Expression of a colorectal antigen defined by a new monoclonal antibody, CO-TL1.

Contains fulltext : 58500.pdf (publisher's version ) (Closed access)A murine monoclonal antibody (MoAb CO-TL1, IgG1) has been raised by differential screening of hybridoma supernatants on sections of human large and small intestines, followed by screening on colon adenomas as well as on colorectal carcinomas. In both paraffin sections and cryostat sections, the antibody stained strongly all cell types in adult, neonatal and fetal human colorectal epithelium, that is, the goblet cells, the columnar cells and the endocrine cells. No staining was observed in the remaining parts of the normal gastrointestinal tract and other tissues. As revealed by immuno electron microscopy the epitope was present in the apical and basolateral cell membranes, the Golgi complex, secretory vesicles of goblet and columnar cells, and also in granules of the endocrine cells. The epitope in colorectal tissue sections was resistant to the deglycosylation enzymes neuramidase, diastase and hyaluronidase indicating its proteinaceous nature. This colorectal antigen remained expressed in 100% of colorectal adenomas (n = 39) and 86% (n = 29) of colorectal carcinomas. The expression was reduced in undifferentiated carcinomas. The CO-TL1 antibody detected also most other gastrointestinal adenocarcinomas and a few carcinomas of the ovary, uterus, breast, gallbladder and pancreas. However, it never detected carcinomas derived from the thyroid, lung, liver, bladder, kidney, prostate, testis, serous membranes of body cavities and skin. A wild-type variant protein of > 300 kDa of the colorectal antigen was identified in normal colorectal epithelium. In colorectal tumours, however, two tumour variant forms were found of 160-200 and 115-140 kDa, respectively. Our data indicate that this new MoAb CO-TL1 can be considered as a useful marker, which identifies normal colorectal epithelium and gastrointestinal tumours and especially colorectal tumours with high accuracy and excludes tumours originated from thyroid, lung, liver, bladder, kidney, prostate, testis, mesothelium and skin

Molecular Basis of Cannabis-Induced Schizophrenia-Relevant Behaviours: Insights from Animal Models

Introduction: Cannabis use is a well-established component risk factor for schizophrenia; however, the mechanisms by which cannabis use increases schizophrenia risk are unclear. Animal models can elucidate mechanisms by which chronic cannabinoid treatment can induce schizophrenia-relevant neural changes, in a standardised manner often not possible using patient-based data. Methods: We review recent literature (within the past 10 years) using animal models of chronic and subchronic treatment with cannabinoids which target the cannabinoid 1 receptor [i.e. ∆9-tetrahydrocannabinol, CP55,940 and WIN55,212-2]. Schizophrenia-relevant behavioural consequences of chronic cannabinoid treatment are first briefly summarised, followed by a detailed account of changes to several receptor systems [e.g. cannabinoid, dopaminergic, glutamatergic, γ-aminobutyric acid (GABAe)rgic, serotonergic, noradrenergic], dendritic spine morphology and inflammatory markers following chronic cannabinoids. We distinguish between adolescent and adult cannabinoid treatments, to determine if adolescence is a period of susceptibility to schizophrenia-relevant molecular changes. Results: Chronic cannabinoid treatment induces behaviours relevant to positive, negative and cognitive symptoms of schizophrenia. Chronic cannabinoids also cause region- and subtype-specific changes to receptor systems (e.g. cannabinoid, dopaminergic, glutamatergic, GABAergic), as well as changes in dendritic spine morphology and upregulation of inflammatory markers. These changes often align with molecular changes observed in post-mortem tissue from schizophrenia patients and correspond with schizophrenia-relevant behavioural change in rodents. There is some indication that adolescence is a period of susceptibility to cannabinoid-induced schizophrenia-relevant neural change, but more research in this field is required to confirm this hypothesis. Conclusions: Animal models indicate several molecular mechanisms by which chronic cannabinoids contribute to schizophrenia-relevant neural and behavioural change. It is likely that a number of these mechanisms are simultaneously impacted by chronic cannabinoids, thereby increasing schizophrenia risk in individuals who use cannabis. Understanding how cannabinoids can affect several molecular targets provides critical insight into the complex relationship between cannabis use and schizophrenia risk