Early Life Exposure to C16-Ceramide Improves Learning and Short-Term Memory Behavior during Adulthood in Mice.

Ceramides, structural components of the cell, are known to play a range of roles in glucose metabolism and apoptosis. C16-ceramide, an abundant molecular species of endogenous ceramide, has not had its influence on learning and memory explored. We administered C16-ceramide to mice immediately after weaning and examined the learning and memory behavior of these mice during adulthood. Mice given C16-ceramide early in life showed improved adult learning/short-term memory behavior without affecting their glucose metabolism. Looking for a plausible mechanism for this, we found that calcium influx, CaMKII/CREB, and the Erk-relevant signaling transduction are increased after C16-ceramide stimulation in primary neurons in vitro. Possible downstream epigenetic molecular events, such as H3K4 methylation and Egr-1 abundance, were also found to be upregulated. Utilizing J20 mice, an Alzheimer disease mice model in which mice were injected after weaning with C16-ceramide, we found that these mice also show improved learning and short-term memory behavior when assessed by the Morris water maze test. Taken together, giving C16-ceramide early in life would seem to benefit learning and short-term memory behavior during adulthood.

Association of mSin1 with mTORC2 Ras and Akt reveals a crucial domain on mSin1 involved in Akt phosphorylation.

mSin1 is a unique component within the mammalian target of rapamycin (mTOR) complex 2 (mTORC2), which is responsible for cellular morphology and glucose metabolism. The association between mSin1 and other mTORC2 components, as well as their functions, has been explored previously; nevertheless, the mapping of the various binding domains of the components is lacking. Based on an evolutionary analysis of the gene, we constructed various fragments and truncated-forms of mSin1. We characterized the individual binding sites of mSin1 with its various partners, including mTOR, Rictor, Ras, and Akt. mTOR and Rictor bind to the amino acid (aa) 100-240 region of mSin1, which is different to the Ras binding site, the aa 260-460 region. A reciprocal examination found that mSin1 associated with the aa 2148-2300 region of mTOR, which is within the kinase domain, and with the carboxyl terminus of Rictor. Interestingly, Akt was found to associate with mSin1 in a region that slightly overlapped with the mTOR/Rictor complex binding site, namely aa 220-260. When only the Akt binding site was deleted from mSin1, phosphorylation of Akt S473 was greatly reduced. Furthermore, the association between Akt and mTOR can be regulated by serum, insulin and LY294002, but not by rapamycin or MAPK kinase inhibitors. Taken together, mSin1 would seem to act as a hub that allows mTORC2 to phosphorylate Akt S473. Our findings should facilitate future proteomic and crystallographic studies, help the development of dominant inhibitors and promote the identification of new drug targets.

Heterogeneous nuclear ribonucleoprotein M associates with mTORC2 and regulates muscle differentiation.

Mammalian target of rapamycin (mTOR) plays a range of crucial roles in cell survival, growth, proliferation, metabolism, and morphology. However, mTOR forms two distinct complexes, mTOR complex 1 and mTOR complex 2 (mTORC1 and mTORC2), via association with a series of different components; this allows the complexes to execute their wide range of functions. This study explores further the composition of the mTORC2 complex. Utilizing Rictor knock-out cells, immunoprecipitation and mass spectrometry, a novel Rictor associated protein, heterogeneous nuclear ribonucleoprotein M (hnRNP M), was identified. The association between hnRNP M and Rictor was verified using recombinant and endogenous protein and the binding site was found to be within aa 1~532 of hnRNP M. The presence of hnRNP M significantly affects phosphorylation of SGK1 S422, but not of Akt S473, PKCα S657 and PKCζ T560. Furthermore, hnRNP M also plays a critical role in muscle differentiation because knock-down of either hnRNP M or Rictor in C2C12 myoblasts reduced differentiation. This decrease is able to be rescued by overexpression SGK S422D in hnRNP M knockdown C2C12 myoblasts. Taken together, we have identified a novel Rictor/mTOR binding molecule, hnRNP M, that allows mTORC2 signaling to phosphorylate SGK1 thus regulating muscle differentiation.