Patterns of KIR-genotypes in women with preimplantation losses after assisted reproductive technologies

  • K. O. Sosnina State Institution «Institute of Hereditary Pathology of the National Academy of Medical Sciences of Ukraine», Ukraine, 79008, Lviv, M. Lysenko str., 31a https://orcid.org/0000-0003-4527-2010
  • D. V. Zastavna State Institution «Institute of Hereditary Pathology of the National Academy of Medical Sciences of Ukraine», Ukraine, 79008, Lviv, M. Lysenko str., 31a https://orcid.org/0000-0002-3858-7180
  • B. I. Tretiak State Institution «Institute of Hereditary Pathology of the National Academy of Medical Sciences of Ukraine», Ukraine, 79008, Lviv, M. Lysenko str., 31a https://orcid.org/0000-0001-6425-4497
  • O. I. Terpylyak State Institution «Institute of Hereditary Pathology of the National Academy of Medical Sciences of Ukraine», Ukraine, 79008, Lviv, M. Lysenko str., 31a https://orcid.org/0000-0001-6274-8362
Keywords: natural killer cells, KIR genes, preimplantation losses, assisted reproductive technologies

Abstract

Aim. To analyze the frequency and distribution of KIR genotypes in women with repeated preimplantation losses during ARTs compared to women with control group. Methods. DNA isolation from leukocytes by the salting method, PCR-SSP, agarose gel electrophoresis; methods of statistical analysis. Results. The molecular genetic determination of KIR genes in the group of women with recurrent implantation failures and in the control group of women was performed. The frequency and distribution of KIR genotypes in the study groups were determined. In women with RIF, a slightly shifted distribution of the frequency of KIR genotypes was found, towards the homozygous genotype by haplotype "A", the frequency of which was almost half of all identified genotypes (42.86 %). The distribution and frequency of KIR genotypes in the control group was normal and described by the Hardy-Weinberg principle. A comparative analysis of the study groups using statistical methods showed a significantly higher frequency of the KIR-AA genotype (χ2=8.875; p<0.005) in the group of women with RIF compared to the control group of women. The calculation of the odds ratio indicates a 2-fold increase of risk for recurrent implantation failures after ARTs (OR=1.94; CI 95 %: 1.25–3.00) in women with the KIR-AA genotype. Conclusions. We regard the KIR-AA genotype as a significant risk factor for preimplantation loss. KIR genotyping is considered an important molecular genetic test for determining the risk of fetal rejection by the maternal immune system, which will help to correctly direct treatment interventions to keep the pregnancy alive.

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