Grafting analysis of the periodic albino mutant of Xenopus laevis

Post-transcriptional regulation mediated by specific neurofilament introns in vivo

Neurons regulate genes post-transcriptionally to coordinate the supply of cytoskeletal proteins, such as the medium neurofilament (NEFM), with demand for structural materials in response to extracellular cues encountered by developing axons. By using a method for evaluating functionality of cis-regulatory gene elements in vivo through plasmid injection into Xenopus embryos, we discovered that splicing of a specific nefm intron was required for robust transgene expression, regardless of promoter or cell type. Transgenes utilizing the nefm 3'-UTR but substituting other nefm introns expressed little or no protein owing to defects in handling of the messenger (m)RNA as opposed to transcription or splicing. Post-transcriptional events at multiple steps, but mainly during nucleocytoplasmic export, contributed to these varied levels of protein expression. An intron of the β-globin gene was also able to promote expression in a manner identical to that of the nefm intron, implying a more general preference for certain introns in controlling nefm expression. These results expand our knowledge of intron-mediated gene expression to encompass neurofilaments, indicating an additional layer of complexity in the control of a cytoskeletal gene needed for developing and maintaining healthy axons.

Secondary embryonic axis formation by transplantation of D quadrant micromeres in an oligochaete annelid

Among spiral cleaving embryos (e.g. mollusks and annelids), it has long been known that one blastomere at the four-cell stage, the D cell, and its direct descendants play an important role in axial pattern formation. Various studies have suggested that the D quadrant acts as the organizer of the embryonic axes in annelids, although this has never been demonstrated directly. Here we show that D quadrant micromeres (2d and 4d) of the oligochaete annelid Tubifex tubifex are essential for embryonic axis formation. When 2d and 4d were ablated the embryo developed into a rounded cell mass covered with an epithelial cell sheet. To examine whether 2d and 4d are sufficient for axis formation they were transplanted to an ectopic position in an otherwise intact embryo. The reconstituted embryo formed a secondary embryonic axis with a duplicated head and/or tail. Cell lineage analyses showed that neuroectoderm and mesoderm along the secondary axis were derived from the transplanted D quadrant micromeres and not from the host embryo. However, endodermal tissue along the secondary axis originated from the host embryo. Interestingly, when either 2d or 4d was transplanted separately to host embryos, the reconstituted embryos failed to form a secondary axis, suggesting that both 2d and 4d are required for secondary axis formation. Thus, the Tubifex D quadrant micromeres have the ability to organize axis formation, but they lack the ability to induce neuroectodermal tissues, a characteristic common to chordate primary embryonic organizers.

Metamorphosis and the regenerative capacity of spinal cord axons in Xenopus laevis

Throughout the vertebrate subphylum, the regenerative potential of central nervous system axons is greatest in embryonic stages and declines as development progresses. For example, Xenopus laevis can functionally recover from complete transection of the spinal cord as a tadpole but is unable to do so after metamorphosing into a frog. Neurons of the reticular formation and raphe nucleus are among those that regenerate axons most reliably in tadpole and that lose this ability after metamorphosis. To identify molecular factors associated with the success and failure of spinal cord axon regeneration, we pharmacologically manipulated thyroid hormone (TH) levels using methimazole or triiodothyronine, to either keep tadpoles in a permanently larval state or induce precocious metamorphosis, respectively. Following complete spinal cord transection, serotonergic axons crossed the lesion site and tadpole swimming ability was restored when metamorphosis was inhibited, but these events failed to occur when metamorphosis was prematurely induced. Thus, the metamorphic events controlled by TH led directly to the loss of regenerative potential. Microarray analysis identified changes in hindbrain gene expression that accompanied regeneration-permissive and -inhibitory conditions, including many genes in the permissive condition that have been previously associated with axon outgrowth and neuroprotection. These data demonstrate that changes in gene expression occur within regenerating neurons in response to axotomy under regeneration-permissive conditions in which normal development has been suspended, and they identify candidate genes for future studies of how central nervous system axons can successfully regenerate in some vertebrates.

