Interleukin-6 and its Contribution to Embryogenesis in Cattle

Speckhart, Savannah Laurel

10 May 2023

In vitro systems like those used for in vitro embryo production are invaluable for our understanding of embryogenesis and the processes that regulate it. However, extensive research has also highlighted that in vitro produced embryos negatively differ from their in vivo counterparts in various ways. Not surprisingly, there is ~20% decrease in pregnancy success from pregnancies established using in vitro produced embryos. Therefore, much research has relied on attempting to produce a better in vitro embryo that more closely resembles their in vivo counterparts. Our laboratory has investigated this by supplementing a cytokine, interleukin-6 (IL6), during in vitro embryo culture. My dissertation work expands upon those initial efforts by answering more detailed questions related to the biological role of IL6 during cattle embryogenesis. In the work presented herein, IL6 supplementation during in vitro culture was able to transform the transcriptome of resulting conceptuses post embryo transfer. The transcriptome of these conceptuses included an abundance of genes associated with survival. Indeed, we witnessed IL6-treated conceptuses resulted in a 20% increased survival rate and were longer than their non-treated counterparts. In the second research project, we employed CRISPR-Cas9 genome editing technology to understand the embryo phenotype after part of the IL6 receptor responsible for signal transduction, interleukin-6 signal transducer (IL6ST), is disrupted. We discovered that IL6ST is required for development before the blastocyst stage. In addition, IL6ST disrupted blastocysts, presumed to contain wildtype, presented with severe, abnormal morphology. Not only did this group of embryos have decreased ICM and TE cell numbers, but they also had an increased occurrence of cells within the TE region that were negative for its traditional marker, CDX2. This suggests IL6ST is likely involved in a pathway responsible for determining cell fate identity at the blastocyst stage. Collectively, IL6 in cooperation with IL6ST, is a key controller of embryogenesis in cattle. / Doctor of Philosophy / There are major events that an embryo must successfully advance from to continue development to form into an organism capable of survival after birth. Over 30% of pregnancies in cattle and humans will fail within the first 30 days of gestation. This time period coincides with several key developmental events that ultimately modify the morphology of the growing embryo. Our laboratory primarily focuses on embryo development around the blastocyst stage. If an embryo advances to this stage, it has a greater likelihood of maintaining viability. Therefore, my dissertation research has focused on early embryonic development from the time of first cleavage (~day 2 of gestation) through embryo elongation (~day 15 of gestation), which encompasses the blastocyst stage. Within this time frame, I have been investigating embryonic effects after supplementation of a protein, interleukin-6 (IL6). Previously, our laboratory has identified IL6 to cause favorable impacts on the developing embryo, but its mode of action was unknown. Therefore, my dissertation research has investigated the mechanistic actions of IL6, and its beta receptor subunit, interleukin-6 signal transducer (IL6ST). In my first research project, we discovered that supplementing IL6 during in vitro embryo culture resulted in increased embryo elongation and survival. In my second research project, we found IL6ST is an absolute requirement for embryo survival to the blastocyst stage. Together, these results indicate IL6 is a very important protein needed for sustained pregnancy viability.

blastocyst

conceptus

cow

embryo

elongation

embryokine

gene-editing

interleukin-6

interleukin-6 signal transducer