Different aggregation properties of sea urchin embryonic cells at different developmental stages. II. Stage specific response to fibronectin and collagen

Fibronectin and collagen were added to cells dissociated from embryos at the blastula and at the 16 cell stages. Both molecules stimulate aggregation of cells dissociated from blastula but they do not affect aggregation of blastomeres dissociated from the 16 cell stage. The stage-specific response to fibronectin and collagen appears to be related to the onset of new functional role(s) of the two molecules at the blastula stage.     

In vitro development and cell allocation of porcine blastocysts derived by aggregation of in vitro fertilized embryos

In pigs, the morphology and cell number of in vitro-produced blastocysts are inferior to those of their in vivo counterparts. The objective of this study was to increase developmental competence and to gain an understanding of cell allocation in blastocysts derived from the aggregation of four-cell stage porcine embryos produced in vitro. After removal of the zona pellucida, two (2x) and three (3x) four-cell stage embryos were aggregated by co-culturing them in aggregation plates. Five days after aggregation, the developmental ability and the number of cells in the aggregated embryos were determined. The percentage of blastocysts was higher (P < 0.05) in both the 2x and 3x aggregated embryos (66.6% and 72.0%, respectively) compared to that of the 1x embryos and the intact controls (43.1% and 36.4%, respectively). The total cell number of blastocysts also increased in aggregated embryos compared to that of intact controls (2.6-fold for 2x and 3.4-fold for 3x) (P < 0.05). The cells of two differentially stained embryos were started to mix at 72 hr after aggregation. In vitro-fertilized porcine aggregates (2x) were developed to blastocyst with a random distribution of cells from each embryo. The mRNA levels for the oct-4, bcl-xL and connexin 43 genes were higher (P < 0.05) and bak gene were lower (P < 0.05) in both the 2x and 3x aggregated embryos than the intact controls. Therefore, the aggregation of the four-cell stage embryos could be used to improve the quality of porcine preimplantation stage embryos produced in vitro.     

The factors that promote the development of symmetry properties in aggregates from dissociated echinoid embryos

Summary Embryos of Hemicentrotus pulcherrimus at the 16 cell, 400 cell or mesenchyme blastula stage of development were dissociated into single cells. The cells were reaggregated, and the development of individual aggregates was monitored. Only aggregates from 16 cell embryos developed into pluteus-like larvae with radial or bilateral symmetry. When embryos at these three developmental stages were incompletely dissociated so that there were mixtures of single cells and groups of undissociated cells, the percentage of aggregates from 16 cell embryos that developed in a pluteus-like manner was greater than in aggregates from completely dissociated 16 cell embryos. Also a small percentage of aggregates from 400 cell embryos now developed into pluteus-like larvae. In both of these experiments small aggregates tend to develop in a more normal manner than larger aggregates.In order to test the role of undissociated cells in promoting pluteus-like development in aggregates from incompletely dissociated blastula stage embryos, pieces of intact animal, lateral, or vegetal blastula wall were grafted to aggregates formed from completely dissociated embryos. While each kind of graft improved the ability of the aggregate to develop in a pluteus-like manner, grafts of vegetal blastula wall were most effective. In an aggregate, a graft differentiates according to its presumptive fate and influences the cells of the aggregate to differentiate in an appropriate manner. The ability of the graft to influence the development of the other cells in the aggregate depends on the developmental stage of the cells that make up the aggregate and the size of the aggregate.     

In vitro development and cell allocation following aggregation of split embryos with tetraploid or developmentally asynchronous blastomeres in rhesus monkeys

