Your search keyword '"Otte, Marianne"' showing total 9 results

1. Recognition of polymorphic Csd proteins determines sex in the honeybee.

Author

Otte, Marianne, Netschitailo, Oksana, Weidtkamp-Peters, Stefanie, Seidel, Claus A. M., and Beye, Martin

Subjects

*GENETIC sex determination, *MICROSATELLITE repeats, *HONEYBEES, *FLUORESCENCE resonance energy transfer

Abstract

The article presents a study which examined whether two different complementary sex determiner (Csd) alleles are genetically essential and sufficient to activate the female pathway. Topics include the sufficiency of two different csd coding sequences to activate the female pathway, Csd protein variants that form trimeric complexes, and the role of the selective coiled-coil (CC) domain binding of Csd protein variants for female determination.

Published

2023

2. Multisite imaging of neural activity using a genetically encoded calcium sensor in the honey bee.

Author

Carcaud, Julie, Otte, Marianne, Grünewald, Bernd, Haase, Albrecht, Sandoz, Jean-Christophe, and Beye, Martin

Subjects

*HONEYBEES, *BEES, *CALCIUM, *INSECT behavior, *COGNITIVE ability, *CHEMICAL structure, *DETECTORS

Abstract

Understanding of the neural bases for complex behaviors in Hymenoptera insect species has been limited by a lack of tools that allow measuring neuronal activity simultaneously in different brain regions. Here, we developed the first pan-neuronal genetic driver in a Hymenopteran model organism, the honey bee, and expressed the calcium indicator GCaMP6f under the control of the honey bee synapsin promoter. We show that GCaMP6f is widely expressed in the honey bee brain, allowing to record neural activity from multiple brain regions. To assess the power of this tool, we focused on the olfactory system, recording simultaneous responses from the antennal lobe, and from the more poorly investigated lateral horn (LH) and mushroom body (MB) calyces. Neural responses to 16 distinct odorants demonstrate that odorant quality (chemical structure) and quantity are faithfully encoded in the honey bee antennal lobe. In contrast, odor coding in the LH departs from this simple physico-chemical coding, supporting the role of this structure in coding the biological value of odorants. We further demonstrate robust neural responses to several bee pheromone odorants, key drivers of social behavior, in the LH. Combined, these brain recordings represent the first use of a neurogenetic tool for recording large-scale neural activity in a eusocial insect and will be of utility in assessing the neural underpinnings of olfactory and other sensory modalities and of social behaviors and cognitive abilities. Eusocial insects such as the honey bees have higher cognitive abilities, but the study of their neural bases has been limited by a lack of tools. This study describes the development of a genetically-encoded calcium sensor and its use for tracking the transformation of odor representation in the olfactory pathways. [ABSTRACT FROM AUTHOR]

Published

2023

3. The strength of the HIV-1 3' splice sites affects Rev function.

Author

Kammler, Susanne, Otte, Marianne, Hauber, Ilona, Kjems, Jørgen, Hauber, Joachim, and Schaal, Heiner

Subjects

*HIV, *VIRAL proteins, *RNA splicing, *NUCLEOTIDE sequence, *MESSENGER RNA, *GLYCOPROTEINS

