Peptides that elicit midgut stem cell differentiation isolated from chymotryptic digests of hemolymph from Lymantria dispar pupae

Intestinal regeneration as an insect resistance mechanism to entomopathogenic bacteria

The intestinal epithelium of insects is exposed to xenobiotics and entomopathogens during the feeding developmental stages. In these conditions, an effective enterocyte turnover mechanism is highly desirable to maintain integrity of the gut epithelial wall. As in other insects, the gut of lepidopteran larvae have stem cells that are capable of proliferation, which occurs during molting and pathogenic episodes. While much is known on the regulation of gut stem cell division during molting, there is a current knowledge gap on the molecular regulation of gut healing processes after entomopathogen exposure. Relevant information on this subject is emerging from studies of the response to exposure to insecticidal proteins from the bacterium Bacillus thuringiensis (Bt) as model intoxicants. In this work we discuss currently available data on the molecular cues involved in gut stem cell proliferation, insect gut healing, and the implications of enhanced healing as a potential mechanism of resistance against Bt toxins.

Degeneration and cell regeneration in the midgut of Podisus nigrispinus (Heteroptera: Pentatomidae) during post-embryonic development

Cell death, proliferation, and differentiation in some developmental stages of insects have been studied in the midgut of ametabolous, which undergo only continuous growth, and holometabolous, which undergo complete metamorphosis. However, in hemimetabolous insects, evolutionarily intermediate between ametabolous and holometabolous, midgut reorganization during the post-embryonic development has been poorly studied. The present study evaluates the post-embryonic development of the midgut of a hemimetabolous insect, Podisus nigrispinus, to test the hypothesis that these insects have programmed cell death and proliferation followed by differentiation of regenerative cells during midgut growth from nymphs to adult. The morphometrical data showed a 6-fold increase in midgut length from the first instar nymph to the adult, which did not result from an increase in the size of the midgut cells, suggesting that the growth of the midgut occurs by an increase in cell number. Cell death was rarely found in the midgut, whereas proliferation of regenerative cells occurred quite frequently. The growth of the midgut of P. nigrispinus appears to result from the proliferation of regenerative cells present in the epithelium; unlike ametabolous and holometabolous insects, the midgut of P. nigrispinus does not undergo extensive remodeling, as shown by the low frequency of digestive cell death.

Expression analyses of caspase-1 and related activities in the midgut of Galleria mellonella during metamorphosis

The cDNA encoding caspase-1, a main protease involved in apoptosis, was cloned and sequenced from the midgut of the greater wax moth, Galleria mellonella. The open reading frame contains 879 nucleotides, encodes 293 amino acids, and was registered as Gmcaspase-1. The sequence comparison showed a high homology to lepidopteran caspase-1, human caspase-3, and ced-3 of Caenorhabditis elegans. Gmcaspase-1 is predicted to contain a short prodomain, large subunit, and small subunit domain. It also exhibits all characteristics of caspase, including three conserved cleavage sites after Asp-25, Asp-192, and Asp-181, three active site residues including a highly conserved QACQG pentapeptide active-site motif, and four substrate binding sites. The expression profiles during development showed that the transcript of Gmcaspase-1 and its protein products appeared in two or more waves in the midgut during metamorphosis. Immunohistochemistry, in situ hybridization, and TUNEL analyses revealed that apoptosis occurred first at the basal, then middle and then apical regions in the midgut epithelium and the yellow body is formed in the lumen. At least three waves of mitosis and differentiation follow the apoptosis waves from the basal and middle to apical parts to form the adult epithelium.

