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REVIEW

Management of phosphorus nutrition of beef cattle grazing seasonally dry rangelands: a review

R. M. Dixon A E , S. T. Anderson B , L. J. Kidd C and M. T. Fletcher D
+ Author Affiliations
- Author Affiliations

A Queensland Alliance for Agriculture and Food Innovation, Centre for Animal Science, The University of Queensland, PO Box 6014, Rockhampton, Qld 4702, Australia.

B School of Biomedical Sciences, The University of Queensland, St Lucia, Qld 4072, Australia.

C School of Veterinary Sciences, The University of Queensland, Gatton, Qld 4343, Australia.

D Queensland Alliance for Agriculture and Food Innovation, Centre for Animal Science, The University of Queensland, Health and Food Sciences Precinct, Coopers Plains, Qld 4108, Australia.

E Corresponding author. Email: r.dixon2@uq.edu.au

Animal Production Science 60(7) 863-879 https://doi.org/10.1071/AN19344
Submitted: 16 June 2019  Accepted: 08 October 2019   Published: 9 April 2020

Abstract

This review examines the effects of phosphorus (P) deficiency as a major constraint to productivity of cattle grazing rangelands with low-P soils. Nutritional deficiency of P may severely reduce liveweight (LW) gain of growing cattle (e.g. by 20–60 kg/annum) and the productivity of breeder cow herds as weaning rate, mortality and calf growth. In seasonally dry tropical environments, the production responses to supplementary P occur primarily during the rainy season when the nutritional quality of pasture as metabolisable energy (ME) and protein is high and pasture P concentration is limiting, even though the P concentrations are higher than during dry season. When ME and nitrogen of rainy-season pasture are adequate, then P-deficient cattle typically continue to gain LW slowly, but with reduced bone mineralisation (i.e. osteomalacia). In beef breeder herds when diet P is insufficient, cows with high bone P reserves can mobilise bone P reserves during late pregnancy and early lactation. Mobilisation may contribute up to the equivalent of ~7 g diet P/day (one-third of the P requirements) in early lactation, and, thus, allow acutely P-deficient breeders to maintain calf growth for at least several months until depletion of cow body P reserves. However, severe P deficiency in cattle is usually associated with reduced voluntary intake (e.g. by 20–30% per kg LW), severe LW loss and poor reconception rates. When P intake is greater than immediate requirements, breeders can replenish bone P. Replenishment in mature cows occurs slowly when ME intake is sufficient only for slow LW gain, but rapidly at ME intakes sufficient for rapid LW gain. Bone P replenishment also occurs in late-pregnant heifers even when losing maternal LW. Intervals of mobilisation and replenishment of body P reserves will often be important for P nutrition of beef breeder cows through annual cycles. Diagnosis of P deficiency in grazing cattle is difficult and must encompass estimation of both diet P intake and availability of P from body reserves. Cattle behaviour (e.g. pica, osteophagea), low soil P concentrations and low herd productivity provide valuable indicators. Some constituents of blood (plasma inorganic P, calcium, plasma inorganic P : calcium ratios and endocrine markers) are valuable indicators, but the threshold values indicative of P deficiency at various ME intakes are not well established. It is evident that knowledge of both the nutritional physiology and requirements for P provide opportunities to better manage P nutrition to alleviate production losses in low-input systems with beef cattle grazing rangelands.

Additional keywords: body P reserves, P mobilisation, P nutrition, P supplementation.


References

AFRC (1991) Technical Committee on Responses to Nutrients. Report 6. A reappraisal of the calcium and phosphorus requirements of sheep and cattle. Nutrition Abstracts and Reviews 61, 573–612. [Series B]

Ahern CR, Shields PG, Enderlin NG, Baker DE (1994) ‘The soil fertility of central and north-east Queensland grazing lands.’ (Meat Research Corporation and Department of Primary Industries Queensland: Brisbane, Qld, Australia)

Allen MJ (2003) Biochemical markers of bone metabolism in animals: uses and limitations. Veterinary Clinical Pathology 32, 101–113.
Biochemical markers of bone metabolism in animals: uses and limitations.Crossref | GoogleScholarGoogle Scholar | 12966461PubMed |

Anderson ST, Benvenutti M, Spiers JG, Goodwin KL, Kidd L, Fletcher MT, Dixon RM (2016) CTX-1 as a diagnostic marker of bone mobilisation in Bos indicus cows. In ‘Proceedings Northern Beef Research update conference’, Rockhampton, Qld, Australia, 15–18 August 2016, p. 182.

