One of the most incredible features of cellular life is the capability of self-replication. And built into the remarkable process of cell division are several checkpoints that ensure the success of this life or death cellular practice. But can a Darwinian mechanism take the credit for this elegant cellular system? On this ID The Future, host Andrew McDiarmid continues his four-part conversation with Dr. Jonathan McLatchie on the intelligent design and irreducible complexity of eukaryotic cell division. In this segment, Dr. McLatchie describes each checkpoint and the role it plays in successful self-replication. This is Part 3 of a four-part series. Read More ›
Could the components of the eukaryotic cell division process have arisen through a gradual, unguided process? On this ID The Future, Dr. Jonathan McLatchie casts light on the unlikelihood of this proposition as he continues a four-episode series with host Andrew McDiarmid on the intelligent design and irreducible complexity of eukaryotic cell division. In this segment, McLatchie dives into some of the key molecular machinery responsible for the success of mitosis: the mitotic spindle and the motor proteins that aid in its assembly and function, explaining why their origin is beyond the reach of a Darwinian process. Read More ›
On this ID The Future, host Andrew McDiarmid begins a short series with Dr. Jonathan McLatchie delving into the remarkable design and irreducible complexity of the eukaryotic cell cycle. The pair review the differences between prokaryotic and eukaryotic cells, the phases involved in eukaryotic cell division, and the concept of irreducible complexity. They explore how various components of the cell division process, such as kinetochores and microtubules, are essential for successful mitosis and why these systems are more likely the product of intelligent design rather than an unguided evolutionary process. Read More ›