The cell adhesion-associated protein Git2 regulates morphogenetic movements during zebrafish embryonic development

Signaling through cell adhesion complexes plays a critical role in coordinating cytoskeletal remodeling necessary for efficient cell migration. During embryonic development, normal morphogenesis depends on a series of concerted cell movements; but the roles of cell adhesion signaling during these movements are poorly understood. The transparent zebrafish embryo provides an excellent system to study cell migration during development. Here, we have identified zebrafish git2a and git2b, two new members of the GIT family of genes that encode ArfGAP proteins associated with cell adhesions. Loss-of-function studies revealed an essential role for Git2a in zebrafish cell movements during gastrulation. Time-lapse microscopy analysis demonstrated that antisense depletion of Git2a greatly reduced or arrested cell migration towards the vegetal pole of the embryo. These defects were rescued by expression of chicken GIT2, indicating a specific and conserved role for Git2 in controlling embryonic cell movements. Git2a knockdown embryos showed defects in cell morphology that were associated with reduced cell contractility. We show that Git2a is required for phosphorylation of myosin light chain (MLC), which regulates myosin II-mediated cell contractility. Consistent with this, embryos treated with Blebbistatin-a small molecule inhibitor for myosin II activity-exhibited cell movement defects similar to git2a knockdown embryos. These observations provide in vivo evidence of a physiologic role for Git2a in regulating cell morphogenesis and directed cell migration via myosin II activation during zebrafish embryonic development.     

Role of FK506-binding protein 12 in development of the chick embryonic heart

A cDNA encoding chicken FK506-binding protein 12 (FKBP12) was isolated and sequenced. The predicted amino acid sequence of the chicken protein shows high homology to those of FKBP12 proteins of other species ranging from human to frog. The possible role of FKBP12 in chick embryonic cardiac development was examined. Northern blot analysis revealed that FKBP12 mRNA is distributed widely in chick embryos, being especially abundant in the heart; the amount of FKBP12 mRNA in the embryonic heart decreased with time. Administration of FK506 to chick embryos at 7 to 9 days resulted in marked cardiac enlargement. FK506 also reduced the expression of myosin, induced a more elongated cell morphology, and impaired network formation in cultured chick embryonic cardiomyocytes. These results suggest that FKBP12 is important in the regulation of contractile function and phenotypic expression in chick cardiomyocytes during embryonic development.     

Patterns of differences in brain morphology in humans as compared to extant apes

Although human evolution is characterized by a vast increase in brain size, it is not clear whether or not certain regions of the brain are enlarged disproportionately in humans, or how this enlargement relates to differences in overall neural morphology. The aim of this study is to determine whether or not there are specific suites of features that distinguish the morphology of the human brain from that of apes. The study sample consists of whole brain, in vivo magnetic resonance images (MRIs) of anatomically modern humans (Homo sapiens sapiens) and five ape species (gibbons, orangutans, gorillas, chimpanzees, bonobos). Twenty-nine 3D landmarks, including surface and internal features of the brain were located on 3D MRI reconstructions of each individual using MEASURE software. Landmark coordinate data were scaled for differences in size and analyzed using Euclidean Distance Matrix Analysis (EDMA) to statistically compare the brains of each non-human ape species to the human sample. Results of analyses show both a pattern of brain morphology that is consistently different between all apes and humans, as well as patterns that differ among species. Further, both the consistent and species-specific patterns include cortical and subcortical features. The pattern that remains consistent across species indicates a morphological reorganization of 1) relationships between cortical and subcortical frontal structures, 2) expansion of the temporal lobe and location of the amygdala, and 3) expansion of the anterior parietal region. Additionally, results demonstrate that, although there is a pattern of morphology that uniquely defines the human brain, there are also patterns that uniquely differentiate human morphology from the morphology of each non-human ape species, indicating that reorganization of neural morphology occurred at the evolutionary divergence of each of these groups.     

