Expression of aryl hydrocarbon hydroxylase induction in mouse tissues in vivo and in organ culture

The elevation of aryl hydrocarbon hydroxylase by various microsomal enzyme inducers in mouse tissues from five inbred strains was examined in vivo and in fetal liver expiants. The magnitude of 3-methylcholanthrene- or β-naphthoflavone-inducible AHH activities in the intact animal varied greatly with the tissue and strain—from no induction in the liver and less than a 2- to 3-fold increase in the lung of DBA/2+ and AKR mice to 4- to 5- and 6- to 7-fold elevation, respectively, in the liver and lung of C57BL mice. Treatment of At or C3H⁺ mice with these inducers increased AHH activity in liver and lung to levels which were intermediate between those observed with tissues from DBA/2+ and C57BL mice. These strain-specific differences in the expression of AHH induction in response to polycyclic hydrocarbons and flavones were also present in fetal liver expiants and were measurable as early as 6 days before parturition. In expiants derived from polycyclic hydrocarbon-“responsive” strains, the extent of enzyme induction was greatest with 4′-bromoflavone, less with β-naphthoflavone and least with 3-methylcholanthrene. Trans-1, 2-dihydroxy-3-methylcholanthrene was about twice as effective in this regard as the parent compound 3-methylcholanthrene. Among expiants from 3-methylcholanthrene-“resistant” strains (DBA/2+, AKR), a disparity in the effects of different classes of compounds was apparent: the flavone derivatives induced aryl hydrocarbon hydroxylase activity from DBA/2+ and AKR expiants by 2- to 3-fold despite the absence of polycyclic hydrocarbon induction in these cultures. Furthermore, although phenobarbital was a comparatively weak inducer under the conditions used in these experiments, this substance stimulated aryl hydrocarbon hydroxylase activity from 3-methylcholanthrene-“responsive” and -“resistant” explants by similar degrees (i.e., about 30%). The results are discussed in the light of previous suggestions on the genetically determined regulation of aryl hydrocarbon hydroxylase induction in mouse tissues.     

Cell proliferation in ectodermal explants from Xenopus embryos

Summary Dissociated prospective ectoderm cells from Xenopus laevis embryos divide autonomously up to the 17th division cycle of the embryo. To examine the requirements for the further proliferation of these cells, the continuation of cell division in compact ectodermal explants beyond the 17th division cycle has been studied. Such explants develop into aggregates of epidermal cells, as can be shown immunohistochemically with an anti-serum against Xenopus epidermal cytokeratin. Cell division in these explants is comparable to the in vivo proliferation rate at least during the first 24 h of cultivation, that is, well beyond the 17th division cycle. Thus, epidermal cells are provided with all the factors necessary for continued proliferation, but these can be effective only when the cells form tight aggregates. The long-term changes in cell number are complex. Mitotic figures are present until the explants disintegrate after 3–4 days. However, the total cell number per explant does not increase during later development. The production of cells by mitotic divisions is likely to be countered by the loss of cells due to cell death, which is indicated by the presence of pyknotic nuclei.     

Microtubule-organizing centers in the mitotic melanophores of Xenopus laevis larvae in vivo: ultrastructural study

Mitotic melanophores of Xenopus laevis larvae at 51-53 stages of development were morphologically studied using light and electron microscopy, with special reference to their microtubule-organizing centers. These melanophores represented a highly branched cell shape in mitosis, each cell process is distributed with melanosomes without exhibiting any responsiveness to hormonal (melatonin) stimulation, and upon completion of mitosis, recovered the ability to translocate these granules in response to such a stimulus. At the metaphase, these cells contained bipolar or multipolar spindles, whose poles were composed of three zones: the centrosome with centrioles; the centrosphere; and an outlying radial arrangement of microtubules and their associated inclusions. In these mitotic melanophores, a number of microtubules are distributed within the radially stretching cell processes, whereas an abundance of microtubules reside in the spindles. Possible origins of the microtubules observed in these cytoplasmic processes are discussed in relation to the loss of the ability of pigment translocation during mitosis.     

Hamster tracheal organ culture in serum-free media: A quantitative comparison of in vitro epithelial morphology with that of in vivo controls

Summary The epithelial morphology of the hamster trachea in serum-free organ culture was compared with that of age-matched in vivo control tissues by collecting and statistically analyzing several quantifiable parameters. By this technique it was possible to detect both subtle and dramatic epithelial alterations. Midtracheal tissues from 6-wk-old male Syrian golden hamsters were used as the explants. Explants were placed on Gelfoam sponges and cultured for 1, 2, and 3 wk in CMRL 1066 alone and in CMRL 1066 to which seven factors were added: insulin and transferrin (5 μg/ml); hydrocortisone (5×10⁻⁷ M); epidermal growth facotr (5 ng/ml); bovine pituitary extract (0.5%); and phosphoethanolamine and ethanolamine (5×10⁻⁵ M). The following data were collected and statistically analyzed for each tracheal ring: number of epithelial cells; proportion and number of each cell type; basement membrane length; linear density of epithelial cells; epithelial height; and mitotic index. Compared to controls, ciliated cells decreased by 52% during washes in Leibovitz (L15) medium and tissue manipulation performed before culture and this loss persisted after cutlure for 1 wk. Explants culturedwithout the factors showed marked changes after 2 and 3 wk including epithelial thickening and folding, which was associated with increased linear density. Many cells in these specimens could not be categorized by type (22% were unidentifiable after 3 wk). Epithelial migration onto the outside of the explant was inhibited. In contrast, explants culturedwith the factors maintained a morphology similar to controls at 2 and 3 wk and epithelial migration onto the outside of the explant was supported. This study shows that explants in CMRL 1066 with the seven factors provide a useful biological model for the in vitro study of the mucociliary respiratory epithelium. This work was supported by grant HL24722 from the National Institutes of Health, Bethesda, Maryland.     

