Data in this study were collected from live body weight records and milk yield for the first three lactations of Egyptian buffaloes maintained at the Mahallet Mousa Experimental Station of Animal Production Research Institute, relying on 987 records of Egyptian buffaloes spread over 16 years. These data were analyzed to estimate genetic parameters using animal model. Overall means in kilograms of BW, WW, W18, WFC, 1stMY, 2ndMY and 3rdMY were 36.56, 96.95, 322.02, 462.09, 1561.53, 1755 and 1837.71, respectively. Direct additive heritability (h2a) for mentioned traits were 0.31, 0.22, 0.24, 0.27, 0.23, 0.23 and 0.17, respectively. Corresponding computation of maternal heritability (h2m) for same traits were 0.39, 0.34, 0.22, 0.40, 0.29, 0.31 and 0.21, respectively. Evaluation of genetic correlations among different all studied traits were positive and ranged from 0.07 to 0.83, while phenotypic correlations were positive and ranged from 0.02 to 0.55. Accuracy of (PBV's) varying from 62 to 76, 62 to 83 and 41 to 77% for sires, cows and dams, successively; pointing out the genetic improvement could be achieved through any pathway of them. Higher direct and maternal heritability for BW and WFC and genetic correlations between first three lactations milk yield and each of BW and WFC higher than genetic correlations between first three lactations milk yield and WW and W18. Therefore, it is appropriate to select buffalo female calves for live body weight at birth than for live body weights at other ages.

Improve milk yield, growth traits, genetic parameters, breeding values and Egyptian buffaloes.

Agudelo-Gómez DA., Pelicioni Savegnago R, Buzanskas ME,. Ferraudo AS, Prado Munari D and Cerón-Muñoz MF. 2015. Genetic principal components for reproductive and productive traits in dual-purpose buffaloes in Colombia. J. Anim. Sci., 93:3801-3809.

Ahmad M, Javed K, Shahzad W, Mehmood F and Khan M H. 2013. Some environmental factors affecting performance traits in registered Nili Ravi buffalo population at field area of Pakistan. Buffalo Bulletin, 32: 764-767.

Albuquerque LG and Meyer K. 2001. Estimates of covariance functions for growth from birth to 630days of age in Nellore cattle. J. Anim., Sci., 79:2776–2789.

Al-Shorepy S A, Alhadrami GA and Abdul Wahab K. 2002. Genetic and phenotypic parameters for early growth traits in Emirati goat. Small Rumin. Res., 45: 217–223.

Awad SH. and Afify AA. 2014. Estimation of genetic and phenotypic parameters for growth traits of Egyptian buffaloes using MTDFREML program. J. Agric. Res. Kafr El-sheikh Univ., 40:742-754.

Boldman KG, Kriese LA, Van Vleck LD and Kachman SD. 1995. Amanual for use of MTDFREML. A set for programs to obtain estimates of variances and covariance (DRAFT). U.S. Department of Agriculture, Agriculture Research Service, Clay Center, NE, USA.

Boligon AA, Albuquerque LG., Mercadante MEZ, Lôbo RB. 2009. Herdabilidades e correlações entre pesos do nascimento à idade adulta em rebanhos da raça Nelore. Rev.Bras. Zootec, 38:2320–2326.

Bourdon RM. 2000. Understanding animal breeding. 2nd ed. Prentice Hall, Upper Saddle River, NJ.

Chud TCS, Caetano SL., Buzanskas ME, Grossi DA, Guidolin DGF, Nascimento GB, Rosa JO, Lôbo RB and Munar DP. 2014. Genetic analysis for gestation length, birth weight, weaning weight, and accumulated productivity in Nellore beef cattle. Livestock Sci., 170:16–21

El-Awady HG, Ashour AF and Shamia SM. 2016. Genetic and economic evaluation for the relationship between somatic cell counts, milk yield and milk constituents in Egyptian buffaloes. Buffalo Bulletin, 35:617-628.

El-Awady HG, Shalaby NA and Mourad KA. 2005. Variance components due to direct and maternal effects and estimation of breeding values for some growth traits of Egyptian buffalo calves. J. Agric. Sci. Mansoura Univ., 30:7425– 7436.

