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© The Rockefeller University Press,
0021-9525/2000//825 $5.00
The Journal of Cell Biology, Volume 149, Number 4,
, 2000 825-834
Original Article |
DNA Dendrimers Localize Myod mRNA in Presomitic Tissues of the Chick Embryo
mindyw{at}pcom.edu
MyoD expression is thought to be induced in somites in response to factors released by surrounding tissues; however, reverse transcription-PCR and cell culture analyses indicate that myogenic cells are present in the embryo before somite formation. Fluorescently labeled DNA dendrimers were used to identify MyoD expressing cells in presomitic tissues in vivo. Subpopulations of MyoD positive cells were found in the segmental plate, epiblast, mesoderm, and hypoblast. Directly after laying, the epiblast of the two layered embryo contained
20 MyoD positive cells. These results demonstrate that dendrimers are precise and sensitive reagents for localizing low levels of mRNA in tissue sections and whole embryos, and that cells with myogenic potential are present in the embryo before the initiation of gastrulation.
Key Words: myogenesis • epiblast • segmental plate • in situ hybridization • muscle transcription factor
© 2000 The Rockefeller University Press
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Introduction |
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Whereas RT-PCR can detect low levels of mRNA, it does not reveal how many cells contain MyoD or where they are located within the embryo. To identify those cells that express MyoD before somite formation, we have performed in situ hybridizations with increasingly younger tissues using the recently developed and sensitive probes, fluorescently labeled 3DNA dendrimers. Dendrimers are highly branched, multilayered structures synthesized by sequential hybridizations of partially complimentary heteroduplexes called DNA monomers (Fig. 1; Nilsen et al. 1997; Vogelbacker et al. 1997; Wang et al. 1998). Greater than 500 molecules of fluorochrome, 32P, digoxigenin, or biotin can be incorporated into the dendrimer. Many of the single-stranded outer arms are cross-linked with an oligonucleotide sequence specific for a particular mRNA or DNA sequence. Since dendrimers produce a 100- to 1,000-fold increase in signal compared with single-stranded oligonucleotide probes in Northern and Southern blots and can be tagged with a fluorochrome, they were predicted to be precise and sensitive probes for mRNA in single cells in tissue sections. In situ hybridizations with Cy3 dendrimers revealed that subpopulations of MyoD positive cells are present throughout the segmental plate, epiblast, mesoderm, and hypoblast.
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Materials and Methods |
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TopAbstractIntroductionMaterials and MethodsResultsDiscussionReferences |
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11 w^2T. Oligonucleotide sequences for specific mRNAs plus 7–30 bases complementary to the dendrimer were either psoralen cross-linked or ligated to at least 20 of the outer surface dendrimer arms. Fluorescent dendrimers were prepared by hybridizing and cross-linking a Cy3-labeled oligonucleotide to at least one half of the arms on the outer surface of the dendrimer. Each dendrimer contained from 250–500 Cy3 molecules.
Dendrimers contained the following cDNA sequences for antisense mRNA: chicken MyoD (Dechesne et al. 1994), 5'-TTC TCA AGA GCA AAT ACT CAC CAT TTG GTG ATT CCG TGT AGT AGC TGC TG-3'; chicken embryonic fast myosin (Freyer and Robbins 1983), 5'-CAG GAG GTG CTG CAG GTC CTT CAC CGT CTG GTC CAG GTT CTT CTT CAT CCT CTC TCC AGG-3'; and chicken glyceraldehyde-3-phosphate dehydrogenase (Dugaiczyk et al. 1983), 5'-ATC AAG TCC ACA ACA CGG TTG CTG TAT CCA AAC TCA TTG TCA TAC CAG GAA-3'. Dendrimers lacking a specific recognition sequence were used as a negative control for background fluorescence.
In Situ Hybridization
The in situ hybridization protocol was modified from that of Sassoon and Rosenthal 1993 and Raap et al. 1994. White Leghorn chick embryos (Truslow Farms) were staged according to the method of Hamburger and Hamilton 1951. Stage 16 (28 pairs of somites), stages 13–14 (17–22 pairs of somites), and stage 4 embryos were fixed in 4% formaldehyde, embedded in paraffin, sectioned transversely at 10 µm, and applied to 3-well teflon printed slides (Electron Microscopy Sciences) coated with 0.2% gelatin. Cells were permeabilized with 0.1% Triton X-100 for 10 min and treated for 5–10 min with 0.1% pepsin (Sigma Chemical Co.) in 0.01 M HCl. 30 µl of hybridization buffer containing 60% deionized formamide, 2x SSC buffer, 50 mM sodium phosphate, 5% dextran sulfate (Sigma Chemical Co.), 15 µg yeast RNA, 15 µg salmon sperm DNA (Boehringer), and 18 ng of Cy3-labeled dendrimers was applied to each section. Sections were incubated at 80°C for 10 min then at 37°C overnight. After rinsing in 60% formamide, nuclei were labeled with bis-benzamide (Sigma Chemical Co.; 1 ng/ml deionized water). Sections were mounted in Gelmount (Fisher Scientific) and observed with a Nikon Eclipse E800 epifluorescence microscope (Optical Apparatus). Photomicrographs of differential interference contrast (DIC) images, bis-benzamide–labeled nuclei, and Cy3 dendrimers were produced with the Optronics DEI 750 video camera and Image-Pro Plus image analysis software (Phase 3 Imagining Systems). Results were consistent in sections from 9 stages 13–14 embryos and 5 stage 4 embryos.
