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104. even-skipped is not a pair-rule gene but has segmental and gap-like functions in Oncopeltus fasciatus, an intermediate germband insect.

Author

Liu, Paul Z. and Kaufman, Thomas C.

Subjects
*DROSOPHILA, *GENES, *BIOLOGICAL evolution, *INSECTS, *GENE expression, *ONCOPELTUS
Abstract

The pair-rule gene even-skipped is required for the initiation of metameric pattern in Drosophila. But Drosophila segmentation is evolutionarily derived and is not representative of most insects. Therefore, in order to shed light on the evolution of insect segmentation, homologs of the pair-rule gene even-skipped have been studied in several insect taxa. However, most of these studies have reported the expression eve but not its function. We report the isolation, expression and function of the homolog of Drosophila even-skipped from the intermediate germband insect Oncopeltus fasciatus. We find that in Oncopeltus, even-skipped striped expression initiates in a segmental and not pair-rule pattern. Weak RNAi suppression of Oncopeltus even-skipped shows no apparent pair-rule like phenotype, while stronger RNAi suppression shows deletion of nearly the entire body. These results suggest that in Oncopeltus, even-skipped is not acting as a pair-rule gene. In almost all insects, prior to its striped expression, even-skipped is expressed in a conserved broad gap-like domain but its function has been largely ignored. We find that this early broad domain is required for activation of the gap genes hunchback and Krüppel. Given the large RNAi deletion phenotype and its regulation of hunchback and Krüppel, even-skipped seems to act as an über-gap gene in Oncopeltus, indicating that it may have both upstream and downstream roles in segmentation. [ABSTRACT FROM AUTHOR]

Published
2005
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106. Expression patterns of the rogue Hox genesHox3/zenandfushi tarazuin the apterygote insectThermobia domestica.

Author

Hughes, Cynthia L., Liu, Paul Z., and Kaufman, Thomas C.

Subjects
GENES, VERTEBRATES, INVERTEBRATES, CONSERVATION biology, HOMEOBOX genes, DROSOPHILA melanogaster
Abstract

Many embryonic patterning genes are remarkably conserved between vertebrates and invertebrates, and the Hox genes are paradigmatic examples of this conservation. Yet even Hox genes can change dramatically in evolution. Two genes in particular— Hox3andfushi tarazu—lost their ancestral roles as homeotic genes and play very different developmental roles in the fruit flyDrosophila melanogaster. TheDrosophila Hox3homologszerknülltandbicoidact in extraembryonic tissues and in establishment of the anteroposterior axis, respectively, whereasfushi tarazuacts in segmentation and neurogenesis. It would be valuable to know what mechanisms allowedHox3andftzto abandon their ancestral roles as homeotic genes and take on new roles. To explore the evolutionary transition of these genes, we analyzed their expression in a primitive insect, the firebratThermobia domestica. The expression patterns seem to represent a stage of evolution intermediate between the ancestral state seen in basal arthropods and the derived expression patterns inDrosophila. These expression data help us to narrow the period in which the gene transitions took place.Hox3appears to have evolved directly intozenwithin the insects, whereasftzseems to have adopted the expression patterns of a segmentation and neurogenesis gene earlier in the mandibulate arthropods. [ABSTRACT FROM AUTHOR]

Published
2004
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107. Krüppel is a gap gene in the intermediate germband insect Oncopeltus fasciatus and is required for development of both blastoderm and germband-derived segments.

Author

Liu, Paul Z. and Kaufman, Thomas C.

Subjects
*DROSOPHILA, *GENES, *INSECTS, *BLASTODERM, *EMBRYOLOGY, *DEVELOPMENTAL biology
Abstract

