scholarly journals tarsal-less is expressed as a gap gene but has no gap gene phenotype in the moth midge Clogmia albipunctata

2018 ◽  
Author(s):  
Eva Jiménez-Guri ◽  
Karl R. Wotton ◽  
Johannes Jaeger
Keyword(s):  
Gene Expression ◽  
Drosophila Melanogaster ◽  
Rna Interference ◽  
Gap Gene ◽  
Gap Genes ◽  
Subtle Effect ◽  
Bona Fide ◽  
Vinegar Fly ◽  
Clogmia Albipunctata ◽  
Overlapping Domains

AbstractGap genes are involved in segment determination during early development of the vinegar fly Drosophila melanogaster and other dipteran insects (flies, midges, and mosquitoes). They are expressed in overlapping domains along the antero-posterior (A–P) axis of the blastoderm embryo. While gap domains cover the entire length of the A–P axis in Drosophila, there is a region in the blastoderm of the moth midge Clogmia albipunctata, which lacks canonical gap gene expression. Is a non-canonical gap gene functioning in this area? Here, we characterize tarsal-less (tal) in C. albipunctata. The homolog of tal in the flour beetle Tribolium castaneum (called milles-pattes, mlpt) is a bona fide gap gene. We find that Ca-tal is expressed in the region previously reported as lacking gap gene expression. Using RNA interference, we study the interaction of Ca-tal with gap genes. We show that Ca-tal is regulated by gap genes, but only has a very subtle effect on tailless (Catll), while not affecting other gap genes at all. Moreover, cuticle phenotypes of Ca-tal depleted embryos do not show any gap phenotype. We conclude that Ca-tal is expressed and regulated like a gap gene, but does not function as a gap gene in C. albipunctata.

scholarly journals tarsal-less is expressed as a gap gene but has no gap gene phenotype in the moth midge Clogmia albipunctata

2018 ◽  
Vol 5 (8) ◽  
pp. 180458 ◽  
Author(s):  
Eva Jiménez-Guri ◽  
Karl R. Wotton ◽  
Johannes Jaeger
Keyword(s):  
Gene Expression ◽  
Drosophila Melanogaster ◽  
Rna Interference ◽  
Gap Gene ◽  
Gap Genes ◽  
Subtle Effect ◽  
Bona Fide ◽  
Vinegar Fly ◽  
Clogmia Albipunctata ◽  
Overlapping Domains

Gap genes are involved in segment determination during early development of the vinegar fly Drosophila melanogaster and other dipteran insects (flies, midges and mosquitoes). They are expressed in overlapping domains along the antero-posterior (A–P) axis of the blastoderm embryo. While gap domains cover the entire length of the A–P axis in Drosophila, there is a region in the blastoderm of the moth midge Clogmia albipunctata , which lacks canonical gap gene expression. Is a non-canonical gap gene functioning in this area? Here, we characterize tarsal-less ( tal ) in C. albipunctata . The homologue of tal in the flour beetle Tribolium castaneum (called milles-pattes, mlpt ) is a bona fide gap gene. We find that Ca-tal is expressed in the region previously reported as lacking gap gene expression. Using RNA interference, we study the interaction of Ca-tal with gap genes. We show that Ca-tal is regulated by gap genes, but only has a very subtle effect on tailless (Ca-tll), while not affecting other gap genes at all. Moreover, cuticle phenotypes of Ca-tal depleted embryos do not show any gap phenotype. We conclude that Ca-tal is expressed and regulated like a gap gene, but does not function as a gap gene in C. albipunctata .

Mutually repressive interactions between the gap genes giant and Kruppel define middle body regions of the Drosophila embryo

Development ◽  
1991 ◽  
Vol 111 (2) ◽  
pp. 611-621 ◽  
Author(s):  
R. Kraut ◽  
M. Levine
Keyword(s):  
Gene Expression ◽  
Weak Interactions ◽  
Ectopic Expression ◽  
Early Embryo ◽  
Drosophila Embryo ◽  
Regulatory Interactions ◽  
Gap Gene ◽  
Gap Genes ◽  
Body Regions ◽  
Bona Fide

