[
Mech Ageing Dev,
2002]
Accurate measures of physiological and metabolic condition could provide more insight into how longevity genes and signalling pathways affect global metabolic activity and life span. The present study is essentially a methodological treatise in which we describe and evaluate a number of methods to assess changes of metabolic activity in ageing Caenorhabditis elegans. Oxygen consumption and CO(2) production rate assays, and measurement of the heat output by microcalorimetry are performed using live worms. For other assays, frozen (-75 degrees C) samples can be used. A lucigenin-mediated light production assay provides information on the metabolic capacity (scope for metabolic activity) of the worms just before freezing. Assaying ATP and ADP levels provides a measure of the instantly available energy. The XTT assay measures the activity of enzymes that can reduce XTT. Blue fluorescence emitted at 420-470 nm is a potentially useful biomarker of the rate of ageing. A protein quantification protocol for normalising all data for quantitative comparisons is presented. We illustrate how these methods can validate or disprove models of gene action inferred from molecular identification.
[
Exp Cell Res,
2014]
One of the most important ways in which animal species vary is in their size. Individuals of the largest animal ever thought to have lived, the blue whale (Balaenoptera musculus), can reach a weight of 190 t and a length of over 30 m. At the other extreme, among the smallest multicellular animals are males of the parasitic wasp, Dicopomorpha echmepterygis, which even as adults are just 140 m in length. In terms of volume, these species differ by more than 14 orders of magnitude. Since size has such profound effects on an organism's ecology, anatomy and physiology, an important task for evolutionary biology and ecology is to account for why organisms grow to their characteristic sizes. Equally, a full description of an organism's development must include an explanation of how its growth and body size are regulated. Here I review research on how these processes are controlled in the nematode, Caenorhabditis elegans. Analyses of small and long mutants have revealed that in the worm, DBL-1, a ligand in the TGF superfamily family, promotes growth in a dose-dependent manner. DBL-1 signaling affects body size by stimulating the growth of syncytial hypodermal cells rather than controlling cell division. Signals from chemosensory neurons and from the gonad also modulate body size, in part, independently of DBL-1-mediated signaling. Organismal size and morphology is heavily influenced by the cuticle, which acts as the exoskeleton. Finally, I summarize research on several genes that appear to regulate body size by cell autonomously regulating cell growth throughout the worm.