Segmentation in long germband insects such as Drosophila occurs essentially simultaneously across the entire body. A cascade of segmentation genes patterns the embryo along its anterior-posterior axis via subdivision of the blastoderm. This is in contrast to short and intermediate germband modes of segmentation where the anterior segments are formed during the blastoderm stage and the remaining posterior segments arise at later stages from a posterior growth zone. The biphasic character of segment generation in short and intermediate germ insects implies that different formative mechanisms may be operating in blastoderm-derived and germband-derived segments. In Drosophila, the gap gene Kriippel is required for proper formation of the central portion of the embryo. This domain of Krüppel activity in Drosophila corresponds to a region that in short and intermediate germband insects spans both blastoderm and germband-derived segments. We have cloned the Krüppel homolog from the milkweed bug, Oncopeltus fasciatus (Hemiptera, Lygaeidae), an intermediate germband insect. We find that Oncopeltus Krüppel is expressed in a gap-like domain in the thorax during the blastoderm and germband stages of embryogenesis. In order to investigate the function of Krüppel in Oncopeltus segmentation, we generated knockdown phenotypes using RNAi. Loss of Krüppel activity in Oncopeltus results in a large gap phenotype, with loss of the mesothoracic through fourth abdominal segments. Additionally, we find that Krüppel is required to suppress both anterior and posterior Hox gene expression in the central portion of the germband. Our results show that Krüppel is required for both blastoderm-derived and germband-derived segments and indicate that Krüppel function is largely conserved in Oncopeltus and Drosophila despite their divergent embryogenesis. [ABSTRACT FROM AUTHOR]

Published
2004
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108. Hox genes and the evolution of the arthropod body plan1.

Author

Hughes, Cynthia L. and Kaufman, Thomas C.

Subjects
*ARTHROPODA, *ANIMAL genetics, *BIOLOGICAL evolution
Abstract

SUMMARY In recent years researchers have analyzed the expression patterns of the Hox genes in a multitude of arthropod species, with the hope of understanding the mechanisms at work in the evolution of the arthropod body plan. Now, with Hox expression data representing all four major groups of arthropods (chelicerates, myriapods, crustaceans, and insects), it seems appropriate to summarize the results and take stock of what has been learned. In this review we summarize the expression and functional data regarding the 10 arthropod Hox genes: labial , proboscipedia , Hox3 / zen , Deformed , Sex combs reduced , fushi tarazu , Antennapedia , Ultrabithorax , abdominal-A , and Abdominal-B. In addition, we discuss mechanisms of developmental evolutionary change thought to be important for the emergence of novel morphological features within the arthropods. [ABSTRACT FROM AUTHOR]

Published
2002
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109. Hox genes and the evolution of the arthropod body plan1.

Author

Hughes, Cynthia L. and Kaufman, Thomas C.

Subjects
ARTHROPODA, ANIMAL genetics, BIOLOGICAL evolution
Abstract

SUMMARY In recent years researchers have analyzed the expression patterns of the Hox genes in a multitude of arthropod species, with the hope of understanding the mechanisms at work in the evolution of the arthropod body plan. Now, with Hox expression data representing all four major groups of arthropods (chelicerates, myriapods, crustaceans, and insects), it seems appropriate to summarize the results and take stock of what has been learned. In this review we summarize the expression and functional data regarding the 10 arthropod Hox genes: labial , proboscipedia , Hox3 / zen , Deformed , Sex combs reduced , fushi tarazu , Antennapedia , Ultrabithorax , abdominal-A , and Abdominal-B. In addition, we discuss mechanisms of developmental evolutionary change thought to be important for the emergence of novel morphological features within the arthropods. [ABSTRACT FROM AUTHOR]

Published
2002
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110. Embryonic expression patterns of the Hox genes of the crayfish Procambarus clarkii (Crustacea, Decapoda).

Author

Abzhanov, Arhat and Kaufman, Thomas C.

Subjects
*PROCAMBARUS clarkii, *HOMEOBOX genes, *GENE expression
Abstract

SUMMARY Higher crustaceans (class Malacostraca) represent the most species-rich and morphologically diverse group of non-insect arthropods. The superorders Eucarida and Peracarida, two large groups that separated over 350 million years ago, encompass most malacostracan diversity. Recently, the Hox genes of the peracarid woodlouse Porcellio scaber (Isopoda) were shown to be expressed in domains that coincide with morphological boundaries of body tagmata, which differ from those in insects (Abzhanov and Kaufman 1999a,b). Moreover, observed changes in Hox expression domains during ontogeny correlate with morphological remodeling, such as a transformation of the first thoracic leg into mouthpart maxillipeds, which occurs in the trunk of the embryo. Decapods have a different modification of the malacostracan bodyplan, with up to three pairs of maxillipeds and extensive fusion and cephalization of the thorax. Here we describe expression patterns of the trunk Hox genes Scr, Antp, Ubx, abd-A and cad in the eucarid crayfish Procambarus clarkii (Decapoda). We find that the crayfish expression patterns, for the most part, resemble those of the woodlouse Porcellio scaber (Isopoda), but are more modulated and complex. Nevertheless, as in Porcellio the boundaries of the Hox expression domains do correlate with morphological features and their modulations to transformations in the embryo. Thus we propose that the trunk Hox genes were likely important in the evolution of and currently play an essential role in the development of the complex decapod bodyplan. [ABSTRACT FROM AUTHOR]

