Pathological implications of cadherin zonation in mouse liver.

Both acute and chronic liver diseases are associated with ample re-modeling of the liver parenchyma leading to functional impairment, which is thus obviously the cause or the consequence of the disruption of the epithelial integrity. It was, therefore, the aim of this study to investigate the distribution of the adherens junction components E- and N-cadherin, which are important determinants of tissue cohesion. E-cadherin was expressed in periportal but not in perivenous hepatocytes. In contrast, N-cadherin was more enriched towards the perivenous hepatocytes. In agreement, ß-catenin, which links both cadherins via α-catenin to the actin cytoskeleton, was expressed ubiquitously. This zonal expression of cadherins was preserved in acute liver injury after treatment with acetaminophen or partial hepatectomy, but disrupted in chronic liver damage like in non-alcoholic steatohepatitis (NASH) or α1-antitrypsin deficiency. Hepatocyte proliferation during acetaminophen-induced liver damage was predominant at the boundary between the damaged perivenous and the intact periportal parenchyma indicating a minor contribution of periportal hepatocytes to liver regeneration. In NASH livers, an oval cell reaction was observed pointing to massive tissue damage coinciding with the gross impairment of hepatocyte proliferation. In the liver parenchyma, metabolic functions are distributed heterogeneously. For example, the expression of phosphoenolpyruvate carboxykinase and E-cadherin overlapped in periportal hepatocytes. Thus, during liver regeneration after acute damage, the intact periportal parenchyma might sustain essential metabolic support like glucose supply or ammonia detoxification. However, disruption of epithelial integrity during chronic challenges may increase susceptibility to metabolic liver diseases such as NASH or vice versa. This might suggest the regulatory integration of tissue cohesion and metabolic functions in the liver.

Insulin/IGF-1 controls epidermal morphogenesis via regulation of FoxO-mediated p63 inhibition.

The multilayered epidermis is established through a stratification program, which is accompanied by a shift from symmetric toward asymmetric divisions (ACD), a process under tight control of the transcription factor p63. However, the physiological signals regulating p63 activity in epidermal morphogenesis remain ill defined. Here, we reveal a role for insulin/IGF-1 signaling (IIS) in the regulation of p63 activity. Loss of epidermal IIS leads to a biased loss of ACD, resulting in impaired stratification. Upon loss of IIS, FoxO transcription factors are retained in the nucleus, where they bind and inhibit p63-regulated transcription. This is reversed by small interfering RNA-mediated knockdown of FoxOs. Accordingly, transgenic expression of a constitutive nuclear FoxO variant in the epidermis abrogates ACD and inhibits p63-regulated transcription and stratification. Collectively, the present study reveals a critical role for IIS-dependent control of p63 activity in coordination of ACD and stratification during epithelial morphogenesis.

The disintegrin/metalloproteinase Adam10 is essential for epidermal integrity and Notch-mediated signaling.

The disintegrin and metalloproteinase Adam10 has been implicated in the regulation of key signaling pathways that determine skin morphogenesis and homeostasis. To address the in vivo relevance of Adam10 in the epidermis, we have selectively disrupted Adam10 during skin morphogenesis and in adult skin. K14-Cre driven epidermal Adam10 deletion leads to perinatal lethality, barrier impairment and absence of sebaceous glands. A reduction of spinous layers, not associated with differences in either proliferation or apoptosis, indicates that loss of Adam10 triggers a premature differentiation of spinous keratinocytes. The few surviving K14-Adam10-deleted mice and mice in which Adam10 was deleted postnatally showed loss of hair, malformed vibrissae, epidermal hyperproliferation, cyst formation, thymic atrophy and upregulation of the cytokine thymic stromal lymphopoetin (TSLP), thus indicating non cell-autonomous multi-organ disease resulting from a compromised barrier. Together, these phenotypes closely resemble skin specific Notch pathway loss-of-function phenotypes. Notch processing is indeed strongly reduced resulting in decreased levels of Notch intracellular domain fragment and functional Notch signaling. The data identify Adam10 as the major Site-2 processing enzyme for Notch in the epidermis in vivo, and thus as a central regulator of skin development and maintenance.

Epidermal insulin/IGF-1 signalling control interfollicular morphogenesis and proliferative potential through Rac activation.

The lifelong self-renewal of the epidermis is driven by a progenitor cell population with high proliferative potential. To date, the upstream signals that determine this potential have remained largely elusive. Here, we find that insulin and insulin-like growth factor receptors (IR and IGF-1R) determine epidermal proliferative potential and cooperatively regulate interfollicular epidermal morphogenesis in a cell autonomous manner. Epidermal deletion of either IR or IGF-1R or both in mice progressively decreased epidermal thickness without affecting differentiation or apoptosis. Proliferation was temporarily reduced at E17.5 in the absence of IGF-1R but not IR. In contrast, clonogenic capacity was impaired in both IR- and IGF-1R-deficient primary keratinocytes, concomitant with an in vivo loss of keratin 15. Together with a reduction in label-retaining cells in the interfollicular epidermis, this suggests that IR/IGF-1R regulate progenitor cells. The expression of dominant active Rac rescued clonogenic potential of IR/IGF-1R-negative keratinocytes and reversed epidermal thinning in vivo. Our results identify the small GTPase Rac as a key target of epidermal IR/IGF-1R signalling crucial for proliferative potential and interfollicular morphogenesis.

Role of aPKC isoforms and their binding partners Par3 and Par6 in epidermal barrier formation.

The skin water barrier, essential for terrestrial life, is formed by a multilayered stratifying epithelium, which shows a polarized distribution of both differentiation and intercellular junction markers. Recently, several reports showed the crucial importance of tight junctions for the in vivo water barrier function of the skin. In simple epithelial cells, intercellular junction formation is closely coupled to the establishment of polarity. However, if and how polarity proteins contribute to epidermal differentiation and junction formation is not yet known. Here, we have characterized the localization and isoform expression of the polarity protein atypical PKC (aPKC) and its binding partners Par3 and Par6 in epidermis and primary keratinocytes of mice. Their distribution is only partially overlapping in the granular layer, the site of functional tight junctions, suggesting that next to a common Par3/Par6/aPKC function they also may have functions independent of each other. Both aPKCzeta and aPKCiota/lambda, are expressed in the epidermis but only aPKCiota/lambda showed a strong enrichment in the junctions, suggesting that this aPKC isoform is important for epidermal tight junction function. Indeed, inhibition of aPKC function showed that endogenous aPKC is crucial for in vitro barrier function and this required the presence of both the Par3 and Par6 binding sites.

E-cadherin is essential for in vivo epidermal barrier function by regulating tight junctions.

Cadherin adhesion molecules are key determinants of morphogenesis and tissue architecture. Nevertheless, the molecular mechanisms responsible for the morphogenetic contributions of cadherins remain poorly understood in vivo. Besides supporting cell-cell adhesion, cadherins can affect a wide range of cellular functions that include activation of cell signalling pathways, regulation of the cytoskeleton and control of cell polarity. To determine the role of E-cadherin in stratified epithelium of the epidermis, we have conditionally inactivated its gene in mice. Here we show that loss of E-cadherin in the epidermis in vivo results in perinatal death of mice due to the inability to retain a functional epidermal water barrier. Absence of E-cadherin leads to improper localization of key tight junctional proteins, resulting in permeable tight junctions and thus altered epidermal resistance. In addition, both Rac and activated atypical PKC, crucial for tight junction formation, are mislocalized. Surprisingly, our results indicate that E-cadherin is specifically required for tight junction, but not desmosome, formation and this appears to involve signalling rather than cell contact formation.