A brain-enriched lncRNA shields cancer cells from immune-mediated killing for metastatic colonization in the brain.

Brain metastases, including prevalent breast-to-brain metastasis (B2BM), represent an urgent unmet medical need in the care of cancer due to a lack of effective therapies. Immune evasion is essential for cancer cells to metastasize to the brain tissue for brain metastasis. However, the intrinsic genetic circuits that enable cancer cells to avoid immune-mediated killing in the brain microenvironment remain poorly understood. Here, we report that a brain-enriched long noncoding RNA (BMOR) expressed in B2BM cells is required for brain metastasis development and is both necessary and sufficient to drive cancer cells to colonize the brain tissue. Mechanistically, BMOR enables cancer cells to evade immune-mediated killing in the brain microenvironment for the development of brain metastasis by binding and inactivating IRF3. In preclinical brain metastasis murine models, locked nucleic acid-BMOR, a designed silencer targeting BMOR, is effective in suppressing the metastatic colonization of cancer cells in the brain for brain metastasis. Taken together, our study reveals a mechanism underlying B2BM immune evasion during cancer cell metastatic colonization of brain tissue for brain metastasis, where B2BM cells evade immune-mediated killing in the brain microenvironment by acquiring a brain-enriched long noncoding RNA genetic feature.

[Comparison of behavioral orthopedic and classical orthopedic rehabilitation : A retrospective cohort study on the factors of mental comorbidity, gender and employment status]. / Verhaltensmedizinisch-orthopädische und klassisch-orthopädische Rehabilitation im Vergleich : Eine retrospektive Kohortenstudie zu den Faktoren psychische Komorbidität, Geschlecht und Erwerbsstatus.

BACKGROUND: Mental comorbidity plays an increasingly important role in determining the specific rehabilitation needs of patients in Germany in the context of other personal, social and occupational factors. In order to make the DRV's list of criteria more meaningful when assigning patients to one type of rehabilitation, this retrospective analysis is intended to determine from which of the two rehabilitation concepts examined (orthopedic rehabilitation or healing procedures (HV)/behavioral-medical orthopedic rehabilitation (BMOR)) patients with mental comorbidity (taking into account gender, employment status of the main orthopedic diagnosis) benefit more. METHODS: Using the screening questionnaires HADS­A, HADS­D, SIMBO and BPI as well as a hospital questionnaire at the beginning of rehabilitation, data from 913 subjects (529 m/384 w) were collected and evaluated. Of these, 43% were assigned to HV and 57% to BMOR. Thus, in addition to the main orthopedic diagnosis, the frequency distribution of the factors psychological comorbidity, sex and, employment status (in the sense of unemployment) was determined. Using HADS, the benefit was determined at the end of the therapy by comparing the score medians. RESULTS: Frequency distributions and the development of HADS scores show that the prior classification according to psychological comorbidity was correct. Women were more often affected by mental comorbidity and women achieved greater success in BMOR. Regarding the main orthopedic diagnosis, a high prevalence of cervical and lumbar spine complaints was found. According to logistic regression with model decomposition, the variables gender, HADS­A and -D at the beginning of rehabilitation and the psychological comorbidity (yes/no) are suitable to correctly allocate the patients with 76.86% to one of the two types of therapy. CONCLUSIONS: The presence of mental comorbidity appears to be a useful indicator that should be retained in the DRV's criteria catalog as one of the main criteria for allocation to BMOR. Female gender in connection with the presence of mental co-morbidity can also be considered a conclusive criterion. With regard to the main orthopedic diagnosis, cervical spine complaints may be particularly suitable as an allocation criterion.

An ionic lock and a hydrophobic zipper mediate the coupling between an insect pheromone receptor BmOR3 and downstream effectors.

Pheromone receptors (PRs) recognize specific pheromone compounds to guide the behavioral outputs of insects, which are the most diverse group of animals on earth. The activation of PRs is known to couple to the calcium permeability of their coreceptor (Orco) or putatively with G proteins; however, the underlying mechanisms of this process are not yet fully understood. Moreover, whether this transverse seven transmembrane domain (7TM)-containing receptor is able to couple to arrestin, a common effector for many conventional 7TM receptors, is unknown. Herein, using the PR BmOR3 from the silk moth Bombyx mori and its coreceptor BmOrco as a template, we revealed that an agonist-induced conformational change of BmOR3 was transmitted to BmOrco through transmembrane segment 7 from both receptors, resulting in the activation of BmOrco. Key interactions, including an ionic lock and a hydrophobic zipper, are essential in mediating the functional coupling between BmOR3 and BmOrco. BmOR3 also selectively coupled with Gi proteins, which was dispensable for BmOrco coupling. Moreover, we demonstrated that trans-7TM BmOR3 recruited arrestin in an agonist-dependent manner, which indicates an important role for BmOR3-BmOrco complex formation in ionotropic functions. Collectively, our study identified the coupling of G protein and arrestin to a prototype trans-7TM PR, BmOR3, and provided important mechanistic insights into the coupling of active PRs to their downstream effectors, including coreceptors, G proteins, and arrestin.

