Specification of mouse telencephalic and mid-hindbrain progenitors following heterotopic ultrasound-guided embryonic transplantation

We have demonstrated the utility of ultrasound backscatter microscopy for targeted intraparenchymal injections into embryonic day (E) 13.5 mouse embryos. This system has been used to test the degree of commitment present in neural progenitors from the embryonic ventral telencephalon and mid-hindbrain region. Many E13.5 ventral telencephalic progenitors were observed to integrate and adopt local phenotypes following heterotopic transplantation into telencephalic or mid-hindbrain targets, whereas mid-hindbrain cells of the same stage were unable to integrate and change fate in the telencephalon. In contrast, many mid-hindbrain cells from an earlier developmental stage (E10.5) were capable of integrating and adopting a forebrain phenotype after grafting into the telencephalon, suggesting that mouse mid-hindbrain progenitors become restricted in their developmental potential between E10.5 and E13.5.     

The Drosophila EGF receptor controls the formation and specification of neuroblasts along the dorsal-ventral axis of the Drosophila embryo

The segmented portion of the Drosophila embryonic central nervous system develops from a bilaterally symmetrical, segmentally reiterated array of 30 unique neural stem cells, called neuroblasts. The first 15 neuroblasts form about 30-60 minutes after gastrulation in two sequential waves of neuroblast segregation and are arranged in three dorsoventral columns and four anteroposterior rows per hemisegment. Each neuroblast acquires a unique identity, based on gene expression and the unique and nearly invariant cell lineage it produces. Recent experiments indicate that the segmentation genes specify neuroblast identity along the AP axis. However, little is known as to the control of neuroblast identity along the DV axis. Here, I show that the Drosophila EGF receptor (encoded by the DER gene) promotes the formation, patterning and individual fate specification of early forming neuroblasts along the DV axis. Specifically, I use molecular markers that identify particular neuroectodermal domains, all neuroblasts or individual neuroblasts, to show that in DER mutant embryos (1) intermediate column neuroblasts do not form, (2) medial column neuroblasts often acquire identities inappropriate for their position, while (3) lateral neuroblasts develop normally. Furthermore, I show that active DER signaling occurs in the regions from which the medial and intermediate neuroblasts will later delaminate. In addition, I demonstrate that the concomitant loss of rhomboid and vein yield CNS phenotypes indistinguishable from DER mutant embryos, even though loss of either gene alone yields minor CNS phenotypes. These results demonstrate that DER plays a critical role during neuroblast formation, patterning and specification along the DV axis within the developing Drosophila embryonic CNS.     

Identification of a novel dual angiotensin II/vasopressin receptor

The development and patterning of the Drosophila wing relies on interactions between cell populations that have the anteroposterior (AP) axis and dorsoventral (DV) axis of the wing imaginal disc as frames of reference [1-3]. Each of these cell populations gives rise to a compartment - a group of cells that have their fates restricted by cell lineage - within which cells acquire specific identities through the expression of 'selector' genes [1,2,4]. The genes engrailed (en) and invected (inv), for example, label cells in the posterior compartment and mediate a set of cell interactions that direct the patterning and growth of the wing along the AP axis [1,2,4]. A similar situation has been proposed to exist across the DV axis, along with apterous (ap) as a dorsal selector gene [5], mediating cell interactions by regulating the expression of Serrate (Ser) [6] [7] and fringe (fng) [8]. In ap mutants, the wing is lost [5] [9], and here we report that this phenotype can be rescued by ectopic expression of either Ser or fng and that, surprisingly, the resulting wings have both dorsal and ventral cell fates.     