Abstract

Background: The HIV-1 Rev protein is a key component in the early to late switch in HIV-1 splicing from early intronless (e.g. tat, rev) to late intron-containing Rev-dependent (e.g. gag, vif, env) transcripts. Previous results suggested that cis-acting sequences and inefficient 5' and 3' splice sites are a prerequisite for Rev function. However, we and other groups have shown that two of the HIV-1 5' splice sites, D1 and D4, are efficiently used in vitro and in vivo. Here, we focus on the efficiency of the HIV-1 3' splice sites taking into consideration to what extent their intrinsic efficiencies are modulated by their downstream cis-acting exonic sequences. Furthermore, we delineate their role in RNA stabilization and Rev function. Results: In the presence of an efficient upstream 5' splice site the integrity of the 3' splice site is not essential for Rev function whereas an efficient 3' splice site impairs Rev function. The detrimental effect of a strong 3' splice site on the amount of Rev-dependent intron-containing HIV-1 glycoprotein coding (env) mRNA is not compensatable by weakening the strength of the upstream 5' splice site. Swapping the HIV-1 3' splice sites in an RRE-containing minigene, we found a 3' splice site usage which was variably dependent on the presence of the usual downstream exonic sequence. The most evident activation of 3' splice site usage by its usual downstream exonic sequence was observed for 3' splice site A1 which was turned from an intrinsic very weak 3' splice site into the most active 3' splice site, even abolishing Rev activity. Performing pull-down experiments with nuclear extracts of HeLa cells we identified a novel ASF/SF2-dependent exonic splicing enhancer (ESE) within HIV-1 exon 2 consisting of a heptameric sequence motif occurring twice (M1 and M2) within this short non-coding leader exon. Single point mutation of M1 within an infectious molecular clone is detrimental for HIV-1 exon 2 recognition without affecting Rev-dependent vif expression. Conclusion: Under the conditions of our assay, the rate limiting step of retroviral splicing, competing with Rev function, seems to be exclusively determined by the functional strength of the 3' splice site. The bipartite ASF/SF2-dependent ESE within HIV-1 exon 2 supports cross-talk between splice site pairs across exon 2 (exon definition) which is incompatible with processing of the intron-containing vif mRNA. We propose that Rev mediates a switch from exon to intron definition necessary for the expression of all intron-containing mRNAs. [ABSTRACT FROM AUTHOR]

Published

2006

4. A genetic switch for worker nutrition-mediated traits in honeybees.

Author

Roth, Annika, Vleurinck, Christina, Netschitailo, Oksana, Bauer, Vivien, Otte, Marianne, Beye, Martin, Kaftanoglu, Osman, and Page, Robert E.

Subjects

*HONEYBEE genetics, *DIMORPHISM in animals, *NUTRITION, *INSECT phenology, *CRISPRS, *MUTANT proteins, *INSECTS

Abstract

Highly social insects are characterized by caste dimorphism, with distinct size differences of reproductive organs between fertile queens and the more or less sterile workers. An abundance of nutrition or instruction via diet-specific compounds has been proposed as explanations for the nutrition-driven queen and worker polyphenism. Here, we further explored these models in the honeybee (Apis mellifera) using worker nutrition rearing and a novel mutational screening approach using the clustered regularly interspaced short palindromic repeats/CRISPR-associated protein 9 (CRISPR/Cas9) method. The worker nutrition-driven size reduction of reproductive organs was restricted to the female sex, suggesting input from the sex determination pathway. Genetic screens on the sex determination genes in genetic females for size polyphenism revealed that doublesex (dsx) mutants display size-reduced reproductive organs irrespective of the sexual morphology of the organ tissue. In contrast, feminizer (fem) mutants lost the response to worker nutrition-driven size control. The first morphological worker mutants in honeybees demonstrate that the response to nutrition relies on a genetic program that is switched "ON" by the fem gene. Thus, the genetic instruction provided by the fem gene provides an entry point to genetically dissect the underlying processes that implement the size polyphenism. [ABSTRACT FROM AUTHOR]

Published

2019

5. A genetic switch for worker nutrition-mediated traits in honeybees.

Author

Roth, Annika, Vleurinck, Christina, Netschitailo, Oksana, Bauer, Vivien, Otte, Marianne, Kaftanoglu, Osman, Page, Robert E., and Beye, Martin

Subjects

*QUEEN honeybees, *GENETIC sex determination, *HONEYBEES, *WORKER honeybees, *INSECT societies, *SEX determination, *NUTRITION

