Glial repair in an insect

The repair of cockroach central nervous connectives, following selective glial disruption, involves an initial invasion of the lesion by a novel cell class. The available evidence, including that obtained using monoclonal antibodies, shows that these cells arise from circulating haemocytes. These invasive exogenous cells are restricted to the lesion zone. They are not only involved in initial repair of the peripheral glial elements, but may also be responsible for initiating recruitment and division of endogenous reactive cells. There is a clear anterior polarity in this recruitment, with significantly higher numbers of cells appearing anterior to, and then within, the lesion area. Characteristically, recognizable exogenous cells decline in number after 3 days, although there is no overall reduction in cell numbers within the lesion at this stage, nor has significant cell division begun. This suggests that the haemocyte-derived cells transform into, or are replaced by, functional perineurial glia, between 3 and 5 days, coincident with the restoration of the blood-brain barrier and the onset of endogenous cell division. Glial repair in the insect CNS can thus be divided into three phases which show striking similarities to the repair sequence in vertebrate brain. These include: an initial invasion of the lesion by exogenous cells, subsequent glial proliferation and then longer term fluxes in cell numbers and distribution.     

Glial repair in the cultured central nervous system of an insect

Summary Insect glial cells are capable of division and repair in organ culture after selective damage with the toxin ethidium bromide. The repair is slower and less organised than seen in vivo after similar treatment and is still incomplete after one month. Granule-containing cells, which play an important role in the early stages of repair in vivo, are never seen in cultured connectives. This observation adds further support to the hypothesis that these cells are derived from haemocytes and that their presence is necessary for rapid and orderly repair. The uptake of ³H-thymidine into perineurial glial cells in vitro, both in control and ethidiumtreated connectives, shows that there is a considerable proliferation of cells in this region. Some uptake of thymidine is also seen in subperineurial glia but division alone cannot account for the large increase in the number of glial nuclei found at the early stages of repair in this region. Further, glial cells with diverse morphologies suggest that subpopulations are present. We conclude that cell migration from undamaged areas, as well as cell proliferation, is necessary for CNS repair in vitro.     

Inhibition of cell division by interferons. The relationship between changes in utilization of thymidine for DNA synthesis and control of proliferation in Daudi cells.

Inhibition of the proliferation of Daudi cells by exposure to human lymphoblastoid interferons is associated with an early and marked decrease in the incorporation into DNA of exogenous [3H]thymidine when cells are incubated with trace amounts of this precursor. In contrast, incorporation of exogenous deoxyadenosine into DNA is unchanged under the same conditions. Interferon treatment results in a lowering of thymidine kinase activity, an effect which may be largely responsible for the inhibition of incorporation of labelled thymidine into DNA. At higher concentrations of exogenous thymidine, which minimize the contribution of intracellular sources to the dTTP pool, the inhibition of thymidine incorporation is abolished. Under conditions in which exogenous thymidine is rigorously excluded from the medium or, conversely, in which cells are entirely dependent on exogenous thymidine for growth, the magnitude of the inhibition of cell proliferation by interferons is the same as under normal culture conditions. We conclude that, even though cell growth is impaired, the rate of DNA synthesis is not grossly inhibited up to 48 h after commencement of interferon treatment. Furthermore, changes in neither the utilization of exogenous thymidine nor the synthesis of nucleotides de novo are responsible for the effect on cell proliferation.     

ABSENCE OF EFFECT OF MULTIPLE INTRAPERITONEAL INJECTIONS ON CELL PROLIFERATION, AND ESTIMATION OF THE CELL CYCLE TIME IN THE EPITHELIUM OF THE OESOPHAGUS AND FORESTOMACH IN MICE, HAMSTERS AND RATS

Counts of labelled epithelial nuclei in mice given single or multiple injections of tritiated thymidine (to label cells synthesizing deoxyribonucleic acid), either alone or after 24 or 48 hr multiple injections of water, showed that multiple intraperitoneal injections did not disturb normal cell proliferation. The rate of cell proliferation was the same in the epithelium of the oesophagus and forestomach, and in these epithelia there was no difference between mice, hamsters and rats. Cell cycle times were estimated in these epithelia from the number of nuclei labelled in animals given single or multiple injections of tritiated thymidine.     

