Two-Dimensional Supersolid Formation in Dipolar Condensates.

Dipolar condensates have recently been coaxed to form the long-sought supersolid phase. While one-dimensional supersolids may be prepared by triggering a roton instability, we find that such a procedure in two dimensions (2D) leads to a loss of both global phase coherence and crystalline order. Unlike in 1D, the 2D roton modes have little in common with the supersolid configuration. We develop a finite-temperature stochastic Gross-Pitaevskii theory that includes beyond-mean-field effects to explore the formation process in 2D and find that evaporative cooling directly into the supersolid phase-hence bypassing the first-order roton instability-can produce a robust supersolid in a circular trap. Importantly, the resulting supersolid is stable at the final nonzero temperature. We then experimentally produce a 2D supersolid in a near-circular trap through such an evaporative procedure. Our work provides insight into the process of supersolid formation in 2D and defines a realistic path to the formation of large two-dimensional supersolid arrays.

CJ-12,373, a novel topoisomerase II inhibitor: fermentation, isolation, structure elucidation and biological activities.

A novel isochroman carboxylic acid CJ-12,373 was isolated from Penicillium sp. CL22557. CJ-12,373 inhibits both DNA gyrase-mediated supercoiling and relaxation without the formation of a cleavage intermediate, suggesting that CJ-12,373 inhibits DNA gyrase at a stage distinct from the religation step. CJ-12,373 is not selective for procaryotic DNA gyrase as it also inhibits relaxation mediated by eukaryotic topoisomerase II. The antimicrobial potency of CJ-12,373, however, is largely attributed to its inhibition of DNA gyrase.

Glycylcyclines bind to the high-affinity tetracycline ribosomal binding site and evade Tet(M)- and Tet(O)-mediated ribosomal protection.

N,N-dimethylglycylamido (DMG) derivatives of 6-demethyl-6-deoxytetracycline and doxycycline bind 5-fold more effectively than tetracycline to the tetracycline high-affinity binding site on the Escherichia coli 70S ribosome, which correlates with a 10-fold increase in potency for inhibition of E. coli cell-free translation. The potencies of DMG-doxycycline and DMG-6-demethyl-6-deoxytetracycline were unaffected by the ribosomal tetracycline resistance factors Tet(M) and Tet(O) in cell-free translation assays and whole-cell bioassays with a conditional Tet(M)-producing E. coli strain.

CJ-12,371 and CJ-12,372, two novel DNA gyrase inhibitors. Fermentation,isolation, structural elucidation and biological activities.

A fermentation broth of an unidentified fungus (N983-46) was found to produce DNA gyrase inhibitors, CJ-12,371 (1) and CJ-12,372 (2). Following isolation by solvent extraction and silica gel and ODS (reverse phase) chromatographies, the structures were determined to be novel spiro-ketal compounds with S-configuration at position C-1. CJ-12,371 and CJ-12,372 inhibit both DNA supercoiling and relaxation mediated by Escherichia coli DNA gyrase. The interaction of these compounds with DNA gyrase appears to be novel in that the compounds inhibit supercoiling and relaxation without blocking religation; thus, no cleavage intermediate of double strand DNA is observed. Both compounds have antibacterial activity against several species of pathogenic Gram-positive bacteria, with MICs between 25 and 100 micrograms/ml. These results suggest that the antibacterial potency of CJ-12,371 and CJ-12,372 is attributed to the inhibition of DNA gyrase. However, the compounds did not inhibit DNA gyrase selectively, as they also inhibited eukaryotic topoisomerase II-mediated relaxation. Semi-synthetic modifications to the dihydroxy motif in CJ-12,371 altered both gyrase- and topoisomerase II-inhibitory activities, but did not enhance selectivity.

Nasal and tracheal responses to chemical and somatic afferent stimulation in anesthetized cats.

Respiratory chemical and reflex interventions have been shown to affect nasal resistance or tracheal tone, respectively. In the present study, nasal caliber (assessed from pressure at a constant flow) and tracheal tone (assessed from pressure in a fluid-filled balloon within an isolated tracheal segment) were monitored simultaneously in anesthetized, paralyzed, artificially ventilated (inspired O2 fraction = 100%) cats. We examined the effect of CO2 inhalation and sciatic nerve stimulation as well as the application of nicotine (6 X 10(-4) mol/l) or lidocaine (2% solution) to the intermediate area of the ventral medullary surface (VMS). CO2 and VMS nicotine resulted in a significant increase in tracheal pressure [147 +/- 73 and 91 +/- 86% (SD), respectively]; and a significant reduction in nasal pressure (-35 +/- 10 and -20 +/- 13%, respectively). In contrast, sciatic nerve stimulation resulted in a significant fall in both tracheal (-50 +/- 36%) and nasal pressure (-21 +/- 13%). Application of 2 or 4% lidocaine to the VMS reduced tracheal pressure but did not significantly affect nasal pressure. After VMS lidocaine, nasal and tracheal responses to CO2, sciatic nerve stimulation, or VMS nicotine, when present, were negligible. These results suggest a role for the VMS in the regulation and coordination of nasal and tracheal caliber responses.

