Pregestational diabetes is a significant risk factor for congenital malformations including major structure birth defects and neural tube defects (NTDs). Maternal hyperglycemia increases the production of reactive oxygen species and impairs the intracellular antioxidant capability, leading to oxidative stress. Multiple evidence supports that hyperglycemia-induced oxidative stress causes malformations. Both in vivo and in vitro treatments with variety of antioxidants can effectively reduce hyperglycemia-induced NTDs. Overexpression of the antioxidant enzyme, superoxide dismutase 1 (SOD1), in transgenic mice ameliorates maternal diabetes-induced NTDs. Although oxidative stress appears to be a central mechanism underlying hyperglycemia-induced malformations, it is unclear whether the downstream intracellular signals mediate oxidative stress as well.

Oxidative stress activates multiple kinase signaling pathways. The protein kinase C (PKC) family consists of 12 isoforms that involve diverse physiological and pathophysiological functions including cell proliferation, differentiation, and apoptosis. In diabetic embryopathy, prolonged PKC activation is associated with maternal diabetes–induced NTDs. We have further reported that hyperglycemia specifically activates PKCα/βII and PKCδ. Specific pharmacological inhibitors to PKCα, PKCβII, or PKCδ have been shown to significantly reduce hyperglycemia-induced NTDs, strongly implicating that activation of these specific PKC isoforms plays a causative role in the induction of NTDs by hyperglycemia. PKC activation results in lipid peroxidation, which leads to cell membrane damage. PKC activation has been linked to altered arachidonic acid (AA) metabolism during lipidperoxidation.

In diabetic embryopathy, hyperglycemia-induced lipid peroxidation alters cell membrane lipid metabolism by shifting AA metabolism from prostaglandin E2 to isoprostanes. The loss of membrane AA destabilizes the cell membrane structure and function. Conversely, AA supplementation has been shown to reduce the incidence of diabetic embryopathy. In the present study, we wanted to determine whether oxidative stress–induced-specific PKC isoform activation triggers lipid peroxidation, which, in turns, intensifies the degree of oxidative stress in embryos exposed to hyperglycemia.

Besides the differential activation mechanisms of the 12 PKC isoforms, individual PKC isoforms exerts distinct physiological and pathophysiological functions via substrate specificity. A limited number of PKC substrate has been identified. Among the known PKC substrates, myristoylated alanine-rich protein kinase C substrate (MARCKS) is a prominent PKC substrate that primarily resides in neural tissues. Furthermore, it has been reported that MARCKS is a specific substrate of PKCβII and PKCδ.

Another prominent PKC substrate is the receptor for activated C kinase 1 (RACK1), which was originally discovered through its binding to active PKCβII and other classic PKC isoforms. RACK1 participates in multiprotein signaling complexes and can enhance PKC-dependent c-Jun-N-terminal kinase (JNK) activation, which plays a causative role in the induction of diabetic embryopathy. Therefore, in the present study, we assessed the activation and levels of these 2 PKC substrates with a goal of defining the role of PKC substrates in oxidative stress-mediated teratogenicity in diabetic embryopathy.

The connection between oxidative stress and PKC activation has not been explored. Because both SOD1 overexpression in vivo and PKC inhibition in vitro reduce hyperglycemia-induced malformations, in the present study, we used SOD1-transgenic (Tg) mice to test whether SOD1 overexpression in vivo blocks hyperglycemia-induced specific PKC isoforms activation and its downstream cascade.