KINETICS OF CELL RENEWAL, CELL MIGRATION AND CELL LOSS IN THE HAIRLESS MOUSE DORSAL EPIDERMIS

Forty hairless mice were given injections of tritiated thymidine every 4th hour during 10 days. At 24 hr intervals groups of four mice were killed. The numbers of labelled basal and differentiating cells were determined by autoradiography with a stripping film technique. To determine the background activity skin sections from uninjected control mice were subjected to the same stripping film procedure. Another group of hairless mice was given one single pulse labelling with tritiated thymidine. The number of labelled mitoses was scored for 12 hr after the injection. At 10, 12 and 15 hr after the injection, the numbers of labelled basal and differentiating cells were also determined. A mathematical model of cell population kinetics in the epidermis has been suggested. The results of different simulations on this model were compared with the observed results. The curve of mean grain counts under continuous labelling increased from day to day with two well-defined plateaux. The percentage of all labelled cells increased rapidly up to the 3rd day, and thereafter the curves gradually flattened off. When basal cells and differentiated cells were considered separately the labelling index of the basal cells increased rapidly for the first 3 days and then flattened off at the 100% level on the 5th day. The labelling index of the differentiating cells was low during the first 3–4 days. Then a steep increase in the percentage of labelled differentiating cells was seen, but the curve flattened off again close to the 100 % level after the 7th day. The labelled mitosis curve had its maximum 5 hr after the thymidine injection. The curve fell again to almost zero at 12 hr. Ten, 12 and 15 hr after the injection, 6, 7 and 7% respectively of the labelled cells were found in the spinous layer. It was concluded that three grains over each nucleus could be used as lower limit for considering a cell as labelled. On this basis, tritiated thymidine injections every 4th hour can be considered as continuous labelling.     

Cholinergic differentiation in neurogenic basal forebrain cultures.

To study early events in the central nervous system (CNS) cholinergic development, cells from rat basal forebrain tissue were placed in culture at an age when neurogenesis in vivo is still active [embryonic day (E) 15]. The rapid mortality of these cells in defined medium, with 50% mortality after 5-10 h, was blocked completely by soluble proteins from the olfactory bulb (a basal forebrain target), extending earlier observations (Lambert, Megerian, Garden, and Klein, 1988). Treated cultures were capable of incorporating thymidine into DNA, and most cells incorporating 3H-thymidine (greater than 90%) also stained positive for neurofilament, confirming neuronal proliferation in the supplemented cultures. A small percentage of 3H-thymidine labelled cells were glial fibrillary acidic protein (GFAP) positive, but growth factors that support astroglial proliferation [epidermal growth factor (EGF), basic fibroblast growth factor (bFGF), and insulin-like growth factor (IGF-1)] were not sufficient for neuronal support. After 5 culture days with supplemented medium, almost 50% of the cells showed choline acetyltransferase (ChAT) immunofluorescence. The cholinergic neurons typically formed clusters separate from noncholinergic cells. These mature cultures did not develop if young cultures were treated with aphidicolin to block DNA synthesis. The data show that cultures of very young rat basal forebrain cells can be neurogenic, giving rise to abundant cholinergic neurons, and that early cell proliferation is essential for long-term culture survival.     

