Ultrastructural evidence for contacts between migrating L5222 rat leukemia cells and extracellular matrix components of the rat mesentery

The nature of interactions between cells migrating through tissues and their structural surroundings are largely unknown. We have therefore examined the ultrastructural relationship between L5222 rat leukemia cells, moving through the loose connective tissue of the mesentery, and components of the extracellular matrix (ECM). Ultrathin tissue sections, fixed in the presence of ruthenium hexammine trichloride (RHT), revealed the following: Constitutents of fibrillar and nonfibrillar elements of the ECM are in contact with the plasma membrane of L5222 cells. Linear nonfibrillar ECM elements contact the plasma membrane at point-like sites, often associated with root-like structures present within the submembraneous microfilament mesh. Aggregates of ECM material are connected to patch-like cell membrane sites, associated with a condensed, plate-like part of the microfilament mesh. Point-like and patch-like contacts are more numerous at the anterior part of polarized migrating L5222 cells than on the posterior end. In round resting leukemia cells they are evenly distributed around the cell periphery. We suggest that the ECM-cell membrane contacts represent tissue adhesion sites. We therefore hypothesize that in migrating cells a coordinate interaction occurs between the contact sites and the continuous microfilament meshwork which results in a simultaneous backward movement of ECM-membrane contacts on the cell body and in a net forward movement of the whole cell. Since Dembo et al. (1981) present a similar mechanism for in vitro locomotion of granulocytes, we assume that blood cell locomotion in vivo and in vitro depends on similar molecular mechanisms: force generation by the cell, transmembraneous linkage between cytoskeletal and ECM elements, and membrane fluidity. The major difference in blood cell locomotion through a three-dimensional tissue or on a plane substratum would then be given by the distribution of contact sites, occurring around the cell periphery or limited to the ventral cell surface, respectively.     

Penetration of an ascitic reticulum cell sarcoma of the golden hampster into the body wall and through the diaphragm. A scanning electron microscopic (SEM) study.

SEM studies on infiltration of the ascitic form of the hamster reticulum cell sarcoma HaTu 25 into the ventral body wall and through the diaphragm were performed during 6 consecutive days after intraperitoneal transplantation. The findings allow an interpretation of the course of events based on 3 main stages: 1) Contraction of mesothelial cells with partial exposure of the submesothelial stratum. 2) Preferential attachment of tumor cells to these denuded areas. 3) Advance of tumor cells within defects gradually extening from the submesothelial stratum of the musculature. These stages were more pronounced and took a more rapid course at the peritoneal side of the diaphragm than at the body wall. At the pleural side of the diaphragm the appearance of single tumor cells within widened intercellular spaces of the mesothelium was recorded prior to the onset of penetration at the peritoneal surface. The rapid migration of tumor cells through the diaphragm as well as the particularly intensive tumor infiltration into this organ is thought to be connected with the mechanism of intravasation of tumor cells into the lymphatic plexus of the diaphragm. During the whole sequence of events, HaTu 25 cells were found to have maintained their spherical configuration and characteristic surface architecture. Apparently, growth pressure is of minor or no importance in this spacial mode of tumor penetration, rather the action of proteolytic enzymes elaborated by the tumor cells has to be taken into consideration.     

Lack of mast cell reactivity during leukemic infiltration of the rat mesentery under syngeneic and allogeneic conditions. A study by transmission electron microscopy (TEM)

The ultrastructural morphology of mast cells localized in rat mesenteries was studied after intraperitoneal implantation of L5222 rat leukemia cells in syngeneic and allogenic hosts. It became evident that the mast cells in the syngeneic (BDIX rat) as well as the allogeneic system (BN rat) showed nor morphological alterations. Degranulation was never observed. This is in contrast to the behavior of macrophages which displayed a strong phagocytotic activity in allogeneic hosts. Thus, it seems that mast cells, under the present experimental conditions, remained inactive during a phase of intense tumor rejection.