The gap genes play a key role in establishing pair-rule and homeotic stripes of gene expression in the Drosophila embryo. There is mounting evidence that overlapping gradients of gap gene expression are crucial for this process. Here we present evidence that the segmentation gene giant is a bona fide gap gene that is likely to act in concert with hunchback, Kruppel and knirps to initiate stripes of gene expression. We show that Kruppel and giant are expressed in complementary, non-overlapping sets of cells in the early embryo. These complementary patterns depend on mutually repressive interactions between the two genes. Ectopic expression of giant in early embryos results in the selective repression of Kruppel, and advanced-stage embryos show cuticular defects similar to those observed in Kruppel- mutants. This result and others suggest that the strongest regulatory interactions occur among those gap genes expressed in nonadjacent domains. We propose that the precisely balanced overlapping gradients of gap gene expression depend on these strong regulatory interactions, coupled with weak interactions between neighboring genes.

scholarly journals Dynamic Maternal Gradients Control Timing and Shift-Rates forDrosophilaGap Gene Expression

2016 ◽  
Author(s):  
Berta Verd ◽  
Anton Crombach ◽  
Johannes Jaeger
Keyword(s):  
Gene Expression ◽  
Gene Regulation ◽  
Drosophila Melanogaster ◽  
Pattern Formation ◽  
Dynamic Process ◽  
Gene Expression Pattern ◽  
The Body ◽  
Transient Dynamics ◽  
Gap Gene ◽  
Gap Genes

AbstractPattern formation during development is a highly dynamic process. In spite of this, few experimental and modelling approaches take into account the explicit time-dependence of the rules governing regulatory systems. We address this problem by studying dynamic morphogen interpretation by the gap gene network inDrosophila melanogaster. Gap genes are involved in segment determination during early embryogenesis. They are activated by maternal morphogen gradients encoded bybicoid (bcd)andcaudal (cad). These gradients decay at the same time-scale as the establishment of the antero-posterior gap gene pattern. We use a reverse-engineering approach, based on data-driven regulatory models called gene circuits, to isolate and characterise the explicitly time-dependent effects of changing morphogen concentrations on gap gene regulation. To achieve this, we simulate the system in the presence and absence of dynamic gradient decay. Comparison between these simulations reveals that maternal morphogen decay controls the timing and limits the rate of gap gene expression. In the anterior of the embyro, it affects peak expression and leads to the establishment of smooth spatial boundaries between gap domains. In the posterior of the embryo, it causes a progressive slow-down in the rate of gap domain shifts, which is necessary to correctly position domain boundaries and to stabilise the spatial gap gene expression pattern. We use a newly developed method for the analysis of transient dynamics in non-autonomous (time-variable) systems to understand the regulatory causes of these effects. By providing a rigorous mechanistic explanation for the role of maternal gradient decay in gap gene regulation, our study demonstrates that such analyses are feasible and reveal important aspects of dynamic gene regulation which would have been missed by a traditional steady-state approach. More generally, it highlights the importance of transient dynamics for understanding complex regulatory processes in development.Author SummaryAnimal development is a highly dynamic process. Biochemical or environmental signals can cause the rules that shape it to change over time. We know little about the effects of such changes. For the sake of simplicity, we usually leave them out of our models and experimental assays. Here, we do exactly the opposite. We characterise precisely those aspects of pattern formation caused by changing signalling inputs to a gene regulatory network, the gap gene system ofDrosophila melanogaster. Gap genes are involved in determining the body segments of flies and other insects during early development. Gradients of maternal morphogens activate the expression of the gap genes. These gradients are highly dynamic themselves, as they decay while being read out. We show that this decay controls the peak concentration of gap gene products, produces smooth boundaries of gene expression, and slows down the observed positional shifts of gap domains in the posterior of the embryo, thereby stabilising the spatial pattern. Our analysis demonstrates that the dynamics of gene regulation not only affect the timing, but also the positioning of gene expression. This suggests that we must pay closer attention to transient dynamic aspects of development than is currently the case.

scholarly journals A damped oscillator imposes temporal order on posterior gap gene expression inDrosophila