Unusual leucophore-like cells specifically appear in the lineage of melanophores in the periodic albino mutant of Xenopus laevis

In the periodic albino mutant (a(p)/a(p)) of Xenopus laevis, peculiar leucophore-like cells appear in the skins of tadpoles and froglets, whereas no such cells are observed in the wild-type (+/+). These leucophore-like cells are unusual in (1) appearing white, but not iridescent, under incident light, (2) emitting green fluorescence under blue light, (3) exhibiting pigment dispersion in the presence of alpha-melanocyte stimulating hormone (alphaMSH), and (4) containing an abundance of bizarre-shaped, reflecting platelet-like organelles. In this study, the developmental and ultrastructural characteristics of these leucophore-like cells were compared with melanophores, iridophores and xanthophores, utilizing fluorescence stereomicroscopy, and light and electron microscopy. Staining with methylene blue, exposure to alphaMSH, and culture of neural crest cells were also performed to clarify the pigment cell type. The results obtained clearly indicate that: (1) the leucophore-like cells in the mutant are different from melanophores, iridophores and xanthophores, (2) the leucophore-like cells are essentially similar to melanophores of the wild-type with respect to their localization in the skin and manner of response to alphaMSH, (3) the leucophore-like cells contain many premelanosomes that are observed in developing melanophores, and (4) mosaic pigment cells containing both melanosomes specific to mutant melanophores and peculiar reflecting platelet-like organelles are observed in the mutant tadpoles. These findings strongly suggest that the leucophore-like cells in the periodic albino mutant are derived from the melanophore lineage, which provides some insight into the origin of brightly colored pigment cells in lower vertebrates.

Maturation of neurites in mixed cultures of spinal cord neurons and muscle cells from Xenopus laevis embryos followed with antibodies to neurofilament proteins

Dissociated cell cultures of Xenopus laevis embryonic spinal cord have proved useful for studying the differentiation of neuronal ionic channels and membrane properties and for examining the dynamics of microtubules in developing neurons. To examine their usefulness for studying neurofilaments in developing neurites, we prepared similar cultures from stage 22 embryos. Between 3 and 55 h after plating, these cultures were fixed and immunostained with antibodies directed against various epitopes of neurofilament proteins from X. laevis. These antibodies were specific for nonphosphorylated epitopes of the two low molecular weight Xenopus neurofilament proteins (Xenopus NF-L and the Xenopus neuronal intermediate filament protein, XNIF), both phosphorylated and nonphosphorylated epitopes of the Xenopus middle molecular weight neurofilament protein (NF-M), and a nonphosphorylated epitope of the Xenopus high molecular weight neurofilament protein (NF-H). The emergence of these neurofilament proteins in culture was compared to the time course previously reported for them in Xenopus spinal cord neurons in situ. To facilitate the comparison of times in culture to developmental stages, the age of cultured neurons was converted to an equivalent Nieuwkoop and Faber normal stage using data presented here on the effect of changing temperature on developmental rates of X. laevis. With the exception of the nonphosphorylated epitope of NF-H, which is indicative of the most mature axons found in situ, the emergence of the other neurofilament protein antibody epitopes closely paralleled that previously reported for these antibodies in situ. Thus, with respect to XNIF, NF-M, and NF-L, the neurites of cultured neurons were typical of young, embryonic Xenopus laevis spinal cord axons. This system should prove useful for studying both the function of these neurofilament proteins during the early stages of axonal development and the dynamics of their transport.

Inhibition of axonal development after injection of neurofilament antibodies into a Xenopus laevis embryo

The ability to target specific cytoskeletal components in axons for disruption within intact developing embryos would provide a valuable tool for studying neuronal development. Neurofilaments are an attractive target for such an approach, because they are neuron specific and are expressed late in embryogenesis principally beginning during axon outgrowth. No pharmacological agents are currently available that disrupt neurofilaments without also affecting general development. One approach that has been used successfully to affect proteins in vivo is to inject specific antibodies into living cells. We employed this approach in Xenopus laevis embryos by injecting two antibodies directed against the middle molecular weight neurofilament protein (NF-M) into a single blastomere of a two-cell stage embryo. Injected antibodies could be detected for as long as 3.5 days in cells descended from the injected blastomere. Only cell bodies of neurons descended from anti-NF-M-injected blastomeres contained abnormal accumulations of intermediate filament proteins, and peripheral nerve development was unilaterally retarded in these neurofilament antibody-injected tadpoles. Such accumulations and peripheral nerve defects were not seen in neurons derived from uninjected blastomeres or from blastomeres injected with control antibodies. These data demonstrate the usefulness of specific antibodies to perturb neuronal development in intact frog embryos and, in addition, suggest a role for neurofilaments in axon elongation.