Cholinergic differentiation in neurogenic basal forebrain cultures

To study early events in the central nervous system (CNS) cholinergic development, cells from rat basal fore brain tissue were placed in culture at an age when neurogenesis in vivo is still active [embryonic day (E) 15]. The rapid mortality of these cells in defined medium, with 50% mortality after 5–10 h, was blocked completely by soluble proteins from the olfactory bulb (a basal forebrain target), extending earlier observations (Lambert, Megerian, Garden, and Klein, 1988). Treated cultures were capable of incorporating thymidine into DNA, and most cells incorporating ³H-thymidine (>90%) also stained positive for neurofilament, confirming neuronal proliferation in the supplemented cultures. A small percentage of ³H-thymidine labelled cells were glial fibrillary acidic protein (GFAP) positive, but growth factors that support astroglial proliferation [epidermal growth factor (EGF), basic fibroblast growth factor (bFGF), and insulin-like growth factor (IGF-1)] were not sufficient for neuronal support. After 5 culture days with supplemented medium, almost 50% of the cells showed choline acetyltransferase (ChAT) immunofluorescence. The cholinergic neurons typically formed clusters separate from noncholinergic cells. These mature cultures did not develop if young cultures were treated with aphidicolin to block DNA synthesis. The data show that cultures of very young rat basal forebrain cells can be neurogenic, giving rise to abundant cholinergic neurons, and that early cell proliferation is essential for long-term culture survival.     

An autoradiographic analysis of neurogenesis in juvenile Aplysia californica

In developing Aplysia californica, a dramatic proliferation of new neurons occurs throughout the central nervous system (CNS) surprisingly late in juvenile development (Cash and Carew, 1989). In the present study, we investigated the source of these new neurons. Using tritiated thymidine autoradiography, we examined two different juvenile stages: stage 11 (before the large-scale proliferation) and stage 12 (at the peak of proliferation). Previous results implicated the body wall as a source for neurons in developing Aplysia (McAllister, Scheller, Kandel, and Axel, 1983; Jacob, 1984). Thus, we focused our attention on the body wall adjacent to a specific central ganglion, the abdominal ganglion. We found that in stage 11 there was uniform labelling of cells across the entire body wall. However, in stage 12 there was significantly more labelling in the body wall region immediately adjacent to the abdominal ganglion compared to flanking regions. Thus, at the time of neuronal proliferation, specific and highly localized regions of the body wall immediately opposite their target in the CNS show a significant increase in cell division. We also examined the distribution of labelled cells in the abdominal ganglion at survival times of 1 and 7 days after thymidine injection. In both stage 11 and stage 12, the fraction of labelled cells on the surface of the ganglion decreased over time, with a corresponding significant increase in the fraction observed on the inside. Our results support the hypothesis that specific regions of body wall are significantly up-regulated in juvenile Aplysia development, giving rise to widespread neuronal proliferation. These neurons then migrate from the body wall to their target ganglion, and from there continue migrating into the ganglion to achieve their final position.     

CELL KINETICS OF GROWTH CARTILAGE IN THE RAT TIBIA II. MEASUREMENTS DURING AGEING

A number of cell kinetic techniques using labelled thymidine and autoradiography have been applied to study growth cartilage in the rat tibia during ageing. No change in the duration of the synthesis phase was found from 4 to 13 weeks of age but there was a reduction in cell proliferation rate during this period. Measurements of labelling index, proliferation zone size and height of hypertrophic cells were used to calculate the growth rate of the bone from 7 days to 1 year. The results agreed well with radiographic measurements of bone growth.     

The cell cycle of glial cells grown in vitro: an immunocytochemical method of analysis.

Studies of cell cycles have traditionally employed [3H]- and [14C]-thymidine to label the DNA of proliferating cells and autoradiography to reveal the thymidine label. The development of antibodies to the thymidine analogue 5-bromodeoxyuridine (BrdU) has allowed the development of an immunocytochemical method analogous to the thymidine autoradiographic technique. In direct comparisons, we found that the immunocytochemical method consistently detected a larger number of proliferating cells. This suggests that it may be a more sensitive index of proliferation than thymidine autoradiography in some systems. We used the BrdU method to analyze the cycle of astroglia cultured from neonatal mouse cerebral cortex. Cells were exposed to BrdU for 1 hr to label a discrete subpopulation of proliferating cells. At 2-36 hr after the pulse, a combination of anti-BrdU immunocytochemistry and counterstaining with propidium iodide was used to identify proliferating cells. The length of the cell cycle was determined by charting the percent of BrdU-labeled mitotic cells vs time after the pulse. We found the average length of the cell cycle of astrocytes grown in vitro to be 20.5 hr. The combined G2 + M phases were 2-3 hr. These values are virtually identical with those found for glial cells in vivo, suggesting that the culture environment does not interfere with the normal control of cell cycle length.     