Posttraumatic stress disorder among incarcerated battered women: a comparison of battered women who killed their abusers and those incarcerated for other offenses

During development, telencephalic neural progenitors acquire positional specification and give rise to distinct structures such as the striatum and cortex. Here, we examine, in vivo, the influence of developmental stage, cell-surface molecules and regional differences along the dorso-ventral and antero-posterior axes on the selective incorporation of neural progenitors derived from different regions of the developing brain, utilizing a cross-species in utero transplantation paradigm. Striatal progenitors derived from the embryonic day (E) 12-14 mouse lateral ganglionic eminence (LGE) were observed consistently to incorporate into the developing striatum as early as 24-48 h following intraventricular injection into the E15-17 rat host. By removing cell-surface molecules from the LGE progenitors, the pattern of incorporation was remarkably different with no preferential striatal incorporation. Cortical progenitors with intact cell-surface molecules, by contrast, displayed little telencephalic (including striatal) incorporation as compared with precursors from the LGE. However, both progenitors from cortex and LGE incorporated widely into diencephalic and mesencephalic structures. The capacity for integration of precursors derived from the LGE and cortex gradually decreased during development of the host and was minimal in the postnatal day (P) 1 host. Unlike the telencephalic precursors, the vast majority of progenitors derived from the midbrain and cerebellar primordium (with cell-surface molecules intact) incorporated into diencephalic and midbrain nuclei with only a few cells observed in the telencephalon. These results demonstrate that incorporation of neural progenitors across the ventricular wall in the embryonic host is strictly developmentally regulated, dependent on their position along the antero-posterior axes and in the case of progenitors from the LGE is mediated by cell-surface molecules expressed on the transplanted cells.     

BCR/ABL- CD34(+)HLA-DR- progenitor cells in early chronic phase, but not in more advanced phases, of chronic myelogenous leukemia are polyclonal

Chronic myelogenous leukemia (CML) is characterized by the Philadelphia (Ph) translocation and BCR/ABL gene rearrangement which occur in a pluripotent hematopoietic progenitor cell. Ph-negative (Ph-) hematopoiesis can be restored in vivo after treatment with -interferon or intensive chemotherapy, suggesting that normal stem and progenitor cells coexist with the Ph+ clone. We have previously shown that Ph- progenitors are highly enriched in the CD34(+)HLA-DR- fraction from early chronic phase (ECP) CML patients. Previous studies have suggested that the Ph-translocation represents a secondary clonal hit occurring in an already clonally mutated Ph- progenitor or stem cells, leaving the unanswered question whether Ph- CD34(+)HLA-DR- progenitors are normal. To show the clonal nature of Ph- CD34(+)HLA-DR- CML progenitors, we have compared the expression of BCR/ABL mRNA with X-chromosome inactivation patterns (HUMARA) in mononuclear cells and in CD34(+)HLA-DR+ and CD34(+)HLA-DR- progenitors in marrow and blood obtained from 11 female CML patients (8 in chronic phase and 3 in accelerated phase [AP] disease). Steady-state marrow-derived BCR/ABL mRNA-, CD34(+)HLA-DR- progenitors had polyclonal X-chromosome inactivation patterns in 2 of 2 patients. The same polyclonal pattern was found in the progeny of CD34(+)HLA-DR- derived long-term culture-initiating cells. Mobilization with intensive chemotherapy induced a Ph-, BCR/ABL mRNA- and polyclonal state in the CD34(+)HLA-DR- and CD34(+)HLA-DR+ progenitors from 2 ECP patients. In a third ECP patient, polyclonal CD34(+) cells could only be found in the first peripheral blood collection. In contrast to ECP CML, steady-state marrow progenitors in late chronic phase and AP disease were mostly Ph+, BCR/ABL mRNA+, and clonal. Further, in the majority of these patients, a Ph-, polyclonal state could not be restored despite mobilization with intensive chemotherapy. We conclude from these studies that CD34(+)HLA-DR- cells that are Ph- and BCR/ABL mRNA- are polyclonal and therefore benign. This population is suitable for autografting in CML.     

