CPR1989 Control of Pig Reproduction III Gamete Physiology (4 abstracts)
*U.S. Department of Agriculture, Agricultural Research Service, Beltsville, Maryland 20705, USA; †University of Pennsylvania, School of Veterinary Medicine, Philadelphia, Pennsylvania 19104, USA; and &Dragger; University of Washington, Howard Hughes Medical Institute, Seattle. Washington 98195, USA
Eleven different regulatory sequences have been used for fusion genes transferred into pigs. Some of these regulatory sequences directed strong gene expression, but control over level of expression was inadequate. Other regulatory sequences directed weak expression, but imparted only brief spikes of induced expression. The predominant gene coding sequences transferred were for growth-related hormones.
Elevation of growth hormone (GH) in expressing transgenic pigs enhanced plasma concentrations of insulin-like growth factor-I (IGF-I), insulin, and glucose, improved feed efficiency about 15%, and markedly reduced subcutaneous fat compared to nontransgenic siblings. Growth rate was enhanced in some transgenic GH pigs but not in others, possibly due to dietary limits.
The ‘over-expression’ of GH was detrimental to the general health of most transgenic pigs. The most prevalent problems were lethargy, lameness, and gastric ulcers. Gilts that expressed foreign GH genes were anoestrous. Boars that expressed foreign GH genes lacked libido, but their semen was fertile when used by artificial insemination. Six different fusion genes have been transmitted from transgenic founders to progeny. Most of the transgenic pigs that produced progeny transmitted the fusion gene as an autosomal dominant trait to about half of their progeny. Regulatory sequences that will permit full control of gene expression must be developed before the full potential or gene transfer in pigs can be realized.
Keywords: pig; transgenic; growth; gene transfer; gene expression
© 1990 Journals of Reproduction & Fertility Ltd