2016 ◽  
Author(s):  
Berta Verd ◽  
Erik Clark ◽  
Karl R. Wotton ◽  
Hilde Janssens ◽  
Eva Jiménez-Guri ◽  
...  
Keyword(s):  
Drosophila Melanogaster ◽  
Surprising Result ◽  
Evolutionary Transitions ◽  
Body Segments ◽  
Gap Gene ◽  
Gap Genes ◽  
Regulatory Cascade ◽  
Vinegar Fly ◽  
Sequential Mode ◽  
Damped Oscillator

AbstractInsects determine their body segments in two different ways. Short-germband insects, such as the flour beetleTribolium castaneum, use a molecular clock to establish segments sequentially. In contrast, long-germband insects, such as the vinegar flyDrosophila melanogaster, determine all segments simultaneously through a hierarchical cascade of gene regulation. Gap genes constitute the first layer of theDrosophilasegmentation gene hierarchy, downstream of maternal gradients such as that of Caudal (Cad). We use data-driven mathematical modelling and phase space analysis to show that shifting gap domains in the posterior half of theDrosophilaembryo are an emergent property of a robust damped oscillator mechanism, suggesting that the regulatory dynamics underlying long- and short-germband segmentation are much more similar than previously thought. InTribolium, Cad has been proposed to modulate the frequency of the segmentation oscillator. Surprisingly, our simulations and experiments show that the shift rate of posterior gap domains is independent of maternal Cad levels inDrosophila. Our results suggest a novel evolutionary scenario for the short- to long-germband transition, and help explain why this transition occurred convergently multiple times during the radiation of the holometabolan insects.Author summaryDifferent insect species exhibit one of two distinct modes of determining their body segments during development: they either use a molecular oscillator to position segments sequentially, or they generate segments simultaneously through a hierarchical gene-regulatory cascade. The sequential mode is ancestral, while the simultaneous mode has been derived from it independently several times during evolution. In this paper, we present evidence which suggests that simultaneous segmentation also involves an oscillator in the posterior of the embryo of the vinegar fly,Drosophila melanogaster. This surprising result indicates that both modes of segment determination are much more similar than previously thought. Such similarity provides an important step towards explaining the frequent evolutionary transitions between sequential and simultaneous segmentation.

scholarly journals The neuroblast timer gene nubbin exhibits functional redundancy with gap genes to regulate segment identity in Tribolium

2021 ◽  
Author(s):  
Olivia R A Tidswell ◽  
Matthew A Benton ◽  
Michael E Akam
Keyword(s):  
Gene Expression ◽  
Regulatory Network ◽  
Gene Network ◽  
In Situ Hybridisation ◽  
Hox Gene ◽  
Gap Gene ◽  
Gap Genes ◽  
Sequential Mode ◽  
And Function

In Drosophila, segmentation genes of the gap class form a regulatory network that positions segment boundaries and assigns segment identities. This gene network shows striking parallels with another gene network known as the neuroblast timer series. The neuroblast timer genes hunchback, Krüppel, nubbin, and castor are expressed in temporal sequence in neural stem cells to regulate the fate of their progeny. These same four genes are expressed in corresponding spatial sequence along the Drosophila blastoderm. The first two, hunchback and Krüppel, are canonical gap genes, but nubbin and castor have limited or no roles in Drosophila segmentation. Whether nubbin and castor regulate segmentation in insects with the ancestral, sequential mode of segmentation remains largely unexplored. We have investigated the expression and functions of nubbin and castor during segment patterning in the sequentially-segmenting beetle Tribolium. Using multiplex fluorescent in situ hybridisation, we show that Tc-hunchback, Tc-Krüppel, Tc-nubbin and Tc-castor are expressed sequentially in the segment addition zone of Tribolium, in the same order as they are expressed in Drosophila neuroblasts. Furthermore, simultaneous disruption of multiple genes reveals that Tc-nubbin regulates segment identity, but does so redundantly with two previously described gap/gap-like genes, Tc-giant and Tc-knirps. Knockdown of two or more of these genes results in the formation of up to seven pairs of ectopic legs on abdominal segments. We show that this homeotic transformation is caused by loss of abdominal Hox gene expression, likely due to expanded Tc-Krüppel expression. Our findings support the theory that the neuroblast timer series was co-opted for use in insect segment patterning, and contribute to our growing understanding of the evolution and function of the gap gene network outside of Drosophila.