Anderson ST, Kidd LJ, Benvenutti MA, Fletcher NT, Dixon RM (2017) New candidate markers of phosphorus status in beef breeder cows. Animal Production Science 57, 2291–2303.
New candidate markers of phosphorus status in beef breeder cows.Crossref | GoogleScholarGoogle Scholar |

Benvenutti M, Dixon RM, Goodwin K, Kidd L, Mayer R, Fletcher MT, Anderson ST (2015) Responses of Bos indicus cows in early lactation to dietary phosphorus deficiency. In ‘Recent advances in animal nutrition in Australia Vol. 2015. 30’, (Ed. RA Swick) Armidale, NSW, Australia, pp. 47–48.

Benvenutti M, Dixon RM, Goodwin K, Anderson ST, Kidd L, Mayer R, Fletcher MT (2016) Effects of diet phosphorus and energy intake during late pregnancy on performance of Droughtmaster heifers. In ‘Proceedings of the Northern Beef Research Update Conference’, Rockhampton, Qld, Australia, 15–18 August 2016, p. 186. (North Australian Beef Research Council, Qld, Australia)

Benzie D, Boyne AW, Dalgarno AC, Duckworth J, Hill R (1959) Studies of the skeleton of sheep. III. The relationship between phosphorus intake and resorption and repair of the skeleton in pregnancy and lactation. Journal of Agricultural Science 52, 1–12.
Studies of the skeleton of sheep. III. The relationship between phosphorus intake and resorption and repair of the skeleton in pregnancy and lactation.Crossref | GoogleScholarGoogle Scholar |

Blair-West JR, Denton DA, McKinley MJ, Radden BG, Ramshaw EH, Wark JD (1992) Behavioural and tissue responses to severe phosphorus depletion in cattle. The American Journal of Physiology 263, R656–R663.

Bortolussi G, Ternouth JH, McMeniman NP (1996) Dietary nitrogen and phosphorus depletion in cattle and their effects on liveweight gain, blood metabolite concentrations and phosphorus kinetics. Journal of Agricultural Science 126, 493–501.
Dietary nitrogen and phosphorus depletion in cattle and their effects on liveweight gain, blood metabolite concentrations and phosphorus kinetics.Crossref | GoogleScholarGoogle Scholar |

Bowen MK, Chudleigh F, Dixon RM, Sullivan MT, Schatz T, Oxley T (2020) Evaluating the economics of phosphorus supplementation of beef cattle grazing northern Australian rangelands. Animal Production Science 60, 683–693.
Evaluating the economics of phosphorus supplementation of beef cattle grazing northern Australian rangelands.Crossref | GoogleScholarGoogle Scholar |

Boxebeld A, Guéguen L, Hannequart G, Durand M (1983) Utilization of phosphorus and calcium and minimal maintenance requirement for phosphorus in growing sheep fed a low-phosphorus diet. Reproduction, Nutrition, Development 23, 1043–1053.
Utilization of phosphorus and calcium and minimal maintenance requirement for phosphorus in growing sheep fed a low-phosphorus diet.Crossref | GoogleScholarGoogle Scholar |

Braithwaite GD (1986) Phosphorus requirements of ewes in pregnancy and lactation. Journal of Agricultural Science 106, 271–278.
Phosphorus requirements of ewes in pregnancy and lactation.Crossref | GoogleScholarGoogle Scholar |

Bravo D, Meschy F, Bogaert C, Sauvant D (2000) Ruminal phosphorus availability from several feedstuffs measured by the nylon bag technique. Reproduction, Nutrition, Development 40, 149–162.
Ruminal phosphorus availability from several feedstuffs measured by the nylon bag technique.Crossref | GoogleScholarGoogle Scholar | 10863958PubMed |

Breves G, Ross R, Höller H (1985) Dietary phosphorus depletion in sheep: effects on plasma inorganic phosphorus, calcium, l,25-(OH)2-vit. D3 and alkaline phosphatase and on gastrointestinal P and Ca balances. Journal of Agricultural Science 105, 623–629.
Dietary phosphorus depletion in sheep: effects on plasma inorganic phosphorus, calcium, l,25-(OH)2-vit. D3 and alkaline phosphatase and on gastrointestinal P and Ca balances.Crossref | GoogleScholarGoogle Scholar |

Breves G, Goff JP, Schroder B, Horst RL (1995) Gastrointestinal calcium and phosphate metabolism in ruminants. In ‘Ruminant physiology: digestion, metabolism, growth and reproduction’. (Eds Wv Engelhardt, S Leonhard-Marek, G Breves, D Giesecke) pp. 135–151. (Ferdinand Enke Verlag: Stuttgart, Germany)

Call JW, Butcher JE, Shupe JL, Lamb RC, Boman RL, Olson AE (1987) Clinical effects of low dietary phosphorus concentrations in feed given to lactating dairy cows. American Journal of Veterinary Research 48, 133–136.

