Cyclooxygenase-2 haplotypes influence the longitudinal risk of malaria and severe malarial anemia in Kenyan children from a holoendemic transmission region.

Cyclooxygenase-2 [(COX-2) or prostaglandin endoperoxide H2 synthase-2 (PTGS-2)] induces the production of prostaglandins as part of the host-immune response to infections. Although a number of studies have demonstrated the effects of COX-2 promoter variants on autoimmune and inflammatory diseases, their role in malaria remains undefined. As such, we investigated the relationship between four COX-2 promoter variants (COX-2 -512 C > T, -608 T > C, -765 G > C, and -1195 A > G) and susceptibility to malaria and severe malarial anemia (SMA) upon enrollment and longitudinally over a 36-month follow-up period. All-cause mortality was also explored. The investigation was carried out in children (n = 1081, age; 2-70 months) residing in a holoendemic Plasmodium falciparum transmission region of western Kenya. At enrollment, genotypes/haplotypes (controlling for anemia-promoting covariates) did not reveal any strong effects on susceptibility to either malaria or SMA. Longitudinal analyses showed decreased malaria episodes in children who inherited the -608 CC mutant allele (RR = 0.746, P = 1.811 × 10-4) and -512C/-608T/-765G/-1195G (CTGG) haplotype (RR = 0.856, P = 0.011), and increased risk in TTCA haplotype carriers (RR = 1.115, P = 0.026). Over the follow-up period, inheritance of the rare TTCG haplotype was associated with enhanced susceptibility to both malaria (RR = 1.608, P = 0.016) and SMA (RR = 5.714, P = 0.004), while carriage of the rare TTGG haplotype increased the risk of malaria (RR = 1.755, P = 0.007), SMA (RR = 8.706, P = 3.97 × 10-4), and all-cause mortality (HR = 110.000, P = 0.001). Collectively, these results show that SNP variations in the COX-2 promoter, and their inherited combinations, are associated with the longitudinal risk of malaria, SMA, and all-cause mortality among children living in a high transmission area for P. falciparum.

Integrated OMICS platforms identify LAIR1 genetic variants as novel predictors of cross-sectional and longitudinal susceptibility to severe malaria and all-cause mortality in Kenyan children.

BACKGROUND: Severe malarial anaemia (SMA) is a leading cause of childhood mortality in holoendemic Plasmodium falciparum regions. METHODS: To gain an improved understanding of SMA pathogenesis, whole genome and transcriptome profiling was performed in Kenyan children (n=144, 3-36months) with discrete non-SMA and SMA phenotypes. Leukocyte associated immunoglobulin like receptor 1 (LAIR1) emerged as a predictor of susceptibility to SMA (P<1×10-2, OR: 0.44-1.37), and was suppressed in severe disease (-1.69-fold, P=0.004). To extend these findings, the relationship between LAIR1 polymorphisms [rs6509867 (16231C>A); rs2287827 (18835G>A)] and clinical outcomes were investigated in individuals (n=1512, <5years) at enrolment and during a 36-month longitudinal follow-up. FINDINGS: Inheritance of the 16,231 recessive genotype (AA) increased susceptibility to SMA at enrolment (OR=1.903, 95%CI: 1.252-2.891, P=0.003), and longitudinally (RR=1.527, 95%CI: 1.119-2.083, P=0.008). Carriage of the 18,835 GA genotype protected against SMA cross-sectionally (OR=0.672, 95%CI: 0.480-0.9439, P=0.020). Haplotype carriage (C16231A/G18835A) also altered cross-sectional susceptibility to SMA: CG (OR=0.717, 95%CI: 0.527-0.9675, P=0.034), CA (OR=0.745, 95%CI: 0.536-1.036, P=0.080), and AG (OR=1.641, 95%CI: 1.160-2.321, P=0.005). Longitudinally, CA carriage was protective against SMA (RR=0.715, 95%CI: 0.554-0.923, P=0.010), while AG carriage had an additive effect on enhanced SMA risk (RR=1.283, 95%CI: 1.057-1.557, P=0.011). Variants that protected against SMA had elevated LAIR1 transcripts, while those with enhanced risk had lower expression (P<0.05). Inheritance of 18,835 GA reduced all-cause mortality by 44.8% (HR=0.552, 95%CI: 0.329-0.925, P=0.024), while AG haplotype carriage increased susceptibility by 68% (HR=1.680, 95%CI: 1.020-2.770, P=0.040). INTERPRETATION: These findings suggest LAIR1 is important for modulating susceptibility to SMA and all-cause childhood mortality.