin or coatomer) that are important for cargo selection and direction of transfer []. While clathrin mediates endocytic protein transport, and transport from ER to Golgi, coatomers primarily mediate intra-Golgi transport, as well as the reverse Golgi to ER transport of dilysine-tagged proteins []. For example, the coatomer COP1 (coat protein complex 1) is responsible for reverse transport of recycled proteins from Golgi and pre-Golgi compartments back to the ER, while COPII buds vesicles from the ER to the Golgi []. Coatomers reversibly associate with Golgi (non-clathrin-coated) vesicles to mediate protein transport and for budding from Golgi membranes []. Activated small guanine triphosphatases (GTPases) attract coat proteins to specific membrane export sites, thereby linking coatomers to export cargos. As coat proteins polymerise, vesicles are formed and budded from membrane-bound organelles. Coatomer complexes also influence Golgi structural integrity, as well as the processing, activity, and endocytic recycling of LDL receptors. In mammals, coatomer complexes can only be recruited by membranes associated to ADP-ribosylation factors (ARFs), which are small GTP-binding proteins. Coatomer complexes are hetero-oligomers composed of at least an alpha, beta, beta', gamma, delta, epsilon and zeta subunits.

•

Protein Domain

IPR027059 | Coatomer_dsu

Type:

Family

Description:

This entry represents the delta subunit of the coatomer complex, which is involved in the regulation of intracellular protein trafficking between the endoplasmic reticulum and the Golgi complex [].Proteins synthesised on the ribosome and processed in the endoplasmic reticulum are transported from the Golgi apparatus to the trans-Golgi network (TGN), and from there via small carrier vesicles to their final destination compartment. This traffic is bidirectional, to ensure that proteins required to form vesicles are recycled. Vesicles have specific coat proteins (such as clathrin or coatomer) that are important for cargo selection and direction of transfer []. While clathrin mediates endocytic protein transport, and transport from ER to Golgi, coatomers primarily mediate intra-Golgi transport, as well as the reverse Golgi to ER transport of dilysine-tagged proteins []. For example, the coatomer COP1 (coat protein complex 1) is responsible for reverse transport of recycled proteins from Golgi and pre-Golgi compartments back to the ER, while COPII buds vesicles from the ER to the Golgi []. Coatomers reversibly associate with Golgi (non-clathrin-coated) vesicles to mediate protein transport and for budding from Golgi membranes []. Activated small guanine triphosphatases (GTPases) attract coat proteins to specific membrane export sites, thereby linking coatomers to export cargos. As coat proteins polymerise, vesicles are formed and budded from membrane-bound organelles. Coatomer complexes also influence Golgi structural integrity, as well as the processing, activity, and endocytic recycling of LDL receptors. In mammals, coatomer complexes can only be recruited by membranes associated to ADP-ribosylation factors (ARFs), which are small GTP-binding proteins. Coatomer complexes are hetero-oligomers composed of at least an alpha, beta, beta', gamma, delta, epsilon and zeta subunits.

•

Protein Domain

IPR013040 | Coatomer_gsu_app_Ig-like_dom

Type:

Domain

Description:

Proteins synthesised on the ribosome and processed in the endoplasmic reticulum are transported from the Golgi apparatus to the trans-Golgi network (TGN), and from there via small carrier vesicles to their final destination compartment. This traffic is bidirectional, to ensure that proteins required to form vesicles are recycled. Vesicles have specific coat proteins (such as clathrin or coatomer) that are important for cargo selection and direction of transfer []. While clathrin mediates endocytic protein transport, and transport from ER to Golgi, coatomers primarily mediate intra-Golgi transport, as well as the reverse Golgi to ER transport of dilysine-tagged proteins []. For example, the coatomer COP1 (coat protein complex 1) is responsible for reverse transport of recycled proteins from Golgi and pre-Golgi compartments back to the ER, while COPII buds vesicles from the ER to the Golgi []. Coatomers reversibly associate with Golgi (non-clathrin-coated) vesicles to mediate protein transport and for budding from Golgi membranes []. Activated small guanine triphosphatases (GTPases) attract coat proteins to specific membrane export sites, thereby linking coatomers to export cargos. As coat proteins polymerise, vesicles are formed and budded from membrane-bound organelles. Coatomer complexes also influence Golgi structural integrity, as well as the processing, activity, and endocytic recycling of LDL receptors. In mammals, coatomer complexes can only be recruited by membranes associated to ADP-ribosylation factors (ARFs), which are small GTP-binding proteins. Coatomer complexes are hetero-oligomers composed of at least an alpha, beta, beta', gamma, delta, epsilon and zeta subunits. This entry represents a β-sandwich structural motif found in the appendage domain of the gamma subunit of coatomer complexes. This subdomain has an immunoglobulin-like β-sandwich fold containing 7 strands in 2 β-sheets in a Greek key topology []. The appendage domain of the gamma coatomer subunit has a similar overall fold to the appendage domain of clathrin adaptors, and can also share the same motif-based cargo recognition and accessory factor recruitment mechanisms.

