ABSTRACT
Limiting calories or specific nutrients without malnutrition, otherwise known as dietary restriction (DR), has been shown to extend lifespan and reduce reproduction across a broad range of taxa. Our recent findings in Drosophila melanogaster show that supplementing flies on macronutrient-rich diets with additional cholesterol can extend lifespan to the same extent as DR, while also sustaining high egg production. Thus, DR may be beneficial for lifespan because it reduces egg production which in turn reduces the mother's demand for sterols, thus supporting longer lifespan. It is also possible that mothers live longer and lay more eggs on high sterol diets because the diet triggers enhanced somatic maintenance and promotes egg production, but at the cost of diminished egg quality. To test this, we measured the viability of eggs and development of offspring from mothers fed either cholesterol-sufficient or cholesterol-limiting diets. We found that even when the mother's diet was completely devoid of cholesterol, viable egg production persisted for â¼10 days. Furthermore, we show that sterol-supplemented flies with long lives lay eggs that have high viability and the same developmental potential as those laid by shorter lived mothers on sterol limiting diets. These findings suggest that offspring viability is not a hidden cost of lifespan extension seen in response to dietary sterol supplementation.
Subject(s)
Drosophila melanogaster , Ovum , Female , Animals , Drosophila melanogaster/physiology , Longevity , Sterols , Diet , CholesterolABSTRACT
Bacterial RNA polymerases (RNAPs) are capable of producing full-length transcripts in the absence of additional factors using in vitro assays. However, in vivo RNAP can become stalled during the elongation phase of transcription due to the presence of various sequence motifs. Subsequently, a host of elongation factors are required to modulate the activity of RNAP. NusA, the most intensively studied elongation factor, plays a role in increasing RNAP pausing and termination. Conversely, it is also important in transcription of rRNA where it functions as an anti-termination factor, helping to ensure only full-length transcripts are produced. Here we show that NusA is closely associated with RNAP within the bacterial nucleoid and that it is preferentially recruited to sites of rRNA synthesis. In vivo and in vitro analyses indicate this results in a change in stoichiometry of NusA:RNAP from 1:1 to approximately 2:1 at the subcellular sites of rRNA synthesis. A model is presented showing how the ratio of NusA:RNAP could affect the activity of the elongation complex so that it functions as an anti-terminator complex during rRNA synthesis.