Migration and proliferation of cultured neural crest cells in W mutant neural crest chimeras.

Chimeric mice, generated by aggregating preimplantation embryos, have been instrumental in the study of the development of coat color patterns in mammals. This approach, however, does not allow for direct experimental manipulation of the neural crest cells, which are the precursors of melanoblasts. We have devised a system that allows assessment of the developmental potential and migration of neural crest cells in vivo following their experimental manipulation in vitro. Cultured C57Bl/6 neural crest cells were microinjected in utero into neurulating Balb/c or W embryos and shown to contribute efficiently to pigmentation in the host animal. The resulting neural crest chimeras showed, however, different coat pigmentation patterns depending on the genotype of the host embryo. Whereas Balb/c neural crest chimeras showed very limited donor cell pigment contribution, restricted largely to the head, W mutant chimeras displayed extensive pigmentation throughout, often exceeding 50% of the coat. In contrast to Balb/c chimeras, where the donor melanoblasts appeared to have migrated primarily in the characteristic dorsoventral direction, in W mutants the injected cells appeared to migrate in the longitudinal as well as the dorsoventral direction, as if the cells were spreading through an empty space. This is consistent with the absence of a functional endogenous melanoblast population in W mutants, in contrast to Balb/c mice, which contain a full complement of melanocytes. Our results suggest that the W mutation disturbs migration and/or proliferation of endogenous melanoblasts. In order to obtain information on clonal size and extent of intermingling of donor cells, two genetically marked neural crest cell populations were mixed and coinjected into W embryos. In half of the tricolored chimeras, no co-localization of donor crest cells was observed, while, in the other half, a fine intermingling of donor-derived colors had occurred. These results are consistent with the hypothesis that pigmented areas in the chimeras can be derived from extensive proliferation of a few donor clones, which were able to colonize large territories in the host embryo. We have also analyzed the development of pigmentation in neural crest cultures in vitro, and found that neural tubes explanted from embryos carrying wt or weak W alleles produced pigmented melanocytes while more severe W genotypes were associated with deficient pigment formation in vitro.     

Partial restriction in the developmental potential of late emigrating avian neural crest cells.

Trunk neural crest cells migrate along two major pathways: a ventral pathway through the somites whose cells form neuronal derivatives and dorsolateral pathway underneath the ectoderm whose cells become pigmented. In avian embryos, the latest emigrating neural crest cells move only along the dorsolateral pathway. To test whether late emigrating neural crest cells are more restricted in developmental potential than early migrating cells, cultures were prepared from the neural tubes of embryos at various stages of neural crest cell migration. "Early" and "middle" aged neural crest cells differentiated into many derivatives including pigmented cells, neurofilament-immunoreactive cells, and adrenergic cells. In contrast, "late" neural crest cells differentiated into pigment cells and neurofilament-immunoreactive cells, but not into adrenergic cells even after 10-14 days. To further challenge the developmental potential of early and late emigrating neural crest cells, they were transplanted into embryos during the early phases of neural crest cell migration, known to be permissive for adrenergic neuronal differentiation. The cells were labeled with the vital dye, DiI, and injected onto the ventral pathway at stages 14-17. Two and three days after injection, some early neural crest cells were found to express catecholamines, suggesting they were adrenergic neuroblasts. In contrast, DiI-labeled late neural crest cells never became catecholamine-positive. These results suggest that the late emigrating neural crest cell population has a more restricted developmental potential than the early migrating neural crest cell population.     

A clonal approach to the problem of neural crest determination.

A fundamental question regarding neural crest development is the possible pluripotential nature of this embryonic tissue. As a first step in examining this problem, clonal techniques are used to produce homogeneous populations of crest cells. Primary cultures of these cells are obtained by explanting neural tubes from Japanese quail in vitro and allowing crest cells to migrate away. The explant is removed, the outgrowth is isolated, dissociated with trypsin, and the cells plated at clonal density. Colonies derived in this manner fall into the following categories: all cells of the colony pigmented; none of the cells pigmented; and some of the cells pigmented, the remainder unpigmented. Pigmented colonies generally arise from small, round cells whereas the non-pigmented colonies usually originate from large, flattened polymorphous cells. Differentiation of melanocytes does not preclude their continued proliferation. The pigment phenotype, in addition, is stable through at least 25 generations. That the mixed colonies, in fact, are clonally derived is shown by physically isolating single cells. The identity of the non-pigment cells was not established in the present work. A possible neural fate is suggested, however, since nerve-like cells develop after the petri plates become overgrown. Neural clones did not form even though nerve growth factor activity is present as a normal constituent of the culture medium and was added as a supplement in some instances. These techniques permit the preparation of large, homogeneous populations of neural crest cells and afford an opportunity to examine aspects of crest determination heretofore impossible to study.     