Cooling the intermediate area of the ventral medullary surface affects tracheal responses to hypoxia.

The intermediate area of the ventral medullary surface (VMS) influences changes in airway tone caused by hypercapnia and intrapulmonary irritant receptor activation. These studies evaluated the effects of cooling the intermediate area of the VMS on the reflex hypoxic responses of the trachealis smooth muscle and of the phrenic nerve. Anesthetized, paralyzed cats were hyperventilated with 100% oxygen to produce phrenic neural apnea. Tracheal tone was measured indirectly by evaluating pressure changes in an innervated tracheal segment and the phrenic electroneurogram was determined from the central end of a cut cervical root. Switching the inspired gas to 12% O2 increased tracheal pressure of 11 of 12 cats but caused phrenic activity to reappear in only 6 of the animals. Ventilation with 6% O2 significantly increased tracheal constriction prior to phrenic activity. After intravenous administration of atropine methyl nitrate tracheal responses to hypoxia were abolished but phrenic neural responses were unaltered. Neither the tracheal pressure nor the phasic phrenic electroneurogram responded to hypoxia after cutting the carotid sinus nerves. When the intermediate area of the VMS was cooled to 20 degrees C prior to ventilation with the hypoxic gases, both tracheal and phrenic responses were significantly diminished. While the cats were hyperventilated with 6% O2, cooling of the intermediate area significantly diminished tracheal pressure and phrenic nerve activity and both returned to the same levels after rewarming. Cooling of the intermediate area blunted tracheal and phrenic responses to carotid body stimulation by NaCN. However, the appearance of tracheal constriction prior to the onset of phasic phrenic activity may suggest that increased trachealis tone may occur independent of cyclical respiratory activity.

A role for the ventral surface of the medulla in regulation of nasal resistance.

Nasal resistance is known to be affected by changes in nasal blood volume and hence to depend on sympathetic discharge to nasal blood vessels. Structures located superficially near the ventrolateral surface of the medulla significantly affect respiratory and sympathetic activity and the tone of the trachea. To assess the importance of these structures on nasal patency, we measured transnasal pressure at a constant flow and examined the change in pressure produced by topically applied N-methyl-D-aspartic acid (NMDA). Experiments were performed in chloralose-anesthetized, paralyzed, and artificially ventilated cats. NMDA administered on the intermediate area of the ventral surface of the medulla decreased transnasal pressure and increased phrenic nerve activity. The response to NMDA could be diminished or abolished by application to the ventral medullary surface of the NMDA antagonist 2-amino-5-phosphonovalerate (2-APV) or the local anesthetic lidocaine. Carotid sinus denervation and posthypothalamic decerebration did not alter the nasal and phrenic nerve responses to NMDA; however, cervical sympathetic denervation decreased these responses, both in intact and in bilaterally adrenalectomized animals. Therefore, activation of NMDA receptors on structures near the ventral surface of the medulla increases tone in the nasal vasculature and leads to a response pattern that includes changes in not only phrenic nerve activity and blood pressure but also nasal patency.

Effect of N-methyl-D-aspartate applied to the ventral surface of the medulla on the trachea.

Structures located near the ventral surface of the medulla (VMS) affect both cardiovascular tone and respiratory activity. In addition cooling the intermediate area of the VMS blocks the increases in parasympathetic activity and tracheal tone resulting from ventilation with hypercapnic or hypoxic gas mixtures, or due to stimulation of mechanoreceptors within the lung. Since cooling the surface of the VMS may affect fibers of passage as well as cell bodies, we performed studies in which pledgets containing N-methyl-D-aspartic acid (NMDA), a synthetic excitatory amino acid, were applied to intermediate area of the VMS. The studies were performed in chloralose-anesthetized, artificially ventilated cats. Application of pledgets containing NMDA (10(-7) mol at 10(-3) M) caused increases in tracheal pressure and the onset of phasic phrenic activity, but application of 10(-8) mol at 10(-4) M of NMDA could produce tracheal constriction without the appearance of phasic phrenic activity. Applying to the entire VMS either 2-amino-5-phosphonovalerate (2-APV, 10(-6) M), a specific antagonist to NMDA, or lidocaine (2%), a local anesthetic, 60 s before the application of pledgets containing NMDA, prevented the increase in tracheal tone and phasic phrenic activity. Intravenous administration of atropine methyl nitrate 0.5 mg/kg, a cholinergic antagonist, blocked tracheal responses to local application of pledgets containing NMDA but did not affect the increase in phasic phrenic nerve activity. These findings suggest that when stimulated, neurons near the surface of the VMS in the vicinity of the intermediate area increase the activity of parasympathetic fibers to the airway.