Taste Bud Cell Generation in the Perihatching Chick

Chick taste bud primordia initially appear in late gestationon embryonic day 17 (E17), 4 days before hatching. To trackDNA synthesis and subsequent taste bud cell proliferation betweenE17 and the second day post-hatching (H2), single 25 µCiinjections of tritiated thymidine (specific activity = 72.5Ci/mmol) were administered in ovo during E15, E16, E17 or E18.Anterior mandibular oral epithelium was processed for lightmicroscopic autoradiography. Sections through each taste bud'scenter were analysed for label (6 silver grains/gemmal cellnucleus), and bud diameter. Results indicated a major part ofgemmal cell DNA synthesis does not occur until after E19 irrespectiveof the day of thymidine injection, suggesting postmitotic orquiescent (decycled) cells assemble to form the early bud primordium(E17–19) based on local tissue interactions. All budsexamined from E20–H2 contained labelled cells. The dayof injection was important since 5-day survival cases afterE16 injection yielded about 25% the number of labelled cells/budas compared with equivalent survival cases following E17–18injections. These results are discussed with respect to parallelchanges in bud shape and increasing bud diameter, and cell proliferationin possible extra- and intragemmal sources of bud cells.     

Quantitative characteristics of cells formed during early postnatal ontogenesis in the cytoarchitectonic layers of the parietal region of the cortex in normal mice and following brain injuries]

By means of computer analysis, size distribution of neurons and glial cells together with the label of 3H-thymidin labelled cells were studied in cytoarchitectonic layers of the field 1 in the mouse parietal cortex injected with the isotope on the 5th day of life and killed 1 month later. In some animals, 3 days before 3H-thymidin injection, the parietal region in the right hemisphere was perforated. The labelled cells were subdivided into 2 groups according to their size: astrocytes (A) and small gliocytes (mg). Labelled A and mg were stated to be rather evenly distributed along the cytoarchitectonic layers in the field 1. The trauma performed resulted in increasing amount of the labelled A and MG in the operated hemisphere. Uniformity in distribution of the labelled A and mg, occupying the position of satellites, did not change considerably at the trauma, in spite of general quantitative increase of the labelled glial cells. One month after the trauma, body dimentions of the mice labelled with A and mg did not considerably differ from those of intact animals, while the size of nerve cells increased. Thus, neurons in the parietal cortex of a growing brain respond to brain trauma with hypertrophy of cell bodies, and glial populations--with increase of their number.     

Growth in retinal glial cells in vitro is affected differentially by two types of cell contact-mediated interactions

Contact among rabbit retinal glial cells in subconfluent culture was previously shown to stimulate DNA synthesis [J. M. Burke (1983) Exp. Cell Res. 146, 204-206]. In this study nonliving surface membranes and metabolic coupling were investigated as mediators of the contact-dependent phenomenon. To evaluate surface membranes, preparations of fixed glial cells and fixed fibroblasts of several types were added in varying numbers to sparse cultures of glia or fibroblasts. In agreement with published data, fibroblast proliferation was inhibited by the fixed cells in a dose-dependent manner. Growth in glial cells was similarly inhibited. Fixed cells of both types were approximately equally effective in suppressing proliferation in cells of both types. No number of fixed cells was identified which, when added to glial cultures, stimulated glial proliferation. In contrast, metabolic coupling among glial cells was associated with increased DNA synthesis. Coupling was detected radioautographically as a flux of labeled precursor molecules from a prelabeled to a recipient population of glial cells in coculture. The cocultures were secondarily incubated with [3H]thymidine to label the nuclei of S-phase recipient cells. In the cocultures there was a higher rate of nuclear labeling in coupled than in uncoupled recipient glial cells. The results suggest that growth in subconfluent retinal glial cell cultures is modulated differentially by two types of interactions which require cell contact: growth is inhibited by interaction among nonliving cell surfaces but stimulated by metabolic cooperation among living cells.     