Identification of c-fos related genes and their induction by neural activation in rainbow trout brain

The anterior portion of the neonatal telencephalic subventricular zone (SVZa) contains proliferating cells that generate an immense number of neurons destined to become the granule and periglomerular cells of the olfactory bulb. In contrast to other immature neurons in the central nervous system, cells arising in the SVZa maintain the ability to divide as they traverse the rostral migratory stream to their final destinations despite expressing an antigenic marker of differentiated neurons (Menezes et al. [1995] Molec. Cell. Neurosci. 6:496-508). Because of their considerable proliferative capacities and unusual mitotic behavior, we decided to determine the cell cycle length of proliferating cells within the SVZa and within the migratory pathway used by SVZa-derived cells. Following the methodology of Nowakowski et al. [1989](J. Neurocytol. 18:311-318), postnatal day 2 rat pups were exposed to 5'-bromo-2'deoxyuridine (BrdU) for increasing periods of time before perfusion. By plotting the percentage of nuclei undergoing DNA synthesis in the SVZa at each time versus the BrdU labeling interval, we determined that approximately 15% of the SVZa population is actively dividing and that these cells have a cycle length of approximately 14 hr, significantly less than the 18.6 hr determined to be the cycle length of dividing cells in more posterior, glia-generating regions of the subventricular zone (Thomaidou et al. [1997] J. Neurosci. 17:1075-1085). The cycle length of cells dividing in the mid portion of the rostral migratory stream, however, is considerably longer: 17.3 hr. This may reflect the need for these cells to coordinate the processes of migration and division. Our studies also suggest that there may be regional differences in the types of descendants produced by the proliferating cells. Retroviral lineage tracing studies showed that those cells that divide within the rostral migratory stream, like proliferating cells within the SVZa, make cells destined for the olfactory bulb. Unlike the progenitors that divide within the SVZa and generate more granule cells than periglomerular cells, the proliferating cells within the migratory pathway generate more periglomerular cells than granule cells. Collectively the proliferating cells of the SVZa and migratory pathway produce a large number of olfactory bulb interneurons. Our work suggests that this may be achieved in part by the relatively rapid divisions of progenitor cells within the SVZa and in part by the ongoing division of migrating cells en route to the olfactory bulb.     

Transient fetal structure, the gangliothalamic body, connects telencephalic germinal zone with all thalamic regions in the developing human brain

Previous studies reported that telencephalic proliferative zones contribute to the development of the pulvinar thalamic nucleus in the human brain (Rakic and Sidman [1969] Z. Anat. Entwicklungsgesch. 129:53-82). The present study examined their possible contribution to the development of other thalamic nuclei. Postmortem brain tissue from human fetuses ranging between 10.5 and 40 weeks of gestation (wg) was processed by Nissl staining, Golgi impregnation, and MAP2 (microtubule-associated protein 2) immunocytochemistry. The gangliothalamic body, suggested to serve as a conduit for cells migrating from the ganglionic eminence to the thalamus, was found in the period from 15 to 34 wg in all rostrocaudal thalamic regions, particularly at the level of the anterior nuclear complex, mediodorsal and pulvinar nucleus, and in addition, the lateral geniculate nucleus. In Nissl-stained sections, the gangliothalamic body is a thin cellular layer situated beneath the thalamic surface, near the telencephalo-diencephalic junction. In Golgi- and MAP2-stained sections, it is a stream of mostly bipolar cells extending from the ganglionic eminence to the medial thalamus. In addition, MAP2-immunoreactivity confirms the neuronal nature of its cells. The present study further supports the hypothesis that certain neurons migrate from the ganglionic eminence to the thalamus through the transient gangliothalamic body during fetal development. Moreover, our data indicate that both the association (mediodorsal and pulvinar), as well as the anterior (limbic) and specific relay nuclei are potential recipients of the telencephalic neurons.     

Test-retest variability of serotonin 5-HT2A receptor binding measured with positron emission tomography and [18F]altanserin in the human brain

