ALBERT

Description: Abstract 3282 Innate lymphocytes can play both protective and pathogenic roles in chronic inflammatory disorders. Recently, killer-cell immunoglobulin-like receptors (KIRs) and its cognitive ligands - human leukocyte antigen (HLA) class I molecules - were identified as genetic risk factors for Crohn's Disease (CD), a common inflammation symptom. Natural killer (NK) cells, the major KIR-expressing cell type, can be educated through KIR-HLA ligation. To uncover the cellular mechanism that determines CD susceptibility, we utilize a novel single-cell functional proteomics microchip and other highly-multiplexed assays (Ma, C. et al. Nature Medicine, 2011, 17, 738–743). We show that, in genetically pertinent individuals, natural killer (NK) cells are functionally reprogrammed to modulate the activation threshold of CD4+ T cells, a major cellular mediator of chronic inflammation. Genetic study of 455 CD patients bearing the AA haplotype identifies that the HLA-C1/C1 allotype, ligand of the KIR2DL3 receptor, is significantly enriched (p

Description: The human leukocyte antigen (HLA) genes are candidate genetic susceptibility loci for childhood acute lymphoblastic leukemia (ALL). We examined the effect of HLA-DP genetic variation on risk and evaluated its potential interaction with 4 proxies for early immune modulation, including measures of infectious exposures in infancy (presence of older siblings, daycare attendance, ear infections) and breastfeeding. A total of 585 ALL cases and 848 controls were genotyped at the HLA-DPA1 and DPB1 loci. Because of potential heterogeneity in effect by race/ethnicity, we included only non-Hispanic white (47%) and Hispanic (53%) children and considered these 2 groups separately in the analysis. Logistic regression analyses showed an increased risk of ALL associated with HLA-DPB1*01:01 (odds ratio [OR] = 1.43, 95% CI, 1.01-2.04) with no heterogeneity by Hispanic ethnicity (P = .969). Analyses of DPB1 supertypes showed a marked childhood ALL association with DP1, particularly for high-hyperdiploid ALL (OR = 1.83; 95% CI, 1.20-2.78). Evidence of interaction was found between DP1 and older sibling (P = .036), and between DP1 and breastfeeding (P = .094), with both showing statistically significant DP1 associations within the lower exposure categories only. These findings support an immune mechanism in the etiology of childhood ALL involving the HLA-DPB1 gene in the context of an insufficiently modulated immune system.

Description: β-thalassemia causes significant morbidity and mortality worldwide. Currently, the diagnosis can be made prenatally for couples at risk using invasive procedures such as chorionic villus sampling and amniocentesis. Noninvasive prenatal testing (NIPT) on maternal blood samples would enable earlier fetal diagnosis and eliminate risks associated with these procedures. The discovery of cell-free fetal DNA (cfFDNA) in maternal plasma and advances in next generation sequencing (NGS) have made NIPT a clinical reality for aneuploidies. Diagnosing autosomal recessive (AR) disorders is more challenging as it requires determination of both the paternally and maternally inherited alleles and can be particularly difficult when both parents carry the same mutation. Previous studies used methods to identify the paternally inherited allele in maternal plasma through the detection of a DNA sequence variant present in the father and absent in the mother. Our method expands the target region beyond the β-globin gene into highly polymorphic regions to increase the likelihood of identifying unique paternal sequences. Unlike the detection of the paternal allele, there is no direct qualitative approach for determining the maternally inherited allele. Our solution is an indirect quantitative method that compares the ratio of allelic sequence reads to infer which maternal allele was inherited by the fetus. We have developed a novel NGS assay which utilizes probe capture enrichment, a method employing thousands of short overlapping oligonucleotide probes complementary to a target sequence region. This design makes it uniquely applicable to short, fragmented DNA, such as cell-free DNA (~150 base pairs). Our probe assay targets a contiguous 900 bp region which spans a portion of the β-globin gene (part of exon 2 as well as the entirety of IVS-1 and exon 1) and extends 579 bp into the highly polymorphic 5' UTR region to identify linked sequence variations. Additionally, the assay targets 451 single nucleotide polymorphisms (SNPs) throughout the genome. SNPs that are "informative" (i.e. an allele present in the fetus and absent in the mother) are used to calculate the fraction of cfDNA from the fetus. We have evaluated our assay's performance in a set of experiments designed to simulate the challenging aspects of cfFDNA: very low quantity and short fragment size. The assay's sensitivity was tested by preparing libraries containing amounts of DNA ranging from 50 to 0.05 ngs. At DNA amounts as low as 5 ng (5-fold lower than that expected in plasma), 100% coverage was achieved for the targeted β-globin region and SNPs. The probe/NGS system successfully captured and sequenced DNA fragments as short as 35 bps and as little as 0.5 ng of DNA with 〉95% coverage. To test the ability of the probe/NGS system to resolve mixtures, DNA samples from patients with known β-globin mutations were combined in ratios ranging from 2.5:97.5 to 20:80 in 25 ng total DNA to mimic the maternal/fetal cfDNA mixture. Our assay was able to detect minority heterozygous mutant alleles at proportions as low as 1.25% and 0.3 ng of DNA. In a mixture designed to simulate a case with a shared parental mutation (CD41/42(-TTCT)), we identified a linked SNP (rs713040) allele, which was within 250 bp of the mutation and unique to the minor fraction. We used this SNP to distinguish the CD41/42 (-TTCT) mutation contributed by the minor fraction. Based on 6 mixtures, we observed 24.3% (110/451) of SNPs to be informative, allowing for a precise estimate of the minor fraction. We estimated the minor fraction to be 11.88% and 5.98% compared to the expected 10% and 5%, respectively. To show proof of concept for inferring the minor ("fetal") genotype when the major ("maternal") genotype was heterozygous mutant (IVS1-5 (G〉C)), the estimated minor fraction (10.4% based on 104 informative SNPs) was used to calculate the expected allelic ratios of the 3 different possible minor ("fetal") genotypes. The minor genotype was correctly inferred as wt/wt based on the observed mixture ratio (42.56/57.41 mut/wt) compared to the expected (44.93/55.07). These data show that our probe capture/NGS system can overcome the challenges implicit in the analysis of cfFDNA for NIPT: low DNA amount (