Minute mosaics caused by early chromosome loss

Summary Two genetic operations have been combined in order to ascertain whether there are differential proliferation rates in the syncytial nuclei and the blastoderm cells prior to the formation of the imaginal disc anlagen. Early chromosome loss caused by the mutantca ^nd has been associated with the generation ofMinute (M/M ⁺) genotypes in normal (M ⁺/M ⁺) zygotes or of non-Minute genotypes inMinute zygotes. The results indicate that there is no growth competition betweenMinute and non-Minute cells prior to the formation of the imaginal discs. Growth competition, however, leads later, during the proliferation phase of the discs, to the demarcation of compartment boundaries within imaginal discs.     

Parameters of cell competition in the compartments of the wing disc of Drosophila.

When compartments in the wing disc of Drosophila are mosaic for two populations of cells, one of which is dividing more slowly, then the slower-growing population tends to be eliminated. The phenomenon leading to the disappearance of nonlethal, slowly dividing Minute cells was termed cell competition by Morata and Ripoll (1975) [Morata, G., and Ripoll, P. (1975). Develop. Biol.427, 211–221]. In this paper the different parameters of cell competition are explored. Starvation of the larvae rescued the Minute clones and permitted the following observations: The Minute clones grow to some extent before being out-competed. Prior to their disappearance, they become fragmented into small patches. Cell competition is greater in the centre of compartments than in the boundary regions. Possible causes of cell competition are discussed, as well as the hypothesis that the phenomenon may be related to the control of growth.     

Growth is required for cell competition in the imaginal discs ofDrosophila melanogaster

Summary Imaginal wing discs from late third-instar larvae were gammairradiated to induce clones of rapidly growingMinute ^– cells in a background of slowly growingMinute cells and culturedin vivo for periods up to 18 days. Clones in discs cultured for 16 to 18 days did not grow significantly larger than clones in uncultured controls, indicating that competition between populations of cells having potentially different mitotic rates does not occur in imaginal discs after their growth is completed.     

Cell lineage restrictions in the genital disc ofDrosophila revealed byMinute gynandromorphs

Summary The genital imaginal disc ofDrosophila differentiates the terminalia, i.e. the genitalia and analia, of both sexes. It represents a composite anlage, containing a female genital primordium, a male genital primordium and an anal primordium. In normal males and females, only one of the two genital primordia differentiates; the other is developmentally repressed. Therefore, cell-lineage relationships between the male and female genital primordia can only be studied in sexual mosaics which differentiate female and male cells. We producedMinute (M)non-Minute(M⁺) gynandromorphs and selected those with sexually mosaic terminalia for a cell-lineage analysis. In these mosaics, either the male (XO) or female (XX) cells wereM ⁺ and thus had a growth advantage. The differential growth rates served as a tool to detect clonal restrictions. In control gynandromorphs (M ⁺M ⁺), the amount of female genitalia differentiated was largely independent of the amount of male genitalia present. In contrast, male and female anal structures, as a rule, added up to one full set. The same was true for the experimentalMM ⁺ gynandromorphs, but the contribution ofXX andXO cells to mosaic terminalia changed drastically due toM ⁺ cells competing successfully against the more slowly growingM cells. Specific subsamples ofMM ⁺ gynandromorphs showed thatM cells in a non-mosaic primordium are shielded from cell competition taking place in the neighbouring mosaic primordium. We conclude that the three primordia of the genital disc represent developmental compartments. In the genital primordia, even developmentally repressedM ⁺ cells compete successfully against developmentally activeM cells.     

Clonal analysis of the undifferentiated wing disk of Drosophila

Using a new cell marker, we have examined the early clonal restrictions in wing imaginal disks from late third instar larvae of Drosophila. Large clones do not significantly alter the gross structure of the disks, allowing us to map the clones relative to morphological landmarks. Clones in the posterior region of the disks behave in a similar way to clones in the adult cuticle; that is, they appear to be restricted to a defined compartment, and the presumptive anterior/posterior compartment border defined by these clones is located in a similar place in every disk. In contrast, clones in the anterior region of the wing disks often cross into the region normally occupied by the posterior compartment and, especially near the margins of the disk, show no common posterior boundary. We believe that the anterior clones are “pushing” the anterior/posterior compartment border, and that this pushing is related to the growth advantage of the marked cells, which are Minute⁺ in a Minute background. Finally, we find that clones do not cross between the adepithelial cells, which contribute to the adult musculature, and the disk epithelium.     

