Drosophila Nociceptors Mediate Larval Aversion to Dry Surface Environments Utilizing Both the Painless TRP Channel and the DEG/ENaC Subunit, PPK1

A subset of sensory neurons embedded within the Drosophila larval body wall have been characterized as high-threshold polymodal nociceptors capable of responding to noxious heat and noxious mechanical stimulation. They are also sensitized by UV-induced tissue damage leading to both thermal hyperalgesia and allodynia very similar to that observed in vertebrate nociceptors. We show that the class IV multiple-dendritic(mdIV) nociceptors are also required for a normal larval aversion to locomotion on to a dry surface environment. Drosophila melanogaster larvae are acutely susceptible to desiccation displaying a strong aversion to locomotion on dry surfaces severely limiting the distance of movement away from a moist food source. Transgenic inactivation of mdIV nociceptor neurons resulted in larvae moving inappropriately into regions of low humidity at the top of the vial reflected as an increased overall pupation height and larval desiccation. This larval lethal desiccation phenotype was not observed in wild-type controls and was completely suppressed by growth in conditions of high humidity. Transgenic hyperactivation of mdIV nociceptors caused a reciprocal hypersensitivity to dry surfaces resulting in drastically decreased pupation height but did not induce the writhing nocifensive response previously associated with mdIV nociceptor activation by noxious heat or harsh mechanical stimuli. Larvae carrying mutations in either the Drosophila TRP channel, Painless, or the degenerin/epithelial sodium channel subunit Pickpocket1(PPK1), both expressed in mdIV nociceptors, showed the same inappropriate increased pupation height and lethal desiccation observed with mdIV nociceptor inactivation. Larval aversion to dry surfaces appears to utilize the same or overlapping sensory transduction pathways activated by noxious heat and harsh mechanical stimulation but with strikingly different sensitivities and disparate physiological responses

Changes in energy metabolism of Mycobacterium tuberculosis in mouse lung and under in vitro conditions affecting aerobic respiration

Transcription profiling of genes encoding components of the respiratory chain and the ATP synthesizing apparatus of Mycobacterium tuberculosis was conducted in vivo in the infected mouse lung, and in vitro in bacterial cultures subjected to gradual oxygen depletion and to nitric oxide treatment. Transcript levels changed dramatically as infection progressed from bacterial exponential multiplication (acute infection) to cessation of bacterial growth (chronic infection) in response to host immunity. The proton-pumping type-I NADH dehydrogenase and the aa3-type cytochrome c oxidase were strongly down-regulated. Concurrently, the less energy-efficient cytochrome bd oxidase was transiently up-regulated. The nitrate transporter NarK2 was also up-regulated, indicative of increased nitrate respiration. The reduced efficiency of the respiratory chain was accompanied by decreased expression of ATP synthesis genes. Thus, adaptation of M. tuberculosis to host immunity involves three successive respiratory states leading to decreased energy production. Decreased bacterial counts in mice infected with a cydC mutant (defective in the cytochrome bd oxidase-associated transporter) at the transition to chronic infection provided initial evidence that the bd oxidase pathway is required for M. tuberculosis adaptation to host immunity. In vitro, NO treatment and hypoxia caused a switch from transcription of type I to type II NADH dehydrogenase. Moreover, cytochrome bd oxidase expression increased, but cytochrome c oxidase expression decreased slightly (nitric oxide) or not at all (hypoxia). These specific differences in respiratory metabolism during M. tuberculosis growth arrest in vitro and in vivo will guide manipulation of in vitro conditions to model bacterial adaptation to host immunity