Spatial and temporal expression of phosphorylated and non-phosphorylated forms of neurofilament proteins in the developing nervous system of Xenopus laevis

Immunocytochemical studies of developing Xenopus laevis embryos and tadpoles (stages 12 1/2 to 46) were performed using a panel of 11 monoclonal antibodies to phosphorylated and non-phosphorylated forms of the neurofilament proteins. These included nine antibodies to the middle molecular weight neurofilament protein (XNF-M, 175 kDa), and two additional antibodies to non-phosphorylated forms of the other two neurofilament proteins (XNF-L, 73 kDa; XNF-H, 205 kDa). The developmental expression of XNF-M, XNF-L and XNF-H, and the progressive phosphorylation of XNF-M in the rhombencephalon, spinal cord, and optic nerve were studied using these antibodies. In the spinal cord and rhombencephalon, non-phosphorylated forms of XNF-M were initially detected during neural tube stages (stages 22-26), one day before XNF-L and XNF-H at early tadpole stages (stage 35/36). In the eye, XNF-M was observed initially during tailbud stages (stage 29/30), but neither XNF-L nor XNF-H was seen even by stage 46 (swimming tadpole). The phosphorylation of XNF-M occurred over a protracted period of several days, both in the neural tube and visual system, and could be divided into four phases. (1) When initially expressed, XNF-M was hypophosphorylated. This was indicated by the early immunostaining of axons and cell bodies with antibodies to dephosphorylated epitopes on XNF-M and by the absence of staining with antibodies to phosphorylated epitopes. (2) After a short timelag (3-9 h) axons were stained by some, but not all antibodies to phosphorylated epitopes. (3) Approximately one day later, all antibodies to phosphorylated epitopes stained the relevant axons. However, XNF-M was not yet fully phosphorylated, as indicated by the continued staining of these axons with antibodies to dephosphorylated epitopes of XNF-M. (4) Two to 3 days after the initial expression of XNF-M, dephosphorylated epitopes disappeared from the axons, establishing the adult pattern. During development, the most heavily phosphorylated neurofilament proteins present at a given stage were found first in distal regions of the axons and progressed gradually toward the neuronal perikarya as development proceeded. This gradient of phosphorylation, established early within the axon, suggests that neurofilaments in the axons mature from their distal ends toward the cell body, a process which may be regulated by local factors within the axons themselves. The similarity of the basic features of NF-M phosphorylation in mammalian, avian, and amphibian axons underscores the importance of this phenomenon for the development of a mature axon.

Immunocytochemical identification of non-neuronal intermediate filament proteins in the developing Xenopus laevis nervous system

Intermediate filament proteins in the postmetamorphic Xenopus laevis nervous system were identified by their crossreactivities on Western blots with a pan-specific intermediate filament antibody (anti-IFA). These intermediate filament protein bands on Western blots were characterized as 3 cytokeratin-like proteins (49, 55, and 58 kDa), one vimentin-like protein (53 kDa), two distinct glial fibrillary acidic protein (GFAP)-like proteins (60 and 67 kDa), and 3 neurofilament proteins (73, 175, and 200 kDa) by evaluation of their crossreactivities with specific antibodies directed against the mammalian forms of these proteins. This panel of antibodies to mammalian proteins, and two additional antibodies directed against a Xenopus GFAP-like protein and a Xenopus neurofilament (NF-M) protein, were used in immunocytochemical studies to determine the developmental expression of these proteins in the Xenopus nervous system. The first antigen to be detected during development was cytokeratin immunoreactivity, which was located in the inner lining of the embryonic neural tube as early as stage 19, and which in immunocytochemical studies in postmetamorphic frogs was abundant in meninges and processes forming the ventricular lining of the ependymal zone. Vimentin immunoreactivity was found in numerous neuroepithelial cell processes in the rhombencephalon and anterior spinal cord by stage 22, in the prosencephalon by stage 33/34, and in the retina by stage 29/30. In the postmetamorphic frog, vimentin immunoreactivity was found to be abundant in radial processes throughout the brain and spinal cord. NF-M protein immunoreactivity was first detected in neurons in the developing neural tube between stages 22 and 24, in the retina by stages 29/30, and continued to increase throughout development. GFAP-like immunoreactivity was detected very early in radial cells in the neural tube (stage 24), and by stage 42 was found throughout the nervous system. This early appearance of GFAP-like immunoreactivity implies that the onset of glial cell differentiation is a relatively early event in Xenopus.