Cell clones and pattern formation: Developmental restrictions in the compound eye ofDrosophila

Summary Five regions of the compound eye have been found to be preferential boundaries for clones of labelledMinute ⁺ cells, and to act restrictively on the growth of cell clones after a given developmental stage. One of these regions is topographically related to the line of pattern inversion existing at the level of the equator. The results of experiments showing independency of origin of restriction lines and line of pattern inversion are reported.     

Epithelial cell-turnover ensures robust coordination of tissue growth in Drosophila ribosomal protein mutants

Highly reproducible tissue development is achieved by robust, time-dependent coordination of cell proliferation and cell death. To study the mechanisms underlying robust tissue growth, we analyzed the developmental process of wing imaginal discs in Drosophila Minute mutants, a series of heterozygous mutants for a ribosomal protein gene. Minute animals show significant developmental delay during the larval period but develop into essentially normal flies, suggesting there exists a mechanism ensuring robust tissue growth during abnormally prolonged developmental time. Surprisingly, we found that both cell death and compensatory cell proliferation were dramatically increased in developing wing pouches of Minute animals. Blocking the cell-turnover by inhibiting cell death resulted in morphological defects, indicating the essential role of cell-turnover in Minute wing morphogenesis. Our analyses showed that Minute wing discs elevate Wg expression and JNK-mediated Dilp8 expression that causes developmental delay, both of which are necessary for the induction of cell-turnover. Furthermore, forced increase in Wg expression together with developmental delay caused by ecdysone depletion induced cell-turnover in the wing pouches of non-Minute animals. Our findings suggest a novel paradigm for robust coordination of tissue growth by cell-turnover, which is induced when developmental time axis is distorted.     

Abnormalities in cell proliferation and apico-basal cell polarity are separable in Drosophila lgl mutant clones in the developing eye

In homozygous mutants of Drosophila lethal-2-giant larvae (lgl), tissues lose apico-basal cell polarity and exhibit ectopic proliferation. Here, we use clonal analysis in the developing eye to investigate the effect of lgl null mutations in the context of surrounding wild-type tissue. lgl⁻ clones in the larval eye disc exhibit ectopic expression of the G1-S regulator, Cyclin E, and ectopic proliferation, but do not lose apico-basal cell polarity. Decreasing the perdurance of Lgl protein in larval eye disc clones, by forcing extra proliferation of lgl⁻ tissue (using a Minute background), leads to a loss in cell polarity and to more extreme ectopic cell proliferation. Later in development at the pupal stage, lgl mutant photoreceptor cells show aberrant apico-basal cell polarity, but this is not associated with ectopic proliferation, presumably because cells are differentiated. Thus in a clonal context, the ectopic proliferation and cell polarity defects of lgl⁻ mutants are separable. Furthermore, lgl⁻ mosaic eye discs have alterations in the normal patterns of apoptosis: in larval discs some lgl⁻ and wild-type cells at the clonal boundary undergo apoptosis and are excluded from the epithelia, but apoptosis is decreased elsewhere in the disc, and in pupal retinas lgl⁻ tissue shows less apoptosis.     

Rubidium transport in Neurospora crassa

Rb⁺ transport in low-K⁺ cells of Neurospora crassa is biphasic, transport at millimolar Rb⁺ being added to a transport process which saturates in the micromolar range. Both processes exhibit Michaelis-Menten kinetics, but in the micromolar phase the kinetic parameters depend on the K⁺ content of the cell (the lower the K⁺ content the lower the K_m and the higher the V_max). Normal-K⁺ cells, suspended in a buffer with millimolar K⁺, do not present Rb⁺ transport in the micromolar range. Millimolar transport in these cells presents kinetics which depend on the K⁺ in buffer (the higher the K⁺ the higher the K_m), although the K⁺ content of the cells is constant. Na⁺ inhibits competitively Rb⁺ transport in low-K⁺ and normal-K⁺ cells, but, even when the differences between the Rb⁺K_m values are more than three orders of magnitude, the apparent dissociation constant for Na⁺ is the same, and millimolar, in both cases.     