Published
2000
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111. Comparative Analysis of the Transcriptome across Distant Species

Author

Gerstein, Mark B., Rozowsky, Joel, Yan, Koon-Kiu, Wang, Daifeng, Cheng, Chao, Brown, James B., Davis, Carrie A, Hillier, LaDeana, Sisu, Cristina, Li, Jingyi Jessica, Pei, Baikang, Harmanci, Arif O., Duff, Michael O., Djebali, Sarah, Alexander, Roger P., Alver, Burak H., Auerbach, Raymond, Bell, Kimberly, Bickel, Peter J., Boeck, Max E., Boley, Nathan P., Booth, Benjamin W., Cherbas, Lucy, Cherbas, Peter, Di, Chao, Dobin, Alex, Drenkow, Jorg, Ewing, Brent, Fang, Gang, Fastuca, Megan, Feingold, Elise A., Frankish, Adam, Gao, Guanjun, Good, Peter J., Guigó, Roderic, Hammonds, Ann, Harrow, Jen, Hoskins, Roger A., Howald, Cédric, Hu, Long, Huang, Haiyan, Hubbard, Tim J. P., Huynh, Chau, Jha, Sonali, Kasper, Dionna, Kato, Masaomi, Kaufman, Thomas C., Kitchen, Robert R., Ladewig, Erik, Lagarde, Julien, Lai, Eric, Leng, Jing, Lu, Zhi, MacCoss, Michael, May, Gemma, McWhirter, Rebecca, Merrihew, Gennifer, Miller, David M., Mortazavi, Ali, Murad, Rabi, Oliver, Brian, Olson, Sara, Park, Peter J., Pazin, Michael J., Perrimon, Norbert, Pervouchine, Dmitri, Reinke, Valerie, Reymond, Alexandre, Robinson, Garrett, Samsonova, Anastasia, Saunders, Gary I., Schlesinger, Felix, Sethi, Anurag, Slack, Frank J., Spencer, William C., Stoiber, Marcus H., Strasbourger, Pnina, Tanzer, Andrea, Thompson, Owen A., Wan, Kenneth H., Wang, Guilin, Wang, Huaien, Watkins, Kathie L., Wen, Jiayu, Wen, Kejia, Xue, Chenghai, Yang, Li, Yip, Kevin, Zaleski, Chris, Zhang, Yan, Zheng, Henry, Brenner, Steven E., Graveley, Brenton R., Celniker, Susan E., Gingeras, Thomas R, and Waterston, Robert

Published
2014
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113. Quantitative Proteomics of a Presymptomatic A53T -Synuclein Drosophila Model of Parkinson Disease

Author

Xun, Zhiyin, Sowell, Renã A., Kaufman, Thomas C., and Clemmer, David E.

