Cytotoxic lymphocytes in COPD airways: increased NK cells associated with disease,iNKT and NKT-like cells with current smoking

Background

Cytotoxic lymphocytes are increased in the airways of COPD patients. Whether this increase is driven primarily by the disease or by smoking is not clear, nor whether it correlates with the rate of decline in lung function.

Methods

Bronchoscopy with BAL was performed in 52 subjects recruited from the longitudinal OLIN COPD study according to pre-determined criteria; 12 with COPD and a rapid decline in lung function (loss of FEV₁?≥?60?ml/year), 10 with COPD and a non-rapid decline in lung function (loss of FEV₁?≤?30?ml/year), 15 current and ex-smokers and 15 non-smokers with normal lung function. BAL lymphocyte subsets were determined using flow cytometry.

Results

In BAL fluid, the proportions of NK, iNKT and NKT-like cells all increased with pack-years. Within the COPD group, NK cells – but not iNKT or NKT-like cells – were significantly elevated also in subjects that had quit smoking. In contrast, current smoking was associated with a marked increase in iNKT and NKT-like cells but not in NK cells. Rate of lung function decline did not significantly affect any of the results.

Conclusions

In summary, increased proportions of NK cells in BAL fluid were associated with COPD; iNKT and NKT-like cells with current smoking but not with COPD. Interestingly, NK cell percentages did not normalize in COPD subjects that had quit smoking, indicating that these cells might play a role in the continued disease progression seen in COPD even after smoking cessation.

Trial registration

Clinicaltrials.gov identifier NCT02729220.

     

The Properties of Amyloid-β Fibrils Are Determined by their Path of Formation

Fibril formation of the amyloid-β peptide (Aβ) follows a nucleation-dependent polymerization process and is associated with Alzheimer's disease. Several different lengths of Aβ are observed in vivo, but Aβ1–40 and Aβ1–42 are the dominant forms. The fibril architectures of Aβ1–40 and Aβ1–42 differ and Aβ1–42 assemblies are generally considered more pathogenic. We show here that monomeric Aβ1–42 can be cross-templated and incorporated into the ends of Aβ1–40 fibrils, while incorporation of Aβ1–40 monomers into Aβ1–42 fibrils is very poor. We also show that via cross-templating incorporated Aβ monomers acquire the properties of the parental fibrils. The suppressed ability of Aβ1–40 to incorporate into the ends of Aβ1–42 fibrils and the capacity of Aβ1–42 monomers to adopt the properties of Aβ1–40 fibrils may thus represent two mechanisms reducing the total load of fibrils having the intrinsic, and possibly pathogenic, features of Aβ1–42 fibrils in vivo. We also show that the transfer of fibrillar properties is restricted to fibril-end templating and does not apply to cross-nucleation via the recently described path of surface-catalyzed secondary nucleation, which instead generates similar structures to those acquired via de novo primary nucleation in the absence of catalyzing seeds. Taken together these results uncover an intrinsic barrier that prevents Aβ1–40 from adopting the fibrillar properties of Aβ1–42 and exposes that the transfer of properties between amyloid-β fibrils are determined by their path of formation.     

Microscale decoupling of sediment oxygen consumption and microbial biomass in an oligotrophic lake

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The closed structure of presequence protease PreP forms a unique 10,000 Angstroms3 chamber for proteolysis

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Behavioral motifs and neural pathways coordinating O2 responses and aggregation in C. elegans

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Intestinal Microbiota Regulate Xenobiotic Metabolism in the Liver

Background

The liver is the central organ for xenobiotic metabolism (XM) and is regulated by nuclear receptors such as CAR and PXR, which control the metabolism of drugs. Here we report that gut microbiota influences liver gene expression and alters xenobiotic metabolism in animals exposed to barbiturates.

Principal findings

By comparing hepatic gene expression on microarrays from germfree (GF) and conventionally-raised mice (SPF), we identified a cluster of 112 differentially expressed target genes predominantly connected to xenobiotic metabolism and pathways inhibiting RXR function. These findings were functionally validated by exposing GF and SPF mice to pentobarbital which confirmed that xenobiotic metabolism in GF mice is significantly more efficient (shorter time of anesthesia) when compared to the SPF group.

Conclusion

Our data demonstrate that gut microbiota modulates hepatic gene expression and function by altering its xenobiotic response to drugs without direct contact with the liver.     

Widespread occurrence of an intranuclear bacterial parasite in vent and seep bathymodiolin mussels

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