Overexpression of IL-10 in C2D Macrophages Promotes a Macrophage Phenotypic Switch in Adipose Tissue Environments

Adipose tissue macrophages are a heterogeneous collection of classically activated (M1) and alternatively activated (M2) macrophages. Interleukin 10 (IL-10) is an anti-inflammatory cytokine, secreted by a variety of cell types including M2 macrophages. We generated a macrophage cell line stably overexpressing IL-10 (C2D-IL10) and analyzed the C2D-IL10 cells for several macrophage markers after exposure to adipocytes compared to C2D cells transfected with an empty vector (C2D-vector). C2D-IL10 macrophage cells expressed more CD206 when co-cultured with adipocytes than C2D-vector cells; while the co-cultured cell mixture also expressed higher levels of Il4, Il10, Il1β and Tnf. Since regular C2D cells traffic to adipose tissue after adoptive transfer, we explored the impact of constitutive IL-10 expression on C2D-IL10 macrophages in adipose tissue in vivo. Adipose tissue-isolated C2D-IL10 cells increased the percentage of CD206⁺, CD301⁺, CD11c⁻CD206⁺ (M2) and CD11c⁺CD206⁺ (M1b) on their cell surface, compared to isolated C2D-vector cells. These data suggest that the expression of IL-10 remains stable, alters the C2D-IL10 macrophage cell surface phenotype and may play a role in regulating macrophage interactions with the adipose tissue.     

An All-or-None Response in the Release of Potassium by Yeast Cells Treated with Methylene Blue and Other Basic Redox Dyes

Basic redox dyes, such as methylene blue, induce a loss of K⁺ from yeast cells. The maximal loss, rather than the rate of loss, is related to the dye concentration, the response following a normal distribution on a plot of log-dose, versus percentage loss of K⁺. This fact taken together with the observed correlation between K⁺ loss and frequency of staining (as measured by microscopic observation), indicates that the response is all-or-none for individual cells. The response is produced by all the basic redox dyes tested (9), but by none of the acidic dyes (4). However, only the oxidized form of the dye is effective. Cations protect the cells from the basic dyes in a competitive manner, the bivalent cations (especially UO₂⁺⁺) being more effective than monovalent cations. It is suggested that the action of the dyes involves two steps, the first a binding to ribonucleic acid in the cell membrane (with competition from cations) and the second, an oxidation of neighboring sulfhydryl groups to the disulfide form. At a threshold level, unique for each cell, a generalized membrane breakdown occurs, resulting in the release of potassium and of other cytoplasmic constituents.     

Proliferation-Linked Apoptosis of Adoptively Transferred T Cells after IL-15 Administration in Macaques

The adoptive transfer of antigen-specific effector T cells is being used to treat human infections and malignancy. T cell persistence is a prerequisite for therapeutic efficacy, but reliably establishing a high-level and durable T cell response by transferring cultured CD8⁺ T cells remains challenging. Thus, strategies that promote a transferred high-level T cell response may improve the efficacy of T cell therapy. Lymphodepletion enhances persistence of transferred T cells in mice in part by reducing competition for IL-15, a common γ-chain cytokine that promotes T cell memory, but lymphodepleting regimens have toxicity. IL-15 can be safely administered and has minimal effects on CD4⁺ regulatory T cells at low doses, making it an attractive adjunct in adoptive T cell therapy. Here, we show in lymphoreplete macaca nemestrina, that proliferation of adoptively transferred central memory-derived CD8⁺ effector T (T_CM/E) cells is enhanced in vivo by administering IL-15. T_CM/E cells migrated to memory niches, persisted, and acquired both central memory and effector memory phenotypes regardless of the cytokine treatment. Unexpectedly, despite maintaining T cell proliferation, IL-15 did not augment the magnitude of the transferred T cell response in blood, bone marrow, or lymph nodes. T cells induced to proliferate by IL-15 displayed increased apoptosis demonstrating that enhanced cycling was balanced by cell death. These results suggest that homeostatic mechanisms that regulate T cell numbers may interfere with strategies to augment a high-level T cell response by adoptive transfer of CD8⁺ T_CM/E cells in lymphoreplete hosts.     