Increased intracellular [dATP] enhances cardiac contraction in embryonic chick cardiomyocytes

Although ATP is the physiological substrate for cardiac contraction, cardiac contractility is significantly enhanced in vitro when only 10% of ATP substrate is replaced with 2'-deoxy-ATP (dATP). To determine the functional effects of increased intracellular [dATP] ([dATP](i)) within living cardiac cells, we used hypertonic loading with varying exogenous dATP/ATP ratios, but constant total nucleotide concentration, to elevate [dATP](i) in contractile monolayers of embryonic chick cardiomyocytes. The increase in [dATP](i) was estimated from dilution of dye added in parallel with dATP. Cell viability, average contractile amplitude, rates of contraction/relaxation, spontaneous beat frequency, and Ca2+ transient amplitude and kinetics were examined. At total [dATP](i) above approximately 70 microM, spontaneous contractions ceased, and above approximately 100 microM [dATP](i), membrane blebbing was also observed, consistent with apoptosis. Interestingly, [dATP](i) of approximately 60 microM ( approximately 40% increase over basal [dATP](i) levels) enhanced both amplitude of contraction and the rates of contraction and relaxation without affecting beat frequency. With total [dATP](i) of approximately 60 microM or less, we found no significant change in Ca2+ transients. These data indicate that there is an "optimal" concentration of exogenously loaded [dATP](i) that under controlled conditions can enhance contractility in living cardiomyocytes without affecting beat frequency or Ca2+ transients.     

Zebrafish chordin-like and chordin are functionally redundant in regulating patterning of the dorsoventral axis

Chordin is the prototype of a group of cysteine-rich domain-containing proteins that bind and modulate signaling of various TGFβ-like ligands. Chordin-like 1 and 2 (CHL1 and 2) are two members of this group that have been described in human, mouse, and chick. However, in vivo roles for CHL1 and 2 in early development are unknown due to lack of loss-of-function analysis. Here we identify and characterize zebrafish, Danio rerio, CHL (Chl). The chl gene is on a region of chromosome 21 syntenic with the area of murine chromosome 7 bearing the CHL2 gene. Inability to identify a separate zebrafish gene corresponding to the mammalian CHL1 gene suggests that Chl may serve roles in zebrafish distributed between CHL1 and CHL2 in other species. Chl is a maternal factor that is also zygotically expressed later in development and has spatiotemporal expression patterns that differ from but overlap those of zebrafish chordin (Chd), suggesting differences but also possible overlap in developmental roles of the two proteins. Chl, like Chd, dorsalizes embryos upon overexpression and is cleaved by BMP1, which antagonizes this activity. Loss-of-function experiments demonstrate that Chl serves as a BMP antagonist with functions that overlap and are redundant with those of Chd in forming the dorsoventral axis.     

Identification of Wnt Genes Expressed in Neural Progenitor Zones during Zebrafish Brain Development

Wnt signaling regulates multiple aspects of vertebrate central nervous system (CNS) development, including neurogenesis. However, vertebrate genomes can contain up to 25 Wnt genes, the functions of which are poorly characterized partly due to redundancy in their expression. To identify candidate Wnt genes as candidate mediators of pathway activity in specific brain progenitor zones, we have performed a comprehensive expression analysis at three different stages during zebrafish development. Antisense RNA probes for 21 Wnt genes were generated from existing and newly synthesized cDNA clones and used for in situ hybridization on whole embryos and dissected brains. As in other species, we found that Wnt expression patterns in the embryonic zebrafish CNS are complex and often redundant. We observed that progenitor zones in the telencephalon, dorsal diencephalon, hypothalamus, midbrain, midbrain-hindbrain boundary, cerebellum and retina all express multiple Wnt genes. Our data identify 12 specific ligands that can now be tested using loss-of-function approaches.     