The role of serotonin in CNS function and in many neuropsychiatric diseases (e.g., schizophrenia, affective disorders, degenerative dementias) support the development of a reliable measure of serotonin receptor binding in vivo in human subjects. To this end, the regional distribution and intrasubject test-retest variability of the binding of [18F]altanserin were measured as important steps in the further development of [18F]altanserin as a radiotracer for positron emission tomography (PET) studies of the serotonin 5-HT2A receptor. Two high specific activity [18F]altanserin PET studies were performed in normal control subjects (n = 8) on two separate days (2-16 days apart). Regional specific binding was assessed by distribution volume (DV), estimates that were derived using a conventional four compartment (4C) model, and the Logan graphical analysis method. For both analysis methods, levels of [18F]altanserin binding were highest in cortical areas, lower in the striatum and thalamus, and lowest in the cerebellum. Similar average differences of 13% or less were observed for the 4C model DV determined in regions with high receptor concentrations with greater variability in regions with low concentrations (16-20%). For all regions, the absolute value of the test-retest differences in the Logan DV values averaged 12% or less. The test-retest differences in the DV ratios (regional DV values normalized to the cerebellar DV) determined by both data analysis methods averaged less than 10%. The regional [18F]altanserin DV values using both of these methods were significantly correlated with literature-based values of the regional concentrations of 5-HT2A receptors determined by postmortem autoradiographic studies (r2 = 0.95, P < 0.001 for the 4C model and r2 = 0.96, P < 0.001 for the Logan method). Brain uptake studies in rats demonstrated that two different radiolabeled metabolites of [18F]altanserin (present at levels of 3-25% of the total radioactivity in human plasma 10-120 min postinjection) were able to penetrate the blood-brain barrier. However, neither of these radiolabeled metabolites bound specifically to the 5-HT2A receptor and did not interfere with the interpretation of regional [18F]altanserin-specific binding parameters obtained using either a conventional 4C model or the Logan graphical analysis method. In summary, these results demonstrate that the test-retest variability of [18F]altanserin-specific binding is comparable to that of other PET radiotracers and that the regional specific binding of [18F]altanserin in human brain was correlated with the known regional distribution of 5-HT2A receptors. These findings support the usefulness of [18F]altanserin as a radioligand for PET studies of 5-HT2A receptors.     

Dorsoventral patterning in the Drosophila central nervous system: the vnd homeobox gene specifies ventral column identity

The Drosophila CNS develops from three columns of neuroectodermal cells along the dorsoventral (DV) axis: ventral, intermediate, and dorsal. In this and the accompanying paper, we investigate the role of two homeobox genes, vnd and ind, in establishing ventral and intermediate cell fates within the Drosophila CNS. During early neurogenesis, Vnd protein is restricted to ventral column neuroectoderm and neuroblasts; later it is detected in a complex pattern of neurons. We use molecular markers that distinguish ventral, intermediate, and dorsal column neuroectoderm and neuroblasts, and a cell lineage marker for selected neuroblasts, to show that loss of vnd transforms ventral into intermediate column identity and that specific ventral neuroblasts fail to form. Conversely, ectopic vnd produces an intermediate to ventral column transformation. Thus, vnd is necessary and sufficient to induce ventral fates and repress intermediate fates within the Drosophila CNS. Vertebrate homologs of vnd (Nkx2.1 and 2.2) are similarly expressed in the ventral CNS, raising the possibility that DV patterning within the CNS is evolutionarily conserved.     

Disgust as the source of false positive effects in the measurement of ophidiophobia

In the adult Drosophila ovary the continuous production of eggs depends upon a small group of stem cells located at the anterior tip of the germarium. These stem cells divide asymmetrically to self renew and to generate a cystoblast, which in females is committed to the oocyte differentiation pathway. While much is known about the development of poststem cell cystoblasts, little is known about when stem cells are formed or how their identity is initially established. To investigate these questions we have used the P-M hybrid dysgenesis syndrome as a tool for ablating the "pre-stem cell" progenitors of the stem cells. Our experiments indicate that the pre-stem cells in females assume stem cell identity during the early pupal stage. Our results also suggest a model in which at least two pre-stem cells must be present within an ovariole for the specification of stem cell fate. When only a single pre-stem cell is sequestered by an ovariole, this cell does not assume stem cell identity, but instead follows the cystoblast-cystocyte differentiation pathway.     

