6 research outputs found
Principle component analysis of bolivian chagas samples along with HapMap 3 populations.
<p>Each point represents one individual with different colors representing each population. Bolivian Chagas samples are coded in magenta. The HapMap populations include: ASW: African ancestry in Southwest USA; CEU: Utah residents with Northern and Western European ancestry from the CEPH collection; CHB: Han Chinese in Beijing, China; CHD: Chinese in Metropolitan Denver, Colorado; GIH: Gujarati Indians in Houston, Texas; JPT: Japanese in Tokyo, Japan; LWK: Luhya in Webuye, Kenya; MEX: Mexican ancestry in Los Angeles, California; MKK: Maasai in Kinyawa, Kenya; TSI: Tuscans in Italy; YRI: Yoruba in Ibadan, Nigeria.</p
Suggestive association results of SNPs in NLRP, CARD, CASP1 genes under an additive model unconditional logistic regression adjusted for population substructure, age, and sex.
<p>P-values reflect Bonferroni adjustment for multiple testing.</p
Genetic association study of NLRP1, CARD, and CASP1 inflammasome genes with chronic Chagas cardiomyopathy among <i>Trypanosoma cruzi</i> seropositive patients in Bolivia
<div><p>About 20–30% of people infected with Chagas disease present with chronic Chagas cardiomyopathy (CCC), the most serious and frequent manifestation of the disease, while others remain asymptomatic and often do not experience Chagas-specific mortality. It is not currently well understood what causes these differential disease outcomes, but a genetic predisposition within the host could play an important role. This study examined variants in the NLRP1, CARD, and CASP1 inflammasome genes among 62 <i>T</i>. <i>cruzi</i> seropositive patients from Bolivia (38 cases with CCC and 24 asymptomatic controls) to uncover associations with CCC. All subjects underwent a complete medical examination including electrocardiogram (EKG) and echocardiogram. After genotype calling and quality control filtering with exclusion of 3 cases and 3 controls, association analysis was performed across 76 directly genotyped SNPs in NLRP1, CARD, and CASP1 genes, adjusting for age, sex, and population stratification. One SNP (rs11651270; Bonferroni-corrected p = 0.036) corresponding to a missense mutation in NLPR1 was found to be significant after adjustment for multiple testing, and a suggestive association was seen in CARD11 (rs6953573; Bonferroni-corrected p = 0.060). Although limited by sample size, the study results suggest variations in the inflammasome, particularly in NLRP1 and CARD11, may be associated with CCC.</p></div
Quantitative Proteomics Reveal ATM Kinase-dependent Exchange in DNA Damage Response Complexes
ATM is a protein kinase that initiates a well-characterized
signaling cascade in cells exposed to ionizing radiation (IR). However,
the role for ATM in coordinating critical protein interactions and
subsequent exchanges within DNA damage response (DDR) complexes is
unknown. We combined SILAC-based tandem mass spectrometry and a subcellular
fractionation protocol to interrogate the proteome of irradiated cells
treated with or without the ATM kinase inhibitor KU55933. We developed
an integrative network analysis to identify and prioritize proteins
that were responsive to KU55933, specifically in chromatin, and that
were also enriched for physical interactions with known DNA repair
proteins. This analysis identified 53BP1 and annexin A1 (ANXA1) as
strong candidates. Using fluorescence recovery after photobleaching,
we found that the exchange of GFP-53BP1 in DDR complexes decreased
with KU55933. Further, we found that ANXA1 knockdown sensitized cells
to IR via a mechanism that was not potentiated by KU55933. Our study
reveals a role for ATM kinase activity in the dynamic exchange of
proteins in DDR complexes and identifies a role for ANXA1 in cellular
radioprotection
Quantitative Proteomics Reveal ATM Kinase-dependent Exchange in DNA Damage Response Complexes
ATM is a protein kinase that initiates a well-characterized
signaling cascade in cells exposed to ionizing radiation (IR). However,
the role for ATM in coordinating critical protein interactions and
subsequent exchanges within DNA damage response (DDR) complexes is
unknown. We combined SILAC-based tandem mass spectrometry and a subcellular
fractionation protocol to interrogate the proteome of irradiated cells
treated with or without the ATM kinase inhibitor KU55933. We developed
an integrative network analysis to identify and prioritize proteins
that were responsive to KU55933, specifically in chromatin, and that
were also enriched for physical interactions with known DNA repair
proteins. This analysis identified 53BP1 and annexin A1 (ANXA1) as
strong candidates. Using fluorescence recovery after photobleaching,
we found that the exchange of GFP-53BP1 in DDR complexes decreased
with KU55933. Further, we found that ANXA1 knockdown sensitized cells
to IR via a mechanism that was not potentiated by KU55933. Our study
reveals a role for ATM kinase activity in the dynamic exchange of
proteins in DDR complexes and identifies a role for ANXA1 in cellular
radioprotection
Quantitative Proteomics Reveal ATM Kinase-dependent Exchange in DNA Damage Response Complexes
ATM is a protein kinase that initiates a well-characterized
signaling cascade in cells exposed to ionizing radiation (IR). However,
the role for ATM in coordinating critical protein interactions and
subsequent exchanges within DNA damage response (DDR) complexes is
unknown. We combined SILAC-based tandem mass spectrometry and a subcellular
fractionation protocol to interrogate the proteome of irradiated cells
treated with or without the ATM kinase inhibitor KU55933. We developed
an integrative network analysis to identify and prioritize proteins
that were responsive to KU55933, specifically in chromatin, and that
were also enriched for physical interactions with known DNA repair
proteins. This analysis identified 53BP1 and annexin A1 (ANXA1) as
strong candidates. Using fluorescence recovery after photobleaching,
we found that the exchange of GFP-53BP1 in DDR complexes decreased
with KU55933. Further, we found that ANXA1 knockdown sensitized cells
to IR via a mechanism that was not potentiated by KU55933. Our study
reveals a role for ATM kinase activity in the dynamic exchange of
proteins in DDR complexes and identifies a role for ANXA1 in cellular
radioprotection