Effects of varying gene targeting parameters on processing of recombination intermediates by ERCC1-XPF.

The ERCC1-XPF structure-specific endonuclease is necessary for correct processing of homologous recombination intermediates requiring the removal of end-blocking nonhomologies. We previously showed that targeting the endogenous CHO APRT locus with plasmids designed to generate such intermediates revealed defective recombination phenotypes in ERCC1 deficient cells, including suppression of targeted insertion and vector correction recombinants and the generation of a novel class of aberrant recombinants through a deletogenic mechanism. In the present study, we examined some of the mechanistic features of ERCC1-XPF in processing recombination intermediates by varying gene targeting parameters. These included altering the distance between the double-strand break (DSB) in the targeting vector and the inactivating mutation in the APRT target gene, and changing the position of the target gene mutation relative to the DSB to result in target mutations that were either upstream or downstream from the DSB. Increasing the distance from the DSB in the targeting vector to the chromosomal target gene mutation resulted in an ERCC1 dependent decrease in the efficiency of gene targeting from intermediates presenting lengthy end-blocking nonhomologies. This decrease was accompanied by a shift in the distribution of recombinant classes away from target gene conversions to targeted insertions in both wild-type and ERCC1 deficient cells, and a dramatic increase in the proportion of aberrant recombinants in ERCC1 deficient cells. Changing the position of the target gene mutation relative to the DSB in the plasmid also altered the distribution of targeted insertion subclasses recovered in wild-type cells, consistent with two-ended strand invasion followed by resolution into crossover-type products and vector integration. Our results confirm expectations from studies of Rad10-Rad1 in budding yeast that ERCC1-XPF activity affects conversion tract length, and provide evidence for the mechanism of generation of the novel, aberrant recombinant class first described in our previous study.

Postprandial induction of chaperone gene expression is rapid in mice.

Molecular chaperones assist in the biosynthesis and processing of proteins. Most chaperones are induced by physiological stresses. We have shown that dietary energy restriction decreases the mRNA and protein levels of many endoplasmic reticulum chaperones in the livers of mice. Here, we have investigated the response of chaperone mRNA to feeding. Control and 50% energy-restricted C3B10RF1 mice were deprived of food for 24 h, fed, and killed 0, 1.5, 5 or 12 h after feeding. Chaperone mRNAs were strongly induced as early as 1.5 h after feeding in control and energy-restricted mice. The integrated levels of these mRNA over 24 h were significantly lower in energy-restricted mice. The mRNA response to energy intake was mirrored over the course of days in the level of chaperone protein. A similar but smaller response to feeding was found in kidney and muscle. Puromycin and cycloheximide failed to inhibit the feeding response, suggesting that feeding releases chaperone expression from an unstable inhibitor. Studies with dibutyryl-cAMP- and glucagon-supplemented, normal and streptozotocin-diabetic mice suggest that glucagon and insulin may be mediators of the feeding response. Adrenalectomy enhanced the feeding induction, but dexamethasone administration had no effect. Thus, postprandial changes in insulin and glucagon may link chaperone gene expression to feeding, possibly in several tissues including liver.