Monitoring stem cell proliferation and differentiation in primary midgut cell cultures from Heliothis virescens larvae using flow cytometry

In the midgut of Heliothis virescens larvae, proliferation and differentiation of stem cell populations allow for midgut growth and regeneration. Basic epithelial regenerative function can be assessed in vitro by purifying these two cell type populations, yet efficient high throughput methods to monitor midgut stem cell proliferation and differentiation are not available. We describe a flow cytometry method to differentiate stem from mature midgut cells and use it to monitor proliferation, differentiation and death in primary midgut stem cell cultures from H. virescens larvae. Our method is based on differential light scattering and vital stain fluorescence properties to distinguish between stem and mature midgut cells. Using this method, we monitored proliferation and differentiation of H. virescens midgut cells cultured in the presence of fetal bovine serum (FBS) or AlbuMAX II. Supplementation with FBS resulted in increased stem cell differentiation after 5 days of culture, while AlbuMAX II-supplemented medium promoted stem cell proliferation. These data demonstrate utility of our flow cytometry method for studying stem cell-based epithelial regeneration, and indicate that AlbuMAX II-supplemented medium may be used to maintain pluripotency in primary midgut stem cell cultures.

Factors affecting proliferation and differentiation of Lepidopteran midgut stem cells

Midgut stem cells of last instar larvae and pupae of Heliothis virescens, Lymantria dispar and several other Lepidopteran species have been cultured in vitro and have been induced to proliferate using low titers of ecdysteroids and the 77-Kda peptide fragment, alpha-arylphorin, isolated and identified from pupal fat body tissue. The insulin-related hormone, Bombyxin, also induced mitosis in cultured midgut stem cells; it appeared to be fast-acting and quickly inactivated, while alpha-arylphorin was slower to act and had a longer lasting effect in vitro, indicating different functions for these proliferation agents. Changes in Calcium ion concentration within or outside the cells discretely affected stem cell differentiation, indicating a role for second messenger participation in peptide regulation of this process. Four different peptides (MDFs 1-4) that induced midgut stem cells to differentiate to mature midgut cell types in vitro were isolated and characterized from conditioned media and hemolymph of H. virescens and L. dispar. However, platelet-derived growth factor (PDGF), epidermal growth factor (EGF), and all-trans retinoic acid (RA) from vertebrate sources induced differentiation to non-midgut cell types as well. MDF1 was located in basal areas of columnar cells of midgut epithelium, although MDF2 was observed in all of the cytoplasm of columnar cells and in droplets of antibody positive material in the midgut lumen, suggesting a digestive function as well for this peptide. Anti-MDF-3 stained the central areas of cultured midgut columnar cells and the bases of columnar cells of midgut epithelium in vivo. Midgut secretory cells stained with anti-MDF-4; streams of MFD-4-positive material were observed extending from secretory cells facing the epithelial lumen, and as a layer on the hemolymph-facing side, suggesting an endocrine or paracrine function for this or an immunologically similar peptide.

Regulation of midgut growth, development, and metamorphosis

The insect midgut is an important site of entry for pathogens and insect control agents. This review focuses on recent information related to midgut epithelial growth, metamorphosis, and repair as a defense against pathogens. The roles of stem cell mitogens and differentiation factors are described. Included is a discussion of apoptosis and autophagy in the yellow body. Sloughing, also described, protects the midgut from virus infections and bacterial toxins through death and replacement of affected cells. The mechanisms by which the repair process reduces the effectiveness of pest control strategies are discussed. Primary tissue culture methods also are described, and their value in understanding the mechanisms by which biologically based insecticides work is discussed.

Starvation suppresses cell proliferation that rebounds after refeeding in the midgut of the American cockroach, Periplaneta americana

Starvation affects behavior, development, metabolism, reproduction, and longevity in almost all animals including insects. In the American cockroach, Periplaneta americana, we investigated the effect of starvation on organ size and cell proliferation activity of the midgut, over a period of one month, using anti-bromodeoxyuridine (BrdU), and anti-phospho-histone H3 antibodies. Under starvation conditions, the midgut became clear and fragile while its length and diameter were reduced. Both the rate of BrdU-uptake in the nucleus and the mitotic activity shown by anti-phospho-histone H3 antibody decreased under long starvation up to half that of the continuously fed control. Refeeding restored BrdU-uptake and mitosis that overshot the fed control. When casein, starch, or cooking oil was fed as representative nutrient sources to the starved cockroaches, all restored BrdU-uptake, but non-nutrient, talc, did not. This study supports the hypothesis that P. americana has a homeostatic mechanism to regulate the cell population of the midgut epithelium according to changes in the nutritional environment.