Whole eyes reconstituted from embryonic half anlagen: alterations in donor-derived territories in Xenopus pigment chimerae

Grafts from pigmented donor embryonic eye rudiments into albino hosts were used to chart i) fates of local cell groups in three positions in whole eye rudiments, and ii) alterations in graft-derived territories when the posterior half of the rudiment was ablated. Small pigmented patches of graft-derived tissue were conspicuous in albino embryos and tadpoles, enabling us to directly monitor their location and size in the eyes of living animals. The three (right eye) positions marked by pigmented grafts were dorsal (12 o'clock), anterior (3 o'clock), and anteroventral (5 o'clock). Control transplants reared without secondary ablation produced black sector territories in pigment retinal epithelium and iris at corresponding 12 o'clock or 2 o'clock or 4 o'clock positions on the larval eyeball. In the experimental series posterior half-anlagen were ablated. The remaining anterior half-anlagen, each containing a pigmented graft, reconstituted spherical larval eyeballs of reduced size. During healing, donor-derived pigmented sector territories remained coherent, but were altered in position and size compared to controls. Dorsal cells (from 12 o'clock grafts) appeared to move rapidly along the newly formed cut edge into the wound and went on to form expanded black sectors in posterior eye regions. More gradually, sector territories of anterior cells (3 o'clock grafts) and anteroventral cells (5 o'clock grafts) shifted toward dorsal in a counterclockwise direction. Thus all three types of graft derived pigment territories were altered in eye anlage fragments as they healed to form half-size spherical eyes.

Melanophore differentiation in the periodic albino mutant of Xenopus laevis

That embryonic ventral truck tissue might play a role in expression of the periodic albino mutant phenotype (ap/ap) in Xenopus laevis was suggested from the experiments of MacMillan (1980). In contrast, the present experiments, involving the culture of isolated regions of Xenopus embryos, have demonstrated that both mutant and wild-type melanoblasts differentiate independently of a ventral trunk factor. A similar conclusion, that mutant melanoblasts differentiate independently of a ventral trunk factor, is derived from observations on neural crest cultures, wherein melanization of neural crest cells in both wild-type and mutant cultures occurred in a manner consistent with their genotype.

Immunocytochemical studies of vasotocin, mesotocin, and neurophysins in the Xenopus hypothalamo-neurohypophysial system

Mesotocinergic and vasotocinergic neurons, which constitute the principal neurons in the hypothalamo-neurohypophysial system in Xenopus, were studied by immunocytochemical techniques. Antibodies that could unequivocally distinguish mesotocin, vasotocin, and their respective neurophysins were used in these studies. A monoclonal antibody directed at rat oxytocin-associated neurophysin (PS-36) detected an antigen that was colocalized with vasotocin, whereas a monoclonal antibody to rat vasopressin-associated neurophysin (PS-45) crossreacted with an antigen in mesotocinergic cells. As vasotocin is regarded as an evolutionary precursor of vasopressin, and as mesotocin is usually associated with oxytocin, we were surprised to see this apparent eptitope switch in the associated neurophysins. One interpretation of this epitope switch is that the final exons encoding for the carboxy-terminals of the mammalian neurophysins, which contain the PS-45 and PS-36 antibody epitopes, are in reversed positions in Xenopus. Approximately 4,000 mesotocinergic and vasotocinergic neurons and their fibers were topographically mapped in the Xenopus hypothalamus. The two types of neurons were intermingled and scattered throughout a large contiguous region including but not limited to the preoptic recess. Small, medium size, and large cells contained these antigens. Immunoreactive fibers were seen in the preoptic area, the neurohypophysial tract, the median eminence, and the neural lobe of the pituitary. The neurophysin-specific monoclonal antibodies have several advantages as phenotypic markers in development; i.e., high titer, low background, and affinity for the prohormone forms as well as for the fully processed neurophysin polypeptides. Their antigens are related gene products whose expression is central to the identity of the two cell types and whose expression is differentially controlled in development. This characterization of their adult distribution provides a basis for future studies of the development of peptidergic phenotype in the central nervous system of Xenopus.