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Protein Domain

IPR037067 | Coatomer_gsu_app_sf

Type:

Homologous_superfamily

Description:

Proteins synthesised on the ribosome and processed in the endoplasmic reticulum are transported from the Golgi apparatus to the trans-Golgi network (TGN), and from there via small carrier vesicles to their final destination compartment. This traffic is bidirectional, to ensure that proteins required to form vesicles are recycled. Vesicles have specific coat proteins (such as clathrin or coatomer) that are important for cargo selection and direction of transfer []. While clathrin mediates endocytic protein transport, and transport from ER to Golgi, coatomers primarily mediate intra-Golgi transport, as well as the reverse Golgi to ER transport of dilysine-tagged proteins []. For example, the coatomer COP1 (coat protein complex 1) is responsible for reverse transport of recycled proteins from Golgi and pre-Golgi compartments back to the ER, while COPII buds vesicles from the ER to the Golgi []. Coatomers reversibly associate with Golgi (non-clathrin-coated) vesicles to mediate protein transport and for budding from Golgi membranes []. Activated small guanine triphosphatases (GTPases) attract coat proteins to specific membrane export sites, thereby linking coatomers to export cargos. As coat proteins polymerise, vesicles are formed and budded from membrane-bound organelles. Coatomer complexes also influence Golgi structural integrity, as well as the processing, activity, and endocytic recycling of LDL receptors. In mammals, coatomer complexes can only be recruited by membranes associated to ADP-ribosylation factors (ARFs), which are small GTP-binding proteins. Coatomer complexes are hetero-oligomers composed of at least an alpha, beta, beta', gamma, delta, epsilon and zeta subunits. This entry represents a β-sandwich structural motif found in the appendage domain superfamily of the gamma subunit of coatomer complexes. This subdomain has an immunoglobulin-like β-sandwich fold containing 7 strands in 2 β-sheets in a Greek key topology []. The appendage domain of the gamma coatomer subunit has a similar overall fold to the appendage domain of clathrin adaptors, and can also share the same motif-based cargo recognition and accessory factor recruitment mechanisms.

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Protein Domain

IPR011710 | Coatomer_bsu_C

Type:

Domain

Description:

Proteins synthesised on the ribosome and processed in the endoplasmic reticulum are transported from the Golgi apparatus to the trans-Golgi network (TGN), and from there via small carrier vesicles to their final destination compartment. This traffic is bidirectional, to ensure that proteins required to form vesicles are recycled. Vesicles have specific coat proteins (such as clathrin or coatomer) that are important for cargo selection and direction of transfer []. While clathrin mediates endocytic protein transport, and transport from ER to Golgi, coatomers primarily mediate intra-Golgi transport, as well as the reverse Golgi to ER transport of dilysine-tagged proteins []. For example, the coatomer COP1 (coat protein complex 1) is responsible for reverse transport of recycled proteins from Golgi and pre-Golgi compartments back to the ER, while COPII buds vesicles from the ER to the Golgi []. Coatomers reversibly associate with Golgi (non-clathrin-coated) vesicles to mediate protein transport and for budding from Golgi membranes []. Activated small guanine triphosphatases (GTPases) attract coat proteins to specific membrane export sites, thereby linking coatomers to export cargos. As coat proteins polymerise, vesicles are formed and budded from membrane-bound organelles. Coatomer complexes also influence Golgi structural integrity, as well as the processing, activity, and endocytic recycling of LDL receptors. In mammals, coatomer complexes can only be recruited by membranes associated to ADP-ribosylation factors (ARFs), which are small GTP-binding proteins. Coatomer complexes are hetero-oligomers composed of at least an alpha, beta, beta', gamma, delta, epsilon and zeta subunits. This entry represents the C-terminal domain of the beta subunit from coatomer proteins (Beta-coat proteins). The C-terminal domain probably adapts the function of the N-terminal domain. Coatomer protein complex I (COPI)-coated vesicles are involved in transport between the endoplasmic reticulum and the Golgi but also participate in transport from early to late endosomes within the endocytic pathway [].