Abstract

A global isotopic labeling strategy combined with multidimensional liquid chromatographies and tandem mass spectrometry was used for quantitative proteome analysis of a presymptomatic A53T -synuclein Drosophila model of Parkinson disease (PD). Multiple internal standard proteins at different concentration ratios were spiked into samples from PD-like and control animals to assess quantification accuracy. Two biological replicates isotopically labeled in forward and reverse directions were analyzed. A total of 253 proteins were quantified with a minimum of two identified peptide sequences (for each protein); 180 (∼71%) proteins were detected in both forward and reverse labeling measurements. Twenty-four proteins were differentially expressed in A53T -synuclein Drosophila; up-regulation of troponin T and down-regulation of fat body protein 1 were confirmed by Western blot analysis. Elevated expressions of heat shock protein 70 cognate 3 and ATP synthase are known to be directly involved in A53T -synuclein-mediated toxicity and PD; three up-regulated proteins (muscle LIM protein at 60A, manganese-superoxide dismutase, and troponin T) and two down-regulated proteins (chaoptin and retinal degeneration A) have literature-supported associations with cellular malfunctions. That these variations were observed in presymptomatic animals may shed light on the etiology of PD. Protein interaction network analysis indicated that seven proteins belong to a single network, which may provide insight into molecular pathways underlying PD. Gene Ontology analysis indicated that the dysregulated proteins are primarily associated with membrane, endoplasmic reticulum, actin cytoskeleton, mitochondria, and ribosome. These associations support prior findings in studies of the A30P -synuclein Drosophila model (Xun, Z. Y., Sowell, R. A., Kaufman, T. C., and Clemmer, D. E. (2007) Protein expression in a Drosophila model of Parkinson's disease. J. Proteome Res. 6, 348–357; Xun, Z. Y., Sowell, R. A., Kaufman, T. C., and Clemmer, D. E. (2007) Lifetime proteomic profiling of an A30P -synuclein Drosophila model of Parkinson's disease. J. Proteome Res. 6, 3729–3738) that defects in cellular components such as actin cytoskeleton and mitochondria may contribute to the development of later symptoms.

Published
2008

114. Quantitative Proteomics of a Presymptomatic A53T α-Synuclein DrosophilaModel of Parkinson Disease

Author

Xun, Zhiyin, Sowell, Renñ A., Kaufman, Thomas C., and Clemmer, David E.

Abstract

A global isotopic labeling strategy combined with multidimensional liquid chromatographies and tandem mass spectrometry was used for quantitative proteome analysis of a presymptomatic A53T α-synuclein Drosophilamodel of Parkinson disease (PD). Multiple internal standard proteins at different concentration ratios were spiked into samples from PD-like and control animals to assess quantification accuracy. Two biological replicates isotopically labeled in forward and reverse directions were analyzed. A total of 253 proteins were quantified with a minimum of two identified peptide sequences (for each protein); 180 (∼71%) proteins were detected in both forward and reverse labeling measurements. Twenty-four proteins were differentially expressed in A53T α-synuclein Drosophila; up-regulation of troponin T and down-regulation of fat body protein 1 were confirmed by Western blot analysis. Elevated expressions of heat shock protein 70 cognate 3 and ATP synthase are known to be directly involved in A53T α-synuclein-mediated toxicity and PD; three up-regulated proteins (muscle LIM protein at 60A, manganese-superoxide dismutase, and troponin T) and two down-regulated proteins (chaoptin and retinal degeneration A) have literature-supported associations with cellular malfunctions. That these variations were observed in presymptomatic animals may shed light on the etiology of PD. Protein interaction network analysis indicated that seven proteins belong to a single network, which may provide insight into molecular pathways underlying PD. Gene Ontology analysis indicated that the dysregulated proteins are primarily associated with membrane, endoplasmic reticulum, actin cytoskeleton, mitochondria, and ribosome. These associations support prior findings in studies of the A30P α-synuclein Drosophilamodel (Xun, Z. Y., Sowell, R. A., Kaufman, T. C., and Clemmer, D. E. (2007) Protein expression in a Drosophila model of Parkinson’s disease. J. Proteome Res.6, 348–357; Xun, Z. Y., Sowell, R. A., Kaufman, T. C., and Clemmer, D. E. (2007) Lifetime proteomic profiling of an A30P α-synuclein Drosophilamodel of Parkinson’s disease. J. Proteome Res.6, 3729–3738) that defects in cellular components such as actin cytoskeleton and mitochondria may contribute to the development of later symptoms.

Published
2008
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115. Cytological Investigation of the Mechanism of Parthenogenesis in Drosophila mercatorum

Author

Eisman, Robert C. and Kaufman, Thomas C.

