Your search keyword '"Andrew J. Schroeder"' showing total 8 results

1. Drosophila Fragile X Protein, DFXR, Regulates Neuronal Morphology and Function in the Brain

Author

Andrew J. Schroeder, Kazuhiko Kume, Joannella Morales, Bassem A. Hassan, David L. Nelson, Patrik Verstreken, P. Robin Hiesinger, and F. Rob Jackson

Subjects

Cell type, Neurite, Neuroscience(all), Molecular Sequence Data, RNA-binding protein, Nerve Tissue Proteins, Biology, Motor Activity, medicine.disease_cause, Fragile X Mental Retardation Protein, medicine, Animals, Drosophila Proteins, Amino Acid Sequence, Neurons, Mutation, Sequence Homology, Amino Acid, General Neuroscience, Brain, RNA-Binding Proteins, medicine.disease, Phenotype, FMR1, Circadian Rhythm, Fragile X syndrome, Fragile X Syndrome, Neuroscience, Neuroglia, Drosophila Protein

Abstract

Mental retardation is a pervasive societal problem, 25 times more common than blindness for example. Fragile X syndrome, the most common form of inherited mental retardation, is caused by mutations in the FMR1 gene. Fragile X patients display neurite morphology defects in the brain, suggesting that this may be the basis of their mental retardation. Drosophila contains a single homolog of FMR1, dfxr (also called dfmr1). We analyzed the role of dfxr in neurite development in three distinct neuronal classes. We find that DFXR is required for normal neurite extension, guidance, and branching. dfxr mutants also display strong eclosion failure and circadian rhythm defects. Interestingly, distinct neuronal cell types show different phenotypes, suggesting that dfxr differentially regulates diverse targets in the brain.

Published

2002

2. Cellular and molecular mechanisms of circadian control in insects

Author

Bikem Akten, Gerard P. McNeil, F. R. Jackson, Kazuhiko Kume, Andrew J. Schroeder, and Mary A. Roberts

Subjects

Cell type, biology, Physiology, Mechanism (biology), fungi, Circadian clock, Anatomy, biology.organism_classification, Insect Science, Melanogaster, Circadian rhythm, Drosophila melanogaster, Manduca, Neuroscience, Function (biology)

Abstract

Genetic analysis in Drosophila melanogaster has identified molecules important for the function of insect circadian clocks, and this has resulted in the elaboration of explicit biochemical models of the clock mechanism. Comparable molecular genetic analysis coupled with neuroanatomical approaches has also delineated cellular elements of the circadian pacemaker controlling insect activity rhythms. However, not much is known about the transfer of temporal information from clock cells in the insect brain to downstream neural elements or other target cells that are regulated by the clock (i.e. clock output pathways). In this review, we focus on the insect literature, with special reference to the fruitfly D. melanogaster and the hawkmoth Manduca sexta, to discuss the candidate molecules, biochemical mechanisms and cell types implicated in the clock control of behavior.

Published

2001

3. Circadian regulation of the lark RNA-binding protein within identifiable neurosecretory cells

Author

Xiaolan Zhang, F. Rob Jackson, Marla J. Hilderbrand-Chae, Andrew J. Schroeder, Tina M. Franklin, and Gerard P. McNeil

Subjects

Nervous system, Cell type, animal structures, Crustacean cardioactive peptide, General Neuroscience, fungi, Neuropeptide, RNA-binding protein, Anatomy, Biology, Cell biology, Cellular and Molecular Neuroscience, medicine.anatomical_structure, Cytoplasm, Ecdysis, medicine, Circadian rhythm

Abstract

Molecular genetic analysis indicates that rhythmic changes in the abundance of the Drosophila lark RNA-binding protein are important for circadian regulation of adult eclosion (the emergence or ecdysis of the adult from the pupal case). To define the tissues and cell types that might be important for lark function, we have characterized the spatial and developmental patterns of lark protein expression. Using immunocytochemical or protein blotting methods, lark can be detected in late embryos and throughout postembryonic development, from the third instar larval stage to adulthood. At the late pupal (pharate adult) stage, lark protein has a broad pattern of tissue expression, which includes two groups of crustacean cardioactive peptide (CCAP)-containing neurons within the ventral nervous system. In other insects, the homologous neurons have been implicated in the physiological regulation of ecdysis. Whereas lark has a nuclear distribution in most cell types, it is present in the cytoplasm of the CCAP neurons and certain other cells, which suggests that the protein might execute two different RNA-binding functions. Lark protein exhibits significant circadian changes in abundance in at least one group of CCAP neurons, with abundance being lowest during the night, several hours prior to the time of adult ecdysis. Such a temporal profile is consistent with genetic evidence indicating that the protein serves a repressor function in mediating the clock regulation of adult ecdysis. In contrast, we did not observe circadian changes in CCAP neuropeptide abundance in late pupae, although CCAP amounts were decreased in newly-emerged adults, presumably because the peptide is released at the time of ecdysis. Given the cytoplasmic localization of the lark RNA-binding protein within CCAP neurons, and the known role of CCAP in the control of ecdysis, we suggest that changes in lark abundance may regulate the translation of a factor important for CCAP release or CCAP cell excitability. © 2000 John Wiley & Sons, Inc. J Neurobiol 45: 14–29, 2000