A developmental study of serotonin-immunoreactive neurons in the embryonic brain of the Marbled Crayfish and the Migratory Locust: Evidence for a homologous protocerebral group of neurons

It is well established that the brains of adult malacostracan crustaceans and winged insects display distinct homologies down to the level of single neuropils such as the central complex and the optic neuropils. We wanted to know if developing insect and crustacean brains also share similarities and therefore have explored how neurotransmitter systems arise during arthropod embryogenesis. Previously, Sintoni et al. (2007) had already reported a homology of an individually identified cluster of neurons in the embryonic crayfish and insect brain, the secondary head spot cells that express the Engrailed protein. In the present study, we have documented the ontogeny of the serotonergic system in embryonic brains of the Marbled Crayfish in comparison to Migratory Locust embryos using immunohistochemical methods combined with confocal laser-scan microscopy. In both species, we found a cluster of early emerging serotonin-immunoreactive neurons in the protocerebrum with neurites that cross to the contralateral brain hemisphere in a characteristic commissure suggesting a homology of this cell cluster. Our study is a first step towards a phylogenetic analysis of neurotransmitter system development and shows that, as for the ventral nerve cord, traits related to neurogenesis in the brain can provide valuable hints for resolving the much debated question of arthropod phylogeny.     

Glutamine Transaminase K and ω-Amidase Activities in Primary Cultures of Astrocytes and Neurons and in Embryonic Chick Forebrain: Marked Induction of Brain Glutamine Transaminase K at Time of Hatching

Abstract: Glutamine transaminase K and ω-amidase activities are present in the chick brain and in the brains of adult mice, rats, and humans. However, the activity of gluta-mine transaminase K in adult mouse brain is relatively low. In the chick embryo, cerebral glutamine transaminase K activity is low between embryonic days 5 and 17, but by day 23 (day of hatching) activity rises dramatically (< 15-fold). Cerebral ω-amidase activity is relatively high at embryonic day 5 but lower between days 5 and 17; at embryonic day 23 the activity rises to a maximum. Both glutamine transaminase K and ω-amidase are present in cultured chick, rat, and mouse astrocytes and neurons. For each species, the activity of glutamine transaminase K is higher in the astrocytes than in the neurons. The activity of ω-amidase is about the same in the cultured chick astrocytes and neurons but significantly higher in rat astrocytes than in rat neurons. The data suggest that the rise in brain glutamine transaminase K activity in the chick embryo at hatching correlates with maturation of astrocytes. Glutamine transaminase K may be involved in glutamine cycling in astrocytes. Glutamine transaminase K appears to be a major cysteine S-conjugate β-lyase of the brain and may play a role in the neurotoxicity associated with exposure to dichloroacetylene and perhaps to other toxins.     

Left-handed cardiac looping by cell chirality is mediated by position-specific convergent extensions

In the embryonic heart development of mammals and birds, a straight initial heart tube undergoes left-handed helical looping, which is a remarkable and puzzling event. We are interested in the mechanism of this chiral helical looping. Recently, observations were reported that myocardial cells in the embryonic chick heart show intrinsic chirality of rotation. The chirality of myocardial cells, via anisotropic polarization of Golgi inside the cells, leads to a left-right (LR) asymmetry of cell shape. On cell boundaries of LR asymmetric cells, phosphorylated myosin and N-cadherin are enriched. Such LR asymmetric cellular circumstances lead to a large-scale three-dimensional chiral structure, the left-handed helical loop. However, the physical mechanism of this looping is unclear. Computer simulations were performed using a cell-based three-dimensional mathematical model assuming an anterior-rightward-biased contractile force of the cell boundaries on the ventral surface of the heart (orientation of a clock hand pointing to 10 to 11 o’clock). An initially straight heart tube was successfully remodeled to the left-handed helical tube via frequent convergent extension (CE) of collective cells, which corresponds to the previously reported observations of chick heart development. Although we assumed that the biased boundary contractile force was uniform all over the ventral side, orientations of the CEs became position specific on the anterior, posterior, right, and left regions on the ventral tube. Such position-specific CEs produced the left-handed helical loop. In addition, our results suggest the loop formation process consists of two distinct phases of preparation and explicit looping. Intrinsic cell properties of chirality in this investigation were discussed relating to extrinsic factors investigated by other researches. Finally, because CE is generally exerted in the axial developmental process across different animal species, we discussed the contribution of CE to the chiral heart structure across species of chick, mouse, Xenopus, and zebrafish.     