Abstract

Thelytokous parthenogenesis (female progeny only) in animals is believed to arise initially in unfertilized eggs produced by bisexual females via the fusion of two haploid nuclei following meiosis, to produce diploid female progeny. The transition from sexual to parthenogenetic mechanisms of reproduction requires that the egg replace the paternal contributions of a haploid genetic complement and the basal body, which is thought to be essential for centrosome formation. The transitional facultative parthenogenetic stage is usually associated with a high rate of failed or abortive development, but the molecular and mechanistic reasons for this failure remain unclear. We show that a facultatively parthenogenetic strain of Drosophila mercatorum produces a high percentage of unfertilized eggs competent to restore diploidy and form centrosomes de novo following meiosis. The female meiotic products replicate and divide by an acentrosomal mechanism in most oocytes and cytoplasmic centrosomes form in 35% of the oocytes. However, after pronuclear replication the cytoplasmic centrosomes must "capture" two haploid nuclei in order to restore diploidy. In practice, this process frequently fails due to centrosome-mediated capture events of single or more than two haploid nuclei, as well as multiple nuclear capture events in a single embryo when excess free centrosomes are not inactivated following formation of the first zygotic nucleus. Additionally, as development proceeds, many of the centrosomes that initiate syncytial development do not remain functional, possibly due to centrosome maturation defects, and later stages of syncytial development fail. The combined effect of the high error rate associated with nuclear capture and the failure of centrosome maturation during later developmental prevents successful parthenogenesis in most of the eggs that initiate development. This shows that the high rate of failed development associated with the transition from sexual to parthenogenetic reproduction is limited by the low probability of the formation of a diploid zygotic nucleus with the correct complement of centrosomes in D. mercatorum.

Published
2007
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116. The Drosophila proboscis is specified by two Hox genes, proboscipedia and Sex combs reduced, via repression of leg and antennal appendage genes

Author

Abzhanov, Arhat, Holtzman, Stacy, and Kaufman, Thomas C.

Abstract

The proboscis is one of the most highly modified appendages in Drosophila melanogaster. However, the phenotypes of proboscipedia (pb) mutants, which transform the proboscis into leg or antenna, indicate a basic homology among these limbs. Recent genetic studies have revealed a developmental system for patterning appendages and identified several genes required for limb development. Among these are: extradenticle (exd), homothorax (hth), dachshund (dac), Distal-less (Dll) and spalt (sal). These limb genes have not been well studied in wild-type mouthparts and their role if any in this appendage is not well understood. Here we demonstrate that the homeotic gene products Proboscipedia (Pb) and Sex combs reduced (Scr) regulate the limb genes in the labial disc to give rise to a unique type of appendage, the proboscis. Pb inhibits exd, dac and sal expression and downregulates Dll. This observation explains the ability of Pb to inhibit the effects of ectopically expressed trunk Hox genes in the proboscis, to suppress leg identity in the trunk and to transform antenna to maxillary palp. Scr suppresses sal expression and also downregulates Dll in the labial discs; discs mutant for both pb and Scr give rise to complete antennae, further demonstrating appendage homology. In the labial disc, Pb positively regulates transcription of Scr, whereas in the embryo, Scr positively regulates pb. Additionally, our results suggests a revised fate map of the labial disc. We conclude that the proboscis constitutes a genetically distinct type of appendage whose morphogenesis does not require several important components of leg and/or antennal patterning systems, but retains distal segmental homology with these appendages.

Published
2001
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117. Homeotic Complex (Hox) gene regulation and homeosis in the mesoderm of the Drosophila melanogasterembryo: the roles of signal transduction and cell autonomous regulation

Author

Miller, David F.B., Holtzman, Stacy L., Kalkbrenner, Amy, and Kaufman, Thomas C.

Abstract

In this paper we evaluate homeosis and Homeotic Complex (Hox) regulatory hierarchies in the somatic and visceral mesoderm. We demonstrate that both Hox control of signal transduction and cell autonomous regulation are critical for establishing normal Hox expression patterns and the specification of segmental identity and morphology. We present data identifying novel regulatory interactions associated with the segmental register shift in Hox expression domains between the epidermis/somatic mesoderm and visceral mesoderm. A proposed mechanism for the gap between the expression domains of Sex combs reduced (Scr)and Antennapedia (Antp)in the visceral mesoderm is provided. Previously, Hox gene interactions have been shown to occur on multiple levels: direct cross-regulation, competition for binding sites at downstream targets and through indirect feedback involving signal transduction. We find that extrinsic specification of cell fate by signaling can be overridden by Hox protein expression in mesodermal cells and propose the term autonomic dominance for this phenomenon.