Transplanted oligodendrocyte progenitor cells expressing a dominant-negative FGF receptor transgene fail to migrate in vivo

The proliferation, migration, survival, and differentiation of oligodendrocyte progenitor cells, precursors to myelin-forming oligodendrocytes in the CNS, are controlled by a number of polypeptide growth factors in vitro. The requirement and roles for individual factors in vivo, however, are primarily unknown. We have used a cell transplantation approach to examine the role of fibroblast growth factor (FGF) in oligodendrocyte development in vivo. A dominant-negative version of the FGF receptor-1 transgene was introduced into oligodendrocyte progenitors in vitro, generating cells that were nonresponsive to FGF but responsive to other mitogens. When transplanted into the brains of neonatal rats, mutant cells were unable to migrate and remained within the ventricles. These results suggest a role for FGF signaling in establishing a motile phenotype for oligodendrocyte progenitor cell migration in vivo and illustrate the utility of a somatic cell mutagenesis approach for the study of gene function during CNS development in vivo.     

Qualitative and quantitative detection of alkaline phosphatase coupled to an oligonucleotide probe for somatostatin mRNA after in situ hybridization using unfixed rat brain tissue

In situ hybridization (ISH) of somatostatin (SOM) mRNA was carried out on sections of rat brain using an alkaline phosphatase (AP) coupled oligonucleotide probe. Different hybridization and AP development conditions were tested for qualitative and quantitative detection of target mRNA on sections of unfixed tissue. Hybridization signal intensities after 24 h of hybridization were high. Comparison with adjacent formaldehyde-fixed tissue sections and hybridization for various lengths of time (2-42 h) indicated that in unfixed tissue retention of SOM mRNA was at least as high as after fixation, and that the mRNA was not degraded during hybridization. The use of tetranitroblue instead of nitroblue tetrazolium chloride in the AP detection medium provided a superior signal-to-noise ratio, and medium stability was improved for quantitative studies on unfixed sections by adding 10% polyvinyl alcohol at pH 8.5. Microphotometric measurements of mean optical densities (MOD) of the formazan reaction product in a defined area within individual neurons of the lateral central amygdaloid nucleus showed a linear increase over the first 23 h of AP reaction time. The mean MOD values per neuron were comparably high in various equally thick sections of the nucleus and increased with section thickness in a linear manner. The findings indicate that the ISH and detection reagents penetrate the entire section and that there is a linear relationship between the amount of AP reaction product measured and the amount of mRNA present in the measured area. Thus, ISH using an AP-coupled oligonucleotide on sections of unfixed tissue appears suitable for quantitative mRNA detection.     

Ribosome-lamella complexes in sinus histiocytes

Prior studies have shown that human umbilical cord blood cells can restore hematopoiesis and be used as a source of stem cells for hematopoietic transplantation. We have performed a study of the best conditions of collection and cryopreservation of blood from eight umbilical cords. We compared the influence of cell separation and of delay between collection and cryopreservation on the numbers of nucleated cells and of hematopoietic progenitors recovered before and after cryopreservation. Ficoll separation resulted in the loss of more than 50% of nucleated cells, but also of a significant number of progenitors before freezing. Unseparated cells could be kept at 25 degrees C as long as 24 h before freezing with minimal loss of progenitors before and after freezing and thawing. In contrast, there was a significant decrease in the number of viable cells and progenitors when cells were maintained at 4 degrees C before freezing. Our data show that cord blood banking is feasible with simple collection and cryopreservation procedures.     

Signalling by the Drosophila epidermal growth factor receptor is required for the specification and diversification of embryonic muscle progenitors

Muscle development initiates in the Drosophila embryo with the segregation of single progenitor cells, from which a complete set of myofibres arises. Each progenitor is assigned a unique fate, characterized by the expression of particular identity genes. We now demonstrate that the Drosophila epidermal growth factor receptor provides an inductive signal for the specification of a large subset of muscle progenitors. In the absence of the receptor or its ligand, SPITZ, specific progenitors fail to segregate. The resulting unspecified mesodermal cells undergo programmed cell death. In contrast, receptor hyperactivation generates supernumerary progenitors, as well as the duplication of at least one SPITZ-dependent myofibre. The development of individual muscles is differentially sensitive to variations in the level of signalling by the epidermal growth factor receptor. Such graded myogenic effects can be influenced by alterations in the functions of Star and rhomboid. In addition, muscle patterning is dependent on the generation of a spatially restricted, activating SPITZ signal, a process that may rely on the localized mesodermal expression of RHOMBOID. Thus, the epidermal growth factor receptor contributes both to muscle progenitor specification and to the diversification of muscle identities.     