Castells L, McNeill DM, Dixon RM, Kidd LJ, Fletcher MT, Goodwin K (2014) Phosphorus supplements in pregnancy improve lactation performance in young cows. Proceedings of the Australian Society of Animal Production 30, 335

Castells L, Dixon RM, Kidd LJ, Goodwin K, Mayer R, Fletcher MT, McNeill DM (2015) Capacity of young cows to gain bone and improve lactation. In ‘Recent advances in animal nutrition in Australia 2015. Vol. 30’, (Ed. RA Swick) Armidale, NSW, Australia, pp. 49–50.

Coates DB (1994) Effect of phosphorus as fertiliser or supplement on pasture and cattle productivity in the semi-arid tropics of north Queensland. Tropical Grasslands 28, 90–108.

Coates DB, Le Feuvre RP (1998) Diet composition of cattle grazing Stylosanthes–grass pastures in the seasonally dry tropics: the effect of phosphorus as fertiliser or supplement. Australian Journal of Experimental Agriculture 38, 7–15.
Diet composition of cattle grazing Stylosanthes–grass pastures in the seasonally dry tropics: the effect of phosphorus as fertiliser or supplement.Crossref | GoogleScholarGoogle Scholar |

Coates DB, Murray RM (1994) Tail-bone density compared with other indicators of phosphorus deficiency in cattle. Proceedings of the Australian Society of Animal Production 20, 329–332.

Coates DB, Ternouth JH (1992) Phosphorus kinetics of cattle grazing tropical pastures and implications for the estimation of their phosphorus requirements. Journal of Agricultural Science 119, 401–409.
Phosphorus kinetics of cattle grazing tropical pastures and implications for the estimation of their phosphorus requirements.Crossref | GoogleScholarGoogle Scholar |

Coates DB, Miller CP, Hendricksen RE, Jones RJ (1997) Stability and productivity of Stylosanthes pastures in Australia. II. Animal production from Stylosanthes pastures. Tropical Grasslands 31, 494–502.

Coates DB, Dixon RM, Mayer RJ, Murray RM (2016) Validation of single photon absorptiometry for on-farm measurement of density and mineral content of tail bone in cattle. Animal Production Science 56, 2054–2059.
Validation of single photon absorptiometry for on-farm measurement of density and mineral content of tail bone in cattle.Crossref | GoogleScholarGoogle Scholar |

Coates DB, Dixon RM, Murray RM, Mayer RJ, Miller CP (2018) Bone mineral density in the tail-bones of cattle: effect of phosphorus status, liveweight, age and physiological status. Animal Production Science 58, 801–810.
Bone mineral density in the tail-bones of cattle: effect of phosphorus status, liveweight, age and physiological status.Crossref | GoogleScholarGoogle Scholar |

Coates DB, Dixon RM, Mayer RJ (2019) Between-year variation in the effects of phosphorus deficiency in breeder cows grazing tropical pastures. Tropical Grasslands – Forrajes Tropicales 7, 223–233.
Between-year variation in the effects of phosphorus deficiency in breeder cows grazing tropical pastures.Crossref | GoogleScholarGoogle Scholar |

Cohen RDH (1974) Phosphorus nutrition of beef cattle. 4. The use of faecal and blood phosphorus for the estimation of phosphorus intake. Australian Journal of Experimental Agriculture and Animal Husbandry 14, 709–715.
Phosphorus nutrition of beef cattle. 4. The use of faecal and blood phosphorus for the estimation of phosphorus intake.Crossref | GoogleScholarGoogle Scholar |

Colwell JD (1963) The estimation of phosphorus fertilizer requirements of wheat in southern New South Wales by soil analyses. Australian Journal of Experimental Agriculture and Animal Husbandry 3, 190–197.
The estimation of phosphorus fertilizer requirements of wheat in southern New South Wales by soil analyses.Crossref | GoogleScholarGoogle Scholar |

CSIRO (2007) ‘Nutrient requirements of domesticated ruminants.’ (CSIRO Publishing: Melbourne, Vic., Australia)

De Brouwer CHM, Cilliers JW, Vermaak LM, van der Merwe HJ, Groenewald PCN (2000) Phosphorus supplementation to natural pasture grazing for beef cows in the Western Highveld region of South Africa. South African Journal of Animal Science 30, 43–52.
Phosphorus supplementation to natural pasture grazing for beef cows in the Western Highveld region of South Africa.Crossref | GoogleScholarGoogle Scholar |

de Waal HO, Randall JH, Koekemoer GJ (1996) The effects of phosphorus supplementation on body mass and reproduction of grazing beef cows supplemented with different levels of phosphorus at Armoedsvlakte. South African Journal of Animal Science 26, 29–36.