El-Bramony MM. 2011. Genetic and phenotypic parameters of milk yield and reproductive performance in the first three lactations of Egyptian buffalo. Egyptian J. Anim. prod., 48:1-10.

El-Bramony MM. 2014. Estimation of genetic and phenotypic parameters for milk yield, lactation length, calving interval and body weight in the first lactation of Egyptian buffalo. Life Sci. J., 11:1012-1119.

Eyduran E, Karakus K, Karakus S and Cengiz F. 2009. Usage of factor scores for determining relationships among body weight and somebody measurements. Bulgarian J. Agric. Sci., 15: 374-378.

Falleiro V, Silveira ES, Ramos AA, Carneiro PLS, Carrillo JA and Malhado CHM. 2013. Genetic parameters for growth traits of Mediterranean buffaloes from Brazil, estimated by Bayesian inference. Buffalo Bulletin, 32:627-631.

Fooda TA. 2005. Possibilities of improving 12-month weight of Egyptian buffaloes by selection index. Ph.D. Thesis Fac. Agric. Ain Shams Univ. Cairo, Egypt.

Guidolin, DGF, Buzanskas ME, Ramos SB, Venturini GC, Lôbo RB, Paz CCP, Munari DP and Oliveira JA. 2012. Genotype–environment interaction for post-weaning trait in Nellore beef cattle. Anim. Prod. Sci., 5:975–980.

Gupta JP, Sachdeva GK, Gandhi RS and Chakaravarty AK. 2015. Developing multiple-trait prediction models using growth and production traits in Murrah buffalo. Buffalo Bulletin, 34: 347-355.

Haile-Mariam M, Bowman PJ, and Goddard ME. 2003. Genetic and environmental relationship among calving interval, survival, persistency of milk yield and somatic cell count in dairy cattle. J. Dairy Sci., 80:189-200.

Hanford KJ, Van Vleck LD and Snowder GD. 2006. Estimates of genetic parameters and genetic trend for reproduction, weight, and wool characteristics of poly pay sheep. Livest. Sci., 102: 72–82.

Harvey WR. 1990. User’s guide For LSMLMW, mixed model least squares program. PC-2 Version. Ohio State. University, Columbus (Mimeograph), USA.

Karakus K, Aygun T, Budag C, Eyduran E and Ozdemir T. 2010. Some factors influencing the birth weights of Norduz kids. Bulgarian J. Agric. Sci., 16: 242-245.

Kaygisiz A, Bakir G and Yilmaz I. 2012. Genetic parameters for direct and maternal effects and an estimation of breeding values for birth weight of Holstein Friesian calves. Bulgarian J. Agri. Sci., 18:117-124.

Mandal A, Neser FWC, Rout PK, Roy R and Notter DR. 2006. Estimation of direct and maternal (co)variance components for pre-weaning growth traits in Muzaffarnagari sheep. Livest. Sci., 9:79–89.

Nutrient Requirements of Beef Cattle. 1996. 7th Rev. Ed. National Academy Press: Washington, DC.

Portolano B, Todaro M, Finocchiaro R and Van Kaam JH. 2002. Estimation of the genetic and phenotypic variance of several growth traits of the Sicilian Girgentana goat. Small Rumin. Res., 45:247–253.

Salces AJ, Bajenting PG and Salces BC. 2013. Estimation of genetic parameters for growth traits of three genotypes of water buffalo bulls raised on a ranching operation. Buffalo Bulletin, 32:760-763.

Sanghuayphrai N, Nakavisut S, Dongpaletum CT, Phothikanit G and Supanun S. 2013. Genetic parameters and trends for weaning weight and calving interval of department of livestock development Swamp buffalo. Buffalo Bulletin, .32:717-722.

Thiruvenkadan AK, Panneerselvam S and Rajendran R. 2009. Non-genetic and genetic factors influencing growth performance in Murrah Buffalos. South African J. of Animal Sci., 39:102-106.

Yadav TB and Singh CV. 2016. Estimation of genetic parameters of first lactation and herd life traits by different animal models in Murrah buffaloes. Animal Molecular Breeding, 6:1-12.