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Publication

11208122 | -

First Author:	Barlowe C
Year:	2000
Journal:	Traffic
Title:	Traffic COPs of the early secretory pathway.
Volume:	1
Issue:	5
Pages:	371-7

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Publication

11409905 | -

First Author:	Takatsu H
Year:	2001
Journal:	Biochem Biophys Res Commun
Title:	Similar subunit interactions contribute to assembly of clathrin adaptor complexes and COPI complex: analysis using yeast three-hybrid system.
Volume:	284
Issue:	4
Pages:	1083-9

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Protein

Q9Z1Z0

Organism:	Mus musculus/domesticus
Length:	959
Fragment?:	false

•

Protein

Q8CIE6

Organism:	Mus musculus/domesticus
Length:	1224
Fragment?:	false

•

Protein

Q9JIF7

Organism:	Mus musculus/domesticus
Length:	953
Fragment?:	false

•

Protein

Q63ZW9

Organism:	Mus musculus/domesticus
Length:	1131
Fragment?:	true

•

Protein

F8WHL2

Organism:	Mus musculus/domesticus
Length:	1233
Fragment?:	false

•

Protein

Q8BTF0

Organism:	Mus musculus/domesticus
Length:	1224
Fragment?:	false

•

Publication

14690497 | -

First Author:	Watson PJ
Year:	2004
Journal:	Traffic
Title:	Gamma-COP appendage domain - structure and function.
Volume:	5
Issue:	2
Pages:	79-88

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Publication

17041781 | -

First Author:	Béthune J
Year:	2006
Journal:	J Membr Biol
Title:	COPI-mediated transport.
Volume:	211
Issue:	2
Pages:	65-79

•

Protein

O89079

Organism:	Mus musculus/domesticus
Length:	308
Fragment?:	false

•

Protein

F6YFR7

Organism:	Mus musculus/domesticus
Length:	234
Fragment?:	true

•

Protein

Q3TDU1

Organism:	Mus musculus/domesticus
Length:	284
Fragment?:	true

•

Protein

Q9D1J2

Organism:	Mus musculus/domesticus
Length:	308
Fragment?:	false

•

Protein

D3Z315

Organism:	Mus musculus/domesticus
Length:	227
Fragment?:	true

•

Protein

F6XIG5

Organism:	Mus musculus/domesticus
Length:	116
Fragment?:	true

•

Protein

E9Q6I5

Organism:	Mus musculus/domesticus
Length:	112
Fragment?:	false

•

Protein

O55029

Organism:	Mus musculus/domesticus
Length:	905
Fragment?:	false

•

Publication

14527408 | -

First Author:	Hoffman GR
Year:	2003
Journal:	Mol Cell
Title:	Conserved structural motifs in intracellular trafficking pathways: structure of the gammaCOP appendage domain.
Volume:	12
Issue:	3
Pages:	615-25