The origins of neural crest cells in the axolotl

We address the question of whether neural crest cells originate from the neural plate, from the epidermis, or from both of these tissues. Our past studies revealed that a neural fold and neural crest cells could arise at any boundary created between epidermis and neural plate. To examine further the formation of neural crest cells at newly created boundaries in embryos of a urodele (Ambystoma mexicanum), we replace a portion of the neural folds of an albino host with either epidermis or neural plate from a normally pigmented donor. We then look for cells that contain pigment granules in the neural crest and its derivatives in intact and sectioned host embryos. By tracing cells in this manner, we find that cells from neural plate transplants give rise to melanocytes and (in one case) become part of a spinal ganglion, and we find that epidermal transplants contribute cells to the spinal and cranial ganglia. Thus neural crest cells arise from both the neural plate and the epidermis. These results also indicate that neural crest induction is (at least partially) governed by local reciprocal interactions between epidermis and neural plate at their common boundary.     

Establishment of the scleral cartilage in the chick.

This study was undertaken to investigate the establishment of the scleral cartilage in the chick embryo. Johnston et al. (1974) has demonstrated that most of the cells of the scleral cartilage originate in the cranial neural crest. By means of a series of chorioallantoic grafts of pigmented retina, and its adherent periocular mesenchyme from stage 11 to 25, the present experiments show that the cranial neural crest cells arrive at the eye in sufficient numbers to form cartilage by stage 14. Pigmented retina, denuded of mesenchyme, from stage 16 embryos implanted into the head of stage 13 embryos induces cartilage formation in head mesenchyme. However, neither pigmented retina nor spinal cord could induce cartilage formation in chorioallantoic mesenchyme. Combination grafts of cranial neural crest and presumptive optic vesicle developed neural tissue, pigmented retina, and in some cases sclera-like cartilage. Thus, periorbital mesenchyme, derived largely from cranial neural crest, at about stage 14 develops the scleral cartilage in response to induction by the pigmented retina.     

Invasive characteristics of neural crest cells in vitro

An investigation of the invasiveness of avian neural crest cells and neural crest-derived melanocytes through a human amniotic basement membrane (BM) was undertaken. Avian neural tube explants or derived melanocyte populations were seeded directly onto BMs in membrane invasion culture system (MICS) chambers for periods of 24, 48, and 72 h. In 36 experimental trials for each group, neither neural crest nor neural crest-derived melanocytes were observed to have invaded the BMs. In concert with these studies, coculturing of B16F10 murine melanoma cells with avian neural crest-derived melanocytes was performed in MICS chambers. Under these experimental conditions, the neural crest-derived melanocytes were able to successfully invade the BMs and to a greater extent than the B16F10 tumor cells. These data suggest that neural crest cells and neural crest-derived melanocytes do not have the ability to invade the BM alone; however, they can be induced to be invasive when cocultured in the presence of B16F10 cells. Alternatively, the B16F10 cells may create weaknesses within the BM that facilitate migration of the pigmented crest cells.     

In vitro stimulation of cartilage in embryonic chick neural crest cells by products of rentinal pigmented epithelium.

The retinal pigmented epithelium of the chick embryo influences head neural crest mesenchymal cells to form the scleral cartilage of the eye. The possible role of extracellular matrix in this interaction was studied. Extracellular matrix was deposited on Millipore filters in vitro by pigmented epithelial cells which were then killed by distilled water lysis. When grown on the Millipore filters which had carried pigmented epithelium, clonal neural crest and periocular mesenchyme “target” cells formed cartilage in 61 of 155 experiments. Cartilage was not formed when the cells were grown on naked filters nor did gels of purified Type I and Type II collagen promote chondrogenesis. It is concluded that extracellular matrix deposited by the pigmented epithelium in vitro is a potent stimulus for the induction of chondrogenesis in competent mesenchyme, and that living pigmented epithelial cells need not be present for such induction.     