Characterization of the oxidative stress response regulatory network in Bacteroides fragilis: An interaction between BmoR and OxyR regulons promotes abscess formation in a model of intra-abdominal infection.

OBJECTIVES: Bacteroides fragilis is an anaerobic bacterium that is commonly found in the human gut microbiota and an opportunistic pathogen in extra-intestinal infections. B. fragilis displays a robust response to oxidative stress which allows for survival in oxygenated tissues such as the peritoneal cavity and lead to the formation of abscesses. In this study, we investigated the synergy of the oxidative stress response regulators OxyR and BmoR in the ability of B. fragilis to resist oxidative damage and to survive in extra-intestinal infection. METHODS: A ΔbmoR ΔoxyR double mutant B. fragilis strain was constructed, and its oxidative stress response was compared to parental and single mutant strains in phenotypical assays and gene expression analysis. The pathogenic potential in an in vivo mouse model of abscess formation was also evaluated. RESULTS: Expression analysis showed a coordinated control of thioredoxin C (trxC) gene expression by BmoR and OxyR during oxygen exposure, with upregulation of trxC in the bmoR mutant strain (4.9-fold increase), downregulation in the oxyR mutant (2.5-fold decrease), and an intermediate level of deregulation (2-fold increase) in the double mutant strain compared to the parent strain. Expression analysis during oxidative stress conditions also showed that BmoR is a major repressor of the CoA-disulfide reductase gene (upregulated 47-fold in the bmoR mutant) while OxyR plays a minor repression role in this gene (upregulated 2.5-fold in the oxyR mutant). Exposure to atmospheric oxygen for up to 72 h revealed that the deletion of bmoR alone had no significant effect in in vitro survival phenotype assays, though it partially abolishes the OxyR sensitivity phenotype in the bmoR/oxyR double mutant strain compared to oxyR mutant. In vivo assays showed that bmoR and oxyR mutants were significantly impaired in the formation and development of abscesses compared to the parent strain in an experimental intra-abdominal infection mouse model. CONCLUSION: Although the full extent of genes whose expression are modulated by BmoR and OxyR is yet to be defined, we present evidence that these regulators have overlapping functions in B. fragilis response to oxidative stress and ability to form abscess in extra-intestinal tissues.

Engineering transcription factor BmoR for screening butanol overproducers.

The wild-type transcription factors are sensitive to their corresponding signal molecules. Using wild-type transcription factors as biosensors to screen industrial overproducers are generally impractical because of their narrow detection ranges. This study took transcription factor BmoR as an example and aimed to expand the detection range of BmoR for screening alcohols overproducers. Firstly, a BmoR mutation library was established, and the mutations distributed randomly in all predicted functional domains of BmoR. Structure of BmoR-isobutanol complex were modelled, and isobutanol binding sites were confirmed by site-directed mutagenesis. Subsequently, the effects of the mutations on the detection range or output were confirmed in the BmoR mutants. Four combinatorial mutants containing one increased-detection-range mutation and one enhanced-output mutation were constructed. Compared with wild-type BmoR, F276A/E627N BmoR and D333N/E627N BmoR have wider detection ranges (0-100 mM) and relatively high outputs to the isobutanol added quantitatively or produced intracellularly, demonstrating they have potential for screening isobutanol overproduction strains. This work presented an example of engineering the wild-type transcription factors with physiological significance for industrial utilization.

Establishment of BmoR-based biosensor to screen isobutanol overproducer.

BACKGROUND: Isobutanol, a C4 branched-chain higher alcohol, is regarded as an attractive next-generation transport fuel. Metabolic engineering for efficient isobutanol production has been achieved in many studies. BmoR, an alcohol-regulated transcription factor, mediates a σ54-dependent promoter Pbmo of alkane monooxygenase in n-alkane metabolism of Thauera butanivorans and displays high sensitivity to C4-C6 linear alcohols and C3-C5 branched-chain alcohols. In this study, to achieve the high-level production of isobutanol, we established a screening system which relied on the combination of BmoR-based biosensor and isobutanol biosynthetic pathway and then employed it to screen isobutanol overproduction strains from an ARTP mutagenesis library. RESULTS: Firstly, we constructed and verified a GFP-based BmoR-Pbmo device responding to the isobutanol produced by the host. Then, this screening system was employed to select three mutants which exhibited higher GFP/OD600 values than that of wild type. Significantly, GFP/OD600 of mutant 10 was 190.7 ± 4.8, a 1.4-fold higher value than that of wild type. Correspondingly, the isobutanol titer of that strain was 1597.6 ± 129.6 mg/L, 2.0-fold higher than the wild type. With the overexpression of upstream pathway genes, the isobutanol production from mutant 10 reached 14.0 ± 1.0 g/L after medium optimization in shake flask. The isobutanol titer reached 56.5 ± 1.8 g/L in a fed-batch production experiment. CONCLUSIONS: This work screened out isobutanol overproduction strains from a mutagenesis library by using a screening system which depended on the combination of BmoR-based biosensor and isobutanol biosynthetic pathway. Optimizing fermentation condition and reinforcing upstream pathway could realize the increase of isobutanol production from the overproducer. Lastly, fed-batch fermentation of the mutant enhanced the isobutanol production to 56.5 ± 1.8 g/L.