Dillon JL, Anderson JR (1990) ‘The analysis of response in crop and livestock production.’ 3rd edn. (Pergamon Press: Oxford, UK)

Dixon RM (2016) Improving prediction of phosphorus intake of cattle grazing tropical pastures. Final report project B.NBP.0719. Meat and Livestock Australia, Sydney, NSW, Australia.

Dixon RM, Coates DB (2011) The relationship between the concentration of phosphorus in the diet and in faeces of cattle grazing tropical grass and grass-legume pastures. Advances in Animal Biosciences 2, 337

Dixon RM, Benvenutti M, Goodwin K, Kidd L, Anderson ST, Mayer R, Fletcher MT (2016a) Effects of diet P intake during late pregnancy and early lactation on performance of mature Droughtmaster cows. In ‘Proceedings of the Northern Beef Research update conference’, Rockhampton, Qld, Australia, 15–18 August 2016, p. 187.

Dixon RM, Castells L, Kidd L, Goodwin KL, Mayer R, McNeill DM, Fletcher MT, Anderson ST (2016b) Responses of deficient breeder cows to additional diet phosphorus. Proceedings of the Australian Society of Animal Production 31, 91

Dixon RM, Coates DB, Mayer RJ, Miller CP (2016c) Productivity and phosphorus content of rib and tail bones in reproducing cows ingesting diets deficient or adequate in phosphorus. Proceedings of the Australian Society of Animal Production 31, 93–94.

Dixon RM, Kidd LJ, Coates DB, Anderson ST, Benvenutti MA, Fletcher MT, McNeill DM (2017) Utilizing mobilization of body reserves to improve management of phosphorus nutrition of breeder cows. Animal Production Science 57, 2280–2290.
Utilizing mobilization of body reserves to improve management of phosphorus nutrition of breeder cows.Crossref | GoogleScholarGoogle Scholar |

Dixon RM, Coates DB, Reid DJ (2018) The effects of supplementary P in the diet on the concentration of P in faeces. Animal Production Science 58, 2600

Dixon RM, Coates DB, Mayer RJ, Miller CP (2019a) Alternative rib bone biopsy measurements to estimate changes in skeletal mineral reserves in cattle. Animal 13, 119–126.
Alternative rib bone biopsy measurements to estimate changes in skeletal mineral reserves in cattle.Crossref | GoogleScholarGoogle Scholar | 29669613PubMed |

Dixon RM, Fletcher MT, Goodwin KL, Reid DJ, McNeill DM, Yong KWL, Petherick JC (2019b) Learned behaviours lead to bone ingestion by phosphorus-deficient cattle. Animal Production Science 59, 921–932.
Learned behaviours lead to bone ingestion by phosphorus-deficient cattle.Crossref | GoogleScholarGoogle Scholar |

Dixon RM, Coates DB (2019c) Blood phosphorous concentration depends on the reproductive status of breeder cows. In ‘Proceedings of the Northern Beef Research update conference’, Brisbane, Qld, Australia, 20–22 August 2019, p. 82.

Dixon RM, Muller J, Mayer B (2019d) Blood phosphorus concentration may be highly variable in mixed age breeder herds. In ‘Proceedings of the Northern Beef Research update conference’, Brisbane, Qld, Australia, 20–22 August 2019, p. 83.

Ferguson JD, Sklan D (2005) Effects of dietary phosphorus and nitrogen on cattle reproduction. In ‘Nitrogen and phosphorus nutrition of cattle’. (Eds E Pfeffer, AN Hristov) pp. 233–253. (CAB International: Wallingford, UK)

Field AC, Suttle NF, Nisbet DI (1975) Effect of diets low in calcium and phosphorus on the development of growing lambs. Journal of Agricultural Science 85, 435–442.
Effect of diets low in calcium and phosphorus on the development of growing lambs.Crossref | GoogleScholarGoogle Scholar |

Field AC, Woolliams JA, Dingwall RA, Munro CS (1984) Animal and dietary variation in the absorption and metabolism of phosphorus by sheep. Journal of Agricultural Science 103, 283–291.
Animal and dietary variation in the absorption and metabolism of phosphorus by sheep.Crossref | GoogleScholarGoogle Scholar |

