Publications
For a complete list of publications, please go to my . Google Scholar
- Yildiz H, Yildirim BŞ, Öztürk SDK, Tek AL (2021) Bitki kromozomlarında sentromerlerin önemi, moleküler yapısı ve organizasyonu. Int J Adv Eng Pure Sci. 33:308–323. PDF .
- Öztürk SDK, Yildirim BŞ, Yildiz H, Tek AL (2021) Geçmişten günümüze genetik ve kromozom mühendisliği çalışmalarının sürdürülebilir tarım ve bitki islahına katkısı. YYU J AGR SCI. 31:246–258. PDF .
- Tek AL, Kara Öztürk SD. 2020. High allelic diversity of the centromere-specific histone H3 (CENH3) in the legume sainfoin (Onobrychis viciifolia). Mol Biol Rep 47:8789–8795.
- Santos AP, Gaudin V, Mozgová I, Pontvianne F, Schubert D, Tek AL, Dvořáčková M, Liu C, Fransz P, Rosa S, Farrona S. 2020. Tidying-up the plant nuclear space: domains, functions, and dynamics. J Exp Bot 71: 5160-5178.
- Tek A.L., R.M. Stupar and K. Nagaki. 2015. Modification of centromere structure: a promising approach for haploid line production in plant breeding. Turk J Agric For. 39: 557-562. Invited review in a special issue. PDF
- Tek A.L., K. Kashihara, M. Murata and K. Nagaki. 2013. Identification of the centromere-specific histone H3 variant in Lotus japonicus. Gene. 538: 8-11. PubMed
- *Iwata, A, A.L.*Tek, M.M.S. Richard, B. Abernathy, A. Fonseca, J. Schmutz, N.W.G. Chen, V. Thareau, C. Magdelenat, Y. Li, M. Murata, A. Pedrosa-Harand, V. Geffroy, K. Nagaki and S.A. Jackson. 2013. Identification and characterization of functional centromeres of common bean. Plant J. 76: 47–60. *equal-contributions. PubMed
- Tek A.L., K. Kashihara, M. Murata and K. Nagaki. 2011. Functional centromeres in Astragalus sinicus include a compact centromere-specific histone H3 and a 20-bp tandem repeat. Chromosome Res. 19: 969-978. PubMed
- Tek A.L., K. Kashihara, M. Murata and K. Nagaki. 2010. Functional centromeres in soybean include two distinct tandem repeats and a retrotransposon. Chromosome Res. 18: 337-347. PubMed
- Tek, A.L., J. Song, J. Macas and J. Jiang. 2005. Sobo, a recently amplified satellite repeat of potato, and its implications for the origin of tandemly repeated sequences. Genetics. 170: 1231-1238. PubMed
- Dong, F., A.L. Tek, A.B.L. Frasca, J.M. McGrath, S.M. Wielgus, J.P. Helgeson and J. Jiang. 2005. Development and characterization of potato-Solanum brevidens chromosomal addition/substitution lines. Cytogenet. Genome Res. 109: 368-372. PubMed
- Kuang, H., F. Wei, M.R. Marano, U. Wirtz, X. Wang, J. Liu, W.P. Shum, J. Zaborsky, L.J. Tallon, W. Rensink, S. Lobst, P. Zhang, C-E. Tornqvist, A.(L.) Tek, J. Bamberg, J. Helgeson, W. Fry, F. You, M-C. Luo, J. Jiang, C.R. Buell and B. Baker. 2005. The R1 resistance gene cluster contains three groups of independently evolving, type I R1 homologues and shows substantial structural variation among haplotypes of Solanum demissum. Plant J. 44: 37-51. PubMed
- Tek, A.L. and J. Jiang. 2004. The centromeric regions of potato chromosomes contain megabase-sized tandem arrays of telomere-similar sequence. Chromosoma. 113: 77-83. PubMed
- Tek, A.L., W.R. Stevenson, J.P. Helgeson and J. Jiang. 2004. Transfer of tuber soft rot and early blight resistances from Solanum brevidens into cultivated potato. Theor. Appl. Genet. 109: 249-254. PubMed
- Stupar, R.M., J. Song, A.L. Tek, Z. Cheng, F. Dong and J. Jiang. 2002. Highly condensed potato pericentromeric heterochromatin contains rDNA-related tandem repeats. Genetics. 162:1435-1444. PubMed