scholarly journals Gap genes are involved in inviability in hybrids between Drosophila melanogaster and D. santomea

2021 ◽  
Author(s):  
Wenhan Chang ◽  
Martin Kreitman ◽  
Daniel R. Matute
Keyword(s):  
Drosophila Melanogaster ◽  
Gene Network ◽  
Developmental Process ◽  
Coding Region ◽  
Pure Species ◽  
Closely Related Species ◽  
Hybrid Inviability ◽  
Gap Gene ◽  
Gap Genes ◽  
Anterior Posterior

ABSTRACTEvolved changes within species lead to the inevitable loss of viability in hybrids. Inviability is also a convenient phenotype to genetically map and validate functionally divergent genes and pathways differentiating closely related species. Here we identify the Drosophila melanogaster form of the highly conserved essential gap gene giant (gt) as a key genetic determinant of hybrid inviability in crosses with D. santomea. We show that the coding region of this allele in D. melanogaster/D. santomea hybrids is sufficient to cause embryonic inviability not seen in either pure species. Further genetic analysis indicates that tailless (tll), another gap gene, is also involved in the hybrid defects. giant and tll are both members of the gap gene network of transcription factors that participate in establishing anterior-posterior specification of the dipteran embryo, a highly conserved developmental process. Genes whose outputs in this process are functionally conserved nevertheless evolve over short timescales to cause inviability in hybrids.

scholarly journals Speeding up anterior-posterior patterning of insects by differential initialization of the gap gene cascade

2018 ◽  
Author(s):  
Heike Rudolf ◽  
Christine Zellner ◽  
Ezzat El-Sherif
Keyword(s):  
Gene Expression ◽  
Drosophila Melanogaster ◽  
Fruit Fly ◽  
Red Flour Beetle ◽  
Evolutionary Transition ◽  
Gap Gene ◽  
Sequential Mode ◽  
Patterning Genes ◽  
Computational Analyses ◽  
Anterior Posterior

AbstractRecently, it was shown that anterior-posterior patterning genes in the red flour beetle Tribolium castaneum are expressed sequentially in waves. However, in the fruit fly Drosophila melanogaster, an insect with a derived mode of embryogenesis compared to Tribolium, anterior-posterior patterning genes quickly and simultaneously arise as mature gene expression domains that, afterwards, undergo slight posterior-to-anterior shifts. This raises the question of how a fast and simultaneous mode of patterning, like that of Drosophila, could have evolved from a rather slow sequential mode of patterning, like that of Tribolium. In this paper, we elucidate a mechanism for this evolutionary transition based on a switch from a uniform to a gradient-mediated initialization of the gap gene cascade by maternal Hb. The model is supported by computational analyses and experiments.

scholarly journals An efficient gene regulatory network inference algorithm for early Drosophila melanogaster embryogenesis

2017 ◽  
Author(s):  
Hirotaka Matsumoto ◽  
Hisanori Kiryu ◽  
Yasuhiro Kojima ◽  
Suguru Yaginuma ◽  
Itoshi Nikaido
Keyword(s):  
Drosophila Melanogaster ◽  
Regulatory Network ◽  
Efficient Algorithm ◽  
Large Scale ◽  
Gap Gene ◽  
Large Scale Data ◽  
Gap Genes ◽  
Simulation Based ◽  
Gene Regulatory ◽  
Scale Data

AbstractThe spatial patterns of gene expression in early Drosophila melanogaster embryogenesis have been studied experimentally and theoretically to reveal the molecular basis of morphogenesis. In particular, the gene regulatory network (GRN) of gap genes has been investigated through mathematical modeling and simulation. Although these simulation-based approaches are useful for describing complex dynamics and have revealed several important regulations in spatial patterning, they are computationally intensive because they optimize GRN with iterative simulation. Recently, the advance of experimental technologies is enabling the acquisition of comprehensive spatial expression data, and an efficient algorithm will be necessary to analyze such large-scale data. In this research, we developed an efficient algorithm to infer the GRN based on a linear reaction-diffusion model. First, we qualitatively analyzed the GRNs of gap genes and pair-rule genes based on our algorithm and showed that two mutual repressions are fundamental regulations. Then, we inferred the GRN from gap gene data, and identified asymmetric regulations in addition to the two mutual repressions. We analyzed the effect of these asymmetric regulations on spatial patterns, and showed that they have the potential to adjust peak position. Our algorithm runs in sub-second time, which is significantly smaller than the runtime of simulation-based approaches (between 8 and 160 h, for exmaple). Neverthe-less, our inferred GRN was highly correlated with the simulation-based GRNs. We also analyzed the gap gene network of Clogmia albipunctata and showed that different mutual repression regulations might be important in comparison with those of Drosophila melanogaster. As our algorithm can infer GRNs efficiently and can be applied to several different network analysis, it will be a valuable approach for analyzing large-scale data.

