ABCMdb

ABCG5 p.Glu146Gln

Predicted by SNAP2:	A: D (95%), C: D (95%), D: D (95%), F: D (95%), G: D (95%), H: D (95%), I: D (95%), K: D (95%), L: D (95%), M: D (95%), N: D (95%), P: D (95%), Q: D (95%), R: D (95%), S: D (95%), T: D (95%), V: D (95%), W: D (95%), Y: D (95%),
Predicted by PROVEAN:	A: D, C: D, D: D, F: D, G: D, H: D, I: D, K: D, L: D, M: D, N: D, P: D, Q: D, R: D, S: D, T: D, V: D, W: D, Y: D,

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[hide] Mutations in the human ATP-binding cassette transp... Hum Mutat. 2002 Aug;20(2):151. Heimerl S, Langmann T, Moehle C, Mauerer R, Dean M, Beil FU, von Bergmann K, Schmitz G
Mutations in the human ATP-binding cassette transporters ABCG5 and ABCG8 in sitosterolemia.
Hum Mutat. 2002 Aug;20(2):151., [PMID:12124998]

Abstract [show]
Phytosterolemia or Sitosterolemia is a rare autosomal recessive disorder characterized by highly elevated plasma levels of plant sterols and cholesterol as a consequence of hyperabsorption and impaired biliary secretion of sterols. The disease is caused by mutations in two half size ATP-binding cassette transporters, ABCG5 and ABCG8. We have analyzed the genomic sequence of ABCG5 and ABCG8 in five well-characterized patients with Sitosterolemia. In the first patient we found a heterozygous mutation in exon 8 of the ABCG5 gene leading to a premature termination of the protein (Arg408Ter). This German patient is the first European showing a mutation of the ABCG5 gene. In a second patient we found a novel heterozygous mutation in exon 5 of ABCG8 (c.584T>A; Leu195Gln). Both patients were heterozygous for the identified mutation, but no mutation could be identified on the other chromosome. In three further analyzed patients we found mutations in exons 7, 9 and 11 of the ABCG8 gene, respectively, of which two result in a premature termination signal for translation products. One of these patients was compound heterozygous (Trp361Ter and Arg412Ter), the other was homozygous for Trp361Ter. The third patient was homozygous for an amino acid exchange (Gly574Arg). In conclusion this report describes one novel mutation affecting a highly conserved amino acid and two previously identified mutations in the ABCG8 gene. In addition, we identified for the first time a mutation in the ABCG5 gene of a European Sitosterolemia patient.

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No. Sentence Comment
77 C Y658stop R121stop R164stop Q172stop R184H L195Q P231T G574R G574E L572P L596R N ABC B S AA R263Q E146Q R405H R543S W536stop R412stop W361stop C R419P R419H R408stop R398H N437K R550S R243stop N ABCG5 ABCG8 S B A IVS1 -2A>G Del547C>191stop L501P L596R 1568_1572delTCTTT 1798_1800delTTC Del Exon 3 C336-337insA 201 * Signature 250 ABCG1 Q..EKDEG.R REMVKEILTA L GLLSCANTR TGS.... .LS GGQR KRLAIA ABCG2 ATTMTNHE.K NERINRVIEE L GLDKVADSK VGTQFIR GVS GGER KRTSIG ABCG4 S..EKQEV.K KELVTEILTA L GLMSCSHTR TAL.... .LS GGQR KRLAIA ABCG5 R..RGNPGSF QKKVEAVMAE L SLSHVADRL IGNYSLG GIS TGER RRVSIA ABCG8 PRTFSQAQ.R DKRVEDVIAE L RLRQCADTR VGNMYVR GLS GGER RRVSIG Figure 2: Alignment of the human ABC transporters G1, G2, G4, G5 and G8. The amino acid change Leu195Gln in ABCG8 found in patient 2 is located intracellularly between the Walker A and the Signature C-motif. Login to comment