Published
2001
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118. Homologs of DrosophilaAppendage Genes in the Patterning of Arthropod Limbs

Author

Abzhanov, Arhat and Kaufman, Thomas C

Abstract

Studies of the genes involved in patterning the appendages of Drosophila melanogasterhave revealed a system of signaling and transcriptional regulation that is responsible for specifying the proximo-distal limb axis. Here we report the expression patterns of presumptive homologs of the Drosophila genes extradenticle, dachshund, nubbin, ventral veins lacking(a.k.a. Cf1-a), and Dllin the limbs of the woodlouse Porcellio scaberand the spider Steatoda triangulosa.Although the expression domains of the appendage genes roughly correspond to those of Drosophila, their relative positions and segmental affiliation are distinct. In addition, the expression patterns of the appendage genes allows a resolution of the segmental composition of different appendages within crustacean and spider embryos. We conclude that certain limb types, e.g., mouthparts, appear to be derived from a leg-like ground-plan via the elimination/fusion of the intermediate and distal podomeres. Moreover, we observe just such a modification during the transformation of the anterior legs into mouthparts in P. scaber.Although our data do not unequivocally resolve the question of homology of the arthropod leg segments, they do provide evidence for a single conserved proximo-distal patterning system in the development of noninsect arthropod limbs.

Published
2000
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119. RNAi analysis of Deformed, proboscipedia and Sex combs reduced in the milkweed bug Oncopeltus fasciatus: novel roles for Hox genes in the Hemipteran head

Author

Hughes, Cynthia L. and Kaufman, Thomas C.

Abstract

Insects have evolved a large variety of specialized feeding strategies, with a corresponding variability in mouthpart morphology. We have, however, little understanding of the developmental mechanisms that underlie this diversity. Until recently it was difficult to perform any analysis of gene function outside of the genetic model insects Drosophila melanogaster and Tribolium castaneum. In this paper, we report the use of dsRNA-mediated interference (RNAi) to dissect gene function in the development of the milkweed bug Oncopeltus fasciatus, which has specialized suctorial mouthparts. The Hox genes Deformed (Dfd), proboscipedia (pb) and Sex combs reduced (Scr) have previously been shown to be expressed in the gnathal appendages of this species. Strikingly, the milkweed bug was found to have an unusual expression pattern of pb. Here, by analyzing single and combination RNAi depletions, we find that Dfd, pb and Scr are used in the milkweed bug to specify the identity of the mouthparts. The exact roles of the genes, however, are different from what is known in the two genetic model insects. The maxillary appendages in the bug are determined by the activities of the genes Dfd and Scr, rather than Dfd and pb as in the fly and beetle. The mandibular appendages are specified by Dfd, but their unique morphology in Oncopeltus suggests that Dfd’s target genes are different. As in flies and beetles, the labium is specified by the combined activities of pb and Scr, but again, the function of pb appears to be different. Additionally, the regulatory control of pb by the other two genes seems to be different in the bug than in either of the other species. These novelties in Hox function, expression pattern and regulatory relationships may have been important for the evolution of the unique Hemipteran head.

Published
2000
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120. Crustacean (malacostracan) Hox genes and the evolution of the arthropod trunk

Author

Abzhanov, Arhat and Kaufman, Thomas C.

Abstract

Representatives of the Insecta and the Malacostraca (higher crustaceans) have highly derived body plans subdivided into several tagma, groups of segments united by a common function and/or morphology. The tagmatization of segments in the trunk, the part of the body between head and telson, in both lineages is thought to have evolved independently from ancestors with a distinct head but a homonomous, undifferentiated trunk. In the branchiopod crustacean, Artemia franciscana, the trunk Hox genes are expressed in broad overlapping domains suggesting a conserved ancestral state (Averof, M. and Akam, M. (1995) Nature 376, 420-423). In comparison, in insects, the Antennapedia-class genes of the homeotic clusters are more regionally deployed into distinct domains where they serve to control the morphology of the different trunk segments. Thus an originally Artemia-like pattern of homeotic gene expression has apparently been modified in the insect lineage associated with and perhaps facilitating the observed pattern of tagmatization. Since insects are the only arthropods with a derived trunk tagmosis tested to date, we examined the expression patterns of the Hox genes Antp, Ubx and abd-A in the malacostracan crustacean Porcellio scaber (Oniscidae, Isopoda). We found that, unlike the pattern seen in Artemia, these genes are expressed in well-defined discrete domains coinciding with tagmatic boundaries which are distinct from those of the insects. Our observations suggest that, during the independent tagmatization in insects and malacostracan crustaceans, the homologous ‘trunk’ genes evolved to perform different developmental functions. We also propose that, in each lineage, the changes in Hox gene expression pattern may have been important in trunk tagmatization.