Gartner RJW, Murphy GM, Hoey WA (1982) Effects on induced, subclinical phosphorus deficiency on feed intake and growth of beef heifers. Journal of Agricultural Science 98, 23–29.
Effects on induced, subclinical phosphorus deficiency on feed intake and growth of beef heifers.Crossref | GoogleScholarGoogle Scholar |

Gillis MB, Edwards JR, Young RJ (1962) Studies in the availability of calcium ortho-phosphates to chickens and turkeys. The Journal of Nutrition 78, 155–161.
Studies in the availability of calcium ortho-phosphates to chickens and turkeys.Crossref | GoogleScholarGoogle Scholar | 13947942PubMed |

Gonzalez-Rivas PA (2012) Estimation of in vitro phosphorus solubility of different sources of phosphorus for cattle. Master of Animal Studies Thesis, University of Queensland, Gatton, Qld, Australia.

Green HH (1925) Perverted appetites. Physiological Reviews 5, 336–348.
Perverted appetites.Crossref | GoogleScholarGoogle Scholar |

Holechek JL, Galyean ML, Wallace JD, Wofford H (1985) Evaluation of faecal indices for predicting phosphorus status of cattle. Grass and Forage Science 40, 489–492.
Evaluation of faecal indices for predicting phosphorus status of cattle.Crossref | GoogleScholarGoogle Scholar |

Ibrahim MNM, Zemmerlink G, Tamminga S (1998) Release of mineral elements from tropical feeds during degradation in the rumen. Asian-Australasian Journal of Animal Sciences 11, 530–537.
Release of mineral elements from tropical feeds during degradation in the rumen.Crossref | GoogleScholarGoogle Scholar |

Jackson D, Rolfe J, English B, Mathews R, Dixon RM, Smith P, MacDonald M (2012) ‘Phosphorus management of beef cattle in northern Australia.’ (Meat and Livestock Australia: Sydney, NSW, Australia)

Jones RK (1974) A study of the phosphorus responses of a wide range of accessions from the genus Stylosantes. Australian Journal of Agricultural Research 25, 847–862.
A study of the phosphorus responses of a wide range of accessions from the genus Stylosantes.Crossref | GoogleScholarGoogle Scholar |

Judkins MB, Wallace JD, Parker EE, Wright JD (1985) Performance and phosphorus status of range cows with and without phosphorus supplementation. Journal of Range Management 38, 139–143.
Performance and phosphorus status of range cows with and without phosphorus supplementation.Crossref | GoogleScholarGoogle Scholar |

Kerridge PC (1990) Phosphorus and beef production in northern Australia. Tropical Grasslands 24, 129–130.

Kerridge PC, Gilbert MA, Coates DB (1990) Phosphorus and beef production in northern Australia. 8. The status and management of soil phosphorus in relation to beef production. Tropical Grasslands 24, 221–230.

Kiarie E, Nyachoti CM (2010) Bioavailability of calcium and phosphorus in feedstuffs for farm animals. In ‘Phosphorus and calcium utilization and requirements in farm animals’. (Eds DMSS Vitti, E Kebreab) pp. 76–93. (CAB International: Wallingford, UK)

Kidd LJ, Dixon RM, Quigley SP, McNeill DM, Poppi DP, Castells L, Fletcher MT, Goodwin KL, Anderson ST (2016a) ‘The use of serial bone biopsies to investigate phosphorus deficiency in growing, pregnant and lactating cattle.’ (Australian and New Zealand Bone and Mineral Society). Available at http://esa-srb.org.au/assets/ESA-SRB-ANZBMS-2016/All-abstracts-220816.pdf [verified 10 March 2020]

Kidd LJ, McNeill DM, Castells L, Goodwin KL, Fletcher MT, Anderson ST, Dixon RM (2016b) Post-weaning phosphorus supplementation restores bone volume in pregnant cows independently of dietary metabolisable energy. In ‘Proceedings of the Northern Beef Research update conference’, Rockhampton, Qld, Australia, 15–18 August 2016, p. 90.