Abstract

Highly social insects are characterized by caste dimorphism, with distinct size differences of reproductive organs between fertile queens and the more or less sterile workers. An abundance of nutrition or instruction via diet-specific compounds has been proposed as explanations for the nutrition-driven queen and worker polyphenism. Here, we further explored these models in the honeybee (Apis mellifera) using worker nutrition rearing and a novel mutational screening approach using the clustered regularly interspaced short palindromic repeats/CRISPR-associated protein 9 (CRISPR/Cas9) method. The worker nutrition-driven size reduction of reproductive organs was restricted to the female sex, suggesting input from the sex determination pathway. Genetic screens on the sex determination genes in genetic females for size polyphenism revealed that doublesex (dsx) mutants display size-reduced reproductive organs irrespective of the sexual morphology of the organ tissue. In contrast, feminizer (fem) mutants lost the response to worker nutrition-driven size control. The first morphological worker mutants in honeybees demonstrate that the response to nutrition relies on a genetic program that is switched "ON" by the fem gene. Thus, the genetic instruction provided by the fem gene provides an entry point to genetically dissect the underlying processes that implement the size polyphenism. In honeybees, nutrition drives dimorphic size development of reproductive organs in fertile queens and sterile workers. A study using the first induced morphological mutants in honeybees demonstrates that this developmental plasticity requires a genetic program that is switched on by the "feminizer" gene. Author summary: In honeybees, nutrition drives dimorphic size development of reproductive organs in fertile queens and sterile workers. The first induced morphological mutants in honeybees demonstrate that this developmental plasticity requires a genetic program that is switched "ON" by the feminizer (fem) gene. [ABSTRACT FROM AUTHOR]

Published

2019

6. Behavioral and molecular studies of quantitative differences in hygienic behavior in honeybees.

Author

Gempe, Tanja, Stach, Silke, Bienefeld, Kaspar, Otte, Marianne, and Beye, Martin

Subjects

*VARROA destructor, *VARROA disease, *HONEYBEE diseases, *HONEYBEE behavior, *GENE expression, *QUANTITATIVE genetics

Abstract

Background: Hygienic behavior (HB) enables honeybees to tolerate parasites, including infection with the parasitic mite Varroa destructor, and it is a well-known example of a quantitative genetic trait. The understanding of the molecular processes underpinning the quantitative differences in this behavior remains limited. Results: We performed gene expression studies in worker bees that displayed quantitative genetic differences in HB. We established a high and low genetic source of HB performance and studied the engagements into HB of single worker bees under the same environmental conditions. We found that the percentage of worker bees that engaged in a hygienic behavioral task tripled in the high versus low HB sources, thus suggesting that genetic differences may mediate differences in stimulated states to perform HB. We found 501 differently expressed genes (DEGs) in the brains of hygienic and non-hygienic performing workers in the high HB source bees, and 342 DEGs in the brains of hygienic performing worker bees, relative to the gene expression in non-hygienic worker bees from the low HB source group. "Cell surface receptor ligand signal transduction" in the high and "negative regulation of cell communication" in the low HB source were overrepresented molecular processes, suggesting that these molecular processes in the brain may play a role in the regulation of quantitative differences in HB. Moreover, only 21 HB-associated DEGs were common between the high and low HB sources. Conclusions: The better HB colony performance is primarily achieved by a high number of bees engaging in the hygienic tasks that associate with distinct molecular processes in the brain. We propose that different gene products and pathways may mediate the quantitative genetic differences of HB. [ABSTRACT FROM AUTHOR]

Published

2016

7. HEXploring of the HIV-1 genome allows landscaping of new potential splicing regulatory elements.

Author

Erkelenz, Steffen, Theiss, Stephan, Otte, Marianne, Widera, Marek, Peter, Jan Otto, and Schaal, Heiner

Subjects

*HIV infection genetics, *AIDS treatment, *GENETIC regulation

Abstract

An abstract on a study that examines the splicing regulatory property of the novel HEXploring of HIV-1 genome is presented.