Published
2000
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121. Novel regulation of the homeotic gene Scr associated with a crustacean leg-to-maxilliped appendage transformation

Author

Abzhanov, Arhat and Kaufman, Thomas C.

Abstract

Homeotic genes are known to be involved in patterning morphological structures along the antero-posterior axis of insects and vertebrates. Because of their important roles in development, changes in the function and expression patterns of homeotic genes may have played a major role in the evolution of different body plans. For example, it has been proposed that during the evolution of several crustacean lineages, changes in the expression patterns of the homeotic genes Ultrabithorax and abdominal-A have played a role in transformation of the anterior thoracic appendages into mouthparts termed maxillipeds. This homeotic-like transformation is recapitulated at the late stages of the direct embryonic development of the crustacean Porcellio scaber (Oniscidea, Isopoda). Interestingly, this morphological change is associated with apparent novelties both in the transcriptional and post-transcriptional regulation of the Porcellio scaber ortholog of the Drosophila homeotic gene, Sex combs reduced (Scr). Specifically, we find that Scr mRNA is present in the second maxillary segment and the first pair of thoracic legs (T1) in early embryos, whereas protein accumulates only in the second maxillae. In later stages, however, high levels of SCR appear in the T1 legs, which correlates temporally with the transformation of these appendages into maxillipeds. Our observations provide further insight into the process of the homeotic leg-to-maxilliped transformation in the evolution of crustaceans and suggest a novel regulatory mechanism for this process in this group of arthropods.

Published
1999
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122. Distribution of the Sex combs reducedGene Products in Drosophila melanogaster

Author

Mahaffey, James W and Kaufman, Thomas C

Abstract

The spatial and temporal distribution of RNA and protein encoded by the homeotic Sex combs reduced(Scr) gene were examined during Drosophila development. The gene products are present in the epidermis of both the labial and first thoracic segments as would be predicted from prior genetic studies. However, the pattern in the central nervous system (CNS) and mesoderm is further restricted; the major expression located in the labial neuromere of the CNS and the mesoderm of the first thoracic segment. The spatial restriction within the CNS is correlated with and may be due to a differential timing of expression in the labial and first thoracic ectoderm. The labial ectoderm accumulates the ScrRNA prior to segregation of the neuroblasts while expression in the first thoracic ectoderm occurs after neuroblast segregation. The protein is also observed in the subesophageal ganglia of both larvae and adults, as well as in the labial and first thoracic imaginal discs. Surprisingly, the protein is also present to a lesser extent in second and third thoracic leg discs.

Published
1987
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123. Structure of the insect head as revealed by the EN protein pattern in developing embryos

Author

Rogers, Bryan T. and Kaufman, Thomas C.

Abstract

The structure of the insect head has long been a topic of enjoyable yet endless debate among entomologists. More recently geneticists and molecular biologists trying to better understand the structure of the head of the Dipteran Drosophila melanogaster have joined the discourse extrapolating from what they have learned about Drosophila to insects in general. Here we present the results of an investigation into the structure of the insect head as revealed by the distribution of engrailed related protein (Engrailed) in the insect orders Diptera, Siphonaptera, Orthoptera and Hemiptera. The results of this comparative embryology in conjunction with genetic experiments on Drosophila melanogaster lead us to conclude: (1) The insect head is composed of six Engrailed accumulating segments, four postoral and two preoral. The potential seventh and eighth segments (clypeus or labrum) do not accumulate Engrailed. (2) The structure known as the dorsal ridge is not specific to the Diptera but is homologous to structures found in other insect orders. (3) A part of this structure is a single segment-like entity composed of labial and maxillary segment derivatives which produce the most anterior cuticle capable of taking a dorsal fate. The segments anterior to the maxillary segment produce only ventral structures. (4) As in Drosophila, the process of segmentation of the insect head is fundamentally different from the process of segmentation in the trunk. (5) The pattern of Engrailed accumulation and its presumed role in the specification and development of head segments appears to be highly conserved while its role in other pattern formation events and tissue-specific expression is variable. An overview of the pattern of Engrailed accumulation in developing insect embryos provides a basis for discussion of the generality of the parasegment and the evolution of Engrailed patterns.