Production of genetically identical pairs of monkeys would have tremendous implications for biomedical research, particularly immunological studies and vaccine trials. Specific aims of this study were to (1) determine whether aggregation of embryos split into halves or quarters with equal numbers of either developmentally asynchronous or tetraploid blastomeres would enhance their developmental potential in vitro and increase total cell numbers in resulting blastocysts, and (2) determine the allocation of tetraploid and developmentally asynchronous blastomeres in resulting blastocysts. Results demonstrated that development into blastocysts was greater (p < 0.05) for embryos split into pairs (39.8%) than for those split into quadruplet sets (17.4%) and similar (p > 0.05) to that of nonmanipulated controls (59.6%). Creation of chimeras from aggregation of a single 4-cell and four 16-cell stage blastomeres resulted in blastocyst formation (69.2%) similar to that of nonmanipulated control embryos (66.9%). However, neither development nor total cell numbers in resulting blastocysts differed between aggregate chimeras and those split into quadruplet sets at the 16-cell stage. Blastocysts resulting from the aggregate chimeras were derived strictly from the 16-cell stage blastomeres, with complete exclusion of the 4-cell stage blastomeres. Aggregation of split embryos with equal numbers of tetraploid blastomeres doubled (p < 0.05) both the proportion developing into blastocysts and the total cell numbers in resulting blastocysts. Tetraploid blastomeres were allocated to both the inner cell mass and trophectoderm of resulting blastocysts. In conclusion, due to exclusion of the less advanced cells, aggregation of developmentally asynchronous blastomeres did not improve the developmental competence or cell numbers of split rhesus embryos. Reconstitution of split embryos with equal numbers of tetraploid blastomeres enhanced their developmental potential and cell numbers in resulting blastocysts. However, tetraploid blastomeres were allocated to both the inner cell mass and trophectoderm.     

Evaluation of developmental competence of vitrified-warmed early cleavage stage embryos and their application for chimeric mouse production.

The developmental competence of in vitro cultured embryos vitrified-warmed at an early cleavage stage (2- or 4, 8-cell stage) was examined by both direct transfer into recipient animals and after in vitro manipulation for chimeric mice production using embryonic stem (ES) cells. Vitrified-warmed embryos transferred at the morulae and blastocyst stages showed fetus development comparable to control embryos, although blastocyst development of vitrified-warmed embryos was significantly slower than that of controls. When vitrified-warmed early cleavage stage embryos were used for chimeric mouse production using ES cells, 1 to 10% of the injected or aggregated embryos developed into chimeric neonates and germ-line chimeric mice were obtained from all ES cell lines. This study indicates that embryos developed in vitro from vitrified-warmed embryos have equivalent competence with unvitrified embryos irrespective of stage of vitrification and that these vitrified-warmed embryos maintain adequate viability even after in vitro manipulation such as aggregation and microinjection with ES cells.     

Cell surface proteins of Drosophila. II. A comparison of embryonic and ecdysone-induced proteins

The cell-surface proteins of Drosophila embryos at gastrula and myoblast fusion stages were characterized by radioiodination and two-dimensional gel electrophoresis. Over 13% of the cell surface proteins detected in gastrula embryos were not found in myoblast fusion stage embryos or in Drosophila embryonic cell line EH34A3 cells. Nearly 18% of the cell-surface proteins detected in myoblast fusion stage embryos were evident only at that stage. Embryonic cell-surface proteins were compared with cell-surface proteins from untreated EH34A3 cells and EH34A3 cells treated with 20-hydroxyecdysone, which induces cell aggregation and the expression of "new" proteins at the cell surface (D. F. Woods and C. A. Poodry, 1983, Dev. Biol. 96, 23-31). Only one of the proteins induced by ecdysone in EH34A3 cells was detected in the NP-40 soluble fraction of radioiodinated cell lysates, even after fractionation by lectin affinity chromatography and immunoprecipitation to enrich for putative ecdysone induced proteins. However, extraction of the NP-40 insoluble pellet of embryo cells revealed one additional protein that was present both in myoblast fusion stage embryos and hormone-treated culture cells. It was concluded that except for these two proteins, the cell-surface proteins induced in cultured cell lines by treatment with 20-hydroxyecdysone are not present in significant amounts in gastrula or myoblast fusion stage embryos.     

Development to term of mouse androgenetic aggregation chimeras.