A beta-lactam antibiotic dampens excitotoxic inflammatory CNS damage in a mouse model of multiple sclerosis

In multiple sclerosis (MS) and its animal model experimental autoimmune encephalomyelitis (EAE), impairment of glial "Excitatory Amino Acid Transporters" (EAATs) together with an excess glutamate-release by invading immune cells causes excitotoxic damage of the central nervous system (CNS). In order to identify pathways to dampen excitotoxic inflammatory CNS damage, we assessed the effects of a beta-lactam antibiotic, ceftriaxone, reported to enhance expression of glial EAAT2, in "Myelin Oligodendrocyte Glycoprotein" (MOG)-induced EAE. Ceftriaxone profoundly ameliorated the clinical course of murine MOG-induced EAE both under preventive and therapeutic regimens. However, ceftriaxone had impact neither on EAAT2 protein expression levels in several brain areas, nor on the radioactive glutamate uptake capacity in a mixed primary glial cell-culture and the glutamate-induced uptake currents in a mammalian cell line mediated by EAAT2. Moreover, the clinical effect of ceftriaxone was preserved in the presence of the EAAT2-specific transport inhibitor, dihydrokainate, while dihydrokainate alone caused an aggravated EAE course. This demonstrates the need for sufficient glial glutamate uptake upon an excitotoxic autoimmune inflammatory challenge of the CNS and a molecular target of ceftriaxone other than the glutamate transporter. Ceftriaxone treatment indirectly hampered T cell proliferation and proinflammatory INFgamma and IL17 secretion through modulation of myelin-antigen presentation by antigen-presenting cells (APCs) e.g. dendritic cells (DCs) and reduced T cell migration into the CNS in vivo. Taken together, we demonstrate, that a beta-lactam antibiotic attenuates disease course and severity in a model of autoimmune CNS inflammation. The mechanisms are reduction of T cell activation by modulation of cellular antigen-presentation and impairment of antigen-specific T cell migration into the CNS rather than or modulation of central glutamate homeostasis.     

The chick embryo fibroblast cytosolic DNA complex--a possible cell-cell messenger

1. The uptake of [3H]thymidine and [3H]uridine labelled DNA-RNA cytosol complex has been studied in chick embryo fibroblast cells. 2. The complex appears to be cleaved into DNA and RNA containing fragments in the recipient cell nucleus: both then enter the cell cytosol fraction, but the RNA fragment in particular is rapidly degraded. 3. Although [3H]thymidine labelled material present in the nucleus co-extracts with bulk nuclear DNA, caesium gradienting shows little or no evidence that integration of host and imported DNA has occurred. 4. It is suggested that the cytosolic/extruded DNA complex may be a "messenger" DNA, capable of the transfer of regulatory information between cells on a transient basis.     

Cell specific DNA-labelling in the repairing blood-brain barrier of the insect Periplaneta americana

Summary This study uses a recently developed technique for preserving the ultrastructure of cells in the insect CNS during immunohistochemical processing for 5-bromo-2-deoxyuridine incorporation into newly synthesised DNA. The results allow us to identify the proliferating cell calsses in the regenerating blood-brain barrier. High resistance barrier cells do not label with the antibody but sheath cells clearly do. Intermediate cell types appearing during repair are identified. It is hypothesised that these cells generate matrix molecules for neural lamella repair and may represent transitional forms as invasive blood cells transdifferentiate into functional sheath cells.     