Compensatory effects of other olfactory genes after CRISPR/cas9 editing of BmOR56 in silkworm, Bombyx mori.

Bombyx mori is an oligophagous economic insect. Cis-Jasmone is one of the main substances in mulberry leaf that attract silkworm for feeding and BmOR56 is its receptor. Potential interaction ways between BmOR56 and cis-Jasmone were explored, which included some crucial amino acids such as Gln172, Val173, Ser176, Lys182, His322, and Arg345. BmOR56 was edited using CRISPR/cas9 for Qiufeng, and a homozygous knockout strain QiufengM was obtained. Compared with Qiufeng, the feeding ability of QiufengM on mulberry leaf did not change significantly, but on artificial diet decreased significantly. QiufengM also showed a dependence on the concentration of mulberry leaf powder. The result indicated that other olfactory genes had a compensatory effect on the attractance of mulberry leaf after the loss of BmOR56. Transcriptome analysis of antennae showed that many genes differentially expressed between Qiufeng and QiufengM, which involved in olfactory system, glucose metabolism, protein metabolism, amino acid metabolism, and insect hormone biosynthesis. Particularly, BmIR21, BmOR53 and BmOR27 were significantly up-regulated, which may have a compensatory effect on BmOR56 loss. In addition, detoxification mechanism was activated and may cause the passivation of feeling external signals in silkworm.

Engineering Transcription Factor BmoR Mutants for Constructing Multifunctional Alcohol Biosensors.

Native transcription factor-based biosensors (TFBs) have the potential for the in situ detection of value-added chemicals or byproducts. However, their industrial application is limited by their ligand promiscuity, low sensitivity, and narrow detection range. Alcohols exhibit similar structures, and no reported TFB can distinguish a specific alcohol from its analogues. Here, we engineered an alcohol-regulated transcription factor, BmoR, and obtained various mutants with remarkable properties. For example, the generated signal-molecule-specific BmoRs could distinguish the constitutional isomers n-butanol and isobutanol, with insensitivity up to an ethanol concentration of 800 mM (36.9 g/L). Linear detection of 0-60 mM of a specific higher alcohol could be achieved in the presence of up to 500 mM (23.0 g/L) ethanol as background noise. Furthermore, we obtained two mutants with raised outputs and over 107-fold higher sensitivity and one mutant with an increased upper detection limit (14.8 g/L n-butanol or isobutanol). Using BmoR as an example, this study systematically explored the ultimate detection limit of a TFB toward its small-molecule ligands, paving the way for in situ detection in biofuel and wine industries.

Elucidation of Sequence-Function Relationships for an Improved Biobutanol In Vivo Biosensor in E. coli.

Transcription factor (TF)-promoter pairs have been repurposed from native hosts to provide tools to measure intracellular biochemical production titer and dynamically control gene expression. Most often, native TF-promoter systems require rigorous screening to obtain desirable characteristics optimized for biotechnological applications. High-throughput techniques may provide a rational and less labor-intensive strategy to engineer user-defined TF-promoter pairs using fluorescence-activated cell sorting and deep sequencing methods (sort-seq). Based on the designed promoter library's distribution characteristics, we elucidate sequence-function interactions between the TF and DNA. In this work, we use the sort-seq method to study the sequence-function relationship of a σ54-dependent, butanol-responsive TF-promoter pair, BmoR-PBMO derived from Thauera butanivorans, at the nucleotide level to improve biosensor characteristics, specifically an improved dynamic range. Activities of promoters from a mutagenized PBMO library were sorted based on gfp expression and subsequently deep sequenced to correlate site-specific sequences with changes in dynamic range. We identified site-specific mutations that increase the sensor output. Double mutant and a single mutant, CA(129,130)TC and G(205)A, in PBMO promoter increased dynamic ranges of 4-fold and 1.65-fold compared with the native system, respectively. In addition, sort-seq identified essential sites required for the proper function of the σ54-dependent promoter biosensor in the context of the host. This work can enable high-throughput screening methods for strain development.