Cell injury and regeneration of human epithelium in organ culture

Human esophageal, tracheal, and pancreatic ductal fragments were collected at autopsy after a postmortem interval of 12 hours or less and maintained in explant organ culture for 30 days. The viability and growth of the explants was assessed by morphology, LDH enzyme release, and cellular outgrowth. The viability and growth of the bronchial explant epithelium was directly related to the postmortem interval. Esophageal epithelial regeneration followed the desquamation of the superficial cell layers. Pancreatic epithelia appeared to grow more slowly and with less outgrowth than the other tissues. Epithelial cell growth along the explant surface and onto the culture dish appeared to proceed through the well-characterized process that follows cell injury, i.e., flattening, migration, replication, and differentiation. Thus, sufficient numbers of viable epithelial cells capable of regeneration were present in routine autopsy epithelium, but there was considerable variation from tissue to tissue and case to case. The most effective and accurate approach to follow when evaluating and predicting the growth and viability of these explants is by using a combination of morphologic, enzymatic and biologic assays. Errors in the interpretation of viability are possible when only one assay method is utilized. These tissues grown in explant organ culture are suitable for studies on the mechanism and response of epithelia to cell injury, recovery and wound healing.Abbreviations 4F-1G 4% formaldehyde, 1% glutaraldehyde - HIFBS heat inactivated fetal bovine serum - IA immediate autopsy - LDH lactate dehydrogenase - OsO₄ osmium tetroxide - RA routine autopsy     

Mechanical properties of muscles from Xenopus borealis following maintenance in organ culture

The mechanical properties of sartorii muscles from the toad Xenopus borealis were studied in organ cultures lasting up to 26 days. Isometric twitch and tetanic tensions diminished in force reaching half their initial values after 15 days in culture. In contrast, twitch time to peak time to half relaxation, twitch-tetanus ratio and muscle weight-body weight ratio, were unchanged. Maximum isotonic shortening velocity (Vmax) declined, with a half time similar to that of the isometric force. The fall in isometric tension is probably due to a breakdown of activation in some fibres. The change in Vmax could be due to a loss of functional sarcomeres in series with the tendons.     

Explant organ culture: A review

Organ explant culture models offer several significant advantages for studies of patho-physiologic mechanisms like cell injury, secretion, differentiation and structure development. Organs or small explants/slices can be removed in vivo and maintained in vitro for extended periods of time if careful attention is paid to the media composition, substrate selection, and atmosphere. In the case of human tissues obtained from autopsy or surgery, additional attention must be paid to the postmortem interval, temperature, hydration, and cause of death. Explant organ culture has been effectively utilized to establish outgrowth cell cultures and characterize the histiotypic relationships between the various cell types within an organ or tissue.J. Resau is a visiting scientist at the NCI-LMO-DCE in Frederick, MD 21702, U.S.A.K. Sakamoto is a visiting scientist from the Department of Surgery, Gunma University School of Medicine, Maebashi, Japan     

Podocytes in metanephric organ culture express characteristic in vivo phenotypes

 Podocytes outgrown from isolated glomeruli in vitro have failed to express fully differentiated in vivo phenotypes. In an attempt to determine whether podocytes in metanephric culture accomplish terminal differentiation, as observed in vivo, we investigated expression of their characteristic phenotypic features in rat metanephric organ cultures using immunohistochemistry and electron microscopy. Rat metanephroi were harvested on embryonic day 12.5 and cultured on transmembrane filters for 9 days. Morphological examination revealed two maturation stages when the podocytes resembled those of the S-shaped body stage and maturational stages of glomeruli in vivo. Electron microscopy revealed that, firstly podocytes lost their intercellular contacts and, simultaneously, the tight junctions shifted into close proximity to cell bases, followed by foot process development. Immunohistochemistry demonstrated that the tight junction protein, ZO-1, and specific podocytic markers, pp44, 5-1–6, podocalyxin and vimentin were expressed in a cell maturity-dependent manner, as observed in newborn rat kidneys. Furthermore, glomerular basement membrane components, collagen type IV and laminin, were expressed in the glomerular center. Our findings that cell maturity-dependent expression of structural and functional phenotypes in podocytes in metanephric culture was the same as that observed in developing kidneys in vivo indicate that podocyte differentiation during glomerulogenesis may be operated by an intrinsic property, such as programmed cell fate. Furthermore, these highly differentiated podocytes in vitro may provide clues that will help to establish a podocyte culture system. Accepted: 26 February 1997     

Cell proliferation in mouse tissues after thymectomy and the administration of T-activin

The epithelium of mouse cornea and lymph nodes was examined for DNA-synthetic and mitotic activity at different times after thymectomy and administration of T-activin, an active factor of the thymus. Thymectomy entails retardation of the rate of corneal epithelium regeneration, diminution in both tissues under study of the amplitude of oscillations in cell proliferation throughout the day. Administration to the animals of the immunoactive thymic factor T-activin makes the circadian rhythm of cell proliferation return to normal. It is assumed that T-activin raises the capacity of lymphocytes to interact with epithelial cells, which manifests itself in the enhancement of their mitotic activity.