[hide] Missense mutations in ABCG5 and ABCG8 disrupt hete... J Biol Chem. 2004 Jun 4;279(23):24881-8. Epub 2004 Mar 30. Graf GA, Cohen JC, Hobbs HH
Missense mutations in ABCG5 and ABCG8 disrupt heterodimerization and trafficking.
J Biol Chem. 2004 Jun 4;279(23):24881-8. Epub 2004 Mar 30., 2004-06-04 [PMID:15054092]

Abstract [show]
Mutations in ABCG5 (G5) or ABCG8 (G8) cause sitosterolemia, an autosomal recessive disease characterized by sterol accumulation and premature atherosclerosis. G5 and G8 are ATP-binding cassette (ABC) half-transporters that must heterodimerize to move to the apical surface of cells. We examined the role of N-linked glycans in the formation of the G5/G8 heterodimer to gain insight into the determinants of folding and trafficking of these proteins. Site-directed mutagenesis revealed that two asparagine residues (Asn(585) and Asn(592)) are glycosylated in G5 and that G8 has a single N-linked glycan attached to Asn(619). N-Linked glycosylation of G8 was required for efficient trafficking of the G5/G8 heterodimer, but mutations that abolished glycosylation of G5 did not prevent trafficking of the heterodimer. Both G5 and G8 are bound by the lectin chaperone, calnexin, suggesting that the calnexin cycle may facilitate folding of the G5/G8 heterodimer. To determine the effects of 13 disease-causing missense mutations in G5 and G8 on formation and trafficking of the G5/G8 heterodimer, mutant forms of the half-transporters were expressed in CHO-K1 cells. All 13 mutations reduced trafficking of the G5/G8 heterodimer from the endoplasmic reticulum to the Golgi complex, and most prevented the formation of stable heterodimers between G5 and G8. We conclude that the majority of the molecular defects in G5 and G8 that cause sitosterolemia impair transport of the sterol transporter to the cell surface.

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No. Sentence Comment
203 No mature G5 was present in cells expressing G5 with the R389H, R419H, or N437K mutations. Login to comment
204 Trafficking was less efficient in cells expressing the E146Q mutation, and only trace amounts of mature G5 were seen in cells expression G5 with the R419P mutation. Login to comment
213 The appearance of the 150 kDa band was only apparent in cells expressing the G5 mutants E146Q and R419P and correlated with the appearance of fully processed G5 as determined by SDS-PAGE. Login to comment
212 The appearance of the 150 kDa band was only apparent in cells expressing the G5 mutants E146Q and R419P and correlated with the appearance of fully processed G5 as determined by SDS-PAGE. Login to comment

[hide] Increased plasma plant sterol concentrations and a... Eur J Med Genet. 2011 Jul-Aug;54(4):e458-60. Epub 2011 May 23. Keller S, Prechtl D, Aslanidis C, Ceglarek U, Thiery J, Schmitz G, Jahreis G
Increased plasma plant sterol concentrations and a heterozygous amino acid exchange in ATP binding cassette transporter ABCG5: a case report.
Eur J Med Genet. 2011 Jul-Aug;54(4):e458-60. Epub 2011 May 23., [PMID:21664501]

Abstract [show]
Whilst conducting a scientific study, an elevated plasma plant sterol concentration of 3.07 mg/dL was established in one proband. Similar levels found in his mothers plasma (2.73 mg/dL) were suggestive of a heterozygous sitosterolemia. The resulting gene analysis for ATP binding cassette transporter G5/G8 (ABCG5/G8) revealed a heterozygous polymorphism in ABCG8 (Thr400Lys, rs4148217), which the proband had inherited from his father. However, a heterozygous amino acid exchange (Arg406Gln) in exon 9 of ABCG5 was revealed, which was inherited from his mother. Although not sufficient evidence exists to regard this sequence variation as a mutation, this previously unreleased sequence variation occurred in a "hot spot" area for sitosterolemia of the ABCG5 gene (exon 9) and the similar increased plasma plant sterol concentrations of the heterozygous mother contribute to the notion, that this very likely presents an inactivating mutation.