In situ hybridizations also were performed on whole, unsectioned embryos. Hamburger and Hamilton 1951 stage 1 embryos were further divided into stages X–XII by the method of Eyal-Giladi and Kochav 1976. Stages X–XII and stage 2 embryos were fixed and permeabilized with Triton X-100 and pepsin as described above. Each embryo was applied to a one-well teflon printed slide (Electron Microscopy Sciences), incubated with 100 µl of hybridization buffer, and processed as described above. Consistent results for MyoD localization were obtained in 4 stage X, 5 stage XI, 3 stage XII, and 5 stage 2 embryos.
Immunofluorescence Localization
Myosin protein was localized in tissue sections with the MF20 mAb to myosin heavy chain (Bader et al. 1982) obtained from the Developmental Studies Hybridoma Bank. Sections were deparaffinized, rehydrated, permeabilized in 0.5% Triton X-100, and incubated in primary then secondary antibodies diluted in 10% goat serum in PBS. The secondary antibody was affinity-purified, goat anti–mouse IgG F(ab')2 fragments conjugated with rhodamine (The Jackson Laboratory). Nuclei were counterstained with bis-benzamide.
Reverse Transcription–Polymerase Chain Reaction
RT-PCR was carried out as described previously (George-Weinstein et al. 1996a,George-Weinstein et al. 1996b). RNA was extracted from Eyal-Giladi and Kochav 1976 stages X–XII embryos and Hamburger and Hamilton 1951 stage 2 embryos. Stage 39 (day 13) pectoralis muscle was included as a positive control for MyoD expression. Primer pairs for MyoD were: nucleotides 620–639, 5'-CGT GAG CAG GAG GAT GCA TA-3'; and nucleotides 864–883, 5'-GGG ACA TGT GGA GTT GTC TG-3' (Lin et al. 1989). Primer pairs for glyceraldehyde-3-phosphate dehydrogenase (GAPDH) were: nucleotides 680–699, 5'-AGT CAT CCC TGA GCT GAA TG-3'; and nucleotides 990–1009, 5'-AGG ATC AAG TCC ACA ACA CG-3' (Dugaiczyk et al. 1983). Reaction products were separated on 6% polyacrylamide gels and 32P-incorporation visualized by autoradiography.
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Results |
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Dendrimers to embryonic fast myosin produced a similar pattern to MyoD in the wedge-shaped somite, but were less abundant (Fig. 3 D). Fluorescence was most intense in the dorsal–medial portion of the dermomyotome. A few cells in the sclerotome and neural tube also were positive (Fig. 3 D). Since the expression of myosin is downstream of MyoD (Weintraub 1993; Rudnicki and Jaenisch 1995; Molkentin and Olson 1996), MyoD mRNA may be translated into protein in these relatively immature somites. Dendrimers to GAPDH produced intense fluorescence throughout the somite (Fig. 3 G). Only one to three dendrimers lacking a specific recognition sequence were randomly distributed throughout each section (Fig. 3 C).
Localization of MyoD mRNA in the Segmental Plate Mesoderm
Since dendrimers correctly detected MyoD mRNA in the dermomyotome, they were tested for their ability to bind to tissues that give rise to skeletal muscle in vitro, and that contain MyoD mRNA detectable by RT-PCR, but not by conventional in situ hybridization.
The pattern of MyoD expression in the segmental plate was similar to that seen with immature somites. MyoD positive cells were present throughout the segmental plate; however, fluorescence was slightly more abundant in the ventral portion of this tissue (Fig. 3 J). MyoD dendrimers also were found in the neural tube (Fig. 3 J). Only a few myosin dendrimers were present in the segmental plate (Fig. 3 H). One to three dendrimers lacking a specific recognition sequence bound to the entire section (not shown).
Localization of MyoD mRNA in Gastrulating Embryos
The same low level of background seen in older embryos was observed in sections through the stage 4 embryo (Fig. 4C and Fig. I). During this stage of development, cells from the dorsal epiblast layer ingress into the primitive streak to form the mesoderm and endoderm (Rosenquist 1971; Fontaine and Le Douarin 1977; Bellairs 1986; Stern and Canning 1990). MyoD positive cells were a mixture of intensely (>6 dendrimers) and weakly (one to two dendrimers) labeled cells. Consistent with the results obtained with RT-PCR (George-Weinstein et al. 1996a), MyoD dendrimers were found in cells throughout the epiblast, mesoderm, and hypoblast (Fig. 4D, Fig. G, and Fig. H). Cells with a strong signal within the epiblast or hypoblast were adjacent to fluorescent cells in the mesoderm (Fig. 4G and Fig. H).