Clonal analysis of quail neural crest cells: They are pluripotent and differentiate in vitro in the absence of noncrest cells

To determine if neural crest cells are pluripotent and establish whether differentiation occurs in the absence of noncrest cells, a cell culture method was devised in which differentiation could be examined in clones derived from single, isolated neural crest cells. Single neural crest cells, which were isolated before the onset of in vivo migration, gave rise to three types of clones: pigmented, unpigmented, and mixed. Pigmented clones consisted of melanocytes only, whereas some unpigmented cells in mixed and unpigmented clones contained catecholamines, identifying them as adrenergic cells. Extracellular matrix derived from quail somite or chick skin fibroblast cultures stimulated adrenergic differentiation and axon formation. These results demonstrate for the first time the existence of pluripotent quail neural crest cells that give rise to at least two progeny, melanocytes and neuronal cells. They also suggest that continuous direct interactions with noncrest cells are not required for the differentiation of these two cell types. However, components of the extracellular matrix derived from noncrest cells may play an important role in expression of the adrenergic phenotype.     

Hypoglycemia due to ectopic release of insulin from a paraganglioma

Insulin-secreting pancreatic tumors and insulin-like growth hormone-secreting non-islet cell tumors can cause hypoglycemia. However, insulin-releasing paraganglioma or pheochromocytoma has almost never been reported. A 67-year-old female patient was admitted to our hospital because of headache, palpitation, perspiration, faintness, frequent sense of hunger and absent-mindedness. These intermittent symptoms had begun approximately a year before admission. On physical examination, she had high blood pressure of 150/90 mm Hg. Hormonal studies demonstrated increased urinary norepinephrine levels, and hyperinsulinemic hypoglycemia was confirmed while the patient was symptomatic. Abdominal MRI revealed a retroperitoneal mass measuring 4.5 cm in the pancreatic region. She was treated with an alpha-blocking agent to control blood pressure preceding the removal of the mass. Histopathological diagnosis was paraganglioma, and immunohistochemically insulin staining in the neoplastic cells was demonstrated. Her blood pressure normalized and hypoglycemia relieved after the operation. The patient did not have recurrence of hypoglycemia after a year of follow-up. Paraganglioma is a rare tumor of the neural crest, and co-secretion of insulin and catecholamines has been reported only by a single case report in the literature. The present patient is another case with this co-secretion.     

Effect of lectins and sugars on primary sperm attachment in the horseshoe crab, Limulus polyphemus L

The in vitro differentiation of quail neural crest cells into serotoninergic neurons is reported. Serotoninergic neurons were identified by two independent methods, formaldehyde-induced histofluorescence and indirect staining with antiserotonin antibodies. Serotonin-positive cells first appeared on the third day in culture, simultaneously, or slightly prior to the first pigmented cells and adrenergic neurons. Comparable numbers of serotoninergic cells were found in crest cell cultures derived from vagal, thoracic/upper lumbar, and lumbosacral levels of the neuraxis. The neural crest origin of the serotonin neurons was further corroborated by the demonstration that cultures of somites, notochords, and neural tubes (three tissues adjacent to the neural crest and thus the most likely contaminants of crest cell cultures) did not contain serotonin-producing cells, and that mast cells were absent in crest cell cultures. The identification of serotoninergic neurons in quail neural crest cell cultures makes an important addition to the number of neural crest derivatives that are capable of differentiating in culture. Furthermore, it suggests that the in vitro culture system will prove a valid approach to the elucidation of the cellular and molecular mechanisms that govern neural crest cell differentiation.     

Neural crest cells: temperature-dependent transformation by Rous sarcoma virus.

Cranial neural crest cells from chick embryos, when cultured under appropriate conditions, differentiate after approx. 1 week into pigmented cells. Neurol crest cells were infested with a mutant (RSV-BH-Ta) of the Bryan 'high titer' strain of Rous sarcoma virus on the second day of culture before the cells were morphologically differentiated, or later after they became pigmented. Cells infected and maintained at the temperature permissive for transformation (37 degrees C) proliferated rapidly compared to uninfected cells are produced extensive cytoplasmic vacuoles in a fashion similar to other types of cells transformed with RSV-BH-Ta at 37 degrees C. Cells infected and maintained at the non-permissive temperature for transformation (41 degrees C) also proliferated rapidly but did not become morphologically transformed. Transformation occurred reversibly following a shift of temperature. Infection of morphologically undifferentiated neural crest cells at either temperature prevented their differentiation into pigment cells, and infection of pigmented neural crest cells at either temperature led to a gradual loss of pigmentation. These results suggest that even at the non-permissive temperature the virus may regulate the state of differentiation of certain types of cells.     

