Study Objectives 1. Understand why different breeds developed within domestic animal species 2. Describe and contrast the growth and development of small and large framed cattle breeds 3. Learn what frame scores are and how they are calculated and interpreted 4. Describe the differences in growth between breeds of cattle, sheep and pigs selected for different purposes 5. Describe the different growth patterns between male, female and castrated animals 6. Learn how and why muscle, fat and bone development differs between the sex classes Genetics — Breeds Genetic factors affecting growth Breeds • Within a species, animal breeders have placed selection pressure on different traits that have led to many different breeds Strength Disease resistance Meat Milk Domestication ~8,500 B.C. Cattle breeds Chianina Holstein Angus Jersey • Within breeds selected for meat and milk production, cattle have also been selected for size • As a result some breeds have very large skeletons and are called large-framed cattle • Breeds with small skeletons are so-called small-framed breeds Distribution of cattle frame size Holstein Jersey Frame score • To determine the frame size of an individual animal, a frame score is given for a particular age range • Frame score is based on the height over the hips Frame score How to evaluate body/frame type • The height or 'frame' of cattle of a given age is closely related to maturity type Maturing type Early Moderate Late Very-late Frame score 1 and 2 3, 4 and 5 6, 7 and 8 9, 10 and 11 growth potential Low/Lack rapid Average high extreme Muscle good good Lean extremely lean Carcass weights 150–180 kg 200–350 kg 350–450 kg Framed >450 Frame type - growth and fattening relationships • Large framed cattle reach heavier weights at a given compositional or physiological maturity, e.g. slaughter weight • Large-framed cattle take longer to reach their mature weight and are therefore considered latermaturing animals • Because small framed animals grow relatively quickly they are called Frame type - growth and fattening relationships • At the same chronological age, large-framed animals are physiologically younger than small-framed animals • If comparisons are made at the same chronological age or same weight, later maturing (large-framed) animals are leaner, while earlier maturing (small framed) animals are fatter and more physiologically mature Small-framed Large-framed Frame type - growth and fattening relationships • Cattle can be compared at the same physiological or compositional endpoint, i.e. 1. Puberty 2. 5% intramuscular fat in the longissimus muscle 3. 19% fat trim • In this case, large-framed, later-maturing cattle can be compositionally equivalent to small-framed cattle Frame type - growth and fattening relationships Effect of Frame Size and Breed on Beef Carcass Composition at a Constant Maturity (19% Fat Trim) % Lean % Fat trim % Bone Hereford Angus X Red Poll X Maine Anjou X Chianina X 68.8 68.4 68.6 69 - - - - 12.3 12.7 12.5 12.1 Small-framed Large-framed Frame type - growth and fattening relationships Effect of Frame Size and Breed on Beef Carcass Composition at a Constant Quality Grade (5% Fat in Longissimus) Hereford Limousin Simmental Charolais Angus X X X X % Lean 67.1 69.6 69.7 70.9 % Fat trim 20.3 18.5 17.2 16.2 % Bone 12.6 11.9 13.1 12.9 Small-framed Large-framed Cattle breeds - Beef vs Dairy Holstein Hereford Cattle breeds - Beef vs Dairy • Selection for muscle is inversely related to milk production • Animals used for milk production are less muscular • Reduction in muscle fiber numbers in milk breeds, which occurs prenatal • Selection has not changed muscle distribution Cattle breeds - Beef vs Dairy Muscle : Bone Ratios • Changes in muscle to bone ratios are primarily responsible for muscling differences across breeds • Mature muscle to bone ratios range from 4:1 to 7:1 for dairy cattle and double-muscled cattle, respectively Weight of muscle plus bone (kg) Effect of breed types on fat distribution • Selection for milk production has shifted the fat distribution on the carcass • As stated earlier, in mature meat cattle, carcass fat is generally evenly distributed between the intermuscular and subcutaneous depots • However, dairy cattle have less subcutaneous fat but more prerenal fat than beef cattle 500 Sheep breeds - Wool vs Meat • Selection for muscle is inversely related to wool production • Meat breeds have superior conformation as measured by muscle:bone ratios = amount of meat per unit of bone • Wool breeds are larger framed, fatten at heavier weights than meat breeds Marino - wool Suffolk - meat Pig Breeds - Maternal vs Meat Yorkshire -maternal • Selection for muscle is inversely related to ability to conceive and produce milk for young • Pietrian pigs are extremely muscular compared to maternal breeds like Yorkshire and Landrace Pietrian - meat Genetics — Sex Genetic factors - Sex Growth and composition are dependant on the sex of the animal • Intact males are capable of > body weights than castrates and females • Intact males attain compositional maturity at later chronological ages than castrates and females • Intact males are generally heavier at any given chronological age • Intact females mature earliest of sex classes, whereas castrates are intermediate Genetic factors - Sex Onset of maturity Barrow = castrated boar Gilt = female pig that has not produced a litter Wether = castrated ram Capon = castrated rooster Pullet = young hen Heifer = young female cow Genetic factors - Sex Exception are pigs: • Gilts (females that have not been bred) mature later and reach heavier weights than barrows (male castrates) • Gilts are leaner than barrows at same chronological age; “why” is unclear • Maybe associated with estrogen secretion enhancing muscle development Genetic factors - Sex Sex – Muscle differences • Intact males have greater Bull proportion of muscle located in forequarter, specifically in neck and thorax, which are associated with secondary sex characteristics • Increased androgen binding receptors in these tissues • Females have increased proportion of muscle in pelvic limb and abdominal wall – support for fetus and udder (mammary gland) • Castrates are intermediate Cow Steer Genetic factors - Sex Sex – Muscle differences • Males have larger muscle fiber diameters than females and castrates • Differences are hormonally driven (Testosterone) • Male >> Castrate >> Female Genetic factors - Sex Sex – Skeleton differences • Estrogen stimulates epiphyseal plate closure • Therefore intact males tend to be taller than females because their long bones grow more before closure • Both estrogens and androgens increase periosteal bone growth (bone thickening) but androgens more. Genetic factors - Sex Sex – Fat differences • Lipogenesis and lipolysis are hormonally regulated through sex steroids with dramatic effects • E.g. animals at equal slaughter weights, from leanest to fattest 1. Cattle: male, castrate, female 2. Sheep: male, castrate, female 3. Swine: male, female, castrate Genetic factors - Sex Sex – Fat differences • Gender effects drive nutrient partitioning • Why do females fatten sooner? - Decreased long bone growth due to increased estrogen - Muscle growth starts to decrease and more nutrients available for fat Epiphyseal plate closes
