Evidence for a chemiosmotic mechanism of ATP synthesis in methanogenic bacteria

Recent studies on methanogenesis from methanol and H₂ in Methanosarcina barkeri have provided the first proof of a chemiosmotic mechanism of ATP synthesis in methanogenic bacteria.     

Signatures of host–pathogen evolutionary conflict reveal MISTR—A conserved MItochondrial STress Response network

Host–pathogen conflicts leave genetic signatures in genes that are critical for host defense functions. Using these “molecular scars” as a guide to discover gene functions, we discovered a vertebrate-specific MItochondrial STress Response (MISTR) circuit. MISTR proteins are associated with electron transport chain (ETC) factors and activated by stress signals such as interferon gamma (IFNγ) and hypoxia. Upon stress, ultraconserved microRNAs (miRNAs) down-regulate MISTR1(NDUFA4) followed by replacement with paralogs MItochondrial STress Response AntiViral (MISTRAV) and/or MItochondrial STress Response Hypoxia (MISTRH). While cells lacking MISTR1(NDUFA4) are more sensitive to chemical and viral apoptotic triggers, cells lacking MISTRAV or expressing the squirrelpox virus-encoded vMISTRAV exhibit resistance to the same insults. Rapid evolution signatures across primate genomes for MISTR1(NDUFA4) and MISTRAV indicate recent and ongoing conflicts with pathogens. MISTR homologs are also found in plants, yeasts, a fish virus, and an algal virus indicating ancient origins and suggesting diverse means of altering mitochondrial function under stress. The discovery of MISTR circuitry highlights the use of evolution-guided studies to reveal fundamental biological processes.

Host-pathogen conflicts leave genetic signatures in genes that are critical for host defense functions. This study uses these “molecular scars” as a guide to identify a vertebrate-specific mitochondrial stress response circuit that interacts with the electron transport chain and is activated by stress signals such as interferon-gamma and hypoxia.     

6-MBOA affects testis size, but not delayed-type hypersensitivity, in white-footed mice (Peromyscus leucopus).

Many rodents use day length to time reproduction to occur when resources are abundant, but some species also use supplementary environmental cues. One supplementary cue is the plant-derived compound, 6-methoxy-2-benzoxazolinone (6-MBOA). Most rodents grow their gonads in response to 6-MBOA in their diets, but it is presently unknown whether they also use 6-MBOA to adjust other aspects of physiology, specifically their immune systems. 6-MBOA is structurally similar to melatonin, and seasonal changes in rodent immune activities are often mediated by melatonin. We therefore predicted that white-footed mice (Peromyscus leucopus), which breed seasonally and are reproductively sensitive to melatonin, would adjust their immune systems when fed 6-MBOA. 6-MBOA treated mice in long day lengths regressed their testes to a greater extent than mice fed a standard diet, or mice kept in short day lengths and fed 6-MBOA or a standard diet. One type of immune activity (delayed-type hypersensitivity) was not affected by 6-MBOA, however, although responses were greater in short versus long day mice. In sum, P. leucopus responded reproductively to 6-MBOA, although differently than other species; immune activity was unaffected. Other aspects of the immune system, especially in herbivorous rodents, may be affected by 6-MBOA and thus warrant further study.     

Acetogenesis and ATP synthesis in Acetobacterium itwoodii are coupled via a transmembrane primary sodium ion gradient

Abstract In cell suspensions of Acetobacterium woodii the acetyl-CoA pathway is coupled to net ATP formation. Acetate formation as well as ATP synthesis and the generation of a transmembrane sodium ion gradient are not inhibited by protonophores but by sodium ionophores. Acetogenesis from CO or formaldehyde + CO as catalyzed by inverted vesicles is coupled to sodium ion uptake. Both processes are not inhibited by protonophores but by sodium ionophores. These experiments are in accordance with the presence of a primary sodium ion pump connected to the acetyl-CoA pathway which enables the cells to synthesize net ATP by means of a Δμ _Na+ in concert with a Na⁺-translocating ATPase.