Koddebusch L, Pfeffer E (1988) Untersuchungen zur Verwertbarkeit von Phosphor verschiedener Herkiinfte an laktierenden Ziegen. [in German] (Studies on the availability of phosphorus of different sources for lactating goats). Journal of Animal Physiology and Animal Nutrition 60, 269–275.
Untersuchungen zur Verwertbarkeit von Phosphor verschiedener Herkiinfte an laktierenden Ziegen. [in German] (Studies on the availability of phosphorus of different sources for lactating goats).Crossref | GoogleScholarGoogle Scholar |

Li X, Zhang D, Yang TY, Bryden WL (2016) Phosphorus bioavailability: a key aspect for conserving this critical animal feed resource with reference to broiler nutrition. Agriculture 6, 25–40.
Phosphorus bioavailability: a key aspect for conserving this critical animal feed resource with reference to broiler nutrition.Crossref | GoogleScholarGoogle Scholar |

Liesegang A, Ursprung R, Gasser J, Sassi ML, Risteli J, Riond JL, Wanner M (2002) Influence of dietary phosphorus deficiency with or without addition of fumaric acid to a diet in pigs on bone parameters. Journal of Animal Physiology and Animal Nutrition 86, 1–16.
Influence of dietary phosphorus deficiency with or without addition of fumaric acid to a diet in pigs on bone parameters.Crossref | GoogleScholarGoogle Scholar | 11906568PubMed |

Lima FR, Mendonca CX, Alvarez JC, Ratti G, Lenharo SLR, Kahn H, Garzillo JMF (1995) Chemical and physical evaluation of commercial dicalcium phosphates as sources of phosphorus in animal nutrition. Poultry Science 74, 1659–1670.
Chemical and physical evaluation of commercial dicalcium phosphates as sources of phosphorus in animal nutrition.Crossref | GoogleScholarGoogle Scholar | 8559731PubMed |

Lima FR, Fernandes JIM, Oliveira E, Fronzaglia GC, Kahn H (1999) Laboratory evaluations of feed-grade and agricultural-grade phosphates. Poultry Science 78, 1717–1728.
Laboratory evaluations of feed-grade and agricultural-grade phosphates.Crossref | GoogleScholarGoogle Scholar | 10626647PubMed |

Little DA (1983) Bovine body composition and phosphorus storage: the in vivo assessment of body composition and phosphorus status, and the dietary phosphorus requirements of cattle for growth. PhD Thesis, University of Queensland, Brisbane, Qld, Australia.

Malafaia P, Garcia FZ, Lopes SP, Souza VC, Filho CFCC, Costa DFA, Veiga CP (2018) Evaluation of an inexpensive needle test for the diagnosis of phosphorus deficiency and management of phosphorus supplementation for cattle: a multiple case study. Annals of the Brazilian Academy of Sciences 90, 3337–3352.
Evaluation of an inexpensive needle test for the diagnosis of phosphorus deficiency and management of phosphorus supplementation for cattle: a multiple case study.Crossref | GoogleScholarGoogle Scholar |

McCosker T, Winks L (1994) ‘Phosphorus nutrition of beef cattle in northern Australia.’ (Department of Primary Industries: Brisbane, Qld, Australia)

McDowell LR (1996) Feeding minerals to cattle on pasture. Animal Feed Science and Technology 60, 247–271.
Feeding minerals to cattle on pasture.Crossref | GoogleScholarGoogle Scholar |

McGowan M, Fordyce G, O’Rourke P, Barnes T, Morton J, Menzies D, Jephcott S (2014) Northern Australian beef fertility project: Cashcow. Final report B.NBP.0382. Meat and Livestock Australia, Sydney, NSW, Australia.

McLean RW, Hendricksen RE, Coates DB, Winter WH (1990) Phosphorus and beef production in northern Australia. 6. Diet attributes and their relation to growth. Tropical Grasslands 24, 197–208.

McMeniman NP (1973) The toxic effect of some phosphate supplements fed to sheep. Australian Veterinary Journal 49, 150–152.
The toxic effect of some phosphate supplements fed to sheep.Crossref | GoogleScholarGoogle Scholar | 4707166PubMed |

Meschy F (2003) Reassessement of dietary allowances: absorbed phosphorus requirements of ruminants. In ‘Recent advances in animal nutrition’. (Eds P Garnsworthy, J Wiseman) pp. 175–189. (Nottingham University Press: Nottingham, UK)

Michalk DL, Zhi-Kai H (1995) The response of round-leafed cassia (Cassia rotundifolia) to phosphorus, potassium and lime on ultisol soils in subtropical China. In ‘Plant interactions at low pH’. (Eds RA Date, NJ Grundon, GE Rayment, ME Probert) pp. 561–564. (Kluwer Academic Publishers: Dordrecht, The Netherlands)

Miller CP, Coates DB, Ternouth JH, White SJ (1998) Phosphorus management for breeding cattle in northern Australia. Final report of Project DAQ093. Meat and Livestock Australia, Sydney, NSW, Australia.

