Effect of high-fat diet on secreted milk transcriptome in midlactation mice.

High-fat diet (HFD) during lactation alters milk composition and is associated with development of metabolic diseases in the offspring. We hypothesized that HFD affects milk microRNA (miRNA) and mRNA content, which potentially impact offspring development. Our objective was to determine the effect of maternal HFD on secreted milk transcriptome. To meet this objective, 4 wk old female ICR mice were divided into two treatments: control diet containing 10% kcal fat and HFD containing 60% kcal fat. After 4 wk on CD or HFD, mice were bred while continuously fed the same diets. On postnatal day 2 (P2), litters were normalized to 10 pups, and half the pups in each litter were cross-fostered between treatments. Milk was collected from dams on P10 and P12. Total RNA was isolated from milk fat fraction of P10 samples and used for mRNA-Seq and small RNA-Seq. P12 milk was used to determine macronutrient composition. After 4 wk of prepregnancy feeding HFD mice weighed significantly more than did the control mice. Lactose and fat concentration were significantly ( P < 0.05) higher in milk of HFD dams. Pup weight was significantly greater ( P < 0.05) in groups suckled by HFD vs. control dams. There were 25 miRNA and over 1,500 mRNA differentially expressed (DE) in milk of HFD vs. control dams. DE mRNA and target genes of DE miRNA enriched categories that were primarily related to multicellular organismal development. Maternal HFD impacts mRNA and miRNA content of milk, if bioactive nucleic acids are absorbed by neonate differences may affect development.

Insertional mutagenesis in Coprinus cinereus: use of a dominant selectable marker to generate tagged, sporulation-defective mutants.

We have constructed a dominant selectable marker, PHT1, for transformation of the basidiomycete Coprinus cinereus. PHT1 consists of a bacterial hygromycin B resistance gene fused to the promoter and terminator regions of the C. cinereus beta-tubulin gene. We found in transformation experiments that PHT1 confers hygromycin B resistance to all strains of C. cinereus tested, that it integrates without apparent bias into the genome, and that it is stable through meiotic crosses. We used a plasmid containing this marker, pPHT1, for restriction enzyme-mediated integration (REMI) and found that this technique could increase transformation efficiencies more than seven-fold. In REMI experiments using KpnI, the integrated DNA was flanked by intact KpnI sites in 53% of the cases examined, single-copy insertions represented 60% of the integration events, and most multicopy insertions were oriented head-to-tail. A screen of REMI-generated transformants yielded sporulation-defective mutants at a frequency of 1.2%. Genetic analysis showed that in six of nine mutants examined, the defect in spore formation is most likely a direct result of the pPHT1 insertion, and in three of these mutants a single pPHT1 locus was shown to cosegregate with the sporulation defect. We used semi-random PCR to isolate the genomic DNA adjacent to one pPHT1 insertion in a sporulation-defective mutant and found that we had disrupted the C. cinereus spo11 gene. Thus, REMI, in combination with pPHT1, is a powerful tool for the dissection of the meiotic process in C. cinereus.