Diploid androgenetic eggs contain two sperm-derived genomes, and only rarely develop to the early somite stage. Also, previous studies have indicated that androgenetic eggs cannot be rescued in aggregation chimeras beyond embryonic stages. Paradoxically, in blastocyst injection chimeras made with androgenetic embryonic stem (ES) cells of the 129/Sv strain, we previously obtained considerable improvement in developmental potential. Although considerable death occurred in utero, overtly normal chimeric fetuses and occasional postnatal chimeras that developed skeletal abnormalities were observed. Consequently, we have re-evaluated the developmental potential of androgenetic aggregation chimeras utilizing androgenetic eggs of the 129/Sv strain, and of the BALB/c and CD-1 strains for comparison. Regardless of strain, androgenetic aggregation chimeras were generally more inviable than previously observed with androgenetic ES cell chimeras, and often the embryoproper was abnormal even when an androgenetic contribution was detected only in the extra-embryonic membranes. This is at least a partial explanation of the greater viability of androgenetic ES cell chimeras, as ES cells do not colonize significantly certain extra-embryonic tissues. Nevertheless, in the 129/Sv strain, occasional development of chimeras to term was obtained, and one chimera that survived postnatally developed identical skeletal abnormalities to those observed previously in androgenetic ES cell chimeras. This result demonstrates that at least one example of paternal imprinting is faithfully conserved in androgenetic ES cells. Also, the postnatal chimerism shows that androgenetic eggs can give rise to terminally differentiated cell types, and are therefore pluripotent. In contrast, only possibly one BALB/c and no CD-1 androgenetic aggregation chimeras developed to term. Therefore, the developmental potential of androgenetic aggregation chimeras is to some extent dependent on mouse strain.     

An assay using embryo aggregation chimeras for the detection of nonlethal changes in X-irradiated mouse preimplantation embryos

We have developed a short-term in vitro assay for the detection of sublethal effects produced by very low levels of ionizing radiation. The assay utilizes mouse embryo aggregation chimeras consisting of one irradiated embryo paired with an unirradiated embryo whose blastomeres have been labeled with fluorescein isothiocyanate (FITC). X irradiation (from 0.05 to 2 Gy) and chimera construction were performed with four-cell stage embryos, and the chimeras were cultured for 40 h to the morula stage. The morulae were partially dissociated with calcium-free culture medium and viewed under phase contrast and epifluorescence microscopy to obtain total embryo cell number and the cellular contribution of irradiated (unlabeled) and control (FITC labeled) embryos per chimera. In chimeras where neither embryo was irradiated, the ratio of the unlabeled blastomeres to the total number of blastomeres per chimera embryo was 0.50 (17.8 +/- 5.6 cells per unlabeled embryo and 17.4 +/- 5.5 cells per FITC-labeled partner embryo). However, in chimeras formed after the unlabeled embryos were irradiated with as little as 0.05 Gy, the ratio of unlabeled blastomeres to the total number of blastomeres per chimera embryo was 0.43 (P less than 0.01). The apparent decreases in cell proliferation were not observed in irradiated embryos that were merely cocultured with control embryos, regardless of whether the embryos were zona enclosed or zona free. We conclude that very low levels of radiation induce sublethal changes in cleaving embryos that are expressed as a proliferative disadvantage within two cell cycles when irradiated embryos are in direct cell-to-cell contact with unirradiated embryos.     

Production of rabbit chimeric embryos by aggregation of zona-free nuclear transfer blastomeres

The objective of this study was to compare in vitro developmental capacity of zona-free aggregated rabbit chimeric embryos and the allocation of EGFP (enhanced green fluorescence protein) gene expression to the inner cell mass (ICM). We produced chimeric embryos by synchronous aggregation of zona-free blastomeres from embryonic cell nuclear transfer (EMB-NT) or somatic cell nuclear transfer (SC-NT) and blastomeres from normal zona-free embryos (N) at the 16-cell stage. In the control group, transgenic (TR) and normal zona-free embryos were used to produce chimeric embryos (TR<>N). EMB-NT embryos were produced by fusion of enucleated oocytes with embryonic cells, which were derived from 32-cell stage transgenic embryos bearing the EGFP gene. The SC-NT embryos were produced by fusing enucleated oocytes with cumulus cells, which were derived from homozygotes transgenic for the EGFP gene female oocytes at 16h post-coitum. Nuclei of transgenic blastomeres emitted a green signal under fluorescence microscopy. Zona-free EMB-NT or zona-free SC-NT rabbit embryos, both with EGFP fluorescence, as well as TR and zona-free rabbit embryos with no fluorescence (EMB-NT<>N, SC-NT<>N, TR<>N) were aggregated on day 2.5 and evaluated on day 5. The proportion of EMB-NT<>N embryos that developed to the blastocyst stage was significantly higher compared with SC-NT derived cells (p < 0.05), but significantly lower than in TR<>N chimeric blastocysts (p < 0.001). Similarly, a higher proportion (p < 0.001) of EGFP-positive cells allocated to ICM of chimeric blastocysts was revealed in TR<>N chimeras (55%), compared with EMB-NT<>N (35%) and SC-NT<>N (21%). Our results indicate that synchronous chimeric embryos reconstructed from TR embryos were better able to develop and colonize the ICM area than EMB-NT and SC-NT embryos. In this study we have demonstrated for the first time that rabbit NT-derived embryos are able to develop into chimeric blastocysts and participate in the ICM area.     