Published

2000

4. An Extraretinally Expressed Insect Cryptochrome with Similarity to the Blue Light Photoreceptors of Mammals and Plants

Author

Marla J. Hilderbrand-Chae, Elizabeth S. Egan, Xiaolan Zhang, Gerard P. McNeil, F. Rob Jackson, Andrew J. Schroeder, Mary A. Roberts, and Tina M. Franklin

Subjects

genetic structures, Molecular Sequence Data, Photosynthetic Reaction Center Complex Proteins, Genes, Insect, In situ hybridization, Biology, Gene dosage, Article, Receptors, G-Protein-Coupled, Mice, Cryptochrome, Biological Clocks, Oscillometry, medicine, Animals, Drosophila Proteins, Humans, Amino Acid Sequence, RNA, Messenger, Circadian rhythm, Eye Proteins, Gene, Genetics, Retina, Flavoproteins, Sequence Homology, Amino Acid, General Neuroscience, fungi, Brain, Chromosome Mapping, Circadian Rhythm, Cell biology, Cryptochromes, medicine.anatomical_structure, Insect Proteins, Drosophila, Photoreceptor Cells, Invertebrate, sense organs, Drosophila Protein, Visual phototransduction

Abstract

Photic entrainment of insect circadian rhythms can occur through either extraretinal (brain) or retinal photoreceptors, which mediate sensitivity to blue light or longer wavelengths, respectively. Although visual transduction processes are well understood in the insect retina, almost nothing is known about the extraretinal blue light photoreceptor of insects. We now have identified and characterized a candidate blue light photoreceptor gene inDrosophila(DCry) that is homologous to the cryptochrome (Cry) genes of mammals and plants. TheDCrygene is located in region 91F of the third chromosome, an interval that does not contain other genes required for circadian rhythmicity. The protein encoded byDCryis ∼50% identical to the CRY1 and CRY2 proteins recently discovered in mammalian species. As expected for an extraretinal photoreceptor mediating circadian entrainment,DCrymRNA is expressed within the adult brain and can be detected within body tissues. Indeed, tissuein situhybridization demonstrates prominent expression in cells of the lateral brain, which are close to or coincident with theDrosophilaclock neurons. Interestingly,DCrymRNA abundance oscillates in a circadian manner inDrosophilahead RNA extracts, and the temporal phasing of the rhythm is similar to that documented for the mouseCry1mRNA, which is expressed in clock tissues. Finally, we show that changes inDCrygene dosage are associated predictably with alterations of the blue light resetting response for the circadian rhythm of adult locomotor activity.

Published

1999

5. Cell-specific expression of the lark RNA-binding protein in Drosophila results in morphological and circadian behavioral phenotypes

Author

Andrew J, Schroeder, Ginka K, Genova, Mary A, Roberts, Yelena, Kleyner, Joowon, Suh, and F Rob, Jackson

Subjects

Male, Neurons, Behavior, Animal, Brain, Gene Expression, RNA-Binding Proteins, Genes, Insect, Circadian Rhythm, Animals, Genetically Modified, Drosophila melanogaster, Animals, Drosophila Proteins, Female, Locomotion

Abstract

Past studies have implicated the Drosophila LARK protein in the circadian control of adult eclosion behavior. LARK has a broad tissue pattern of distribution, and is pan-neuronal in the differentiated brain. In certain peptidergic neurons, LARK abundance changes in a circadian manner. However, the precise cellular requirement for LARK, with respect to circadian behavior, is still not known. To explore this issue, we employed the GAL4/UAS binary expression system to increase LARK abundance in defined neuronal cell types. Interestingly, LARK expression in Crustacean Cardioactive Peptide (CCAP) neurons caused an early-eclosion phenotype, whereas a similar perturbation in the Eclosion Hormone (EH) cells resulted in abnormally late peaks of eclosion. Surprisingly, LARK expression in Pigment Dispersing Factor (PDF)- or TIMELESS (TIM)-containing clock neurons caused behavioral arrhythmicity, even though clock protein cycling was found to be normal in these flies. Although the observed effects of LARK expression mirrored those seen with genetic ablation of the relevant peptidergic populations, there was no evidence of defective cell development or morphology. This suggests that an alteration of cell function rather than cell death is the cause of the aberrant phenotypes. Diminished PDF immunoreactivity in flies expressing LARK in the PDF neurons suggests that an effect on neuropeptide synthesis, transport, or release may contribute to the observed arrhythmicity. Importantly, the expression of LARK in several other cell populations did not have detectable effects on development, viability or behavior, indicating a specificity of action within certain cell types.

