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Data Collection
Data Collection for Seedstock Producers
At the core of genetic improvement is the collection of data. While data quality is critical, quantity of data collected can sometimes overcome the limitations on data quality that inherently occur in farm and ranch operations. Along with weights and scores for economically relevant traits and their indicator traits, accurate identification of animals, parents, contemporary groups, and other important details (e.g., age) are essential.
At the core of genetic improvement is the collection of high quality data. Data quality can be impacted by several clearly identified factors. While completeness, timeliness, accuracy, and conformity are all essential, consistency is often the least understood and most overlooked consideration for quality data. Collecting, recording, manipulating and processing data using consistent procedures at both the farm and association levels is the most important aspect to maintaining quality data.
In order to keep all data collected associated with an individual animal an effective beef cattle identification system is essential. Standards have been developed for identification methods that ensure unique and accurate identification of animals during the transmission and processing of data. Because the number of animals processed in genetic evaluation is routinely in the millions, it is not practical to routinely use registration number information for on-farm data collection. Standards for ear tagging and on-farm electronic identification have also been implemented. In addition, recording of animal identification is closely associated with the collection of genomic information.
Historically, many beef breed genetic evaluations were based on progeny weaned and/or registered and did not require that data be recorded from females that failed to reproduce or whose progeny were not registered. By contrast, inventory-based Whole Herd Reporting (WHR) requires the collection of annual production and performance records on all cattle within a herd.
Data recording on individual cows is essential for the prediction of female fertility. Cow fertility is often the most impactful factor on profitability in the beef herd. Additionally, accurate and complete cow data are essential for the prediction of traits with a maternal influence (e.g. weaning weight).
The female production data to be recorded on each cow must be standardized because it is often the most complex data that a producer deals with.
Data collection of complete and accurate data on individual calf performance through slaughter or breeding is critical to making genetic improvement. Using consistent methods for taking animals' weights, measures, and scores is key to accurate data. Additionally, using a commercial or breed association supplied performance recording software helps to improve consistency of data collection and reporting.
Identification Systems
Whole Herd Reporting
Contemporary Groups
content by Jennifer Bormann
Basics
One of the most important aspects of an accurate genetic evaluation is proper contemporary grouping. Environment and management have a large effect on calf performance. When animals are exposed to variable environments or management practices (feed, pasture, shelter, vaccination, etc), it is impossible to determine if their differences in performance are due to genetics or environment. Selecting the highest performing animals in this situation is likely to result in selecting animals that had an advantageous environment. Because environment is not inherited, genetic progress is drastically decreased. When every calf is treated as uniformly as possible, the differences between them are more likely to be due to their genetics. In other words, the higher performing animals are more likely to be the genetically superior animals. Selecting the genetically superior animals results in greater genetic progress. The creation of contemporary groups is the mechanism that allows us to account for management and environmental differences between animals. A contemporary group is a set of same-sex calves that were born within a relatively short window of time and have been managed the same since birth. Each calf in the group has received the same opportunity to express its genetic merit for traits of interest.
If a subset of calves from a group receive different treatment, then those calves should be recoded as a different contemporary group. An example might be a small group of bulls from the larger group sent to a bull test, or perhaps being pulled out to fit for a show. Those bulls should have their data coded with a different contemporary group than the larger group from which they came. Another example might be if a group of calves is large enough that they can’t be weaned/weighed on the same day, they may be broken into separate contemporary groups and weighted on different days. Once animals are separated into a different group, they can never be recombined with the original group.
Every piece of performance data recorded should have the proper contemporary group attached to it. To optimize the amount of information that can be obtained from each performance record, it is best to keep contemporary groups as large as possible while still maintaining equal management and environment for all calves. Single animal contemporary groups add no information to the genetic evaluation. While keeping contemporary groups as large as possible is useful, every animal must receive equal management. It is better to have 2 smaller groups that are truly managed the same within group than one large group with unequal management. Improper contemporary grouping can lead to inaccurate and biased genetic evaluations.
In general, ET calves, multiple births, and freemartins are separated into their own contemporary groups. These situations result in different rearing environments for the calf that make it impossible to fairly compare them to other animals.
Components by Trait
Contemporary group definitions by trait (See BIF Guidelines)*
Calving ease and birth weight: Breeder herd code, Year, Season, Sex, Management code, ET or not
Weaning weight: Calving ease/birth weight contemporary group criteria, Management code (include pasture), Weigh date, Weaning sex
Yearling weight: Weaning weight contemporary group criteria, Management code, Weight date, Yearling sex
Ultrasound traits: Yearling weight contemporary group criteria, Management code (if different than yearling management), Scan date
Carcass traits: Yearling contemporary group criteria, Management code (if different than yearling management), On feed date, Harvest date, Days on feed, Grading date, Carcass sex, Breed of dam
Heifer pregnancy: Yearling weight contemporary group criteria, Breeding management code, Breeding season start and end dates, Exposure, Breeding pasture/sire
Mature cow weight, height, and body condition score: Breeder herd code, Year, Date measured, Cow age at measurement, Birth management code
Stayability: Breeder herd code, Birth year, Herd code in which cow produced a calf
Feed Efficiency: Yearling contemporary group criteria, Feed efficiency management code, Date on feed, Scan or harvest date, Sex
- Depending on the type of evaluation (single breed, multi-breed, animal model, sire model) breed composition of the calf or dam may be part of the contemporary group definition.
Data Collection on Calves
Survival to Weaning
Disposal
Disease
Birth Weight
Content by Michael Gonda and Bradie Schmidt, SDSU
Hoof Tapes
Weaning Weight
Yearling Weight
Content by Michael Gonda and Bradie Schmidt, SDSU
CE Scores
Hip Height/Frame
Docility
Ultrasound (link to UGC website)
Data Collection on Yearling Bulls
Content by Madison Butler/Megan Rolf
Breeding Soundness Exam
Scrotal Circumference
Data Collection on Yearling Heifers
Pelvic Measurements
Content by Dave Patterson
Reproductive Tract Scores
Content by Dave Patterson
Exposure Data
Content by Dave Patterson?
Pregnancy Data
Content by Dave Patterson?
CE Scores
Content by Dave Patterson?
Data Collection on Mature Cows
Stayability
Content by Warren Snelling
Calf Record/Reason Code (for Stayability)
Pregnancy Data
Gestation Length
Calving Interval
Mature Height and Weight
content by Heather Bradford
Body Condition Scores
Content by Dave Lalman
Teat and Udder Scores
Content by David Riley
Foot and Leg Scores
content by Lane Giess
Intake
Adaptability-Related Traits
PAP Scores
Content by Mark Enns, Milt Thomas, and Scott Speidel
Hair Shedding
Content by Trent Smith
Genomic Data
Use of genomic data requires quality sample collection. Once samples are acquired and processed according to breed association specifications, the data can be incorporated into reporting systems for breed associations, including reporting schemes for monogenic traits such as horned/polled genotype or genetic abnormality carrier status as well as for quantitative traits, which will be utilized within either single-step genomic BLUP or single-step hybrid marker effects models for genetic prediction. Genotype data can also be utilized for other applications, as detailed below.
Parentage Testing
content by Megan Rolf
Data Collection for Commercial Producers
Content by Jackie Atkins and Chip Kemp
See Seedstock Data Collection (link)
Herd Measurements
Calving Distribution
Bull Measurements
Cow Measurements
MPPA
Data Collection at Feedlots
Content by Larry Kuehn
Average Daily Gain
Intake and Feed Efficiency
Health Traits
Carcass Data Collection at the Packing Plant
Content by Tommy Perkins