Published

2013

8. Sex Determination in Honeybees: Two Separate Mechanisms Induce and Maintain the Female Pathway.

Author

Gempe, Tanja, Hasselmann, Martin, Schiøtt, Morten, Hause, Gerd, Otte, Marianne, and Beye, Martin

Subjects

*HONEYBEES, *HETEROZYGOSITY, *GENETIC carriers, *INTERSEXUALITY in animals, *ANIMAL morphology, *GENETIC sex determination

Abstract

Organisms have evolved a bewildering diversity of mechanisms to generate the two sexes. The honeybee (Apis mellifera) employs an interesting system in which sex is determined by heterozygosity at a single locus (the Sex Determination Locus) harbouring the complementary sex determiner (csd) gene. Bees heterozygous at Sex Determination Locus are females, whereas bees homozygous or hemizygous are males. Little is known, however, about the regulation that links sex determination to sexual differentiation. To investigate the control of sexual development in honeybees, we analyzed the functions and the regulatory interactions of genes involved in the sex determination pathway. We show that heterozygous csd is only required to induce the female pathway, while the feminizer (fem) gene maintains this decision throughout development. By RNAi induced knockdown we show that the fem gene is essential for entire female development and that the csd gene exclusively processes the heterozygous state. Fem activity is also required to maintain the female determined pathway throughout development, which we show by mosaic structures in fem-repressed intersexuals. We use expression of Fem protein in males to demonstrate that the female maintenance mechanism is controlled by a positive feedback splicing loop in which Fem proteins mediate their own synthesis by directing female fem mRNA splicing. The csd gene is only necessary to induce this positive feedback loop in early embryogenesis by directing splicing of fem mRNAs. Finally, fem also controls the splicing of Am-doublesex transcripts encoding conserved male- and female-specific transcription factors involved in sexual differentiation. Our findings reveal how the sex determination process is realized in honeybees differing from Drosophila melanogaster. [ABSTRACT FROM AUTHOR]

Published

2009

9. Evidence for the evolutionary nascence of a novel sex determination pathway in honeybees.

Author

Hasselmann, Martin, Gempe, Tanja, Schiøtt, Morten, Nunes-Silva, Carlos Gustavo, Otte, Marianne, and Beye, Martin

Subjects

*GENETIC sex determination, *HONEYBEES, *ALLELES, *SEX chromosomes, *DROSOPHILA melanogaster, *FRUIT flies, *AMINO acids, *RNA, *COMPLEMENTATION (Genetics)

Abstract

Sex determination in honeybees (Apis mellifera) is governed by heterozygosity at a single locus harbouring the complementary sex determiner (csd) gene, in contrast to the well-studied sex chromosome system of Drosophila melanogaster. Bees heterozygous at csd are females, whereas homozygotes and hemizygotes (haploid individuals) are males. Although at least 15 different csd alleles are known among natural bee populations, the mechanisms linking allelic interactions to switching of the sexual development programme are still obscure. Here we report a new component of the sex-determining pathway in honeybees, encoded 12 kilobases upstream of csd. The gene feminizer (fem) is the ancestrally conserved progenitor gene from which csd arose and encodes an SR-type protein, harbouring an Arg/Ser-rich domain. Fem shares the same arrangement of Arg/Ser- and proline-rich-domain with the Drosophila principal sex-determining gene transformer (tra), but lacks conserved motifs except for a 30-amino-acid motif that Fem shares only with Tra of another fly, Ceratitis capitata. Like tra, the fem transcript is alternatively spliced. The male-specific splice variant contains a premature stop codon and yields no functional product, whereas the female-specific splice variant encodes the functional protein. We show that RNA interference (RNAi)-induced knockdowns of the female-specific fem splice variant result in male bees, indicating that the fem product is required for entire female development. Furthermore, RNAi-induced knockdowns of female allelic csd transcripts result in the male-specific fem splice variant, suggesting that the fem gene implements the switch of developmental pathways controlled by heterozygosity at csd. Comparative analysis of fem and csd coding sequences from five bee species indicates a recent origin of csd in the honeybee lineage from the fem progenitor and provides evidence for positive selection at csd accompanied by purifying selection at fem. The fem locus in bees uncovers gene duplication and positive selection as evolutionary mechanisms underlying the origin of a novel sex determination pathway. [ABSTRACT FROM AUTHOR]

Published

2008