CD98 Heavy Chain Is a Potent Positive Regulator of CD4+ T Cell Proliferation and Interferon-γ Production In Vivo

Upon their recognition of antigens presented by the MHC, T cell proliferation is vital for clonal expansion and the acquisition of effector functions, which are essential for mounting adaptive immune responses. The CD98 heavy chain (CD98hc, Slc3a2) plays a crucial role in the proliferation of both CD4⁺ and CD8⁺ T cells, although it is unclear if CD98hc directly regulates the T cell effector functions that are not linked with T cell proliferation in vivo. Here, we demonstrate that CD98hc is required for both CD4⁺ T cell proliferation and Th1 functional differentiation. T cell-specific deletion of CD98hc did not affect T cell development in the thymus. CD98hc-deficient CD4⁺ T cells proliferated in vivo more slowly as compared with control T cells. C57BL/6 mice lacking CD98hc in their CD4⁺ T cells could not control Leishmania major infections due to lowered IFN-γ production, even with massive CD4⁺ T cell proliferation. CD98hc-deficient CD4⁺ T cells exhibited lower IFN-γ production compared with wild-type T cells, even when comparing IFN-γ expression in cells that underwent the same number of cell divisions. Therefore, these data indicate that CD98hc is required for CD4⁺ T cell expansion and functional Th1 differentiation in vivo, and suggest that CD98hc might be a good target for treating Th1-mediated immune disorders.     

Accumulation of cytolytic CD8 T cells in B16-melanoma and proliferation of mature T cells in TIS21-knockout mice after T cell receptor stimulation

In vivo and in vitro effects of TIS21 gene on the mature T cell activation and antitumor activities were explored by employing MO5 melanoma orthograft and splenocytes isolated from the TIS21-knockout (KO) ² mice. Proliferation and survival of mature T cells were significantly increased in the KO than the wild type (WT) ³ cells, indicating that TIS21 inhibits the rate of mature T cell proliferation and its survival. In MO5 melanoma orthograft model, the KO mice recruited much more CD8⁺ T cells into the tumors at around day 14 after tumor cell injection along with reduced tumor volumes compared with the WT. The increased frequency of granzyme B⁺ CD8⁺ T cells in splenocytes of the KO mice compared with the WT may account for antitumor-immunity of TIS21 gene in the melanoma orthograft. In contrast, reduced frequencies of CD107a⁺ CD8⁺ T cells in the splenocytes of KO mice may affect the loss of CD8⁺ T cell infiltration in the orthograft at around day 19. These results indicate that TIS21 exhibits antiproliferative and proapoptotic effects in mature T cells, and differentially affects the frequencies of granzyme B⁺ CD8⁺ T-cells and CD107a⁺ CD8⁺ T-cells, thus transiently regulating in vivo anti-tumor immunity.     

Intratumoral CD8+ T/FOXP3+ cell ratio is a predictive marker for survival in patients with colorectal cancer

The human immune system consists of a balance between immune surveillance against non-self antigens and tolerance of self-antigens. CD8⁺ T cells and CD4⁺ regulatory T cells (Tregs) are the main players for immune surveillance and tolerance, respectively. We examined immunohistochemically the immunological balance at the tumor site using 94 surgically resected colorectal cancer tissues. Forkhead box P3 (FOXP3)⁺ cells were considered to be Tregs in the present study. The number of intratumoral FOXP3⁺ cells (itFOXP3⁺ cells) was positively correlated with lymph node metastases (P = 0.030). itCD8⁺ T/itFOXP3⁺ cell ratio negatively correlated with pathological stages (P = 0.048). Next, relationship between the number of itCD8⁺ T cells or itFOXP3⁺ cells and survival prognosis in 94 patients who underwent a curative resection was analyzed. Only itCD8⁺ T/itFOXP3⁺ cell ratio positively correlated with disease-free survival (0.023) and overall survival (P = 0.010). Multivariate analysis indicated that itCD8⁺ T/itFOXP3⁺ cell ratio is an independent prognostic factor (P = 0.035) of overall survival. The number of itFOXP3⁺ cells positively correlated with transforming growth factor-beta TGF-β production at the tumor site (P = 0.020). In conclusion, itCD8⁺ T/itFOXP3⁺ cell ratio is a predictive marker for both disease-free survival time and overall survival time in patients with colorectal cancer. Importantly, itCD8⁺ T/itFOXP3⁺ cell ratio may be an independent prognostic factor. And, tumor-producing TGF-β may contribute to the increased number of itFOXP3⁺ cells.     