Tumor-Promoting Phorbol Esters Promote Melanogenesis and Prevent Expression of the Adrenergic Phenotype in Quail Neural Crest Cells

Tumor-promoting phorbol esters were used to manipulate the in vitro development of neural crest cells. When plated at clonal density in secondary culture, quail neural crest cells from the trunk region gave rise to three types of colonies, pigmented, unpigmented, and mixed. Pigmented colonies consisted exclusively of melanocytes; up to 50% of the unpigmented and mixed colonies contained adrenergic nerve cells which could be identified by a catecholamine-specific histofluorescence method. Addition of potent tumor promoters to the culture medium shortened the doubling time of neural crest cells and altered their morphologic appearance. It also delayed the onset of pigmentation, prevented the expression of the adrenergic phenotype, reduced the number of unpigmented and mixed colonies, and increased the number of pigmented colonies, most likely by directing progenitor cells preferentially to the melanogenic pathway. There was a clear correlation between the ability of phorbol esters to promote skin tumors in mice and their ability to interfere with the in vitro development of quail neural crest cells. The potent promoters 12–0–tetradecanoyl phorbol 13–acetate (TPA) and phorbol 12,13–didecanoate (PDD) were most effective, phorbol 12,13–diacetate (PDA) was considerably less effective, the nonpromoting analogues 4–0–methyl 12–0–tetradecanoyl phorbol 13–acetate (4–0–Me-TPA) and 4α-phorbol 12,13–didecanoate (4α-PDD) and the parent alcohol phorbol (PHR) had little or no effect.     

The role of phenylalanine in differentiating amphibian melanocytes

To see whether phenylalanine serves as a substrate in melanogenesis, hanging drop explants of neural crest from amphibian (Ambystoma maculatum and A. mexicanum) embryos were subjected on the seventh day in vitro to treatment with phenylalanine-³H and studied by means of light microscopic radioautography. All melanin-containing cells showed label. On the other hand, when puromycin, an inhibitor of protein synthesis, together with the labeled amino acid was administered to the cultures, no radioactivity was incorporated by pigmented cells. Comparable results were obtained when leucine was substituted for phenylalanine. In control experiments, puromycin and labeled tyrosine or 3,4-dihydroxyphenylalanine (DOPA), both known precursors for melanin synthesis, were administered to the neural crest cultures. In these experiments, puromycin had no effect on the incorporation of label by pigmented cells. Our data strongly indicate that in differentiating amphibian melanocytes with functional pigment-forming systems, phenylalanine is used in protein synthesis, but does not serve as a substrate for the tyrosine-tyrosinase system.In another series of experiments, explants of neuroepithelium (neural crest anlage) were grown from the time of explantation to the seventh day in vitro in the presence of phenyllactic acid, an analog of phenylalanine. Pigment cells developed normally.These results suggest that phenylalanine plays little or no role in pigment cell differentiation.     

Connexin 43 expression reflects neural crest patterns during cardiovascular development

