The study was aimed at sourcing and characterizing genotypes from different parts of Ebonyi State for use in future maize breeding. Therefore, conscious expeditions were made to the old 13 local government areas (LGAs) of Ebonyi State (Abakaliki, Afikpo North, Afikpo South, Ebonyi, Ezza North, Ezza South, Ikwo, Ishielu, Ivo, Ohaozara, Ohaukwu and Onicha). In each LGA, at least two cobs of each maize genotype were collected from their local market. A total of 26 local maize cultivars were collected. The maize genotypes collected from the 13 local councils were characterized based on location, seed colour, seed type, cob length, cob circumference, number of rows per cob, number of seeds per row, 100 seed weight (g) at 15.5% moisture content, kernel density (g/cm³) at 15.5% moisture content. After characterization, equal quantities of the samples were made from the 26 genotypes and taken to the laboratory for chemical analyses of nutritional contents such as percentage crude protein, oil, amylose and amylopectin. Results obtained showed that Ishiotu I and II both from Afikpo North had the longest cob length, cob circumference and number rows per cob. Ikwo yellow had the highest 100 seed weight and there is no doubt that this would result to higher grain yield. Significant and positive correlation were found between cob circumference and number of rows per cob (r = 0.526**). Number of seeds per row were also found to be significantly and positively correlated with cob length (r = 0.634**) and cob circumference (r = 0.458*). Kernel density was found to be significantly and positively correlated with amylose (r = 0.465*). It was also discovered that amylose had significant and negative correlation with amylopectin (r = -0.995**). Protein correlated positively with oil (r = 0.133), but was not significant. However, Ikwo yellow recorded the highest protein content of 8.06%. The low protein content in some other genotypes presents a great challenge to plant breeders in form of quality improvement. It was therefore concluded that maize genotypes for any breeding and/or improvement for agronomic and quality traits should necessarily include samples from Afikpo North and Ikwo LGAs of Ebonyi State. Also, these areas should be considered for both extensive and intensive cultivation of maize in furtherance of the present administration’s transformation agenda on agriculture.

Cameron, J.W. (1947). Chemico-genetic basis for the reserve carbohydrates in maize endosperm. Genetic. 32:459-485.

Chia, J.M, C. Song, P.J. Bradbury, et al. (2012). Maize HapMap2 identified extant variation from a genome in flux. Nt genet, 44:803-807. PubMed Abstract/Publidher Full Text.

Gen Stat (2007). Gen Stat for windows, Discover, 3rd edn. Lawes Agricultural Trust, Rothamsted Experimental Station, UK.

IITA (2011). International Institute for Tropical Agriculture. Annual report for the year 2011.

Kostova, A., E. Todorovska, N. Christov, V. Sevov and A. I. Atanassov (2006). Molecular characterization of Bulgarian maize germplasm collection via SSR markers. Biotechnol. Eq. 20(2):29-36.

Kramer, H.H and R.L. whistler (1949). Qualitative effects of certain genes on the amylase content of corn endosperm starch. Agron. Jour. 41. 409-411.

Losa, A., H. Hartings, A. Verderio and M. Motto (2011). Assessment of genetic diversity and relationships among maize inbred genotypes developed in Italy. Maydica 56 (1): 95-104.

Ngwuta, A, A., J.C. Harriman, G.C. Onyishi, O. Nze, J.O. Orji, E.O. Okporie and S.C. Chukwu (2013). Performance of maize genotypes for fresh maize consumption in Owerri west, south eastern Nigeria. Nig. J. Genetics 27: 115 – 126.

Obi, I.U. (1991). Maize, its Agronomy, Diseases, Pest and Food Values. Optimal Computer Solutions ltd. Enugu Publishers. 76 Agbani Road Enugu, Nigeria, XXVIII + pp: 206.

Obi, I.U. (2002). Statistical Methods of Detecting Differences Between Treatment Means and Research Methodology Issues in Laboratory and Field Experiments. 2nd Edition published by AP Express Publishers Ltd, 3 Obollo Road, Nsukka, Nigeria

Okporie E. O. (2008). Characterization of maize (Zea mays L.) Germplasm with principal component analysis. Agro – science: Jor. Of Trop. Agric., Food, Envir & Extn. Vol & No 1 66-71

Okporie E. O. and I. U. Obi (2004). Development of acid tolerant, high yielding and high nutritional maize variety after two years of mass selection. Sci. of Agric food tech and Envir. Vol .4 pp 23 – 30.

Okporie, E.O. (2000). Development of high quality green maize (Zea mays L.) varieties under acid soil conditions of south eastern Nigeria. Unpublished Ph.D thesis submitted to the Department of Crop science, University of Nigeria, Nsukka, Nigeria, XV+192

Okporie, E.O. (2006). Statistics for Agricultural and Biological Sciences. Cheston Agency Limited Enugu.

Okporie, E.O., S.C. Chukwu, and G.C. Onyishi (2013). Phenotypic Recurrent Selection for Increase Yield and Chemical Constituents of Maize (Zea mays L.). World Applied Sciences Journal 21 (7): 994-999

Zuber, M.S., W.L Deatherage , C.O Grogan and M.M. Mcmasters (1960). Chemical composition of kernel fraction of corn. Agron. J. 51: 572.

Liu, K, M. Goodman, S. Muse, J.S. Smith, E.S. Buckler and J. Doebley (2003). Genetic structure and diversity among maize inbred lines as inferred from DNA microasatellites. Genetics, 165: 2117-2128. pubMed Abstract/publisher full text/PubMed Central Full text.

Mazemouk, S., P. Dubreui, M. Bosio, L. Decousset, A. Charcosset, S. Praud and B. Mangin (2011). Effect of population structure corrections on the results of association mapping tests in complex maize diversity panels. Theor Appl Genet, 122:21149-1160. PubMed Abstract/Publisher full text/Pub Med Central full text.

Yan, J., M. Warburton and J. Crouch (2011). Association Mapping for Enhancing Maize (Zea mays L.) Genetic Improvement. Crop Sci, 51:433-449. Publisher Full Text.