The outermost layer of the epidermis, stratum corneum (SC), is composed of corneocytes, which are embedded in extracellular lipids, including ceramides. SC functions as an epidermal permeability barrier to defend our body against external threats, such as UV irradiation and pathogens ^[11][12]. Ceramides, a class of sphingolipids containing a backbone of a sphingoid base (or referred to as sphingosine) that is linked to a fatty acid (FA) via an amide bond, are the predominant lipid comprising approximately 50% of the SC lipid content by mass, and the most effective structural component for the formation of the epidermal permeability barrier ^[11][12]. Ceramides are produced in the skin through two major pathways ^[12][13]: (i) the de novo synthesis pathway that is initiated by serine palmitoyltransferase (SPT) and catalyzes the condensation of serine and palmitoyl-CoA to produce 3-ketosphiganine, which is further metabolized to sphinganine. Sphinganine is then amide-linked (N-acylated) by ceramide synthases (CerSs) to generate ceramides with different acyl chain lengths; and (ii) the sphingomyelinase (SMase)-dependent hydrolysis of sphingomyelin, a key component of the plasma membrane. In the present study, we show that N-palmitoyl serinol (PS) differently regulates ceramide generation in different cellular conditions, i.e., stressed/diseased condition vs. un-stressed (normal) condition. Because an IL-4-mediated decrease in ceramides could cause abnormal barrier functions—induction of excessive transepidermal water loss, and an increased risk of pathogenic infection—PS likely accelerates the enhancement of the skin barrier function by a prompt increase in ceramide content due to the SM hydrolysis pathway, through activation of SMases in the plasma membrane as well as the SPT/CerS-mediated de novo synthesis pathway under stressed conditions, compared with un-stressed conditions, in which the SPT-mediated de novo synthesis pathway is only operated.

Prior studies have demonstrated that epidermal ceramide levels are altered (increased or decreased) in certain skin inflammatory environments, such as atopic dermatitis (AD) ^[13][15]. Ceramide levels are significantly reduced in the lesional skin of patients with AD, a chronic inflammatory skin disease in which the Th2 cytokines, e.g., IL-4 and IL-13, are key drivers involved with the underlying inflammatory process ^[14][16]. In particular, ceramides containing long-chain FAs (22–26 carbons in length) are significantly decreased, while ceramides with short-chain FAs (<20 carbons in length) are, conversely, increased in the lesional skin of patients with AD ^[15][16][17][17,18,19]. Of six CerS isoforms, both CerS2 and CerS3 are expressed at high levels in the skin and have been shown to synthesize the longer ceramide species; whereas other isoforms of CerS are associated with the production of ceramide species containing the shorter FAs ^[15][16][17,18]. Consistent with these findings, PS selectively activates CerS2 and CerS3 to elevate ceramides with 22–26 carbon-containing FAs, which are particularly responsible for the formation of the epidermal permeability barrier in both un-stressed or stressed conditions.

The endocannabinoid system (ECS) has lately been proven to be an important signaling network that modulates a wide range of biological responses in multiple tissues, including the skin, which expresses endocannabinoids such as anandamide, 2-AG, and the endocannabinoid receptor CB1 and/or CB2 ^[8][18][8,20]. Prior studies showed that endocannabinoids could regulate ceramide production via the endocannabinoid receptor CB1-mediated signaling events in certain neuronal cells or cancer cells, e.g., astrocytes, glial cell, glioma cell, as follows ^[5][8][19][5,8,21]: (i) CB1 activation increases the catalytic action of SMase, which hydrolyze SM to ceramide in the plasma membrane via the factor associated with neutral SMase (FAN)-containing signaling complex-mediated cellular mechanism; (ii) CB1 activation stimulates the activity of de novo synthetic SPT that increases condensation of serine and palmitoyl-CoA to produce ceramide. However, to our knowledge, it has not been identified if the endocannabinoid receptor CB1 is coupled to the generation of ceramide in the skin. We demonstrate here that PS, an analog of the endocannabinoid N-palmitoyl ethanolamine, increases ceramide production by both de novo synthesis and SM hydrolysis pathways to stimulate epidermal barrier integrity under an in vitro AD-like model. Although we first showed the relationship of ECS and ceramide generation in the skin, further studies are still needed to identify the more detailed mechanism(s) of how PS stimulates ceramide production, i.e., the involvement of the FAN-containing signaling complex.

In summary, our studies revealed that the PS-mediated activation of CB1 accounts for the generation of epidermal ceramides through the de novo synthesis and SM hydrolysis pathways. In particular, PS selectively elevates ceramides with 22–26 carbon-containing FAs via activation of CerS2 and CerS3. These findings indicate that PS likely contributes to improving the epidermal barrier function of certain skin diseases, such as atopic dermatitis and aged skin, in which ceramide levels are dramatically diminished. Hence, pharmacological modulation of CB1 by endocannabinoids, or its analogs, might be considered as therapeutic and/or preventive strategies for such skin conditions.