Segmental polarity and identity in the abdomen of Drosophila is controlled by the relative position of gap gene expression

Development ◽  
1989 ◽  
Vol 107 (Supplement) ◽  
pp. 21-29 ◽  
Author(s):  
Ruth Lehmann ◽  
Hans Georg Frohnhöfer
Keyword(s):  
Gene Expression ◽  
Relative Concentration ◽  
Posterior Pole ◽  
Drosophila Embryo ◽  
Gene Products ◽  
Gap Gene ◽  
Gap Genes ◽  
Posterior Group ◽  
Pole Plasm ◽  
Maternal Gene

The establishment of the segmental pattern in the Drosophila embryo is directed by three sets of maternal genes: the anterior, the terminal and the posterior group of genes. Embryos derived from females mutant for one of the posterior group genes lack abdominal segmentation. This phenotype can be rescued by transplantation of posterior pole plasm into the abdominal region of mutant embryos. We transplanted posterior pole plasm into the middle of embryos mutant either for the posterior, the anterior and posterior, or all three maternal systems and monitored the segmentation pattern as well as the expression of the zygotic gap gene Krüppel in control and injected embryos. We conclude that polarity and identity of the abdominal segments do not depend on the relative concentration of posterior activity but rather on the position of gap gene expression. By changing the pattern of gap gene expression, the orientation of the abdomen can be reversed. These experiments suggest that maternal gene products act in a strictly hierarchical manner. The function of the maternal gene products becomes dispensable once the position of the zygotically expressed gap genes is determined. Subsequently the gap genes will control the pattern of the pair-rule and segment polarity genes.

The zygotic control of Drosophila pair-rule gene expression. II. Spatial repression by gap and pair-rule gene products

Development ◽  
1989 ◽  
Vol 107 (3) ◽  
pp. 673-683 ◽  
Author(s):  
S.B. Carroll ◽  
S.H. Vavra
Keyword(s):  
Gene Expression ◽  
Expression Patterns ◽  
Control Mechanisms ◽  
Gap Gene ◽  
Gap Genes ◽  
Gene Mutant ◽  
Pair Rule Gene ◽  
Regulatory Effects ◽  
Pair Rule ◽  
Zygotic Control

We examined gene expression patterns in certain single and double pair-rule mutant embryos to determine which of the largely repressive pair-rule gene interactions are most likely to be direct and which interactions are probably indirect. From these studies we conclude that: (i) hairy+ and even-skipped (eve+) regulate the fushi tarazu (ftz) gene; (ii) eve+ and runt+ regulate the hairy gene; (iii) runt+ regulates the eve gene; but, (iv) runt does not regulate the ftz gene pattern, and hairy does not regulate the eve gene pattern. These pair-rule interactions are not sufficient, however, to explain the periodicity of the hairy and eve patterns, so we examined specific gap gene mutant combinations to uncover their regulatory effects on these two genes. Our surprising observation is that the hairy and eve genes are expressed in embryos where the three key gap genes hunchback (hb), Kruppel (Kr), and knirps (kni) have been removed, indicating that these gap genes are not essential to activate the pair-rule genes. In fact, we show that in the absence of either hb+ or kni+, or both gap genes, the Kr+ product represses hairy expression. These results suggest that gap genes repress hairy expression in the interstripe regions, rather than activate hairy expression in the stripes. The molecular basis of pair-rule gene regulation by gap genes must involve some dual control mechanisms such that combinations of gap genes affect pair-rule transcription in a different manner than a single gap gene.

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