Porcine somatotropin alters body composition and the distribution of fat and lean tissue in the finisher gilt
D. Suster A B , B. J. Leury B , R. Hewitt B C , D. J. Kerton A and F. R. Dunshea A B DA Department of Primary Industries, 600 Sneydes Road, Werribee, Vic. 3030, Australia.
B The University of Melbourne, Melbourne, Vic. 3010, Australia.
C PIC Australia, PO Box 39, Grong Grong, NSW 2652, Australia.
D Corresponding author. Email: Frank.Dunshea@dpi.vic.gov.au
Australian Journal of Experimental Agriculture 45(6) 683-690 https://doi.org/10.1071/EA04135
Submitted: 21 July 2004 Accepted: 11 October 2004 Published: 29 June 2005
Abstract
The present study was designed to determine whether porcine somatotropin (pST) reduces whole animal and belly fat using dual energy X-ray absorptiometry and manual dissection. The study utilised 24 Large White × Landrace gilts selected at 16 weeks of age with an approximate liveweight of 80 kg and housed in individual pens. Gilts were stratified on liveweight into 8 blocks and 1 pig from each block was assigned to either 0, 5 or 10 mg per day of pST. Pigs were fed ad libitum a wheat-based diet containing 200 g crude protein, 10.2 g available lysine and 14.6 MJ DE/kg, to ensure that responses to pST were expressed. Feed intake and liveweight were measured on a weekly basis. An Hologic QDR4500A dual energy X-ray absorptiometer was used to determine lean, fat and ash composition of pigs initially and again 4 weeks later at the end of the experiment. After slaughter, the composition of the whole half carcass as well as the shoulder, ham, belly and loin primal cuts was determined with dual energy X-ray absorptiometry and verified with manual dissection. Daily pST treatment decreased feed intake (3440, 2710 and 2537 g/day for 0, 5 or 10 mg pST per day, respectively; P<0.001) and decreased feed conversion ratio (2.95, 2.18 and 2.03 g/g; P<0.001) even though there was no significant effect on daily gain. Pigs treated with pST deposited more lean tissue (620, 839 and 873 g/day; P<0.05) and less fat (384, 218 and 176 g/day; P<0.001) than control animals, but there was no effect of pST on ash deposition. As a consequence, pigs treated with 5 and 10 mg pST/day contained 5 and 9 kg less dissectible fat than control gilts, respectively. A dose dependent decrease in belly, loin, ham and shoulder fat was also observed, although the decrease in belly fat was more pronounced than for the whole carcass and other primal cuts. Overall, pST treatment has the potential to decrease carcass and especially belly fat in pigs and increase consumer acceptance of pork in markets that place a premium on carcass fat and lean yield in the belly region. The results determined with dual energy X-ray absorptiometry were confirmed by manual dissection.
Additional keywords: DXA, lean tissue, belly, primal cuts, growth
Acknowledgments
The first author thanks Australian Pork Limited (APL) for the provision of a post-graduate student stipend.
Berman DM,
Nicklas BJ,
Rogus EM,
Dennis KE, Goldberg AP
(1998) Regional differences in adrenoceptor binding and fat cell lipolysis in obese, postmenopausal women. Metabolism: Clinical and Experimental 47, 467–473.
Boyd RD,
Bauman DE,
Beermann DH,
DeNeergaard AF,
Souza L, Butler WR
(1986) Titration of the porcine growth hormone dose which maximizes growth performance and lean deposition in swine. Journal of Animal Science 64(Suppl. 1), 218.
Budd TJ,
Atkinson JL,
Buttery PJ,
Salter AM, Wiseman J
(1994) Effect of insulin and isoproterenol on lipid metabolism in porcine adipose tissue from different depots. Comparative Biochemistry and Physiology. Pharmacology, Toxicology and Endocrinology 108, 137–143.
| Crossref | GoogleScholarGoogle Scholar |
Campbell RG,
Johnson RJ,
Taverner MR, King RH
(1991) Interrelationships between exogenous porcine somatotropin (PST) administration and dietary protein and energy intake on protein deposition capacity and energy metabolism of pigs. Journal of Animal Science 69, 1522–1531.
Campbell RG,
Steele NC,
Caperna TJ,
McMurtry JP,
Solomon MB, Mitchell AD
(1988) Interrelationships between energy intake and endogenous porcine growth hormone administration on the performance, body composition and protein and energy metabolism of growing pigs weighing 25 to 55 kilograms liveweight. Journal of Animal Science 66, 1643–1655.
D’Souza DN,
Pethick DW,
Dunshea FR,
Suster D,
Pluske JR, Mullan BP
(2004) The pattern of fat and lean muscle tissue deposition differs in the different pork, primal cuts of female pigs during the finisher growth phase. Livestock Production Science 91, 1–8.
Dunshea FR
(1993) Effect of metabolism modifiers on lipid metabolism in the pig. Journal of Animal Science 71, 1966–1977.
Dunshea FR
(2002) Metabolic and production responses to different porcine somatotropin injection regimes in pigs. Australian Journal of Agricultural Research 53, 785–791.
| Crossref | GoogleScholarGoogle Scholar |
Dunshea FR
(2005) Sex and porcine somatotropin impact on variation in growth performance and back fat thickness. Australian Journal of Experimental Agriculture 45, 677–682.
