Targeted microRNA expression in dairy cattle directs production of ß-lactoglobulin-free, high-casein milk.

Milk from dairy cows contains the protein ß-lactoglobulin (BLG), which is not present in human milk. As it is a major milk allergen, we wished to decrease BLG levels in milk by RNAi. In vitro screening of 10 microRNAs (miRNAs), either individually or in tandem combinations, identified several that achieved as much as a 98% knockdown of BLG. One tandem construct was expressed in the mammary gland of an ovine BLG-expressing mouse model, resulting in 96% knockdown of ovine BLG in milk. Following this in vivo validation, we produced a transgenic calf, engineered to express these tandem miRNAs. Analysis of hormonally induced milk from this calf demonstrated absence of BLG and a concurrent increase of all casein milk proteins. The findings demonstrate miRNA-mediated depletion of an allergenic milk protein in cattle and validate targeted miRNA expression as an effective strategy to alter milk composition and other livestock traits.

Reporter system for the detection of in vivo gene conversion: changing colors from blue to green using GFP variants.

We have devised a system for the study of in vivo gene correction based on the detection of color variants of the green fluorescent protein (GFP) from the jellyfish Aequorea victoria. The intensity and spectra of the fluorescence emitted by the blue (BFP) and red-shifted (EGFP) variants of GFP differ from each other. We modified one nucleotide from an EGFP expression vector that we predicted would yield a blue variant (TAC-CAC, Tyr(66)-His(66)). Cells that were either transiently or stably transfected with the reporter system were used to test the functionality and feasibility of the detection of in vivo gene correction. A thio-protected single-stranded oligonucleotide designed to convert the genotype of the blue variant to that of the EGFP variant by the correction of a single base pair was delivered to the reporter cells using a variety of methodologies and strategies.Conversion events were easily observed using fluorescent microscopy because of the enhanced emission intensity and different spectra of the EGFP variant.

Protamine sulfate protects exogenous DNA against nuclease degradation but is unable to improve the efficiency of bovine sperm mediated transgenesis.

The present study investigated whether protamine sulfate can be used to improve the efficiency of bovine sperm mediated transgenesis (SMT) by protecting the plasmid pCX-EGFP against nuclease activity. A high proportion (31%) of bovine spermatozoa transfected with the plasmid pCX-EGFP maintain their motility. Using an in vitro assay, protamine sulfate protected the plasmid against degradation by DNase I. However, upon transfecting spermatozoa, the plasmid remained intact regardless of whether it was complexed to protamine sulfate. When in vitro fertilisation (IVF) was undertaken using transfected sperm, 14.6 and 10.2% of blastocysts derived from pCX-EGFP only and pCX-EGFP-protamine transfected sperm, respectively, were PCR positive for the plasmid. In conclusion, using spermatozoa transfected with either pCX-EGFP or pCX-EGFP-protamine complexes, produced PCR positive blastocysts after SMT. However, the use of protamine sulfate does not improve the efficiency of SMT suggesting that factors other than nuclease activity could be limiting.