A review of insect stem cell types

Insect stem cells have been described from both embryonic and adult tissues from a diversity of insect species, although much of the focus in insect stem cell research has been on Drosophila. Insects are a vast and diverse group and it is surprising that a critical aspect of their development like stem cells has not received more attention. In this review we discuss the current state of knowledge of insect stem cell types. We examine what stem cell types have been identified from insects, and briefly discuss what is known about their regulation.

Role of integrin beta1-like protein in proliferation and differentiation of cultured stem cells from midgut of Heliothis virescens

Cultured midgut cells from Heliothis virescens larvae were incubated with anti-human integrin beta1 made in rabbit and then passed over a column of magnetic beads bound to anti-rabbit IgG (MACS, Miltenyi Bergisch Gladbach, Germany). Cells bound to integrin beta1 antibody also bound to the anti-rabbit IgG on the magnetic beads (MACS) and were retained in the column while it remained in the magnetic field. Non-bound cells were eluted at this time. They did not stain with anti-integrin antibody just after elution. Removing the column from the magnetic field allowed cells bound to the beads-integrin beta1 antibody to be eluted. All of these cells stained with human anti-integrin beta1 upon elution. Each cell fraction was cultured in medium for 3 days. During this time, the populations of cells tended to return to heterogeneous staining patterns characteristic of control populations. However, cells that did not stain immediately with anti-integrin beta1 antibody exhibited double the rate of multiplication and 8 times more differentiation than the integrin-antibody positive cells that eluted later, as well as the non-treated control cells. In a second experiment, midgut cells were incubated for 4 days with various titers of human anti-integrin beta1 to block surface integrin beta1-like reactive sites. Stem cells blocked with anti-integrin beta1 antibody during incubation exhibited double the rate of differentiation than non-treated control cells and those showing anti-integrin beta1-positive stain upon elution.

Stimulation of Midgut Stem Cell Proliferation and Differentiation by Insect Hormones and Peptides

Stem cells derived from midguts of the caterpillar, Spodoptera littoralis, can be induced to multiply and differentiate in vitro. Ecdysone (E) and 20-hydroxyecdysone (20E) had a concentration-dependent effect: E was more active in cell proliferation and 20E in differentiation. Ecdysteroid receptors in midgut stem cell nuclei were stained with the antibody 9B9. In addition, alpha-arylphorin and four midgut differentiation factors (MDF) specifically stimulated proliferation and differentiation of stem cells, respectively. The activity of a panel of peptide growth factors and hormones on growth and metamorphosis of the insect midgut is discussed.

Altering the fate of stem cells from midgut of Heliothis virescens:the effect of calcium ions

Cultured stem cells from larval midgut tissue of the lepidopteran Heliothis virescens respond to alterations in external calcium ion concentration (Ca(2+) (out)) by changing the rate of stem cell proliferation and by differentiating to larval or non-larval phenotypes. Decreasing the external concentration of Ca(2+) with the Ca(2+) chelating agent EGTA increased proliferation of stem cells in culture, and doubled the proportion of cells differentiating to columnar and goblet cells typical of larval midgut compared to controls. In contrast, increasing inward transport of Ca(2+) into the cells by increasing the concentration of external calcium ion concentration, or by incubation with the Ca(2+) ionophore A23187 (which tends to open inward plasma membrane Ca(2+) channels), induced dose-dependent differentiation to non-midgut cell types such as squamous and scale-like cells. However, the latter treatments did not significantly alter stem cell proliferation or differentiation to normal larval midgut epithelium.