Further studies on thermal treatment of two-cell stage embryos to produce complete embryonic stem-cell-derived mice by cell-aggregation methods

Employing aggregation techniques with two embryonic sources, one from two-cell stage embryos treated by thermal stimulation and the other from mouse embryonic stem (ES) cells that had been obtained from a feeder layer, simple and most effective methods of producing a complete generation of mice from ES cells were explored. Although thermal treatment affected embryos at various developmental stages, the embryos at the two-cell stage of development were selected because of the remarkably reduced number of cells present in the inner cell mass (ICM) at blastocyst stage after thermal conditioning. Under these conditions, a combination of thermally treated host embryos and an aggregated ES cell-clump was found to produce a high rate of live newborns by natural delivery. That the newborns were completely derived from ES cells was checked by two criteria: microsatellite analysis and coat color analysis. Importantly, all of these mice were healthy and fertile. The aggregation techniques reported here might well be applied to other animal species whose ES cells form stable colonies on a feeder layer.     

Cell surface proteins in the early embryogenesis of Pleurodeles waltlii

Surface proteins in the first embryonic stages (8–32 cells, morula, blastula, early and late gastrula) of Pleurodeles waltlii were selectively labelled by ¹²⁵I using lactoperoxidase and glucose/glucose oxidase. Iodination was effected either on non-dissociated embryos or after their dissociation with EDTA. On the outer surface of non-dissociated embryos the two-dimensional electrophoresis revealed only three groups of ¹²⁵I-labelled proteins which did not change during all studied stages. Quite different results were obtained with the cells of dissociated embryos. In addition to the iodinated proteins of the embryonic outer surface seven major iodinated proteins were identified. These proteins originate from the regions of cell-cell contacts in intact embryo. Their two-dimensional pattern in dissociated cells changes between stages 8–32 cells and morula. The next important difference was observed during gastrulation, which corresponds in Pleurodeles waltlii to the first morphogenetic movements. Therefore the outside and inside cell surfaces of embryo are different already at stage 8–32 cells (and probably earlier), before the first step of morphogenesis. The changes of cell surface proteins at early embryonal development take place inside the embryo, in the regions of cell-cell interactions.     

Embryos aggregation improves development and imprinting gene expression in mouse parthenogenesis

Mouse parthenogenetic embryonic stem cells (PgESCs) could be applied to study imprinting genes and are used in cell therapy. Our previous study found that stem cells established by aggregation of two parthenogenetic embryos at 8‐cell stage (named as a₂PgESCs) had a higher efficiency than that of PgESCs, and the paternal expressed imprinting genes were observably upregulated. Therefore, we propose that increasing the number of parthenogenetic embryos in aggregation may improve the development of parthenogenetic mouse and imprinting gene expression of PgESCs. To verify this hypothesis, we aggregated four embryos together at the 4‐cell stage and cultured to the blastocyst stage (named as 4aPgB). qPCR detection showed that the expression of imprinting genes Igf2, Mest, Snrpn, Igf2r, H19, Gtl2 in 4aPgB were more similar to that of fertilized blastocyst (named as fB) compared to 2aPgB (derived from two 4‐cell stage parthenogenetic embryos aggregation) or PgB (single parthenogenetic blastocyst). Post‐implantation development of 4aPgB extended to 11 days of gestation. The establishment efficiency of GFP‐a₄PgESCs which derived from GFP‐4aPgB is 62.5%. Moreover, expression of imprinting genes Igf2, Mest, Snrpn, notably downregulated and approached the level of that in fertilized embryonic stem cells (fESCs). In addition, we acquired a 13.5‐day fetus totally derived from GFP‐a₄PgESCs with germline contribution by 8‐cell under zona pellucida (ZP) injection. In conclusion, four embryos aggregation improves parthenogenetic development, and compensates imprinting genes expression in PgESCs. It implied that a₄PgESCs could serve as a better scientific model applied in translational medicine and imprinting gene study.     