Proteolytic processing of the Aplysia egg-laying hormone prohormone

By using matrix-assisted laser desorption/ionization time-of-flight MS, individual peptidergic neurons from Aplysia are assayed. A semiquantitative method is developed for comparing single-cell profiles by using spectral normalization, and peptides are localized to specific cells by mass spectrometric cell mapping. In addition to all previously identified products of the egg-laying hormone (ELH) gene, other peptides are formed from proteolytic hydrolysis of Leu-Leu residues within ELH and acidic peptide (AP). AP exhibits further processing to yield AP1-20 and AP9-27. These peptides appear to be colocalized in vesicles with ELH, transported to specific neuronal targets, and released in a Ca2+-dependent manner. A differential peptide distribution is observed at a specific target cell, and a low-frequency variation of AP, [Thr21]AP, is detected in a single animal.     

Transplantation of CG4 oligodendrocyte progenitor cells in the myelin-deficient rat brain results in myelination of axons and enhanced oligodendroglial markers

Transplantation of oligodendrocyte (Ol) progenitor cells into the central nervous system is a promising approach for the treatment of myelin disorders. This approach requires providing adequate numbers of healthy cells with myelinating potential. We recently showed the successful transplantation of Ol progenitors into the myelin-deficient (md) rat brain. In the present work, CG4 cells, a cell line with properties of Ol progenitors, were labeled with fast blue and grafted into P3-P5 pups born to carrier mothers. Examination of host brains 2 weeks posttransplant indicated that CG4 cells display a much more extensive migration capacity than their wild-type counterparts. These cells synthesized myelin components. In addition, ultrastructural analysis showed myelin formation along axons of md hosts in various brain regions, including corpus callosum, cerebellum, and brainstem. Furthermore, in situ hybridization studies performed on sagittal sections revealed extensive expression of transferrin-mRNA within the md host parenchyma. The high survival and functional features displayed by CG4 cells after transplantation, together with their striking wide distribution within the host parenchyma, as assessed by the presence of myelinated fibers in mutant hosts, emphasizes the importance of using highly motile and proliferative Ol progenitor cells. Strategies to improve the condition and life span of md rat pups are currently under investigation.     

Ionic mechanisms of regional action potential heterogeneity in the canine right atrium

Atrial action potential heterogeneity is a major determinant of atrial reentrant arrhythmias, but the underlying ionic mechanisms are poorly understood. To evaluate the basis of spatial heterogeneity in canine right atrial repolarization, we isolated cells from 4 regions: the crista terminalis (CT), appendage (APG), atrioventricular ring (AVR) area, and pectinate muscles. Systematic action potential (AP) differences were noted: CT cells had a "spike-and-dome" morphology and the longest AP duration (APD; value to 95% repolarization at 1 Hz, 270+/-10 ms [mean+/-SEM]); APG and pectinate muscle cells had intermediate APDs (180+/-3 and 190+/-3 ms, respectively; P<0.001 versus CT for each), with APG cells having a small phase 1; and AVR cells had the shortest APD (160+/-4 ms, P<0.001 versus other regions). The inward rectifier and the slow and ultrarapid delayed rectifier currents were similar in all regions. The transient outward K+ current was significantly smaller in APG cells, explaining their small phase 1 and high plateau. L-type Ca2+ current was greatest in CT cells and least in AVR cells, contributing to their longer and shorter APD, respectively. The E-4031-sensitive rapid delayed rectifier K+ current was larger in AVR cells compared with other regions. Voltage- and time-dependent current properties were constant across regions. We conclude that myocytes from different right atrial regions of the dog show systematic variations in AP properties and ionic currents and that the spatial variation in ionic current density may explain AP differences. Regional variation in atrial ionic currents may play an important role in atrial arrhythmia generation and may present opportunities for improving antiarrhythmic drug therapy.