Moir KM (1960) Nutrition of grazing cattle. 2. Estimation of phosphorus and calcium in pasture selected by grazing cattle. Queensland Journal of Agricultural Science 17, 373–383.

Partridge IJ, Wright JW (1992) The value of round-leafed cassia (Cassia rotundifolia) cv. Wynn) in a native pasture grazed with steers in south-east Queensland. Tropical Grasslands 26, 263–269.

Peters M, Tarawali SA, Alkamper J (1994) Evaluation of tropical pasture legumes for fodder banks in sub-humid Nigeria. 1. Accessions of Centrosema brasilianum, C. pascuorum, Chamaecrista rotundifolia and Stylosantes hamata. Tropical Grasslands 28, 65–73.

Pfeffer E, Rodehutscord M, Breves G (1995) Effects of reducing dietary calcium and/or phosphorus on performance and body composition in male kids. Journal of Animal Physiology and Animal Nutrition 74, 243–252.
Effects of reducing dietary calcium and/or phosphorus on performance and body composition in male kids.Crossref | GoogleScholarGoogle Scholar |

Pfeffer E, Beede DK, Valk H (2005) Phosphorus metabolism in ruminants and requirements of cattle. In ‘Nitrogen and phosphorus nutrition of cattle’. (Eds E Pfeffer, AN Hristov) pp. 195–231. (CAB International: Wallingford, UK)

Quigley S, Poppi D, Schatz T (2015) Validation and demonstration of a diagnostic tool for phosphorus status of beef cattle. Final project report B NBP.0537. Meat and Livestock Australia, Sydney, NSW, Australia.

Read MVP, Engels EAN, Smith WA (1986a) Phosphorus and the grazing ruminant. 2. The effects of supplementary P on cattle at Glen and Armoedsvlakte. South African Journal of Animal Science 16, 7–12.

Read MVP, Engels EAN, Smith WA (1986b) Phosphorus and the grazing ruminant. 3. Rib bone samples as an indicator of the P status of cattle. South African Journal of Animal Science 16, 13–17.

Rodehutscord M, Heuvers H, Pfeffer E (2000) Effect of organic matter digestibility on obligatory faecal phosphorus loss in lactating goats, determined from balance data. Animal Science 70, 561–568.
Effect of organic matter digestibility on obligatory faecal phosphorus loss in lactating goats, determined from balance data.Crossref | GoogleScholarGoogle Scholar |

Rose AL (1954) Osteomalacia in the Northern Territory. Australian Veterinary Journal 30, 172–177.
Osteomalacia in the Northern Territory.Crossref | GoogleScholarGoogle Scholar |

Sathler DFT, Prados LF, Zanetti D, Silva BC, Valadares Filho SC, Pacheco MVC, Amaral PM, Renno LN, Paulino MF (2017) Reducing mineral usage in feedlot diets for Nellore cattle: 1. Impacts of calcium, phosphorus, copper, manganese, and zinc contents on microbial efficiency and ruminal, intestinal, and total digestibility of dietary constituents. Journal of Animal Science 95, 1715–1726.

Schatz T, McCosker K (2018) Phosphorus supplementation of Brahman heifers in phosphorus deficient country in the NT. Proceedings of the Australian Society of Animal Production 58, 2695

Schatz T, McCosker K (2019) Phosphorus supplementation and female PiP levels in the VRD, NT. In ‘Proceedings of the Northern Beef Research update conference’, Brisbane, Qld, Australia, 20–22 August 2019, p. 58.

Scott D (1986) Control of phosphorus balance in ruminants. In ‘Aspects of digestive physiology in ruminants’. (Eds A Dobson, MJ Dobson) pp. 156–174. (Cornell University Press: Ithaca, NY, USA)

Shastak Y, Rodehutscord M (2013) Determination and estimation of phosphorus availability in growing poultry and their historical development. World’s Poultry Science Journal 69, 569–586.
Determination and estimation of phosphorus availability in growing poultry and their historical development.Crossref | GoogleScholarGoogle Scholar |

Shupe JL, Butcher JE, Call JW, Olson AE, Blake JT (1988) Clinical signs and bone changes associated with phosphorus deficiency in beef cattle. American Journal of Veterinary Research 49, 1629

Spangenberg HP (1997) Phosphorus supplementation to grazing beef cows at two sites in the Northern Cape. PhD Thesis, University of the Orange Free State, Bloemfontein, South Africa.

