Putative calcium‐binding domains of the Caenorhabditis elegans BK channel are dispensable for intoxication and ethanol activation

Alcohol modulates the highly conserved, voltage‐ and calcium‐activated potassium (BK) channel, which contributes to alcohol‐mediated behaviors in species from worms to humans. Previous studies have shown that the calcium‐sensitive domains, RCK1 and the Ca²⁺ bowl, are required for ethanol activation of the mammalian BK channel in vitro. In the nematode Caenorhabditis elegans, ethanol activates the BK channel in vivo, and deletion of the worm BK channel, SLO‐1, confers strong resistance to intoxication. To determine if the conserved RCK1 and calcium bowl domains were also critical for intoxication and basal BK channel‐dependent behaviors in C. elegans, we generated transgenic worms that express mutated SLO‐1 channels predicted to have the RCK1, Ca²⁺ bowl or both domains rendered insensitive to calcium. As expected, mutating these domains inhibited basal function of SLO‐1 in vivo as neck and body curvature of these mutants mimicked that of the BK null mutant. Unexpectedly, however, mutating these domains singly or together in SLO‐1 had no effect on intoxication in C. elegans. Consistent with these behavioral results, we found that ethanol activated the SLO‐1 channel in vitro with or without these domains. By contrast, in agreement with previous in vitro findings, C. elegans harboring a human BK channel with mutated calcium‐sensing domains displayed resistance to intoxication. Thus, for the worm SLO‐1 channel, the putative calcium‐sensitive domains are critical for basal in vivo function but unnecessary for in vivo ethanol action.     

Abrupt expression of TLR4 in TLR4-deficient macrophages imposes a selective disadvantage: genetic evidence for TLR4-dependent responses to endogenous, nonmicrobial stimuli

TLR4 is crucial for macrophage responses to LPS. It is less clear whether TLR4 may also transduce signals from host factors, and if so, with what consequences. Immortalized bone marrow-derived macrophage cell lines, termed T4Cr and T4ko, were established from TLR4null strains, C57BL/10ScNCr and TLR4 knockout mice, respectively. Multiple transfections and selections were conducted to stably introduce TLR4 into these cell lines. Among 196 individual clones isolated, 48 expressed TLR4 on the cell surface but did not respond to LPS due to a deletion in the MyD88 gene. The remaining clones integrated TLR4 DNA into the genome but expressed neither detectable TLR4 mRNA nor TLR4 protein. To test the possibility that TLR4null cells lack modulating factors to protect against a harmful effect of TLR4, 15 stably transfected clones were generated in the presence of conditioned media from wild-type macrophages. Some of these cells expressed a small amount of TLR4 and regained responsiveness to LPS. Because no microbial ligands were available to the cell lines during their generation, signaling via endogenous ligands is likely to have occurred in TLR4-expressing, signal-competent macrophages and imposed a proliferative or other selective disadvantage. These studies support the existence of constitutive signaling via TLR4 during in vitro culture of macrophages without microbial products, and help account for the lack of reports of restoration of TLR4 expression in normally TLR4-expressing types of cells in vitro whose TLR4 genes are deleted or disrupted.     

Identification of yin-yang regulators and a phosphorylation consensus for male germ cell-associated kinase (MAK)-related kinase

MAK (male germ cell-associated protein kinase) and MRK/ICK (MAK-related kinase/intestinal cell kinase) are human homologs of Ime2p in Saccharomyces cerevisiae and of Mde3 and Pit1 in Schizosaccharomyces pombe and are similar to human cyclin-dependent kinase 2 (CDK2) and extracellular signal-regulated kinase 2 (ERK2). MAK and MRK require dual phosphorylation in a TDY motif catalyzed by an unidentified human threonine kinase and tyrosine autophosphorylation. Herein, we establish that human CDK-related kinase CCRK (cell cycle-related kinase) is an activating T157 kinase for MRK, whereas active CDK7/cyclin H/MAT1 complexes phosphorylate CDK2 but not MRK. Protein phosphatase 5 (PP5) interacts with MRK in a complex and dephosphorylates MRK at T157 in vitro and in situ. Thus, CCRK and PP5 are yin-yang regulators of T157 phosphorylation. To determine a substrate consensus, we screened a combinatorial peptide library with active MRK. MRK preferentially phosphorylates R-P-X-S/T-P sites, with the preference for arginine at position -3 (P-3) being more stringent than for prolines at P-2 and P+1. Using the consensus, we identified a putative phosphorylation site (RPLT(1080)S) for MRK in human Scythe, an antiapoptotic protein that interacts with MRK. MRK phosphorylates Scythe at T1080 in vitro as determined by site-directed mutagenesis and mass spectrometry, supporting the consensus and suggesting Scythe as a physiological substrate for MRK.     

3-(Arylamino)-3-phenylpropan-2-olamines as a new series of dual norepinephrine and serotonin reuptake inhibitors

A series of 3-(arylamino)-3-phenylpropan-2-olamines was prepared and screened for their ability to inhibit monoamine reuptake. A number of analogues displayed significant dual norepinephrine and serotonin reuptake inhibition. Compounds in this class exhibited minimal affinity for the dopamine transporter.     

The active tube clearance system: a novel bedside chest-tube clearance device

OBJECTIVE:: Chest-tube clogging can lead to complications after heart and lung surgery. Surgeons often choose large-diameter chest tubes or place more than one chest tube when concerned about the potential for clogging. The purpose of this report is to describe the design and function of a proprietary active tube clearance system, a novel device that clears clots and debris from chest tubes. DEVICE DESCRIPTION:: The active tube clearance system is a novel chest tube clearance apparatus developed to maintain chest tube patency. Chest tube clearance is achieved by advancing the specially designed clearance member back and forth within the chest tube under sterile conditions, breaking down and pulling clots back toward the drainage receptacle, thereby leaving the inner portion of the chest tube clear of any obstructing material. CONCLUSIONS:: By maintaining chest tube patency, chest tube drainage can be performed more safely, and this apparatus may possibly lead to the use of smaller chest tubes and less invasive insertion techniques.