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Protein Coding Gene

MGI:1917497 | Psmd1

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:2143994 | Psme4

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:104880 | Psmb6

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1916327 | Psmd11

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1347014 | Psmb3

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:98858 | Psmd3

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1096366 | Psme3

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:105047 | Psmc5

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1914247 | Psmd12

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1347006 | Psma6

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:104883 | Psma3

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:106054 | Psmc1

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:104885 | Psma2

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1913663 | Psmd6

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1914339 | Psmc6

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1194513 | Psmb5

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1921152 | Psmb11

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1096367 | Psme1

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1096365 | Psme2

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1096584 | Psmd2

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:104884 | Psmb1

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1346526 | Psmb9

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1346527 | Psmb8

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1920927 | Psma8

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1914248 | Psmd5

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:107637 | Psmb7

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1913284 | Psmd14

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1098754 | Psmc3

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1346072 | Psmf1

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1347070 | Psma7

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1098257 | Psmb4

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1201670 | Psmd4

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1347009 | Psma5

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1347045 | Psmb2

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:109555 | Psmc2

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1914401 | Psmd9

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1346093 | Psmc4

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1888669 | Psmd8

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1347005 | Psma1

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1345192 | Psmd13

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1096380 | Psmb10

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1351511 | Psmd7

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1347060 | Psma4

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein Coding Gene

MGI:1858898 | Psmd10

Type:	protein_coding_gene
Organism:	mouse, laboratory

•

Protein

Q9R1P1

Organism:	Mus musculus/domesticus
Length:	205
Fragment?:	false

•

Protein

P99026

Organism:	Mus musculus/domesticus
Length:	264
Fragment?:	false

•

Protein

Q60692

Organism:	Mus musculus/domesticus
Length:	238
Fragment?:	false

•

Protein

P70195

Organism:	Mus musculus/domesticus
Length:	277
Fragment?:	false

•

Protein

P28063

Organism:	Mus musculus/domesticus
Length:	276
Fragment?:	false

•

Protein

P46471

Organism:	Mus musculus/domesticus
Length:	433
Fragment?:	false

•

Protein

O35955

Organism:	Mus musculus/domesticus
Length:	273
Fragment?:	false

•

Protein

Q8BG41

Organism:	Mus musculus/domesticus
Length:	302
Fragment?:	false

•

Protein

Q9CR00

Organism:	Mus musculus/domesticus
Length:	222
Fragment?:	false

•

Protein

P28076

Organism:	Mus musculus/domesticus
Length:	219
Fragment?:	false

•

Protein

Q9R1P0

Organism:	Mus musculus/domesticus
Length:	261
Fragment?:	false

•

Protein

Q9WVJ2

Organism:	Mus musculus/domesticus
Length:	376
Fragment?:	false

•

Protein

Q8BG32

Organism:	Mus musculus/domesticus
Length:	422
Fragment?:	false

•

Protein

Q9Z2U0

Organism:	Mus musculus/domesticus
Length:	248
Fragment?:	false

•

Protein

P97372

Organism:	Mus musculus/domesticus
Length:	239
Fragment?:	false

•

Protein

P54775

Organism:	Mus musculus/domesticus
Length:	418
Fragment?:	false

•

Protein

P14685

Organism:	Mus musculus/domesticus
Length:	530
Fragment?:	false

•

Protein

Q9Z2U1

Organism:	Mus musculus/domesticus
Length:	241
Fragment?:	false

•

Protein

Q9R1P3

Organism:	Mus musculus/domesticus
Length:	201
Fragment?:	false

•

Protein

Q9CWH6

Organism:	Mus musculus/domesticus
Length:	250
Fragment?:	false

•

Protein

P61290

Organism:	Mus musculus/domesticus
Length:	254
Fragment?:	false

•

Protein

P97371

Organism:	Mus musculus/domesticus
Length:	249
Fragment?:	false

•

Protein

Q99JI4

Organism:	Mus musculus/domesticus
Length:	389
Fragment?:	false

•

Protein

O70435

Organism:	Mus musculus/domesticus
Length:	255
Fragment?:	false

•

Protein

P62334

Organism:	Mus musculus/domesticus
Length:	389
Fragment?:	false

•

Protein

Q9D8W5

Organism:	Mus musculus/domesticus
Length:	456
Fragment?:	false

•

Protein

Q9QUM9

Organism:	Mus musculus/domesticus
Length:	246
Fragment?:	false

•

Protein

O09061

Organism:	Mus musculus/domesticus
Length:	240
Fragment?:	false

•

Protein

O88685

Organism:	Mus musculus/domesticus
Length:	442
Fragment?:	false

•

Protein

Q8BJY1

Organism:	Mus musculus/domesticus
Length:	504
Fragment?:	false

•

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Subject:
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