An exploratory analysis of the competing effects of alcohol use and advanced hepatic fibrosis on serum HDL.

While alcohol use has been shown to increase serum HDL, advanced liver disease associates with decreased serum HDL. The combined influence of alcohol consumption and liver fibrosis is poorly defined. In this study, we sought to investigate the competing effects of alcohol use and hepatic fibrosis on serum HDL and to determine if the presence of advanced hepatic fibrosis ablates the reported effect of alcohol consumption on serum HDL. We performed a cross-sectional, exploratory analysis examining the interaction between alcohol use and advanced hepatic fibrosis on serum HDL levels in 10,528 patients from the Partners Biobank. Hepatic fibrosis was assessed using the FIB-4 index. We excluded patients with baseline characteristics that affect serum HDL, independent of alcohol use or the presence or advanced hepatic fibrosis. We observed an incremental correlation between increasing HDL levels and amount of alcohol consumed (P < 0.0001), plateauing in those individuals who drink 1-2 drinks per day, Contrastingly, we found a negative association between the presence of advanced hepatic fibrosis and lower HDL levels, independent of alcohol use (beta coefficient: -0.011075, SEM0.003091, P value: 0.0001). Finally, when comparing subjects with advanced hepatic fibrosis who do not use alcohol to those who do, we observed that alcohol use is associated with increased HDL levels (54.58 mg/dL vs 67.26 mg/dL, p = 0.0009). This HDL-elevating effect of alcohol was more pronounced than that seen in patients without evidence of advanced hepatic fibrosis (60.88 mg/dL vs 67.93 mg/dL, p < 0.0001). Our data suggest that the presence of advanced hepatic fibrosis does not blunt the HDL-elevating effect of alcohol use.

Serum HMGB1 associates with liver disease and predicts readmission and mortality in patients with alcohol use disorder.

Identifying the minority of patients with alcohol use disorder (AUD) who develop the wide spectrum of alcohol-associated liver disease (ALD), and risk-stratifying these patients, is of critical importance. High-Mobility Group Box 1 protein (HMGB1) is an alarmin that has been implicated in the pathogenesis of multiple liver diseases. Its use as a biomarker for liver disease in those with AUD has not been studied. In this report, we investigated the association between serum HMGB1 and the presence, severity, and progression of ALD in two well-characterized cohorts of patients with AUD. In our discovery cohort of 80 patients, we found that patients with AUD and ALD exhibited higher serum HMGB1 levels compared to patients with AUD only (p = 0.0002). Additionally, serum HMGB1 levels were positively associated with liver disease severity (p < 0.0001). We found that index serum HMGB1 levels were associated with liver disease progression, defined by an increase in MELD score at 120 days (p = 0.0397). Serum HMGB1 was notable for its diagnostic and prognostic ability; it proved able to distinguish accurately between severe and non-severe forms of ALD in both our discovery cohort (AUC = 0.8199, p = 0.0003) and an independent validation cohort of 74 patients with AUD (AUC = 0.8818, p < 0.0001). Moreover, serum HMGB1 levels effectively predicted both liver-related readmission (AUC = 0.8849, p < 0.0001) and transplantation/death (AUC = 0.8614, p = 0.0002) at 90 days. The predictive potential of HMGB1 was also validated in an independent cohort of patients with AUD. Taken together, our results suggest that serum HMGB1 shows promise as a biologically relevant biomarker for ALD in patients with AUD.

Development of a Humanized Murine Model for the Study of Oxalobacter formigenes Intestinal Colonization.

BACKGROUND: Oxalobacter formigenes are bacteria that colonize the human gut and degrade oxalate, a component of most kidney stones. Findings of clinical and epidemiological studies suggest that O. formigenes colonization reduces the risk for kidney stones. We sought to develop murine models to allow investigating O. formigenes in the context of its native human microbiome. METHODS: For humanization, we transplanted pooled feces from healthy, noncolonized human donors supplemented with a human O. formigenes strain into recipient mice. We transplanted microbiota into mice that were treated with broad-spectrum antibiotics to suppress their native microbiome, were germ free, or received humanization without pretreatment or received sham gavage (controls). RESULTS: All humanized mice were stably colonized with O. formigenes through 8 weeks after gavage, whereas mice receiving sham gavage remained uncolonized (P < .001). Humanization significantly changed the murine intestinal microbial community structure (P < .001), with humanized germ-free and antibiotic-treated groups overlapping in ß-diversity. Both germ-free and antibiotic-treated mice had significantly increased numbers of human species compared with sham-gavaged mice (P < .001). CONCLUSIONS: Transplanting mice with human feces and O. formigenes introduced new microbial populations resembling the human microbiome, with stable O. formigenes colonization; such models can define optimal O. formigenes strains to facilitate clinical trials.

Comparative prevalence of Oxalobacter formigenes in three human populations.

There has been increasing interest in the human anaerobic colonic bacterium Oxalobacter formigenes because of its ability to metabolize oxalate, and its potential contribution to protection from calcium oxalate kidney stones. Prior studies examining the prevalence of this organism have focused on subjects in developed countries and on adults. Now using O. formigenes-specific PCR, we have compared the prevalence of these organisms among subjects in two remote areas in which modern medical practices have hardly been present with a USA group of mothers and their infants for the first three years of life. Among the Amerindians of the Yanomami-Sanema and Yekwana ethnic groups in Venezuela and the Hadza in Tanzania, O. formigenes was detected in 60-80% of the adult subjects, higher than found in adults from USA in this and prior studies. In young children, the prevalence was much lower in USA than in either tribal village. These data extend our understanding of the epidemiology of O. formigenes carriage, and are consistent with the hypothesis that the rising incidence of kidney stones is associated with the progressive loss of O. formigenes colonization in populations that have been highly impacted by modern medical practices.

Oxalobacter formigenes-associated host features and microbial community structures examined using the American Gut Project.

BACKGROUND: Increasing evidence shows the importance of the commensal microbe Oxalobacter formigenes in regulating host oxalate homeostasis, with effects against calcium oxalate kidney stone formation, and other oxalate-associated pathological conditions. However, limited understanding of O. formigenes in humans poses difficulties for designing targeted experiments to assess its definitive effects and sustainable interventions in clinical settings. We exploited the large-scale dataset from the American Gut Project (AGP) to study O. formigenes colonization in the human gastrointestinal (GI) tract and to explore O. formigenes-associated ecology and the underlying host-microbe relationships. RESULTS: In >8000 AGP samples, we detected two dominant, co-colonizing O. formigenes operational taxonomic units (OTUs) in fecal specimens. Multivariate analysis suggested that O. formigenes abundance was associated with particular host demographic and clinical features, including age, sex, race, geographical location, BMI, and antibiotic history. Furthermore, we found that O. formigenes presence was an indicator of altered host gut microbiota structure, including higher community diversity, global network connectivity, and stronger resilience to simulated disturbances. CONCLUSIONS: Through this study, we identified O. formigenes colonizing patterns in the human GI tract, potential underlying host-microbe relationships, and associated microbial community structures. These insights suggest hypotheses to be tested in future experiments. Additionally, we proposed a systematic framework to study any bacterial taxa of interest to computational biologists, using large-scale public data to yield novel biological insights.