Background <p>Neonatal respiratory distress syndrome (RDS) is among the most prevalent morbidities in late preterm and term infants. Although the gut–lung axis has been implicated in neonatal respiratory disease, the relationship between RDS and early gut microbiome composition remains poorly characterized. This study aimed to characterize gut microbiome alterations associated with RDS and surfactant replacement therapy (SRT), and to evaluate the biological plausibility of a disease-specific probiotic intervention.</p> Methods <p>Two complementary cohorts were prospectively enrolled. In the clinical observational cohort (<i>n</i> = 45), fecal samples collected within 48&#xa0;h of birth were analyzed by Nanopore 16S rRNA sequencing across three groups: infants without RDS (control group, <i>n</i> = 25), infants with RDS who did not receive SRT (RDS(S−) group, <i>n</i> = 7), and infants with RDS who received SRT (RDS(S+) group, <i>n</i> = 13). In the probiotic discovery cohort (<i>n</i> = 40), gut microbiota of infants without RDS (CON group, <i>n</i> = 17) and infants with RDS (RDS group, <i>n</i> = 23) were characterized by metagenomic sequencing and culturomics. Candidate probiotic strains were evaluated in a fermenter for intestinal microbiota model (FIMM) and a fecal microbiota transplantation (FMT) mouse model.</p> Results <p>The RDS(S−) group exhibited depletion of beneficial taxa including <i>Bifidobacterium</i> and <i>Lacticaseibacillus</i> and enrichment of opportunistic pathogens including <i>Enterococcus</i> and <i>Staphylococcus</i>. Following SRT, gut microbial profiles partially shifted toward those of the control group. <i>Limosilactobacillus fermentum</i> SLAM_LAF05 and <i>Bifidobacterium longum</i> SLAM_BIL02 were identified as CON-enriched candidate probiotic strains through direct microbiome comparison and selected based on superior acid and bile tolerance and adhesion capacity. In the FIMM model, probiotic supplementation increased microbial diversity and suppressed opportunistic pathogens. In the FMT mouse model, probiotic supplementation was associated with upregulation of ZO-1, MUC2, and Reg3g, reduction of fecal calprotectin, and restoration of serum IgG levels.</p> Conclusions <p>This study provides an early translational characterization of RDS-associated gut dysbiosis and its partial resolution following SRT, and establishes proof-of-concept for a disease-specific probiotic approach. These findings offer a new perspective on the interplay between gut microbial dynamics and the early postnatal respiratory course, and provide a basis for future investigations into microbiota-targeted strategies in neonates with RDS.</p>

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Gut dysbiosis associated with neonatal respiratory distress syndrome and biological plausibility of disease-specific probiotic intervention: a translational study

  • Eunsol Seo,
  • Seung Hyun Kim,
  • Min‑Jin Kwak,
  • Jae Kyoon Hwang,
  • Ghulam Mustafa,
  • Yun Sil Chang,
  • Jeong-Kyu Hoh,
  • Byong-Hun Jeon,
  • Hyun-Kyung Park,
  • Younghoon Kim

摘要

Background

Neonatal respiratory distress syndrome (RDS) is among the most prevalent morbidities in late preterm and term infants. Although the gut–lung axis has been implicated in neonatal respiratory disease, the relationship between RDS and early gut microbiome composition remains poorly characterized. This study aimed to characterize gut microbiome alterations associated with RDS and surfactant replacement therapy (SRT), and to evaluate the biological plausibility of a disease-specific probiotic intervention.

Methods

Two complementary cohorts were prospectively enrolled. In the clinical observational cohort (n = 45), fecal samples collected within 48 h of birth were analyzed by Nanopore 16S rRNA sequencing across three groups: infants without RDS (control group, n = 25), infants with RDS who did not receive SRT (RDS(S−) group, n = 7), and infants with RDS who received SRT (RDS(S+) group, n = 13). In the probiotic discovery cohort (n = 40), gut microbiota of infants without RDS (CON group, n = 17) and infants with RDS (RDS group, n = 23) were characterized by metagenomic sequencing and culturomics. Candidate probiotic strains were evaluated in a fermenter for intestinal microbiota model (FIMM) and a fecal microbiota transplantation (FMT) mouse model.

Results

The RDS(S−) group exhibited depletion of beneficial taxa including Bifidobacterium and Lacticaseibacillus and enrichment of opportunistic pathogens including Enterococcus and Staphylococcus. Following SRT, gut microbial profiles partially shifted toward those of the control group. Limosilactobacillus fermentum SLAM_LAF05 and Bifidobacterium longum SLAM_BIL02 were identified as CON-enriched candidate probiotic strains through direct microbiome comparison and selected based on superior acid and bile tolerance and adhesion capacity. In the FIMM model, probiotic supplementation increased microbial diversity and suppressed opportunistic pathogens. In the FMT mouse model, probiotic supplementation was associated with upregulation of ZO-1, MUC2, and Reg3g, reduction of fecal calprotectin, and restoration of serum IgG levels.

Conclusions

This study provides an early translational characterization of RDS-associated gut dysbiosis and its partial resolution following SRT, and establishes proof-of-concept for a disease-specific probiotic approach. These findings offer a new perspective on the interplay between gut microbial dynamics and the early postnatal respiratory course, and provide a basis for future investigations into microbiota-targeted strategies in neonates with RDS.