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No. Sentence Comment
57 In addition to splicing, insertions, deletion, and complete rearrangement of the ABCG5 gene,13 mutations with an amino acid exchange resulting in sitosterolemia are published (Gln22Term [14], Glu77Term [15], Glu146Gln [16], Arg243Term [17], Gly269Arg, Tyr329Term [7], Arg389His, Arg408Term, Arg419His, Arg419Pro [17], Asn437Lys [18], Arg446Term [1], Arg550Ser [16]). Login to comment

[hide] Two genes that map to the STSL locus cause sitoste... Am J Hum Genet. 2001 Aug;69(2):278-90. Epub 2001 Jul 9. Lu K, Lee MH, Hazard S, Brooks-Wilson A, Hidaka H, Kojima H, Ose L, Stalenhoef AF, Mietinnen T, Bjorkhem I, Bruckert E, Pandya A, Brewer HB Jr, Salen G, Dean M, Srivastava A, Patel SB
Two genes that map to the STSL locus cause sitosterolemia: genomic structure and spectrum of mutations involving sterolin-1 and sterolin-2, encoded by ABCG5 and ABCG8, respectively.
Am J Hum Genet. 2001 Aug;69(2):278-90. Epub 2001 Jul 9., [PMID:11452359]

Abstract [show]
Sitosterolemia is a rare autosomal recessive disorder characterized by (a) intestinal hyperabsorption of all sterols, including cholesterol and plant and shellfish sterols, and (b) impaired ability to excrete sterols into bile. Patients with this disease have expanded body pools of cholesterol and very elevated plasma plant-sterol species and frequently develop tendon and tuberous xanthomas, accelerated atherosclerosis, and premature coronary artery disease. In previous studies, we have mapped the STSL locus to human chromosome 2p21. Recently, we reported that a novel member of the ABC-transporter family, named "sterolin-1" and encoded by ABCG5, is mutated in 9 unrelated families with sitosterolemia; in the remaining 25 families, no mutations in sterolin-1 could be identified. We identified another ABC transporter, located <400 bp upstream of sterolin-1, in the opposite orientation. Mutational analyses revealed that this highly homologous protein, termed "sterolin-2" and encoded by ABCG8, is mutated in the remaining pedigrees. Thus, two highly homologous genes, located in a head-to-head configuration on chromosome 2p21, are involved as causes of sitosterolemia. These studies indicate that both sterolin-1 and sterolin-2 are indispensable for the regulation of sterol absorption and excretion. Identification of sterolin-1 and sterolin-2 as critical players in the regulation of dietary-sterol absorption and excretion identifies a new pathway of sterol transport.

