Alexander Stoeck

Ectodomain shedding of L1 adhesion molecule promotes cell migration by autocrine binding to integrins

The L1 adhesion molecule plays an important role in axon guidance and cell migration in the nervous system. L1 is also expressed by many human carcinomas. In addition to cell surface expression, the L1 ectodomain can be released by a metalloproteinase, but the biological function of this process is unknown. Here we demonstrate that membrane-proximal cleavage of L1 can be detected in tumors and in the developing mouse brain. The shedding of L1 involved a disintegrin and metalloproteinase (ADAM)10, as transfection with dominant-negative ADAM10 completely abolishes L1 release. L1-transfected CHO cells (L1-CHO) showed enhanced haptotactic migration on fibronectin and laminin, which was blocked by antibodies to αvβ5 and L1. Migration of L1-CHO cells, but not the basal migration of CHO cells, was blocked by a metalloproteinase inhibitor, indicating a role for L1 shedding in the migration process. CHO and metalloproteinase-inhibited L1-CHO cells were stimulated to migrate by soluble L1-Fc protein. The induction of migration was blocked by αvβ5-specific antibodies and required Arg-Gly-Asp sites in L1. A 150-kD L1 fragment released by plasmin could also stimulate CHO cell migration. We propose that ectodomain-released L1 promotes migration by autocrine/paracrine stimulation via αvβ5. This regulatory loop could be relevant for migratory processes under physiological and pathophysiological conditions.

L1 expression as a predictor of progression and survival in patients with uterine and ovarian carcinomas

BACKGROUND Ovarian and uterine carcinomas are the most common cause of cancer-related deaths in gynecological malignant diseases. We aimed to assess whether the L1 adhesion molecule, an important mediator for cell migration for neural and tumour cells, is expressed in these carcinomas. METHODS We investigated L1 expression by immunohistochemistry, RT-PCR, and Western blot analysis of tumour samples. Soluble L1 in the serum was detected by ELISA and immunoprecipitation. FINDINGS We detected the L1 adhesion molecule in ovarian and uterine tumours in a stage-dependent manner. In a retrospective study L1 was found in 46 of 58 ovarian carcinomas and 20 of 72 uterine adenocarcinomas. L1 expression was an excellent predictor of poor outlook (p<0.00001). Patients with L1 positive uterine tumours were at high risk for progression even in the endometrioid-type tumours, which usually have a favourable prognosis. In uterine tumours, expression of L1 in curettage samples enabled us to identify aggressive tumours before the operation. Soluble L1 was specifically detected in serum samples from patients with ovarian and uterine tumours. ADAM10, which was implicated in previous studies as L1 sheddase, was expressed in tumours in which soluble L1 was present in the serum. INTERPRETATION L1 is overexpressed in ovarian and uterine carcinomas and is associated with short survival. L1 can serve as a new marker for prediction of clinical outcome and could be helpful to identify patients with uterine tumours who are at high risk for recurrent disease. L1 expression and cleavage could promote dissemination of tumours by facilitating cell migration.

A role for exosomes in the constitutive and stimulus-induced ectodomain cleavage of L1 and CD44

Ectodomain shedding is a proteolytic mechanism by which transmembrane molecules are converted into a soluble form. Cleavage is mediated by metalloproteases and proceeds in a constitutive or inducible fashion. Although believed to be a cell-surface event, there is increasing evidence that cleavage can take place in intracellular compartments. However, it is unknown how cleaved soluble molecules get access to the extracellular space. By analysing L1 (CD171) and CD44 in ovarian carcinoma cells, we show in the present paper that the cleavage induced by ionomycin, APMA (4-aminophenylmercuric acetate) or MCD (methyl-beta-cyclodextrin) is initiated in an endosomal compartment that is subsequently released in the form of exosomes. Calcium influx augmented the release of exosomes containing functionally active forms of ADAM10 (a disintegrin and metalloprotease 10) and ADAM17 [TACE (tumour necrosis factor a-converting enzyme)] as well as CD44 and L1 cytoplasmic cleavage fragments. Cleavage could also proceed in released exosomes, but only depletion of ADAM10 by small interfering RNA blocked cleavage under constitutive and induced conditions. In contrast, cleavage of L1 in response to PMA occurred at the cell surface and was mediated by ADAM17. We conclude that different ADAMs are involved in distinct cellular compartments and that ADAM10 is responsible for shedding in vesicles. Our findings open up the possibility that exosomes serve as a platform for ectodomain shedding and as a vehicle for the cellular export of soluble molecules.