We used transgenic mice in which the promoter sequence for connexin 43 linked to a lacZ reporter was expressed in neural crest but not myocardial cells to document the pattern of cardiac neural crest cells in the caudal pharyngeal arches and cardiac outflow tract. Expression of lacZ was strikingly similar to that of cardiac neural crest cells in quail-chick chimeras. By using this transgenic mouse line to compare cardiac neural crest involvement in cardiac outflow septation and aortic arch artery development in mouse and chick, we were able to note differences and similarities in their cardiovascular development. Similar to neural crest cells in the chick, lacZ-positive cells formed a sheath around the persisting aortic arch arteries, comprised the aorticopulmonary septation complex, were located at the site of final fusion of the conal cushions, and populated the cardiac ganglia. In quail-chick chimeras generated for this study, neural crest cells entered the outflow tract by two pathways, submyocardially and subendocardially. In the mouse only the subendocardial population of lacZ-positive cells could be seen as the cells entered the outflow tract. In addition lacZ-positive cells completely surrounded the aortic sac prior to septation, while in the chick, neural crest cells were scattered around the aortic sac with the bulk of cells distributed in the bridging portion of the aorticopulmonary septation complex. In the chick, submyocardial populations of neural crest cells assembled on opposite sides of the aortic sac and entered the conotruncal ridges. Even though the aortic sac in the mouse was initially surrounded by lacZ-positive cells, the two outflow vessels that resulted from its septation showed differential lacZ expression. The ascending aorta was invested by lacZ-positive cells while the pulmonary trunk was devoid of lacZ staining. In the chick, both of these vessels were invested by neural crest cells, but the cells arrived secondarily by displacement from the aortic arch arteries during vessel elongation. This may indicate a difference in derivation of the pulmonary trunk in the mouse or a difference in distribution of cardiac neural crest cells. An independent mouse neural crest marker is needed to confirm whether the differences are indeed due to species differences in cardiovascular and/or neural crest development. Nevertheless, with the differences noted, we believe that this mouse model faithfully represents the location of cardiac neural crest cells. The similarities in location of lacZ-expressing cells in the mouse to that of cardiac neural crest cells in the chick suggest that this mouse is a good model for studying mammalian cardiac neural crest and that the mammalian cardiac neural crest performs functions similar to those shown for chick.     

The relationship between migration and chondrogenic potential of trunk neural crest cells in Ambystoma mexicanum

Based on results of transplantation experiments, it has long been believed that trunk neural crest cells are incapable of chondrogenesis. When pigmented trunk neural crest cells of Ambystoma mexicanum are transplanted to cranial levels of albino (a/a) embryos, the graft cells ultimately produce ectopic fins, but are incapable of following the chondrogenic cranial neural crest pathways. Therefore, heterotopic transplantation does not expose these cells to the same environment experienced by cranial neural crest cells, and is neither an adequate nor a sufficient test of chondrogenic potential. However, in vitro culture of trunk neural crest cells with pharyngeal endoderm does provide a direct test of chondrogenic ability. That cartilage does not form under these conditions demonstrates conclusively that trunk neural crest cells possess no chondrogenic potential.     

Spontaneous neurite outgrowth and vasoactive intestinal peptide-Iike immunoreactivity of cultures of human paraganglioma cells from the glomus jugulare

Summary The chief cells of paraganglionic tissues have morphological and functional similarities to adrenal chromaffin cells, and both cell types are derived from the neural crest. In the present investigation cells from two glomus jugulare paragangliomas were studied in culture. Approximately 50% of the cells from one tumor, and 7% from the other spontaneously formed neurite-like processes. Numerous granular and agranular synaptic-like vesicles also appeared in the process-forming cells. In contrast to findings with normal and neoplastic adrenal chromaffin cells, addition of nerve growth factor (NGF) to the culture medium had no major effects on proportion of cells with processes. Dexamethasone caused only a small decrease in process length. Culturing of the tumors also appeared to promote production of material with VIP-like immunoreactivity. It is concluded that the phenotype of paraganglioma as well as pheochromocytoma cells may be altered in vitro. Responsiveness to specific factors such as NGF or steroids, however, may vary for related tumor cell types in different anatomic locations.     