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No. Sentence Comment
134 A human full- Table 2 Compilation of Mutations in ABCG5 and ABCG8 PATIENT (NATIONALITY/ETHNICITY) MUTATIONS IN ABCG5a ABCG8b 4 (U.S./white) Trp361X (1173GrA) / Arg412X (1324CrT) 9 (U.S./white) Arg543Ser (1719GrT) / Gln172X (604CrT) 56c (U.S./white) Trp361X (1173GrA) / Tyr658X (2064CrG) 60 (U.S./white) Trp361X (1173GrA) / IVS1 -2 ArG 90c (U.S./white) Trp361X (1173GrA) / Trp361X (1173GrA) 94 (U.S./white) Trp361X (1173GrA) / Arg184His (641GrA) 120 (U.S./white) Trp361X (1173GrA) / Leu501Pro (1592TrC) 125 (U.S./white) Trp361X (1173GrA) / Trp361X (1173GrA) 128 (U.S./white) Leu596Arg (1877TrG) / IVS1 -2 ArG 172 (U.S./white) Trp361X (1173GrA) / Tyr658Stop (2064CrG) 166c (U.S./white) Trp361X (1173GrA) / Arg412X (1324CrT) 32 (SA/white) Arg121X (451CrT) / Arg121X (451CrT) 98 (Dutch/white) Trp361X (1173GrA) / Gly574Glu (1811GrA) 102c,d (U.S./white) Trp361X (1173GrA) / … 84c (U.S./Amish-Mennonite) Gly574Arg (1810GrA) / Gly574Arg (1810GrA) 108c (U.S./Amish-Mennonite) Gly574Arg (1810GrA) / Gly574Arg (1810GrA) 135 (Columbian/white) Trp536X (1698GrA) / Trp536X (1698GrA) 175 (French) 1798_1800delTTC / Arg405His (1304GrA) 20 (Finnish) Trp361X (1173GrA) / Trp361X (1173GrA) 154 (Finnish) Trp361X (1173GrA) / … 116 (Norwegian) Trp361X (1173GrA) / Trp361X (1173GrA) 163 (Swedish) Trp361X (1173GrA) / Leu572Pro (1805TrC) 15 (U.S./white) 1568_1572delTCTTT / IVS1 -2 ArG 143 (SA/Asian) Arg164X (580CrT) / Arg121X (451CrT) 25 (SA/Asian) Arg243X (876CrT) / Arg243X (876CrT) 40 (Japanese) Arg419His (1396GrA) / Arg419His (1396GrA) 46 (Japanese) Arg389His (1306GrA) / Arg389His (1306GrA) 63 (Japanese) del exon 3 / del exon 3 113 (Japanese) Arg389His (1306GrA) / Arg389His (1306GrA) 132 (Japanese) Arg419His (1396GrC) / Arg550Ser (1790ArC) 140 (Japanese) Arg408X (1362CrT) / Arg408X (1362CrT) 146 (Japanese) Arg389His (1306GrA) / Arg389His (1306GrA) 157 (U.S./white) Arg419Pro (1396GrC) / Arg419Pro (1396GrC) 149 (African American) Glu146Gln (576GrC) / 026; 1c,e (German/Swiss) Trp361X / Trp361X 2c,e (U.S./Amish) Gly574Arg / Gly574Arg 3c,e (U.S./white) Trp361X / Tyr658X 5c,d (U.S./white) Trp361X / Arg412X 6c,e (U.S./white) Leu596Arg / … 7d (U.S./Hispanic) Arg412X / del547Cr191X 8c,e (New Zealand/white) Trp361X / … 4e (Chinese) Arg263Gln / Pro231Thr 9e (Chinese) Arg408X / … a GenBank accession number AF312715. Login to comment
146 of Alleles Frequency Restriction-Enzyme Recognition ABCG5: Glu146Gln 1 .05 Gain of AlwNI Arg243X 2 .10 Gain of AlwNI Arg389His 6 .30 Loss of BstUI Arg408X 3 .15 Loss of AvaI Arg419Pro 2 .10 Loss of BstUI Arg419His 3 .15 Loss of BstUI del exon 3 2 .10 … Arg550Ser 1 .05 … Total 20 ABCG8: Arg121X 3 .061 Gain of DdeI Arg164stop 1 .020 … Gln172X 1 .020 Gain of BfaI Arg184His 1 .020 Gain of NalIII Pro231Thr 1 .020 Loss of NlaIV Arg263Gln 1 .020 Gain of AluI Trp361X 19 .39 … Arg405His 1 .020 … Arg412X 3 .061 Gain of DdeI Leu501Pro 1 .020 Loss of AluI Trp536X 2 .041 Gain of AhdI Arg543Ser 1 .020 … Leu572Pro 1 .020 Gain of FauI Gly574Glu 1 .020 Loss of MspI Gly574Arg 4 .082 Loss of MspI Leu596Arg 1 .020 Gain of MspI Tyr658X 2 .041 Gain of SfcI IVS1 -2ArG 3 .061 Gain of BtgI 1798_1800delTTC 1 .020 … 1568_1572delTCTTT 1 .020 … Total 49 Mutations of Sterolin-2/ABCG8 as the Cause of Sitosterolemia Information on the exon/intron boundaries was used to screen probands, including those known to be mutated for sterolin-1, and to compare them to normal controls. Login to comment