Roux-en-Y gastric bypass (RYGB) has been demonstrated to be the most effective treatment for morbid obesity, yet the impact of RYGB on intestinal permeability is not fully known. In this work, we subjected obese mice to RYGB and sham operation procedures. Serum lipopolysaccharide (LPS) level, inflammatory cytokines and intestinal permeability were measured at 8 weeks post surgery. In contrast to sham surgery, RYGB reduced body weight, improved glucose tolerance and insulin resistance, and decreased serum levels of LPS, IL6 and TNFα. Intestinal permeability of the common limb and colon was significantly improved in the RYGB group compared to the sham group. The mRNA levels of IL1β, IL6, and TLR4 in the intestine were significantly decreased in the RYGB group compared with the sham group. The expression levels of intestinal islet-derived 3β (REG3β), islet-derived 3γ (REG3γ) and intestinal alkaline phosphatase (IAP) were higher in the RYGB group than in the sham group. In conclusion, in a diet-induced obesity (DIO) mouse model, both decreased intestinal permeability and attenuated systemic inflammation after RYGB surgery were associated with improved innate immunity, which might result from enhanced production of IAP and antimicrobial peptides.

Congenital heart defects, one of the most common birth defects, affect approximately 1% of live birth globally and remain the leading cause of infant mortality in developed countries. Utilizing the pathogenicity score and inheritance mode from whole exome sequencing results, a heterozygous mutation (NM_001278939.1: c.1939G>T, p.Gly647Ter) in elastin (ELN) was identified among 6,440 variants in a female proband born with an atrial septal defect accompanied by pulmonary artery stenosis. Results of RT-PCR showed that the mutation (NM_001278939.1: c.1939G>T, p.Gly647Ter) did not affect the expression levels of ELN mRNA but increased protein level. The content of ELN truncate (functional component) was significantly lower in both the intracellular and extracellular compartments after mutation. These results indicate that the ELN mutation (NM_001278939.1: c.1939G>T, p.Gly647Ter) affected the protein truncate, which may be a functional component of ELN and play crucial roles for this pedigree. Here we report of an ELN heterozygous variant associated with congenital heart disease accompanied with pulmonary artery stenosis, which is less common. Based on our results, we speculate that this may be the main molecular mechanism underlying the mutation-led functional changes, and propose that the decrease of ELN protein level may cause this pedigree vascular abnormality, especially pulmonary artery stenosis, and reinforce the view that ELN insufficiency is the primary cause of these vascular lesions. This may be the main molecular mechanism underlying the mutation-led functional changes. Thus, systematic analysis not only enables us to better understand the etiology of this disease but also contributes to clinical and prenatal diagnosis.