Development, validation, and application of the ribosome separation and reconstitution system for protein translation in vitro

Stress-induced molecular damage to ribosomes can impact protein synthesis in cells, but cell-based assays do not provide a clear way to distinguish the effects of ribosome damage from stress responses and damage to other parts of the translation machinery. Here we describe a detailed protocol for the separation of yeast ribosomes from other translational machinery constituents, followed by reconstitution of the translation mixture in vitro. This technique, which we refer to as Ribosome Separation and Reconstitution (RSR), allows chemical modifications of yeast ribosomes without compromising other key translational components. In addition to the characterization of stress-induced ribosome damage, RSR can be applied to a broad range of experimental problems in studies of yeast translation.

An efficient method for the physical mapping of transgenes in barley using in situ hybridization

The genetic transformation of crops by particle bombardment and Agrobacterium tumefaciens systems have the potential to complement conventional plant breeding programmes. However, before deployment, transgenic plants need to be characterized in detail, and physical mapping is an integral part of this process. Therefore, it is important to have a highly efficient method for transgene detection by fluorescence in situ hybridization (FISH). This study describes a new approach, which provides efficient control of probe length and labelling, both of which play an important role in in situ hybridization of transgenes. The approach is based on reducing the size of the plasmid prior to labelling by nick translation, rather than using the whole or linearized plasmid, or varying the amounts of DNaseI in the nick translation mixture. This provided much more efficient labelling of the probe, which yielded optimal hybridization, minimal fluorescent background, and accurate physical location of the transgene.Key words: barley, transformation, FISH, transgene detection, probe design.

Import of rat liver mitochondrial transhydrogenase

The biosynthesis of pyridine dinucleotide transhydrogenase has been studied in isolated rat hepatocytes and in a rabbit reticulocyte-lysate translation system supplemented with either intact isolated rat liver mitochondria or the soluble matrix fraction from isolated mitochondria. In intact hepatocytes, the transhydrogenase precursor was short-lived in the cytosol and was efficiently imported into the membranous fraction. When the cell-free translation mixture was incubated with intact mitochondria, the transhydrogenase precursor was processed to the mature form, to an extent that depended on the amount of added mitochondria. Incubation of the translation mixture with the soluble mitochondria matrix fraction converted the precursor to a mature-sized protein with 75% efficiency, this being blocked by various proteinase inhibitors such as EDTA, 1,10-phenanthroline and leupeptin.

Biosynthesis of intestinal microvillar proteins. Translational evidence in vitro that aminopeptidase N is synthesized as a Mr-115000 polypeptide

A crude RNA fraction, prepared from pig small intestine, was found to be more efficient than a fraction enriched in polyadenylated RNA in directing translation of polypeptides with Mr greater than 100000 in a rabbit reticulocyte lysate system. Aminopeptidase N (EC 3.4.11.2) synthesized in vitro was immunopurified from the translation mixture and analysed by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. It was found to have an apparent Mr of 115000 regardless of whether the translation was performed in the absence or presence of proteinase inhibitors. This result contradicts the possibility of aminopeptidase N being synthesized as a large single-chain precursor polypeptide.