Hemorheological alterations in sickle cell anemia and their clinical consequences: the role of genetic modulators

Sickle cell anemia (SCA) is an autosomal recessive chronic hemolytic anemia, caused by homozygosity for the HBB:c.20A>T mutation. The disease presents with high clinical heterogeneity, stroke being the most devastating manifestation. This study aimed to identify genetic modulators of severe hemolysis and stroke risk in children with SCA, as well as understand their consequences at the hemorheological level. Sixty-six children with SCA were categorised according to their degree of cerebral vasculopathy (Stroke/Risk/Control). Relevant data were collected from patients’ medical records. Several polymorphic regions in genes related to vascular cell adhesion and tonus were characterized by molecular methodologies. Data analyses were performed using R software. Several in silico tools (e.g. TFBind, MatInspector) were applied to investigate the main variant consequences. Some genetic variants in vascular adhesion molecule-1 gene promoter and endothelial nitric oxide synthase gene were associated with higher levels of hemolysis and stroke events. They modify important transcription factor binding sites or disturb the corresponding protein structure/function. Our findings emphasize the relevance of the genetic variants in modulating the degree of hemolysis and development of cerebral vasculopathy due to their effect on gene expression, modification of protein biological activities related with erythrocyte/endothelial interactions and consequent hemorheological abnormalities in SCA.

Gene-environment interactions in Autism Spectrum Disorders (ASD)

Spectrum Disorder (ASD), is a heterogeneous neurodevelopmental disorder with na estimated global prevalence rate of 17:10000, and a male to female ratio of 4:1. Patients with ASD presente language and communication difficulties and stereotyped behaviours. Comorbidity with other disorders, such as Intelectual Disability, Fragile-X syndrome (FXS) epilepsy and tuberous sclerosis frequently occurs. ASD presents amultifactorial etiopathology, and genetic factos alone are not suficiente to explain how the syndrome arises, with recente studies establishing ASD heritability at approximately 50%. Pre-, peri- and post-natal exposure to toxic environmental factos has been implicated in the development of ASD. Involvement of epigenetic regulatory mechanisms has been suggested, supported by the occurrence of autistic symptoms in patients with disorders aris ing from epigenetic mutations, such as FXS. A polygenic and epistatic model is a strong hypothesis to explain ASD. The main goal of this project is to identify specific exposure patterns to environmental toxicants in children diagnosed with ASD and integrate the results with genetic and epigenetic data.