Ventilatory response to helium-oxygen breathing during exercise: effect of airway anesthesia

Krishnan, Bharath S., Ron E. Clemens, Trevor A. Zintel,Martin J. Stockwell, and Charles G. Gallagher. Ventilatory response to helium-oxygen breathing during exercise: effect of airwayanesthesia. J. Appl. Physiol. 83(1):82-88, 1997.The substitution of a normoxic helium mixture(HeO₂) for room air (Air) during exercise results in a sustained hyperventilation, which is present evenin the first breath. We hypothesized that this response is dependent onintact airway afferents; if so, airway anesthesia (Anesthesia) shouldaffect this response. Anesthesia was administered to the upper airwaysby topical application and to lower central airways by aerosolinhalation and was confirmed to be effective for over 15 min. Subjectsperformed constant work-rate exercise (CWE) at 69 ± 2 (SE) % maximal work rate on a cycle ergometer on three separate days: twiceafter saline inhalation (days 1 and3) and once after Anesthesia(day 2). CWE commenced after a briefwarm-up, with subjects breathing Air for the first 5 min (Air-1),HeO₂ for the next 3 min, and Airagain until the end of CWE (Air-2). The resistance of the breathingcircuit was matched for Air andHeO₂. BreathingHeO₂ resulted in a small butsignificant increase in minute ventilation(I) anddecrease in alveolar PCO₂ in both theSaline (average of 2 saline tests; not significant) and Anesthesiatests. Although Anesthesia had no effect on the sustainedhyperventilatory response to HeO₂breathing, theI transientswithin the first six breaths ofHeO₂ were significantly attenuatedwith Anesthesia. We conclude that theI response to HeO₂ is not simply due to areduction in external tubing resistance and that, in humans, airwayafferents mediate the transient but not the sustained hyperventilatoryresponse to HeO₂ breathing duringexercise.

     

Three-Dimensional Protein Fold Determination from Backbone Amide Pseudocontact Shifts Generated by Lanthanide Tags at Multiple Sites

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Molecular modeling of the chromatosome particle

In an effort to understand the role of the linker histone in chromatin folding, its structure and location in the nucleosome has been studied by molecular modeling methods. The structure of the globular domain of the rat histone H1d, a highly conserved part of the linker histone, built by homology modeling methods, revealed a three-helical bundle fold that could be described as a helix–turn–helix variant with its characteristic properties of binding to DNA at the major groove. Using the information of its preferential binding to four-way Holliday junction (HJ) DNA, a model of the domain complexed to HJ was built, which was subsequently used to position the globular domain onto the nucleosome. The model revealed that the primary binding site of the domain interacts with the extra 20 bp of DNA of the entering duplex at the major groove while the secondary binding site interacts with the minor groove of the central gyre of the DNA superhelix of the nucleosomal core. The positioning of the globular domain served as an anchor to locate the C-terminal domain onto the nucleosome to obtain the structure of the chromatosome particle. The resulting structure had a stem-like appearance, resembling that observed by electron microscopic studies. The C-terminal domain which adopts a high mobility group (HMG)-box-like fold, has the ability to bend DNA, causing DNA condensation or compaction. It was observed that the three S/TPKK motifs in the C-terminal domain interact with the exiting duplex, thus defining the path of linker DNA in the chromatin fiber. This study has provided an insight into the probable individual roles of globular and the C-terminal domains of histone H1 in chromatin organization.     

Prediction of an HMG-box fold in the C-terminal domain of histone H1: insights into its role in DNA condensation

In eukaryotes, histone H1 promotes the organization of polynucleosome filaments into chromatin fibers, thus contributing to the formation of an important structural framework responsible for various DNA transaction processes. The H1 protein consists of a short N-terminal "nose," a central globular domain, and a highly basic C-terminal domain. Structure prediction of the C-terminal domain using fold recognition methods reveals the presence of an HMG-box-like fold. We recently showed by extensive site-directed and deletion mutagenesis studies that a 34 amino acid segment encompassing the three S/TPKK motifs, within the C-terminal domain, is responsible for DNA condensing properties of H1. The position of these motifs in the predicted structure corresponds exactly to the DNA-binding segments of HMG-box-containing proteins such as Lef-1 and SRY. Previous analyses have suggested that histone H1 is likely to bend DNA bound to the C-terminal domain, directing the path of linker DNA in chromatin. Prediction of the structure of this domain provides a framework for understanding the higher order of chromatin organization.     

Integrate-and-fire models of insolation-driven entrainment of broadcast spawning in corals

The circa-annual cycle of gametogenesis produces mature gametes at the spawning “season” for successful mass spawning of broadcast corals. We develop a bioenergetic integrate-and-fire model that reveals how annual insolation rhythms can entrain the gametogenetic cycles in tropical hermatypic corals to the appropriate spawning season, since photosynthate is their primary source of energy. In the presence of short-term fluctuations in the energy input, a feedback regulatory mechanism is likely required to achieve coherence of spawning times to within one lunar cycle, in order for subsequent signals such as lunar and diurnal light cycles to unambiguously determine the “correct” night of spawning. The feedback mechanism can also provide robustness against population heterogeneity that may arise due to genetic and environmental effects. We solve the integrate-and-fire bioenergetic model numerically using the Fokker–Planck equation and use analytical tools such as rotation number to study entrainment.     

Diacylglycerol-induced membrane targeting and activation of protein kinase Cepsilon: mechanistic differences between protein kinases Cdelta and Cepsilon

Two novel protein kinases C (PKC), PKCdelta and PKCepsilon, have been reported to have opposing functions in some mammalian cells. To understand the basis of their distinct cellular functions and regulation, we investigated the mechanism of in vitro and cellular sn-1,2-diacylglycerol (DAG)-mediated membrane binding of PKCepsilon and compared it with that of PKCdelta. The regulatory domains of novel PKC contain a C2 domain and a tandem repeat of C1 domains (C1A and C1B), which have been identified as the interaction site for DAG and phorbol ester. Isothermal titration calorimetry and surface plasmon resonance measurements showed that isolated C1A and C1B domains of PKCepsilon have comparably high affinities for DAG and phorbol ester. Furthermore, in vitro activity and membrane binding analyses of PKCepsilon mutants showed that both the C1A and C1B domains play a role in the DAG-induced membrane binding and activation of PKCepsilon. The C1 domains of PKCepsilon are not conformationally restricted and readily accessible for DAG binding unlike those of PKCdelta. Consequently, phosphatidylserine-dependent unleashing of C1 domains seen with PKCdelta was not necessary for PKCepsilon. Cell studies with fluorescent protein-tagged PKCs showed that, due to the lack of lipid headgroup selectivity, PKCepsilon translocated to both the plasma membrane and the nuclear membrane, whereas PKCdelta migrates specifically to the plasma membrane under the conditions in which DAG is evenly distributed among intracellular membranes of HEK293 cells. Also, PKCepsilon translocated much faster than PKCdelta due to conformational flexibility of its C1 domains. Collectively, these results provide new insight into the differential activation mechanisms of PKCdelta and PKCepsilon based on different structural and functional properties of their C1 domains.