A study of cell interactions involved in Pleurodeles waltlii epidermal differentiation

Summary A polyclonal antibody (SP-2) has been produced, which recognizes antigens expressed in epidermal cells of Pleurodeles waltlii embryos. The antigens appear first at the end of gastrulation in the external surface of the embryo and are selectively expressed in ectodermally derived epidermal structures. Ectodermal commitment was investigated using cell cultures and blastocoel graft experiments. The four animal blastomeres of the 8-cell stage as well as the animal cap explants of the early gastrula stage cultured in vitro differentiate into epidermis, and SP-2 antigens are expressed. The expression of SP-2-defined antigens is inhibited both in vivo and in vitro by the inductive interaction of chordomesoderm. Once dissociated, ectodermal cells do not react with SP-2. Conversely, the aggregation of ectodermal cells may restore the expression of SP-2 antigens. Transplantation of animal cap explants or isolated ectodermal cells into the blastocoel of a host embryo at the early gastrula stage shows that only cells integrated into the epidermis express the marker antigens. When vegetal cells were dissociated from donor embryos before the mid-blastula stage and implanted into the blastocoel of host embryos at the early gastrula stage, their progeny were found in all germ layers, cells that were found in the host epidermis were stained with SP-2, whereas those contributing to mesoderm and endoderm were not. Thus the acquisition of cell polarity in epidermal differentiation and the organization of cells into epithelial structures are essential for SP-2-defined antigen expression.     

Influence of Donor Age on Establishing Well-Differentiated Clonal Cultures from Embryonic Chicken Retinal Pigmented Epithelium

Retinal pigmented epithelia (RPE) isolated from chicken embryos of various developmental stages were dissociated into single cells, and their ability to re-express defferentiated characteristics in clonal culture was investigated. The lighty pigmented, columnar cells isolated from stage 25 to 29 embryos dissociated more easily than the heavily pigmeted, cuboidal cells from embryos of stages 30 to 34. The yield of RPE cells per embryo increased with donor age, paralleling the growth of the epithelium in vivo . However, the potential these cells to attach, to proliferate, and to form typical, welldifferentiated RPE colonies declined with donor age. Cells from stage 25 embryos developed exclusively into large, typical epithelial colonies which expressed all stages of differentiation from flat, unpigmented cells at the margin to cuboidal, pigmented cells in the centre. At the other end of the spectrum, cells from stage 34 embryos frequently formed small, atypical colonies of unpigmented cells, in addition to typical but relatively small colonies. The plating efficiency (calculated on the basis of pigmented colonies formed within 3 weeks) dropped from more than 2% at stage 25 to 0.01% at stage 34.     

cAMP enhanced aggregation of cells from early chick embryos.

Whole chick embryos incubated for 24–36 hr were disaggregated with EDTA. The populations of single cells were incubated both in suspension and after being plated at various densities on agar blocks in a humid environment. In both cases aggregates formed. The aggregation was enhanced by cAMP and 3-isobutyl-1-methylxanthine (IBMX; a phosphodiesterase inhibitor). The density of aggregates which formed on the agar blocks decreased sharply at a critical cell density, suggesting that aggregation was mediated by a relayed signal. The critical density was decreased by IBMX and increased by phosphodiesterase (PDE), suggesting that aggregation was mediated by a cyclic nucleotide, most probably cAMP. Evidence was obtained for the presence of an extracellular PDE.     

Determination of limb bud chondrocytes during a transient block of the cell cycle.

The process of determination is studied by using a cell culture system derived from dissociated chick embryo limb buds. When limb bud cells obtained from embryos younger than stage 25 (undertermined) are temporarily prevented from passing through the cell cycle (either by maintaining the cells on a petri dish or in the presence of high concentrations of cyclic AMP, both of which depress thymidine-H(3) incorporation), some cells subsequently form cartilage colonies. These results support the hypothesis that a temporary block at some stage in the cell cycle causes mesoblasts to acquire the capacity to differentiate into cartilage cells.     