Suttle N (2010) ‘Mineral nutrition of livestock.’ 4th edn. (CAB International: Wallingford, UK)

Ternouth JH, Coates DB (1997) Phosphorus homoeostasis in grazing breeder cattle. Journal of Agricultural Science 128, 331–337.
Phosphorus homoeostasis in grazing breeder cattle.Crossref | GoogleScholarGoogle Scholar |

Ternouth JH, Sevilla CC (1990) The effects of low levels of dietary phosphorus upon the dry matter intake and metabolism of lambs. Australian Journal of Agricultural Research 41, 175–184.
The effects of low levels of dietary phosphorus upon the dry matter intake and metabolism of lambs.Crossref | GoogleScholarGoogle Scholar |

Ternouth JH, Bortolussi G, Coates DB, Hendricksen RE, Mclean RW (1996) The phosphorus requirements of growing cattle consuming forage diets. Journal of Agricultural Science 126, 503–510.
The phosphorus requirements of growing cattle consuming forage diets.Crossref | GoogleScholarGoogle Scholar |

Theiler A, Green HH (1932) Aphosphorosis in ruminants. Nutrition Abstracts and Reviews 1, 359–385.

Theiler A, Du Toit PJ, Malan AI (1937) The influence of variations in the dietary phosphorus and in the Ca : P ratio on the production of rickets in cattle. The Onderstepoort Journal of Veterinary Science and Animal Industry 8, 375–414.

Turner AW, Kelley RB, Dann AT (1935) Peg-leg of cattle in north Queensland. Journal of the Council for Scientific and Industrial Research 8, 120–136.

Valk H, Sebek LBJ, Beynen AC (2002) Influence of phosphorus intake on excretion and blood plasma and saliva concentrations of phosphorus in dairy cows. Journal of Dairy Science 85, 2642–2649.
Influence of phosphorus intake on excretion and blood plasma and saliva concentrations of phosphorus in dairy cows.Crossref | GoogleScholarGoogle Scholar | 12416818PubMed |

Van de Klis JD, Versteegh HAJ (1996) Phosphorus nutrition of poultry. In ‘Recent advances in animal nutrition’. (Eds PC Garnsworthy, J Wiseman, W Haresign) pp. 71–83. (Nottingham University Press, Nottingham, UK)

Van Niekerk BDH, Jacobs GA (1985) Protein, energy and phosphorus supplementation of cattle fed low quality forage. South African Journal of Animal Science 15, 133–136.

Wadsworth JC, McLean RW, Coates DB, Winter WH (1990) Phosphorus and beef production in northern Australia. 5. Animal phosphorus status and diagnosis. Tropical Grasslands 24, 185–196.

Winks L (1990) Phosphorus and beef production in northern Australia. 2. Responses to phosphorus by ruminants: a review. Tropical Grasslands 24, 140–158.

Winks L, Laing AR (1972) Urea, phosphorus and molasses supplements for grazing beef weaners. Proceedings of the Australian Society of Animal Production 9, 253–257.

Winks L, Laing AR, Wright GS, Stokoe J (1976) Effects of nitrogen, phosphorus and molasses on the performance of weaner cattle during the dry season in north Queensland. Journal of the Australian Institute of Agricultural Science 42, 246–251.

Winks L, Laing AR, O’Rourke PK, Wright GS (1979) Factors affecting the response to urea-molasses supplements by yearling cattle in tropical Queensland. Australian Journal of Experimental Agriculture and Animal Husbandry 19, 522–529.
Factors affecting the response to urea-molasses supplements by yearling cattle in tropical Queensland.Crossref | GoogleScholarGoogle Scholar |

Winter WH (1988) Supplementation of steers grazing Stylosanthes hamata pastures at Katherine, Northern Territory. Australian Journal of Experimental Agriculture 28, 669–682.
Supplementation of steers grazing Stylosanthes hamata pastures at Katherine, Northern Territory.Crossref | GoogleScholarGoogle Scholar |

Winter WH, Coates DB, Hendricksen RE, Kerridge PC, McLean RW, Miller CP (1990) Phosphorus and beef production in northern Australia. 4. The response of cattle to fertilizer and supplementary phosphorus. Tropical Grasslands 24, 170–184.

Zanetti D, Menezes ACB, Silva FAS, Costa e Silva LF, Rotta PP, Detmann E, Engle TE, Valadares Filho SC (2017) In situ and in vitro estimation of mineral release from common feedstuffs fed to cattle. Journal of Agricultural Science 155, 1160–1173.
In situ and in vitro estimation of mineral release from common feedstuffs fed to cattle.Crossref | GoogleScholarGoogle Scholar |