Behavior of neural crest cells on embryonic basal laminae

Neural crest cells separate from the neural epithelium in a region devoid of a basal lamina and migrate along pathways bordered by intact basal laminae. The distribution of basal laminae suggests that they might have an important role in the morphogenesis of the neural crest by acting as a barrier to migration. The experiments reported here have tested directly whether neural crest cells can penetrate a basal lamina. Isolated neural tubes, neural crest cells cultured for 24 hr, or pigmented neural crest cells were explanted onto human placental amnions from which the epithelium had been removed to expose the basal lamina. In no case did neural crest cells or crest derivatives penetrate the basal lamina to invade the underlying stroma. If crest cells were grown on the stromal side of the amnion, they invaded the connective tissue. Pigmented neural crest derivative and [3H]thymidine-labeled nonpigmented crest cells were also confronted with chick embryonic basal laminae by grafting the cells into the lumen of the neural tube at the axial levels where host crest migration had commenced. Most of the grafted cells invaded the neural epithelium and accumulated after 24 hr at the basal surface of the neural tube. A few crest cells escaped through the dorsal surface of the neural tube and entered the overlying ectoderm, presumably through the wound created during the grafting procedure. Some of these grafted cells, located initially by light microscopy, were examined at the higher magnification and resolution offered by the transmission electron microscope to determine the relationship of the grafted cells to the basal lamina. In 50% (14 total) of the cases, the crest cells never reached the basal lamina of the neural tube, but were trapped by cell junctions between the neural epithelial cells. Of the remaining grafted cells that were relocated in the TEM (50%, total 15) all were spread on the basal lamina, but were not seen penetrating it. Likewise, in the three cases where crest cells were found in the epidermal ectoderm, all were in contact with the basal lamina of the ectoderm but did not have any processes extending through it. In three cases, at the level of the light microscope, crest cells were found to extend through the basal surface of the neural tube. In all these instances, the cells followed the dorsal root nerve exiting through a region of the neural tube that is devoid of a basal lamina.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cell cycle changes during neural crest cell differentiation in vitro.

Chick trunk neural tubes containing neural crest cells were cultured in vitro. Cell outgrowth from these neural tube explants consists primarily of a small stellate cell population. After 3 days in culture the small stellate cell population undergoes a remarkable change in morphology that is characterized by a more refractile appearance in the phase contrast microscope. Subsequent to this change in morphology, pigment granules become visible in the cytoplasm after 4 days in culture. After 6 days in culture, virtually all of the small stellate cells are pigmented. The cell cycle parameters of the small stellate cell population are: S = 4.4 ± 1.2 hr (SD). G2 = 1.5 ± 1.0 hr (SD). M = 1.7 ± 0.6 hr (SD). and Gl = 3.8 ± 1.0 hr (SD). Continuous label experiments demonstrate that (G1+G2+M) increases from 7 hr in Day 4 cells, as yet unpigmented, to 12 hr in Day 5 cells that have become pigmented. This change is consistent with an increase in G1 and/or G2 that is closely correlated with the appearance of pigment granules. It is of interest that this cell cycle change is correlated with a rather late event in the developmental program of these neural crest cells rather than with the earlier morphological change observed after 3 days in culture.     

Control of neural crest cell dispersion in the trunk of the avian embryo

Many hypotheses have been advanced to explain the orientation and directional migration of neural crest cells. These include positive and negative chemotaxis, haptotaxis, galvanotaxis, and contact inhibition. To test directly the factors that may control the directional dispersion of the neural crest, I have employed a variety of grafting techniques in living embryos. In addition, time-lapse video microscopy has been used to study neural crest cells in tissue culture. Trunk neural crest cells normally disperse from their origin at the dorsal neural tube along two extracellular pathways. One pathway extends laterally between the ectoderm and somites. When either pigmented neural crest cells or neural crest cells isolated from 24-hr cultures are grafted into the space lateral to the somites, they migrate: (1) medially toward the neural tube in the space between the ectoderm and somites and (2) ventrally along intersomitic blood vessels. Once the grafted cells contact the posterior cardinal vein and dorsal aorta they migrate along both blood vessels for several somite lengths in the anterior-posterior axis. Neural crest cells grafted lateral to the somites do not immediately move laterally into the somatic mesoderm of the body wall or the limb. Dispersion of neural crest cells into the mesoderm occurs only after blood vessels and nerves have first invaded, which the grafted cells then follow. The other neural crest pathway extends ventrally alongside the neural tube in the intersomitic space. When neural crest cells were grafted to a ventral position, between the notochord and dorsal aorta, in this intersomitic pathway at the axial level of the last somite, the grafted cells migrate rapidly within 2 hr in two directions: (1) dorsally, in the intersomitic space, until the grafted cells contact the ventrally moving stream of the host neural crest and (2) laterally, along the dorsal aorta and endoderm. All of the above experiments indicate that neither a preestablished chemotactic nor adhesive (haptotactic) gradient exists in the embryo since the grafted neural crest cells will move in the reverse direction along these pathways toward the dorsal neural tube. For the same reason, these experiments also show that dispersal of the neural crest is not directed passively by other environmental controls, since the cells can clearly move counter to their usual pathway and against such putative passive mechanisms.(ABSTRACT TRUNCATED AT 400 WORDS)