Influence of the ventral surface of the medulla on tracheal responses to CO2.

These studies investigated the role of the intermediate area of the ventral surface of the medulla (VMS) in the tracheal constriction produced by hypercapnia. Experiments were performed in chloralose-anesthetized, paralyzed, and artificially ventilated cats. Airway responses were assessed from pressure changes in a bypassed segment of the rostral cervical trachea. Hyperoxic hypercapnia increased tracheal pressure and phrenic nerve activity. Intravenous atropine pretreatment or vagotomy abolished the changes in tracheal pressure without affecting phrenic nerve discharge. Rapid cooling of the intermediate area reversed the tracheal constriction produced by hypercapnia. Graded cooling produced a progressive reduction in the changes in maximal tracheal pressure and phrenic nerve discharge responses caused by hypercapnia. Cooling the intermediate area to 20 degrees C significantly elevated the CO2 thresholds of both responses. These findings demonstrate that structures near the intermediate area of the VMS play a role in the neural cholinergic responses of the tracheal segment to CO2. It is possible that neurons or fibers in intermediate area influence the motor nuclei innervating the trachea. Alternatively, airway tone may be linked to respiratory motor activity so that medullary interventions that influence respiratory motor activity also alter bronchomotor tone.

Influence of ventrolateral surface of medulla on reflex tracheal constriction.

To assess the role of structures located superficially near the ventrolateral surface of the medulla on the reflex constriction of tracheal smooth muscle that occurs when airway and pulmonary receptors are stimulated mechanically or chemically, experiments were conducted in alpha-chloralose-anesthetized, paralyzed, and artificially ventilated cats. Pressure changes within a bypassed segment of the trachea were used as an index of alterations smooth muscle tone. The effects of focal cooling of the intermediate areas or topically applied lidocaine on the ventral surface of the medulla on the response of the trachea to mechanical and chemical stimulation of airway receptors were examined. Atropine abolished tracheal constriction induced by mechanical stimulation of the carina or aerosolized histamine, showing that the responses were mediated over vagal pathways. Moderate cooling of the intermediate area (20 degrees C) or local application of lidocaine significantly decreased the tracheal constrictive response to mechanical activation of airway receptors. Furthermore, when the trachea was constricted by histamine, cooling of the intermediate area significantly diminished the increased tracheal tone, whereas rewarming restored tracheal tone to the previous level. These findings suggest that under the conditions of the experiments the ventral surface of the medulla plays an important role in constriction of the trachea by inputs from intrapulmonary receptors and in the modulation of parasympathetic outflow to airway smooth muscle.

Medullary effects of nicotine and GABA on tracheal smooth muscle tone.

Airway tone can be modulated centrally by the brain as well as by peripheral receptors. In part these changes in airway caliber seem to be secondary to changes in respiratory activity. Since structures near the ventrolateral medullary surface (VMS) can produce profound effects on respiration, it seems reasonable to believe that they might also be capable of modifying tracheal tone. In this study we examined the effects of two agents with respect to their action on tracheal tone: nicotine, a respiratory stimulant when applied to the VMS, and gamma aminobutyric acid (GABA), a respiratory depressant when similarly administered. In chloralose anesthetized, paralyzed, artificially ventilated cats, tracheal tone was assessed by measuring pressure changes in a rostral bypassed segment of the trachea, while phrenic nerve activity was examined simultaneously. Nicotine administered on the intermediate area of the VMS both before and after carotid sinus denervation increased phrenic activity and induced constriction of the rostral tracheal segment. The response to nicotine could be blocked by application of a nicotine antagonist, hexamethonium, or prior local administration of lidocaine to the VMS. Activation of GABAergic receptors by application of GABA on the intermediate area of the VMS markedly reduced respiratory activity and nearly abolished the increased tracheal tone produced by inhalation of 7% CO2 in O2. The effects of GABA were eliminated by the prior administration to the VMS of bicuculline, a GABA receptor antagonist. These results indicate that structures located on the ventral surface of the medulla which affect breathing may also play a significant role in the regulation of airway smooth muscle tone.