Dunshea FR,
Cox ML,
Borg MR,
Sillence MN, Harris DR
(2002) Porcine somatotropin (pST) administered using a commercial delivery system improves growth performance of rapidly-growing, group-housed finisher pigs. Australian Journal of Agricultural Research 53, 287–293.
| Crossref | GoogleScholarGoogle Scholar |
Dunshea FR,
Harris DM,
Bauman DE,
Boyd RD, Bell AW
(1992a) Temporal response of blood glucose and plasma metabolite and hormone concentrations during somatotropin treatment of growing pigs. Journal of Animal Science 70, 123–131.
Dunshea FR,
Harris DM,
Bauman DE,
Boyd RD, Bell AW
(1992b) Effect of porcine somatotropin on in vivo glucose kinetics and lipogenesis in growing pigs. Journal of Animal Science 70, 141–151.
Etherton TD,
Wiggins JP,
Evock CM,
Chung CS,
Rebhun JF,
Walton PE, Steele NC
(1987) Stimulation of pig growth performance by porcine growth hormone: determination of the dose–response relationship. Journal of Animal Science 64, 433–443.
Goodband RD,
Hines RH,
Nelssen JL,
Kropf DH, Schricker BR
(1993a) Porcine somatotropin and dietary lysine influence bone mineralization and mechanical properties of bones in finishing swine. Journal of Animal Science 71, 673–678.
Goodband RD,
Nelssen JL,
Hines RH,
Kropf DH,
Stoner GR,
Thaler RC,
Lewis AJ, Schricker BR
(1993b) Interrelationships between porcine somatotropin and dietary lysine on growth performance and carcass characteristics of finishing swine. Journal of Animal Science 71, 663–672.
Harris DM,
Dunshea FR,
Bauman DE,
Boyd RD,
Wang S-Y,
Johnson PA, Clarke SD
(1993) Effect of in vivo somatotropin treatment of growing pigs on adipose tissue lipogenesis. Journal of Animal Science 71, 3293–3300.
King RH,
Campbell RG,
Smits RJ,
Morley WC,
Ronnfeldt K,
Butler K, Dunshea FR
(2000) Interrelationships between dietary lysine, sex, and porcine somatotropin administration on growth performance and protein deposition in pigs between 80 and 120 kg live weight. Journal of Animal Science 78, 2639–2651.
Kelly TL,
Berger N, Richardson TL
(1998) DXA body composition: theory and practice. Applied Radiation And Isotopes: Including Data, Instrumentation And Methods For Use In Agriculture, Industry And Medicine 49, 511–513.
Lee KC,
Azain MJ,
Hausman DB, Ramsay TG
(2000) Somatotropin and adipose tissue metabolism: substrate and temporal effects. Journal of Animal Science 78, 1236–1246.
McCauley I,
Watt M,
Suster D,
Kerton DJ,
Oliver WT,
Harrell RJ, Dunshea FR
(2003) An immunocastration vaccine (Improvac) and porcine somatotropin (Reporcin) have synergistic effects upon growth performance in both boars and gilts. Australian Journal of Agricultural Research 54, 11–20.
| Crossref | GoogleScholarGoogle Scholar |
Mitchell AD,
Scholz AM,
Pursel VG, Evock-Clover CM
(1998) Composition analysis of pork carcasses by dual-energy x-ray absorptiometry. Journal of Animal Science 76, 2104–2114.
Oliver WT,
McCauley I,
Harrell RJ,
Suster D, Dunshea FR
(2003) A GnRF vaccine (Improvac) and porcine somatotropin have synergistic and additive effects on growth performance in group-housed boars and gilts, respectively. Journal of Animal Science 81, 1959–1966.
Ostrowska E,
Muralitharan M,
Cross RF,
Bauman DE, Dunshea FR
(1999) Dietary conjugated linoleic acid increases lean tissue and decreases fat deposition in the growing pig. The Journal of Nutrition 129, 2037–2042.
Shields RG,
Mahan DC, Graham PL
(1983) Changes in swine body composition from birth to 145 kg. Journal of Animal Science 57, 43–54.
Suster D,
Leury BJ,
Hofmeyr CD, Dunshea FR
(2004a) The accuracy of dual energy X-ray absorptiometry (DXA), weight and P2 back fat to predict half-carcass and primal-cut composition in pigs within and across research experiments. Australian Journal of Agricultural Research 55, 973–982.
| Crossref | GoogleScholarGoogle Scholar |
Suster D,
Leury BJ,
King RH,
Mottram M, Dunshea FR
(2004b) Interrelationships between porcine somatotropin (pST), betaine and energy level on body composition and tissue distribution of finisher boars. Australian Journal of Agricultural Research 55, 983–990.
| Crossref | GoogleScholarGoogle Scholar |
Suster D,
Leury BJ,
Ostrowska E,
Butler KL,
Kerton DJ,
Wark JD, Dunshea FR
(2003) Accuracy of dual energy X-ray absorptiometry (DXA), weight and P2 back fat to predict whole body and carcass composition in pigs within and across experiments. Livestock Production Science 84, 231–242.
| Crossref | GoogleScholarGoogle Scholar |
Thiel LF,
Beermann DH,
Krick BJ, Boyd RD
(1993) Dose-dependent effects of exogenous porcine somatotropin on the yield, distribution, and proximate composition of carcass tissues in growing pigs. Journal of Animal Science 71, 827–835.
Walton PE, Etherton TD
(1986) Stimulation of lipogenesis by insulin in swine adipose tissue: Antagonism by porcine growth hormone. Journal of Animal Science 62, 1584–1595.