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Localization of MyoD mRNA in Pregastrulating Embryos
Stages X–XII embryos consist of an epiblast and an incompletely formed hypoblast (Eyal-Giladi and Kochav 1976). MyoD mRNA was detected by RT-PCR in these embryos, as well as in the stage 2 embryo (Fig. 5). Dendrimers were used to localize MyoD in single cells of whole, unsectioned stage X embryos. Approximately 20 MyoD positive cells were located in the posterior epiblast (Fig. 6 C). Most cells were intensely labeled with >10 dendrimers. The number of MyoD positive cells increased in stages XI–XII embryos, extending more laterally in the posterior epiblast (Fig. 6 F). By stage 2, fluorescence also was observed in the anterior–lateral epiblast (Fig. 6 H). The central region of the epiblast was negative. Background from myosin dendrimers (Fig. 6D and Fig. G) and dendrimers lacking a recognition sequence (not shown) was as low as in the older embryos (one to three dendrimers per section).
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Discussion |
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TopAbstractIntroductionMaterials and MethodsResultsDiscussionReferences |
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We propose that the small number of intensely labeled MyoD positive cells in presomitic tissues are stably committed to the myogenic lineage, whereas the weakly fluorescent population may be programmed to follow other fates, depending on their location within the embryo. The evidence for a committed population of muscle precursors is that the number of epiblast cells from stages X–XII embryos that differentiate into muscle in culture (
1%) is similar to the number of cells with a relatively high amount of MyoD within the embryo (George-Weinstein et al. 1996a, George-Weinstein et al. 1997; DeLuca et al. 1999). Over the next 24 h, a change occurs within the epiblast that enables >90% of cells to form muscle in culture (George-Weinstein et al. 1996a). This may reflect the increase in the weakly labeled MyoD positive cells in vivo, a release from inhibitory signals when the epiblast is isolated from the mesoderm (George-Weinstein et al. 1996a), the ability of these older epiblast cells to switch from E- to N-cadherin, and cadherin-mediated cell–cell communication in vitro (George-Weinstein et al. 1997). Interestingly, even though >95% of stage 4 epiblast cells synthesize MyoD protein in vitro and most differentiate, a few neurons, chondroblasts, and notochord cells develop among the multitude of muscle cells (George-Weinstein et al. 1996a). This suggests that small numbers of cells are stably committed to a variety of lineages at early stages of development. However, the majority of epiblast cells appear to be uncommitted because, even though most will form muscle in culture, the epiblast does give rise to all tissues of the embryo (Rosenquist 1971; Fontaine and Le Douarin 1977; Bellairs 1986; Stern and Canning 1990).
Cells with MyoD were located throughout the epiblast, mesoderm, and hypoblast. This resembles the ubiquitous expression of MyoD in the Xenopus embryo at the midblastula transition as determined by RT-PCR (Rupp and Weintraub 1991). In theory, stably committed myogenic cells that are randomly distributed throughout the epiblast would eventually become incorporated into nonmuscle tissues as well as the somites. This would explain the presence of cells with myogenic potential in the central nervous system (Fig. 2 and Fig. 3; Tajbakhsh et al. 1994), bone marrow (Wakitani et al. 1995; Ferrari et al. 1998), and dorsal aorta (De Angelis et al. 1999). Although committed to the myogenic lineage, they may remain undifferentiated in an environment that is not permissive for myogenesis.
In the embryo, committed precursors may be responsible for influencing surrounding uncommitted cells to follow the same pathway of differentiation as themselves (Gurdon 1992; Horvitz and Herskowitz 1992; Schnabel 1995). Both committed and uncommitted stem cells are present in the adult (Bjornson et al. 1999; Pittenger et al. 1999). The adult bone marrow contains myogenic cells that can be recruited to regenerate skeletal muscle in vivo (Wakitani et al. 1995; Ferrari et al. 1998). It is not known whether these cells are pluripotent, stably committed myogenic precursors, or both. Given the sensitivity and precision of fluorescently labeled dendrimers, these reagents will be useful in determining the extent of heterogeneity in stem cell populations. Once identified and isolated, stably programmed cells might be used to seed populations of pluripotent cells before implantation into diseased tissues.
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Acknowledgments |
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This work was supported by the National Institutes of Health (HD36650-01) to M. George-Weinstein.
Submitted: 13 December 1999
Revised: 5 April 2000
Accepted: 10 April 2000
Harold Weintraub died on March 28, 1995.
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