BOMBYXIN STIMULATES PROLIFERATION OF CULTURED STEM CELLS DERIVED FROM HELIOTHIS VIRESCENS AND MAMESTRA BRASSICAE LARVAE1

Bombyxin stimulated proliferation of cultured midgut stem cells that were derived from two noctuiid moth larvae, Heliothis virescens and Mamestra brassicae. Bombyxin exhibited the highest activity at 10(-12) M. The number of cells increased for 3 d after the addition of bombyxin. Although a single addition of bombyxin did not maintain proliferation, a second addition, made 3 d after the first treatment, retained the effect. Results suggest that the decline of effect after the first addition was not due to the loss of sensitivity of the cultured cells but to the loss of effect of the growth factor added. Addition of bombyxin at more than 10(-10) M was less effective. Bombyxin did not affect the number of cultured midgut cells without pupal fat body extract (FBX). The data suggest that FBX contains the factors that maintain sensitivity of midgut cells to proliferate in the presence of bombyxin. Bombyxin must be a unique growth factor that stimulates proliferation of midgut stem cells in vitro from lepidopteran larvae.

Implications for the functions of the four known midgut differentiation factors: An immunohistologic study of Heliothis virescens midgut

Antibodies to the peptides that induce differentiation of midgut larval stem cells, the midgut differentiating factors MDF-2, MDF-3, and MDF-4, bind to columnar cells in midgut cultures and in intact midgut of Heliothis virescens, in manners similar to the binding of anti- MDF-1 to those tissues. Antibodies to MDF-2 and MDF-3 also stained droplets in the midgut lumen, suggesting that columnar cells may also release MDF-2- and MDF-3-like cytokines to the lumen. Antibody to MDF-4 exhibited similar staining patterns but also recognized stem and differentiating cells, the presumed targets of peptides that regulate stem cell differentiation. Antibody to MDF-4 also bound to one type of endocrine cell in midgut cultures and in sections of midgut, as well as to the endocrine secretion released both to the midgut lumen and the hemolymph. Antibodies to the MDFs 1, 2, and 3, incubated with cultures of midgut cells, did not appear to prevent differentiation of the stem cells in the cultures but affected viability of mature cells, reflected in increased apoptosis and doubling of the number of differentiating cells compared to controls. Only antibody to MDF-4 induced temporary necrosis and inhibition of population recovery, indicating that MDF4 may be the true differentiation factor. The other MDFs may have additional functions beyond regulation of midgut stem cell differentiation in vivo.

Stimulation of midgut stem cell proliferation by Manduca sexta alpha-arylphorin

Extracts of the green-colored perivisceral fat body of newly ecdysed Manduca sexta pupae stimulate mitosis in midgut stem cells of Heliothis virescens cultured in vitro. Using a combination of cation- and anion-exchange chromatography, we have isolated a protein from these fat body extracts that accounts for the observed stem cell proliferation. SDS-PAGE analysis of the protein results in a single band of 77 kDa. Sequences of tryptic peptides from this protein are identical to internal sequences of the storage hexamer alpha-arylphorin. The alpha-arylphorin isolated by our procedure represents a small fraction of the total arylphorin present in the fat body extract. However, it alone seems responsible for the stimulation of mitotic activity in H. virescens midgut stem cells.

Stem cells from midguts of Lepidopteran larvae: clues to the regulation of stem cell fate

Previously, we showed that isolated stem cells from midguts of Heliothis virescens can be induced to multiply in response to a multiplication protein (MP) isolated from pupal fat body, or to differentiate to larval types of mature midgut cells in response to either of 4 differentiation factors (MDFs) isolated from larval midgut cell-conditioned medium or pupal hemolymph. In this work, we show that the responses to MDF-2 and MP in H. virescens stem cells decayed at different time intervals, implying that the receptors or response cascades for stem cell differentiation and multiplication may be different. However, the processes appeared to be linked, since conditioned medium and MDF-2 prevented the action of MP on stem cells; MP by itself appeared to repress stem cell differentiation. Epidermal growth factor, retinoic acid, and platelet-derived growth factor induced isolated midgut stem cells of H. virescens and Lymantria dispar to multiply and to differentiate to mature midgut cells characteristic of prepupal, pupal, and adult lepidopteran midgut epithelium, and to squamous-like cells and scales not characteristic of midgut tissue instead of the larval types of mature midgut epithelium induced by the MDFs. Midgut stem cells appear to be multipotent and their various differentiated fates can be influenced by several growth factors.