Biased competition between Lgr5 intestinal stem cells driven by oncogenic mutation induces clonal expansion

The concept of ‘field cancerization’ describes the clonal expansion of genetically altered, but morphologically normal cells that predisposes a tissue to cancer development. Here, we demonstrate that biased stem cell competition in the mouse small intestine can initiate the expansion of such clones. We quantitatively analyze how the activation of oncogenic K-ras in individual Lgr5⁺ stem cells accelerates their cell division rate and creates a biased drift towards crypt clonality. K-ras mutant crypts then clonally expand within the epithelium through enhanced crypt fission, which distributes the existing Paneth cell niche over the two new crypts. Thus, an unequal competition between wild-type and mutant intestinal stem cells initiates a biased drift that leads to the clonal expansion of crypts carrying oncogenic mutations.     

Increased Potassium Absorption Confers Resistance to Group IA Cations in Rubidium-Selected Suspension Cells of Brassica napus

Cell lines of suspension cultures of Brassica napus cv. Jet Neuf were identified for their ability to tolerate 100 millimolar Rb⁺, a level which was double the normally lethal concentration. Ten spontaneous isolates were obtained from approximately 5 × 10⁷ cells, one of which was reestablished as a cell suspension. This cell line, JL5, was also resistant to the other group IA cations— Li⁺, Na⁺, K⁺, and Cs⁺—and this trait was stable for at least 30 cell generations in the absence of Rb⁺ selection pressure. The growth characteristics were similar to those of sensitive cells under nonselective conditions. The selected JL5 cells were shown by analysis to have effected more net accumulation of K⁺ and Rb⁺ and less of Na⁺ than did the unselected cells. JL5 and unselected cells after 14 days of culture in basal medium contained 597.2 and 258.2 micromoles of K per gram dry weight, respectively. Michaelis-Menten kinetic analysis of K⁺ influx showed that JL5 possessed an elevated phase 1 V_max, but there was no alteration in its K_m. This is the first time that a plant mutation has been shown to have both increased influx and net absorption of a major essential cation.     

The role of hERG1 K channels and a functional link between hERG1 K channels and SDF-1 in acute leukemic cell migration

Stromal cell-derived factor-1 (SDF-1) and its unique receptor, CXCR4, regulate stem/progenitor cell migration and retention in the bone marrow and are required for hematopoiesis. Recent studies found that hERG1 K⁺ channels were important regulators of tumor cell migration. In this study, we investigated whether SDF-1 induced acute leukemic cell migration associated with hERG1 K⁺ channels. Our results showed that E-4031, a specific hERG1 K⁺ channels inhibitor, significantly blocked SDF-1-induced migration of leukemic cell lines, primary acute leukemic cells, leukemic stem cells and HEK293T cells transfected with herg-pEGFP. The migration of phenotypically recognizable subsets gave the indication that lymphoblastic leukemic cells were inhibited more than myeloid cells while in the presence of E-4031 which maybe associated with herg expression. SDF-1 increased hERG1 K⁺ current expressed in oocytes and HEK293T cells transfected with herg-pEGFP. There were no significant changes of CXCR4 expression on both HL-60 cells and primary leukemic cells regardless if untreated or treated with E-4031 for 24 h (P > 0.05). The hERG1 K⁺ current increased by SDF-1 might contribute to the mechanism of SDF-1-induced leukemic cell migration. The data suggested that hERG1 K⁺ channels functionally linked to cell migration induced by SDF-1.