Published

2003

6. Targeted ablation of CCAP neuropeptide-containing neurons of Drosophila causes specific defects in execution and circadian timing of ecdysis behavior

Author

Jae H. Park, John Ewer, Charlotte Helfrich-Förster, Andrew J. Schroeder, and F. Rob Jackson

Subjects

animal structures, media_common.quotation_subject, Molecular Sequence Data, Neuropeptide, Biology, Molting, Genes, Regulator, Animals, Circadian rhythm, Amino Acid Sequence, Metamorphosis, Molecular Biology, Bursicon, media_common, Neurons, Crustacean cardioactive peptide, Base Sequence, fungi, Neuropeptides, Pupa, Gene Expression Regulation, Developmental, Anatomy, biology.organism_classification, Cell biology, Circadian Rhythm, Manduca sexta, Ecdysis, Drosophila, Moulting, Developmental Biology

Abstract

Insect growth and metamorphosis is punctuated by molts, during which a new cuticle is produced. Every molt culminates in ecdysis, the shedding of the remains of the old cuticle. Both the timing of ecdysis relative to the molt and the actual execution of this vital insect behavior are under peptidergic neuronal control. Based on studies in the moth, Manduca sexta, it has been postulated that the neuropeptide Crustacean cardioactive peptide (CCAP)plays a key role in the initiation of the ecdysis motor program. We have used Drosophila bearing targeted ablations of CCAP neurons (CCAP KO animals) to investigate the role of CCAP in the execution and circadian regulation of ecdysis. CCAP KO animals showed specific defects at ecdysis, yet the severity and nature of the defects varied at different developmental stages. The majority of CCAP KO animals died at the pupal stage from the failure of pupal ecdysis, whereas larval ecdysis and adult eclosion behaviors showed only subtle defects. Interestingly, the most severe failure seen at eclosion appeared to be in a function required for abdominal inflation, which could be cardioactive in nature. Although CCAP KO populations exhibited circadian eclosion rhythms, the daily distribution of eclosion events (i.e.,gating) was abnormal. Effects on the execution of ecdysis and its circadian regulation indicate that CCAP is a key regulator of the behavior. Nevertheless, an unexpected finding of this work is that the primary functions of CCAP as well as its importance in the control of ecdysis behaviors may change during the postembryonic development of Drosophila.

Published

2003

7. Genetic analysis of functional domains within the Drosophila LARK RNA-binding protein

Author

F. Rob Jackson, Andrew J. Schroeder, Gerard P. McNeil, and Mary A. Roberts

Subjects

Male, Time Factors, Mutant, Amino Acid Motifs, Immunoblotting, Molecular Sequence Data, Mutagenesis (molecular biology technique), RNA-binding protein, Biology, medicine.disease_cause, Epitopes, Sex Factors, Genetics, medicine, Animals, Drosophila Proteins, Amino Acid Sequence, Transgenes, Crosses, Genetic, Zinc finger, Mutation, RNA recognition motif, Models, Genetic, RNA-Binding Proteins, Phenotype, Immunohistochemistry, Circadian Rhythm, Protein Structure, Tertiary, Fertility, RNA, Drosophila, Female, Function (biology), Research Article, Protein Binding

Abstract

LARK is an essential Drosophila RNA-binding protein of the RNA recognition motif (RRM) class that functions during embryonic development and for the circadian regulation of adult eclosion. LARK protein contains three consensus RNA-binding domains: two RRM domains and a retroviral-type zinc finger (RTZF). To show that these three structural domains are required for function, we performed a site-directed mutagenesis of the protein. The analysis of various mutations, in vivo, indicates that the RRM domains and the RTZF are required for wild-type LARK functions. RRM1 and RRM2 are essential for viability, although interestingly either domain can suffice for this function. Remarkably, mutation of either RRM2 or the RTZF results in the same spectrum of phenotypes: mutants exhibit reduced viability, abnormal wing and mechanosensory bristle morphology, female sterility, and flightlessness. The severity of these phenotypes is similar in single mutants and double RRM2; RTZF mutants, indicating a lack of additivity for the mutations and suggesting that RRM2 and the RTZF act together, in vivo, to determine LARK function. Finally, we show that mutations in RRM1, RRM2, or the RTZF do not affect the circadian regulation of eclosion, and we discuss possible interpretations of these results. This genetic analysis demonstrates that each of the LARK structural domains functions in vivo and indicates a pleiotropic requirement for both the LARK RRM2 and RTZF domains.

Published

2001

8. A Timely Expression Profile

Author

F. Rob Jackson and Andrew J. Schroeder

Subjects

Genetics, biology, Gene Expression Profiling, Vertebrate, Cell Biology, Computational biology, General Biochemistry, Genetics and Molecular Biology, Molecular analysis, Circadian Rhythm, Expression (architecture), Gene Expression Regulation, Biological Clocks, biology.animal, Animals, RNA, DNA microarray, Animal species, Molecular Biology, Gene, Oligonucleotide Array Sequence Analysis, Developmental Biology

Abstract

Molecular genetic analysis has yielded a detailed mechanistic understanding of invertebrate and vertebrate circadian oscillators, but we still know little about how such molecular oscillators are connected to rhythmic physiological processes. Two recent papers in Cell and Neuron now address this scientific issue through the use of gene chip technology to identify clock-regulated genes in an animal species.