A thymus candidate in lampreys.

Immunologists and evolutionary biologists have been debating the nature of the immune system of jawless vertebrates--lampreys and hagfish--since the nineteenth century. In the past 50 years, these fish were shown to have antibody-like responses and the capacity to reject allografts but were found to lack the immunoglobulin-based adaptive immune system of jawed vertebrates. Recent work has shown that lampreys have lymphocytes that instead express somatically diversified antigen receptors that contain leucine-rich-repeats, termed variable lymphocyte receptors (VLRs), and that the type of VLR expressed is specific to the lymphocyte lineage: T-like lymphocytes express type A VLR (VLRA) genes, and B-like lymphocytes express VLRB genes. These clonally diverse anticipatory antigen receptors are assembled from incomplete genomic fragments by gene conversion, which is thought to be initiated by either of two genes encoding cytosine deaminase, cytosine deaminase 1 (CDA1) in T-like cells and CDA2 in B-like cells. It is unknown whether jawless fish, like jawed vertebrates, have dedicated primary lymphoid organs, such as the thymus, where the development and selection of lymphocytes takes place. Here we identify discrete thymus-like lympho-epithelial structures, termed thymoids, in the tips of the gill filaments and the neighbouring secondary lamellae (both within the gill basket) of lamprey larvae. Only in the thymoids was expression of the orthologue of the gene encoding forkhead box N1 (FOXN1), a marker of the thymopoietic microenvironment in jawed vertebrates, accompanied by expression of CDA1 and VLRA. This expression pattern was unaffected by immunization of lampreys or by stimulation with a T-cell mitogen. Non-functional VLRA gene assemblies were found frequently in the thymoids but not elsewhere, further implicating the thymoid as the site of development of T-like cells in lampreys. These findings suggest that the similarities underlying the dual nature of the adaptive immune systems in the two sister groups of vertebrates extend to primary lymphoid organs.

Transition to pancreatic cancer in response to carcinogen.

BACKGROUND: It has become obvious that the traditional assumptions about the transition from normal pancreas to pancreatic cancer are incomplete. Experimental studies reveal that the earliest changes during transition to pancreatic adenocarcinoma involve premalignant lesions that are derived from acinar, islet, and ductal cells. OBSERVATIONS: Changes are rapid, occurring in days. As part of redifferentiation and transformation to adenocarcinoma, cells regain the characteristics of developing pancreas. Elements significant in identifying precursor cell types include Pdx1, hedgehog signaling, notch signaling, and nestin, an intermediate filament expressed by precursor cell types. CONCLUSIONS: Thus pancreatic carcinogenesis is not simply a matter of transition of ductal cells to cancer cells months after insult by the carcinogen; ductal cells are not the sole source transitioning to cancer, and PanINs are not the sole route to adenocarcinoma. Tubular complexes, derived from multiple cell sources, are included in routes to pancreatic cancer. Markers characteristic of developing pancreas are consistent with this transition. Cells previously thought to be terminally differentiated become, in effect, stem cells.

Cell wounding in early experimental acute pancreatitis.

It is well established that damage to the outer membrane of cells is a common phenomenon allowing abnormal transmission of substances into the cytosol. Penetration of albumin into acinar cells has been detected in experimental acute pancreatitis, raising the possibility that membrane damage is a very early event, potentially representing the first changes leading to pancreatitis. To determine if direct damage to the cell membrane is a key factor during induction of acute pancreatitis, thus altering the balance of extra- and intracellular substances, fluorescein-dextran was administered with supramaximal doses of caerulein via the jugular vein or by injection directly into the pancreas. This tracer rapidly penetrates into cells. Two patterns of tracer penetration are observed: cytosolic and vesicular/vacuolar. Fluorescein-dextran administered intravenously with caerulein penetrates into the cytosol of acinar cells within 10 min. Strong cytoplasmic fluorescence occurs within 5 min after direct injection. It may be concluded that supramaximal caerulein, administered in vivo, damages the cell membrane of acinar cells, allowing large molecules to enter the cytosol. Thus Ca(2+) and other substances may enter the cells in abnormally high concentrations, initiating the cellular changes characteristic of pancreatitis. The results raise the question whether membrane wounding may play a role in the initiation of human pancreatitis.

Origin and development of the precursor lesions in experimental pancreatic cancer in rats.

Notwithstanding the importance of understanding how pancreatic ductal adenocarcinoma develops, the process remains controversial. A key question is whether the cells of origin of the tubular complexes that constitute precursor lesions are derived from a single cell type or from multiple types. Suggestions that they arise solely from centroacinar cells or ductal cells have been based on inference due to their morphologic appearance in tissue from patients or investigation of limited numbers of tubular complexes in animal models later in the carcinogenic process. The present study establishes clearly that two steps are involved; rapid transdifferentiation to produce tubular complexes followed later by transformation of the component cells. Animals were killed at intervals beginning 1 day after implantation of the carcinogen dimethylbenzanthracene. Transdifferentiation of acinar cells to ductal cells does not require cell division. Transition of lobules to tubular complexes begins by 2 days after implantation of carcinogen. Within 4 days after implantation well-developed tubular complexes are present. Islets participate in the process. Ductal adenocarcinoma is observed by 1 month after implantation of carcinogen. Chymotrypsin and cytokeratin localized by immunocytochemistry indicate acinar and ductal cell characteristics. Acino-ductal transdifferentiation persists in carcinogen-implanted animals, but not in controls implanted with sodium chloride crystals or subjected to sham implantation. The precursor lesions (tubular complexes) are formed by the transdifferentiation of acinar cells and to a lesser extent islet cells, with the incorporation of the duct cells pre-existing in the lobules. Therefore, cells that at one time were acinar cells, islet cells, and duct cells, provide the precursor cells for the ductal adenocarcinoma that develops from tubular complexes. The results raise the question whether the transdifferentiated cells in the tubular complexes of patients with chronic pancreatitis are more susceptible to carcinogenic influences, resulting in the increased rate of pancreatic cancer.