Cellular analysis on localization of lens forming potency in the newt iris epithelium

The localization of a lens forming potency in the iris epithelium was studied by autoradiographic analysis of the distribution of ³H-thymidine labelled cells to be participated in lens regeneration in newts. DNA synthesis started from the dorsal portion of the iris epithelium around 4 days after lentectomy. 5 days after lentectomy, a large number of labelled cells were mostly found in the dorsal sector, showing strong contrast to the ventral and lateral sectors of iris, which contained a few labelled cells. The labelled index (the number of labelled cells/the number of cells in the definite pigmented area of the iris epithelium) of the dorsal sector attained the highest value, 29.7 ± 2.35, on day 7 after lentectomy, and dropped temporarily. This was followed by the second peak on day 12. The dorso-ventral ratio of the labelled index reached to the highest value, 6.87 ± 0.67, on day 5. This ratio decreased rapidly after the completion of a lens rudiment, and it became about 1. In “chase” experiments by diluting the radio-isotope with excess cold thymidine, it was obviously shown that most of the cells labelled with the radio-isotope and distributed in the dorsal marginal iris 5 days after lentectomy participated in the formation of a lens regenerate during the period of chasing. From these results, the following conclusion was drawn. The iris epithelium consists of at least 2 different cell populations; one is capable of transformation into lens cells and is distributed mostly in the dorsal portion of the iris epithelium, while the other has no potency for transformation and is able to grow to compensate a loss of the dorsal marginal cells which transformed into lens cells during the process of lens regeneration.     

Rate of loss of tritiated thymidine label in basal cells in mouse epithelial tissues

A subpopulation of epithelial cells which retains a tritiated thymidine label (termed label-retaining cells, LRCs) has been previously demonstrated in skin and oral mucosae of mice and hamsters. To examine the rate of decrease in the number of LRCs and the changes in degree of labelling, young mice were labelled with tritiated thymidine and the rate at which label was diluted from basal keratinocytes assessed for up to 90 days. The number of LRCs in each tissue examined decreased from 15 to 90 days after labelling with the epidermal tissues maintaining a higher percentage of LRCs than the oral mucosae. Grain counts for LRCs in each tissue at each time period indicated that the number of silver grains overlying LRCs also decreased with time. The observed decrease in numbers of LRCs and the change in their degree of labelling with time suggest that such cells divide slowly, a property associated with stem cells.     

Rate of Loss of Tritiated Thymidine Label In Basal Cells In Mouse epithelial tissues

A subpopulation of epithelial cells which retains a tritiated thymidine label (termed label-retaining cells, LRCs) has been previously demonstrated in skin and oral mucosae of mice and hamsters. to examine the rate of decrease in the number of LRCs and the changes in degree of labelling, young mice were labelled with tritiated thymidine and the rate at which label was diluted from basal keratinocytes assessed for up to 90 days. the number of LRCs in each tissue examined decreased from 15 to 90 days after labelling with the epidermal tissues maintaining a higher percentage of LRCs than the oral mucosae. Grain counts for LRCs in each tissue at each time period indicated that the number of silver grains overlying LRCs also decreased with time. the observed decrease in numbers of LRCs and the change in their degree of labelling with time suggest that such cells divide slowly, a property associated with stem cells.     

Asexual reproduction in Microstomum lineare (Turbellaria). I. An autoradiographic and ultrastructural study

The distribution of cells preparing for proliferation during asexual reproduction by paratomy in Microstomum lineare (Turbellaria) was investigated using the technique of exogenous tritiated thymidine ([³H]T) labelling and routine electron microscopy. The subsequent fates of labelled cells in developing and mature zooids were followed by fixing tissues at various intervals. The only labelled cells are mesenchymal and gastrodermal neoblasts, occurring along the whole worm without any special growth zones or axial gradient. Organ primordia develop as a result of locally dividing as well as of migrating cells.