Socially induced brain development in a facultatively eusocial sweat bee Megalopta genalis (Halictidae)

Changes in the relative size of brain regions are often dependent on experience and environmental stimulation, which includes an animal''s social environment. Some studies suggest that social interactions are cognitively demanding, and have examined predictions that the evolution of sociality led to the evolution of larger brains. Previous studies have compared species with different social organizations or different groups within obligately social species. Here, we report the first intraspecific study to examine how social experience shapes brain volume using a species with facultatively eusocial or solitary behaviour, the sweat bee Megalopta genalis. Serial histological sections were used to reconstruct and measure the volume of brain areas of bees behaving as social reproductives, social workers, solitary reproductives or 1-day-old bees that are undifferentiated with respect to the social phenotype. Social reproductives showed increased development of the mushroom body (an area of the insect brain associated with sensory integration and learning) relative to social workers and solitary reproductives. The gross neuroanatomy of young bees is developmentally similar to the advanced eusocial species previously studied, despite vast differences in colony size and social organization. Our results suggest that the transition from solitary to social behaviour is associated with modified brain development, and that maintaining dominance, rather than sociality per se, leads to increased mushroom body development, even in the smallest social groups possible (i.e. groups with two bees). Such results suggest that capabilities to navigate the complexities of social life may be a factor shaping brain evolution in some social insects, as for some vertebrates.     

钙调蛋白及其调节酶PDE在鸡脑胚胎发育过程中的变化

钙调蛋白(CaM)参与脑中多种细胞过程的调节,推测它与大脑的分化发育有关。本实验研究了鸡脑从胚胎早期(原基)至大脑成熟各发育阶段可溶部分的CaM及其调节酶——环核苷酸磷酸二酯酶(PDE)的含量或活力变化。未经孵育的鸡胚中检测不出CaM,在孵育3—14天的胚脑中CaM含量逐渐增加:总CaM增加了3倍,活性CaM增加了4倍;而且在鸡脑细胞分裂分化最活跃的期间(皮质和髓质形成期间,即孵育8—14天),活性CaM的增加尤为显著(增加近3倍)。提示CaM与脑细胞的分裂分化有关。PDE的活力出现晚于CaM5天,随着胚龄增加,不断上升,提示它与脑细胞的分裂分化无直接关系,可能与大脑的功能活动有关。本实验还研究了鸡脑发育期中可逆性钙结合蛋白的变化。     

Ethanol-induced increased endogenous homocysteine levels and decreased ratios of SAM/SAH are only partially attenuated by exogenous glycine in developing chick brains

The effects of exogenous ethanol (EtOH) and/or glycine on chick (Gallus gallus) embryo viability, brain apoptosis (caspase-3 activities), and the endogenous levels of brain homocysteine (HoCys), S-adenosylmethionine (SAM), S-adenosylhomocysteine (SAH), and SAM/SAH were studied. Embryonic EtOH exposure caused decreased embryo viability as measured by EtOH-induced reductions in % living embryos at theoretical stage 37, EtOH-induced reductions in embryo masses, and EtOH-induced reductions in brain caspase-3 (Casp-3) activities. Exogenous glycine failed to attenuate EtOH-induced decreased embryo viability and EtOH-induced increased brain Casp-3 activities. Embryonic EtOH exposure caused elevated levels of endogenous HoCys, decreased levels of SAM, increased levels of SAH, and decreased SAM/SAH ratios in embryonic chick brains. While exogenous glycine failed to attenuate EtOH-induced increased HoCys levels, exogenous glycine attenuated EtOH-induced decreased levels of SAM, increased levels of SAH, and decreased SAM/SAH levels in embryonic chick brains.     

DNA synthesis, mitosis, and differentiation in cardiac myogenesis

Cardiac muscle cells obtained by trypsinizing 5-day chick embryonic heart were cultured as single cells in separate culture dishes. Using this technique, problems of heterotypic cell interactions, “overgrowth” of one cell type, etc., are eliminated. Experiments performed on these single cell cultures show that the muscle cells in the embryonic chick hearts differ in morphology, including content of cross-striated myofibrils; in ability to synthesize DNA and undergo mitosis; and in frequency of contraction. Contracting cells containing cross-striated myofibrils undergo mitosis in vitro, giving rise to spontaneously beating daughter cells. These daughter cells contain cytoplasmic fibrils, which bind fluorescein-labeled antimyosin immediately after cytokinesis. Some cardiac muscle cells from 5-day heart do not divide in culture; the rest undergo 1–5 doublings. This preliminary investigation suggests that the new muscle cells formed during cardiac growth are derived from mitotically active “overtly” differentiated cardiac muscle cells.     

Effects of electric fields on fibroblast contractility and cytoskeleton

We used silicone rubber substrata and fluorescent staining of cytoskeletal components to study the mechanisms by which electrical voltage gradients cause reorientation of embryonic chick fibroblasts in tissue culture. No evidence was found for a direct stimulation of cell contractility, either parallel or perpendicular to the voltage gradient. Instead, there was a gradual weakening in cell contractility in the axis parallel to this gradient, accompanied by progressive retraction of lamellae oriented along this axis, apparently due to selective weakening of cell-substratum adhesions. The cells then elongated perpendicular to the electric field, and strengthened their contractility in that axis. Fluorescence microscopy showed that cytoplasmic actin stress fibers and microtubules oriented perpendicular to the imposed voltage gradient. Many more cases were observed in which cell morphology had reoriented, but the actin fibers had not, as compared to the converse (cytoskeleton oriented, but no morphology). This disparity further supports the interpretation that the redirection of cell contractility is a consequence of morphological reorientation, rather than its cause. We also studied the effects of reversing the polarity of the electric fields at constant intervals (of as long as 1 minute). Fibroblasts failed to orient in response to such alternating fields, even after long exposure, but these same cells did reorient in response to pulsed currents in a consistent direction separated by "rest periods" (with no current). This combination of results is more consistent with an electrophoretic mechanism than with one depending on voltage-induced changes in membrane permeabilities.     

Cardiomyocyte sensor responsive to changes in physical and chemical environments

Conventional cardiac physiology experiments investigate in vitro beat frequency using cells isolated from adult or neonatal rat hearts. In this study, we show that various cantilever shapes and drug treatments alter cardiomyocyte contraction force in vitro. Four types of cantilevers were used to compare the contractile forces: flat, peg patterned, grooved, and peg and grooved. Contraction force was represented as bending deflection of the cantilever end. The deflections of the flat, peg patterned, grooved, and peg and grooved cantilevers were 24.2 nN, 41.6 nN, 121 nN, and 134.2 nN, respectively. We quantified the effect of drug treatments on cardiomyocyte contractile forces on the grooved cantilever using Digoxin, Isoproterenol, and BayK8644, all of which increase contractile force, and Verapamil, which decreases contractile force. The cardiomyocyte contractile force without drugs decreased 8 days after culture initiation. Thus, we applied Digoxin, Isoproterenol, and BayK8644 at day 8, and Verapamil at day 5. Digoxin, Isoproterenol, and BayK8644 increased the cardiomyocyte contractile forces by 19.31%, 9.75%, and 23.81%, respectively. Verapamil decreased the contraction force by 48.06%. In summary, contraction force changes in response to adhesion surface topology and various types of drug treatments. We observed these changes by monitoring cell alignment, adhesion, morphology, and bending displacement with cantilever sensors.     

Protein friction and filament bending facilitate contraction of disordered actomyosin networks

We use mathematical modeling and computation to investigate how protein friction facilitates contraction of disordered actomyosin networks. We simulate two-dimensional networks using an agent-based model, consisting of a system of force-balance equations for myosin motor proteins and semiflexible actin filaments. A major advantage of our approach is that it enables direct calculation of the network stress tensor, which provides a quantitative measure of contractility. Exploiting this, we use repeated simulations of disordered networks to confirm that both protein friction and actin filament bending are required for contraction. We then use simulations of elementary two-filament systems to show that filament bending flexibility can facilitate contraction on the microscopic scale. Finally, we show that actin filament turnover is necessary to sustain contraction and prevent filament aggregation. Simulations with and without turnover also exhibit contractile pulses. However, these pulses are aperiodic, suggesting that periodic pulsation can only arise because of additional regulatory mechanisms or more complex mechanical behavior.