Integration of Wet-Lab Measures, Milk Infrared Spectra, and Genomics to Improve Difficult-to-Measure Traits in Dairy Cattle Populations

Overview

Journal Front Genet

Date 2020 Nov 2

PMID 33133149

Citations 5

Authors

Alessio Cecchinato

Hugo Toledo-Alvarado

Sara Pegolo

Attilio Rossoni

Enrico Santus

Christian Maltecca

Giovanni Bittante

Francesco Tiezzi

Affiliations

Soon will be listed here.

Abstract

The objective of this study was to evaluate the contribution of Fourier-transformed infrared spectroscopy (FTIR) data for dairy cattle breeding through two different approaches: (i) estimating the genetic parameters for 30 measured milk traits and their FTIR predictions and investigating the additive genetic correlation between them and (ii) evaluating the effectiveness of FTIR-derived phenotyping to replicate a candidate bull's progeny testing or breeding value prediction at birth. Records were available from 1,123 cows phenotyped using gold standard laboratory methodologies (LAB data). This included phenotypes related to fine milk composition and milk technological characteristics, milk acidity, and milk protein fractions. The dataset used to generate FTIR predictions comprised 729,202 test-day records from 51,059 Brown Swiss cows (FIELD data). A first approach consisted of estimating genetic parameters for phenotypes available from LAB and FIELD datasets. To do so, a set of bivariate animal models were run, and genetic correlations between LAB and FIELD phenotypes were estimated using FIELD information obtained at the population level. Heritability estimates were generally higher for FIELD predictions than for the corresponding LAB measures. The additive genetic correlations (r ) between LAB and FIELD phenotypes had different magnitudes across traits but were generally strong. Overall, these results demonstrated the potential of using FIELD information as indicator traits for the indirect genetic improvement of LAB measures. In the second approach, we included genotype information for 1,011 cows from the LAB dataset, 1,493 cows from the FIELD dataset, 181 sires with daughters in both LAB and FIELD datasets, and 540 sires with daughters in the FIELD dataset only. Predictions were obtained using the single-step GBLUP method. A four fold cross-validation was used to assess the predictive ability of the different models, assessed as the ability to predict masked LAB records from daughters of progeny testing bulls. The correlation between observed and predicted LAB measures in validation was averaged over the four training-validation sets. Different sets of phenotypic information were used sequentially in cross-validation schemes: (i) LAB cows from the training set; (ii) FIELD cows from the training set; and (iii) FIELD cows from the validation set. Models that included FIELD records showed an improvement for the majority of traits. This study suggests that breeding programs for difficult-to-measure traits could be implemented using FTIR information. While these programs should use progeny testing, acceptable values of accuracy can be achieved also for bulls without phenotyped progeny. Robust calibration equations are, deemed as essential.

Citing Articles

Multiple-trait genomic prediction for swine meat quality traits using gut microbiome features as a correlated trait.

Tiezzi F, Schwab C, Shull C, Maltecca C J Anim Breed Genet. 2024; 142(1):102-117.

PMID: 38985010 PMC: 11629054. DOI: 10.1111/jbg.12887.

Use of Milk Infrared Spectral Data as Environmental Covariates in Genomic Prediction Models for Production Traits in Canadian Holstein.

Tiezzi F, Fleming A, Malchiodi F Animals (Basel). 2022; 12(9).

PMID: 35565615 PMC: 9099576. DOI: 10.3390/ani12091189.

Comparison of Single-Breed and Multi-Breed Training Populations for Infrared Predictions of Novel Phenotypes in Holstein Cows.

Mota L, Pegolo S, Baba T, Morota G, Penagaricano F, Bittante G Animals (Basel). 2021; 11(7).

PMID: 34359121 PMC: 8300349. DOI: 10.3390/ani11071993.

Phenotypic and genetic variation of ultraviolet-visible-infrared spectral wavelengths of bovine meat.

Bittante G, Savoia S, Cecchinato A, Pegolo S, Albera A Sci Rep. 2021; 11(1):13946.

PMID: 34230594 PMC: 8260661. DOI: 10.1038/s41598-021-93457-5.

Integrating genomic and infrared spectral data improves the prediction of milk protein composition in dairy cattle.

Baba T, Pegolo S, Mota L, Penagaricano F, Bittante G, Cecchinato A Genet Sel Evol. 2021; 53(1):29.

PMID: 33726672 PMC: 7968271. DOI: 10.1186/s12711-021-00620-7.

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