FAM83H and casein kinase I regulate the organization of the keratin cytoskeleton and formation of desmosomes.

FAM83H is essential for the formation of dental enamel because a mutation in the FAM83H gene causes amelogenesis imperfecta (AI). We previously reported that the overexpression of FAM83H often occurs and disorganizes the keratin cytoskeleton in colorectal cancer cells. We herein show that FAM83H regulates the organization of the keratin cytoskeleton and maintains the formation of desmosomes in ameloblastoma cells. FAM83H is expressed and localized on keratin filaments in human ameloblastoma cell lines and in mouse ameloblasts and epidermal germinative cells in vivo. FAM83H shows preferential localization to keratin filaments around the nucleus that often extend to cell-cell junctions. Alterations in the function of FAM83H by its overexpression, knockdown, or an AI-causing truncated mutant prevent the proper organization of the keratin cytoskeleton in ameloblastoma cells. Furthermore, the AI-causing mutant prevents desmosomal proteins from being localized to cell-cell junctions. The effects of the AI-causing mutant depend on its binding to and possible inhibition of casein kinase I (CK-1). The suppression of CK-1 by its inhibitor, D4476, disorganizes the keratin cytoskeleton. Our results suggest that AI caused by the FAM83H mutation is mediated by the disorganization of the keratin cytoskeleton and subsequent disruption of desmosomes in ameloblasts.

LC3, a microtubule-associated protein1A/B light chain3, is involved in cytoplasmic lipid droplet formation.

The cytoplasmic lipid droplet (LD) is one of organelles that has a neutral lipid core with a single phospholipid layer. LDs are believed to be generated between the two leaflets of the endoplasmic reticulum (ER) membrane and to play various roles, such as high effective energy storage. However, it remains largely unknown how LDs are generated and grow in the cytoplasm. We have previously shown that the Atg conjugation system that is essential for autophagosome formation is involved in LD formation in hepatocytes and cardiac myocytes. We show here that LC3 itself is involved in LD formation by using RNA interference (RNAi). All cultured cell lines examined, in which the expression of LC3 was suppressed by RNAi, showed reduced LD formation. Triacylglycerol, a major component of LDs, was synthesized and degraded in LC3 mRNA-knockdown cells as well as in control cells. Interestingly, potential of the bulk protein degradation in the knockdown-cells was also evident in the control cells. These findings indicate that LC3 is involved in the LD formation regardless of the bulk degradation, and that LC3 has two pivotal roles in cellular homeostasis mediated by autophagy and lipid metabolism.

Autophagic neuron death.

Neurons of the central nervous system (CNS) tissue are terminally differentiated cells and have large volumes, unlike cells of peripheral tissues. Such neurons possess abundant lysosomes in which damaged and unneeded intracellular constituents are degraded. A cellular process to bring the unneeded constituents to lysosomes is referred to as macroautophagy (autophagy), which is essential for the maintenance of cellular metabolism under physiological conditions. In fact, mice deficient in Atg7 or Atg5 specifically in CNS tissue have ubiquitin aggregates in neurons and massive loss of cerebral and cerebellar cortical neurons, resulting in neurodegeneration and short life span. In addition, acceleration of autophagy induced by the loss of lysosomal proteinases such as cathepsin D or cathepsins B and L, or by hypoxic/ischemic (H/I) brain injury, causes neurodegeneration. Moreover, lysosomes with undigested materials due to loss of proteinases are enwrapped by double membranes to produce autophagosomes, resulting in the further accumulation of autolysosomes. H/I brain injury at birth that is an important cause of cerebral palsy, mental retardation, and epilepsy causes energy failure, oxidative stress, and unbalanced ion fluxes, leading to a high induction of autophagy in brain neurons. Since mice that are unable to execute autophagy (due to brain-specific deletion of Atg7 or Atg5) die as a result of massive loss of cerebral and cerebellar neurons with accumulation of ubiquitin aggregates, induction of neuronal autophagy after H/I injury is generally considered neuroprotective, as it maintains cellular homeostasis. However, our data showing that H/I injury-induced pyramidal neuron death in the neonatal hippocampus is largely prevented by Atg7 deficiency indicate the presence of autophagic neuron death. In this section, we introduce various methods for the detection of autophagic neuron death in addition to other death modes of CNS neurons.