ADAM10-mediated cleavage of L1 adhesion molecule at the cell surface and in released membrane vesicles

Cells can release membrane components in a soluble form and as membrane vesicles. L1, an important molecule for cell migration of neural and tumor cells, is released by membrane‐proximal cleavage, and soluble L1 promotes cell migration. Release of L1 is enhanced by shedding inducers such as phorbol ester and pervanadate, but it is also enhanced by depletion of cellular cholesterol with methyl‐β‐cyclodextrin (MCD). How such different compounds can induce shedding is presently unknown. We show here that ADAM10 is involved in L1 cleavage, which occurs at the cell surface and in the Golgi apparatus. MCD and pervanadate treatment induced the release of microvesicles containing full‐length L1 and the active form of ADAM10. L1 cleavage occurred in isolated vesicles. L1‐containing microvesicles could trigger haptotactic cell migration. Only the neural L1 form carrying the RSLE signal for clathrin‐dependent endocytosis was recruited and cleaved in vesicles. Phorbol ester treatment activated L1 cleavage predominantly at the cell surface. Our results provide evidence for two pathways of L1 cleavage, based on ADAM10 localization, that can be activated differentially: 1) direct cleavage at the cell surface, and 2) release and cleavage in secretory vesicles most likely derived from the Golgi apparatus. The findings establish a novel role for ADAM10 as a vesicle‐based protease.

Cleavage of L1 in Exosomes and Apoptotic Membrane Vesicles Released from Ovarian Carcinoma Cells

Purpose: The L1 adhesion molecule (CD171) is overexpressed in human ovarian and endometrial carcinomas and is associated with bad prognosis. Although expressed as a transmembrane molecule, L1 is released from carcinoma cells in a soluble form. Soluble L1 is present in serum and ascites of ovarian carcinoma patients. We investigated the mode of L1 cleavage and the function of soluble L1. Experimental Design: We used ovarian carcinoma cell lines and ascites from ovarian carcinoma patients to analyze soluble L1 and L1 cleavage by Western blot analysis and ELISA. Results: We find that in ovarian carcinoma cells the constitutive cleavage of L1 proceeds in secretory vesicles. We show that apoptotic stimuli like C2-ceramide, staurosporine, UV irradiation, and hypoxic conditions enhance L1-vesicle release resulting in elevated levels of soluble L1. Constitutive cleavage of L1 is mediated by a disintegrin and metalloproteinase 10, but under apoptotic conditions multiple metalloproteinases are involved. L1 cleavage occurs in two types of vesicles with distinct density features: constitutively released vesicles with similarity to exosomes and apoptotic vesicles. Both types of L1-containing vesicles are present in the ascites fluids of ovarian carcinoma patients. Soluble L1 from ascites is a potent inducer of cell migration and can trigger extracellular signal-regulated kinase phosphorylation. Conclusions: We suggest that tumor-derived vesicles may be an important source for soluble L1 that could regulate tumor cell function in an autocrine/paracrine fashion.

Brain development in mice lacking L1–L1 homophilic adhesion

A new mouse line has been produced in which the sixth Ig domain of the L1 cell adhesion molecule has been deleted. Despite the rather large deletion, L1 expression is preserved at normal levels. In vitro experiments showed that L1–L1 homophilic binding was lost, along with L1-α5β1 integrin binding. However, L1–neurocan and L1–neuropilin binding were preserved and sema3a responses were intact. Surprisingly, many of the axon guidance defects present in the L1 knockout mice, such as abnormal corticospinal tract and corpus callosum, were not observed. Nonetheless, when backcrossed on the C57BL/6 strain, a severe hydrocephalus was observed and after several generations, became an embryonic lethal. These results imply that L1 binding to L1, TAG-1, or F3, and L1-α5β1 integrin binding are not essential for normal development of a variety of axon pathways, and suggest that L1–L1 homophilic binding is important in the production of X-linked hydrocephalus.

L1 augments cell migration and tumor growth but not β3 integrin expression in ovarian carcinomas

L1 is a neural cell adhesion molecule involved in cell migration, axon growth and guidance. Recent data have shown that L1 is overexpressed in ovarian and endometrial tumors and is associated with bad prognosis. How L1 promotes tumor progression is presently unknown. Here we show that L1 expression is predominantly confined to the invasive front of ovarian carcinomas. Overexpression of L1 in carcinoma cell lines by adenovirus‐mediated gene transfer enhanced the haptotactic cell migration on extracellular matrix proteins. Expression of L1 augmented tumor growth of carcinomas xenografted in nonobese diabetic/severe combined immunodeficient mice (NOD/SCID). A recent report has demonstrated L1‐dependent upregulation of β3 integrin involving activation of the extracellular signal‐regulated kinase (erk) pathway. We find that L1 and β3 integrin are not coexpressed in ovarian carcinoma tissues. Overexpression of L1 did not upregulate β3 integrin in ovarian carcinoma cell lines but could do so in HEK293 cells. Our results suggest that L1 could drive progression by enhancing cell migration and tumor growth but that L1 dependent and erk‐regulated gene expression requires cell‐type specific elements.

Erratum: (Journal of Cell Biology (November 12, 2001) 155:4 (661-673))

Correction After publication of this work [1], we noted that while we were initially going to include muscle function tests in this study, as our manuscript evolved and we decided to include earlier time points for characterization, we decided to remove it because pups younger than 2 weeks cannot be measured. While we removed this from the results, we missed retracting them from the methods section of the abstract. Therefore, the methods section of the abstract should instead read: