Heritable protein variants induced by exposure to ethylnitrosourea: heritability, subcellular location, and tissue distribution

Protein mutations revealed by two-dimensional electrophoresis

High-resolution two-dimensional electrophoresis (2DE) can resolve many hundreds of proteins present in complex mixtures depending on the method of detection. These proteins can be characterised qualitatively, with respect to their electrophoretic mobilities (i.e. charge and apparent molecular mass) and quantitatively, using densitometry, to determine their amounts. There has been a widespread application of 2DE in the analysis and characterisation of protein mutations for a range of organisms. This review presents examples of the use of 2DE to study naturally occurring protein mutations and polymorphisms as well as the characterisation of induced protein mutations in prokaryotes and eukaryotes. Examples are presented to illustrate the use of 2DE to detect mutations affecting the electrophoretic mobility and biosynthesis of individual proteins as well as mutations leading to global alterations in cellular protein synthesis. The advantages and disadvantages of 2DE in the detection of protein mutations are discussed.

Altered protein expression detected in the F1 offspring of male mice exposed to fission neutrons

Liver protein expression in F1 offspring arising from spermatogonia exposed to 60 cGy of fission spectrum neutrons from the JANUS reactor was compared to that in offspring from unexposed spermatogonia by using two-dimensional electrophoresis (2DE). Approximately 100 protein spots in 2DE patterns from 167 control offspring and 530 offspring from irradiated sires were monitored for quantitative decreases of 50%, indicative of mutation events causing the loss of one normal copy of a structural gene. Reproducible abnormalities were found only in 3 patterns, all from the offspring of neutron-irradiated sires. Two of the three patterns were from littermates (brother and sister) and both showed an approximately 70% decrease in the amount of liver protein MSN188. The third pattern was from a male mouse sired by a different male and showed an approximately 50% decrease in the abundance of protein MSN94. The decreased abundance of MSN188 and MSN94 was assumed to be due to mutation events referred to as NEUT1 and NEUT2, respectively. Sibling crosses between the 2 mice showing the NEUT1 trait produced offspring with control, decreased and undetectable levels of MSN188 in a ratio of 0.25:0.5:0.25. Test crosses between the F1 offspring expressing the NEUT2 trait back to C57BL/6JANL mice produced offspring expressing normal or decreased amounts of MSN94 in a ratio of 0.5:0.5. Inbreeding of individuals expressing decreased amounts of MSN94 produced mice expressing control, decreased amounts, or no detectable amount of that protein in a ratio of 0.25:0.5:0.25. These results indicate that the decreased abundance of MSN188 or MSN94 originally detected in the F1 offspring is due to a genetically transmissible event. Unlike the heritable protein changes observed previously in the F1 offspring of sires exposed to N-ethyl-N-nitrosourea in which a protein variant was produced, both the NEUT1 and NEUT2 mutation events appear to prevent the production of any protein product. These 2 mutations may thus represent mutation lesions other than point mutations (e.g., deletions or translocations) detectable as quantitative changes in protein expression in the F1 generation.

Mouse liver protein database: a catalog of proteins detected by two-dimensional gel electrophoresis

Alterations in the abundance or structure of mouse liver proteins are being studied using two-dimensional gel electrophoresis (2-DE) to build a database of protein changes correlating with exposure to ionizing radiation or toxic chemicals. Thus far, studies have included the analysis of proteins from the offspring of exposed parents or from the exposed individuals themselves. In order to characterize and identify proteins found altered by such exposures, sex- and strain-related differences in protein patterns have been analyzed, and the subcellular locations of a large portion of the mapped proteins have been determined. As part of these studies, data are collected and stored using a variety of computer hardware and software tools that allow the accumulation of information on the origin of samples, gel identification, experiment description, and protein similarities and differences. This accumulation of information constitutes the mouse liver protein database. Relational database software is used to tie the different facets of the database together so that the results of a variety of experiments can be compared and interrelated. The database optimizes the information obtained from 2-DE gel sets by allowing use of the data for many purposes, including monitoring of gel resolution to ensure the collection of high quality data and correlation of protein effects induced by different agents. This first edition of the Argonne National Laboratory mouse liver protein database lays the foundation for future work and communication that should elucidate the significance of observed protein effects as possible markers of exposure to toxic agents.

Linkage of neutrophil response to a mutagen gene (Nrm-1) to the agouti locus in the rat

The ACI or BDIV rats responded with decreased or increased neutrophil levels in blood after the N-methyl-N-nitrosourea (MNU) administration. The F1 hybrids had decreased neutrophil counts, and the BDIV x (BDIV x ACI)F1 backcross offspring showed two phenotypes. The sex of the rats and the neutrophil response to MNU assorted independently. The results indicated that the neutrophil response to MNU was regulated by autosomal gene Nrm-1 with two alleles. The Nrm-1d regulates the decrease and the Nrm-1i regulates the increase of neutrophils in blood after the MNU administration. The results were confirmed by the SKUMIX computer program. We found that the Nrm-1 gene was linked to the agouti locus (chi-square = 10.3, P less than 0.001). The map distance between two genes was 33 +/- 5 cM. The Nrm-1 gene thus resides on the linkage group IV of the rat.