Regulation in the neural plate of Xenopus laevis demonstrated by genetic markers

To follow the subsequent history of grafted tissue in experiments designed to study regulation and commitment in the amphibian neural plate, previous workers have relied on graft scars, vital dyes applied externally to cells, or xenoplastic grafts. Each of these methods has been criticized on the grounds that they do not indicate unambiguously the origins of individual cells within the operated host. To overcome these difficulties, homoplastic, genetically marked embryonic grafts were taken from the prospective spinal neuroectoderm of triploid and tetraploid Xenopus laevis frogs and transplanted to presumptive eye and prosencephalic regions of the neural plate of diploid X. laevis embryos. Orthotopic presumptive eye grafts also were done. Marked cells were scored in section either by nucleolar number or computerized nuclear size analysis. Of 28 heterotopically grafted embryos that survived to stage 41, when the retina has differentiated, prospective spinal cord neuroectoderm in eight animals gave rise to cell types unique to the eye. The remaining 20 survivors appeared to be mosaic. These results substantiate claims of regulation in the neural plate and extend these observations to the level of individual cell types, a level of resolution not previously obtained in other studies.

Experimental evidence for the accumulation of egg pigment in the brain cavities of Xenopus tadpoles

The origin and fate of darkly pigmented clusters of cells that float freely in the brain cavities of the tadpoles of Xenopus laevis have been experimentally investigated. The results point to the conclusion that the clusters are the sites of egg pigment accumulation, which remain within the brain cavities or at its walls until metamorphosis.

Allograft rejection in Xenopus laevis following larval thymectomy

Xenopus laevis thymectomized at stages 41 through 49 accept first set allografts, while animals thymectomized at stage 51 or older reject allografts in times similar to intact animals. However, thymectomy at progressively earlier stages results in a greater proportion of animals unable to reject second set grafts. In some animals, the allograft response remains deficient even after multiple challenges. The results indicate that alloreactive cells are thymus dependent, and suggest that the thymus processes precursor thymocytes starting upon its formation at around stage 41. The processed cells, competent to respond to alloantigens, are released to the periphery almost immediately. While an increasing pool of processed T cells accumulates during stages 41-49, the persistent defective allograft response displayed by animals thymectomized during these stages suggests that early thymectomy may leave a population of alloreactive cells qualitatively defective in some subpopulation necessary for normal allograft responses, or that any residual cells processed prior to thymectomy are capable of only limited clonal expansion.

The control of mealanoblast differentiation in the periodic albino mutant of Xenopus

Studies on the incidence of melanophores in older ventral trunk tissues and in isolated regions of periodic albino embryos of Xenopus suggest that melanin granule formation in mutant melanoblasts depends on an environmental contribution which arises at stage 43 in the endodermal tissues.

Embryonic appearance of alpha, beta, and gamma crystallins in the periodic albinism (ap) mutant of Xenopus laevis

The appearance of the crystallins during lens development in the periodic albinism (ap/ap) mutant of Xenopus laevis has been studied. Using antibodies specific for total crystallins, alpha + beta crystallins, and gamma crystallins in the immunofluorescence technique, the first positive reaction for all could be demonstrated in the Nieuwkoop-Faber Stage 31 lens rudiment. The antibody to alpha + beta crystallins exhibited differences in intensity from cell to cell in the early rudiment, while the reaction to the other antibodies was uniform throughout the rudiment. As lens differentiation progressed, immunofluorescence was restricted in all cases to the lens fiber area, up to and including Nieuwkas positive, however, for total lens crystallins. These results are at variance with earlier studies on lens development and the crystallins in wildtype (+/+) X. laevis, where a positive reaction for gamma and total crystallins could be detector total lens crystallins. That this divergence in the mutant is due to a pleiotropic effect or directly to the inductive failure of the endomesoderm to initiate melanogenesis, is discussed.

Clarification of studies on the origin of thymic lymphocytes

The thesis that lymphocytes originate in situ by the direct transformation of epithelial cells within the thymic primordium in anurous frogs is untenable. On the contrary, in both the leopard frog and the African clawed toad, the lymphocytes that first appear in the embryonic thymus are derived from extrathymic lymphopoietic cells that invaded the developing organ. The exact source of origin of the invading lymphopoietic cells remains problematic.