Characterization of bep1 and bep4 antigens involved in cell interactions during Paracentrotus lividus development

We have identified and partially characterised two antigens, extracted with 3% butanol, from Paracentrotus lividus embryos dissociated at the blastula stage, and encoded by the cDNA clones previously described as bep1 and bep4 (bep-butanol extracted proteins). The cDNA fragments containing the specific central portions of bep1 and bep4 were expressed as MS2 polymerase fusion proteins in Escherichia coli. These two fusion proteins, called 1C1 (bep1) and 4A1 (bep4), were injected subcutaneously into rabbits and the corresponding polyclonal antibodies generated. Western blot analysis of proteins, extracted with 3% butanol, from sea urchin embryos at the blastula stage (b.e.p.), established that both antibodies recognize two 33 KDa proteins. Reducing and non-reducing electrophoretic conditions show that both antibodies against bep1 and bep4 related proteins react also with a protein band of a molecular weight 66 KDa, indicating that these two antigens probably exist as dimers. Immunolocalization with anti 1C1 and 4A1 antibodies shows the presence of the related antigens also on the cell surface. Fab fragments of the polyclonal antibodies against 1C1 and 4A1 inhibited reaggregation of sea urchin embryonic cells, dissociated from blastula stage embryos. This prevention of reaggregation indicates that these proteins probably play a role in cell interaction during sea urchin embryonic development.     

Establishment of an In Vitro System Representing the Chicken Gut-Associated Lymphoid Tissue

The bursa of Fabricius is critical for B cell development and differentiation in chick embryos. This study describes the production in vitro, from dissociated cell suspensions, of cellular agglomerates with functional similarities to the chicken bursa. Co-cultivation of epithelial and lymphoid cells obtained from embryos at the appropriate developmental stage regularly led to agglomerate formation within 48 hours. These agglomerates resembled bursal tissue in having lymphoid clusters overlaid by well organized epithelium. Whereas lymphocytes within agglomerates were predominantly Bu-1a⁺, a majority of those emigrating onto the supporting membrane were Bu-1a⁻ and IgM⁺. Both agglomerates and emigrant cells expressed activation-induced deaminase with levels increasing after 24 hours. Emigrating cells were actively proliferating at a rate in excess of both the starting cell population and the population of cells remaining in agglomerates. The potential usefulness of this system for investigating the response of bursal tissue to avian Newcastle disease virus (strain AF2240) was examined.     

An acid extract from dissociation medium of sea urchin embryos, induces mesenchyme differentiation.

When material extracted by 1 M acetic acid from the dissociation medium of sea urchin embryos is added at low concentrations to isolated primary mesenchyme cells, it induces skeletogenesis. The same material added to dissociated blastula cells, or to embryos at the blastula stage, stimulates skeleton formation and pigment cell differentiation. On dissociated cells, it also increases cell reaggregation, thymidine incorporation and survival. On embryos, it induces exogastrulation and appearance of extraembryonic pigment cells. The activity of the extract is resistant to raised temperatures and partially to tryptic digestion but is abolished by trypsin treatment followed by heating. The active fraction does not readily filter through Amicon XM-50 and is retarded by column chromatography on Bio-Gel P-60.     

Steric exclusion of cells. A mechanism of glycosaminoglycan-induced cell aggregation.

The mechanism by which chondroitin sulfate enhances both the self-aggregation and the concanavalin A (ConA)-induced agglutination of trypsin-dissociated embryonic chick retina cells was investigated. Studies with fluorescently labeled ConA showed no influence of chondroitin sulfate on patching or capping. When ³H- or ³⁵SO₄-labeled glycosaminoglycans or proteoglycans from retinas were added to freshly dissociated cells, an average of less than 2% of the label became associated with the unwashed cell pellet, and most of this was removed from the cells by a single wash. The presence of ConA did not alter the amount of binding by this criterion. Rapid cell aggregation in the absence of ConA was promoted by a number of natural and synthetic polymers. Aggregation rate bore a direct relationship to polymer viscosity at low viscosities and was inhibited at high viscosities, apparently due to reduced cell collision frequency. For any given polymer, aggregation was directly related to its molecular weight and concentration. Linear polymers were more effective than branched ones. Neutral polymers were as effective as those which were strongly polyanionic. Stable aggregates of formalin-fixed cells were not promoted by polymers. All of these observations are consistent with the hypothesis that enhancement of retina cell aggregation by physiological concentrations of glycosaminoglycans is due largely to steric exclusion of the cells by the polymer mesh. Although others have shown that glycosaminoglycans probably interact specifically with some cells, the evidence presented here suggests that these macromolecules by virtue of their excluded volumes could also have important non-specific influences on cell migration and cell reorganization during morphogenesis.