Published
1996
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124. Homeotic genes have specific functional roles in the establishment of the Drosophila embryonic peripheral nervous system

Author

Heuer, Josef G. and Kaufman, Thomas C.

Abstract

The Drosophila embryonic peripheral nervous system (PNS) contains segment-specific spatial patterns of sensory organs which derive from the ectoderm. Many studies have established that the homeotic genes of Drosophila control segment specific characteristics of the epidermis, and more recently these genes have also been shown to control gut morphogenesis through their expression in the visceral mesoderm (Tremml, G. and Bienz, M. (1989), EMBO J. 8, 2677-2685). We report here the roles of homeotic genes in establishing the spatial patterns of sensory organs in the embryonic PNS. The PNS was examined in embryos homozygous for mutations in the homeotic genes Sex combs reduced (Scr), Antennapedia (Antp), Ultrabithorax (Ubx), abdominal-A (abd-A) and Abdominal-B (Abd-B) with antibodies that label specific subsets of sensory organs. Our results suggest that the homeotic genes have specific roles in establishing the correct spatial patterns of sensory organs in their normal domains of expression. In addition, we also report the effects of ectopic expression of the homeotic genes labial (lab), Deformed (Dfd), Scr, Antp or Ubx on the normal development of sensory organs in the embryonic PNS. Interestingly, while previous studies have concluded that ectopic expression of the homeotic genes Dfd, Scr and Antp has no effect on the segmental identity of the abdominal segments, our results demonstrate that this is not true. We show that ectopic expression of these genes does result in the disruption of the developing PNS in the abdomen. Our results are suggestive of a role for the homeotic gene products in regulating genes which are necessary for generating sensory progenitor cells in the developing PNS.

Published
1992
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125. Control of expression of the homeotic labial (lab) locus of Drosophila melanogaster. evidence for both positive and negative autogenous regulation

Author

Chouinard, Scott and Kaufman, Thomas C.

Abstract

The homeotic gene labial (lab) is required for proper development of the embryonic and adult head in Drosophila melanogaster. The lab gene product accumulates in a complex pattern in both embryonic and imaginal tissue. During embryogenesis, lab is expressed in the endodermally derived cells of the midgut, in ectodermally derived cells of the procephalon and dorsal ridge, and in a small subset of progenitor sensory cells. imaginal expression is restricted to a narrow region of the peripodial membrane of the eye-antennal disc. As part of our continuing effort to understand the role of lab in development, we have begun a dissection of the regulatory elements of the lab transcription unit and used germ line transformation experiments to determine which aspects of the observed expression pattern are essential for proper head development and viability. Transgenic embryos harboring an abridged lab gene are able to overcome the embryonic lethality associated with the loss of lab function and survive to adulthood. Interestingly, in these transgenic lines the lab protein accumulates only in a subset of those embryonic cells that normally express the gene, namely the procephalon and the anterior midgut. We also find that, once initiated, lab expression is maintained by positive autoregulation. Although lab minigene activity is sufficient to rescue the embryonic lethality of lab mutations, the transgenes fail to rescue defects in the adult head capsule. However, the defects observed in this study encompass a broader domain than those seen using somatic recombination to generate lab−1 clonal tissue. The failed rescue and observed cuticular defects are, at least in part, explained by the observation that the transgenes, rather than failing to be expressed, are associated with ectopic accumulation of lab protein in the peripodial membrane of the antennal disc. Moreover, this aberrant expression pattern is correlated with the abnormal expression of two other homeotic genes, Deformed (Dfd) and Sex combs reduced (Scr) in the eye-antennal disc. These results are only observed when the transgene is resident in a lab− genotype and ectopic expression of lab and misregulation of Dfd and Scr are not seen in a lab+ background. This result suggests that the wild-type lab gene product is necessary for the normal regulation of the locus in the imaginal discs, but unlike the case in the embryo, the event is negative. We discuss the biological implications of these results in relation to the role of lab in development.

Published
1991
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126. Developmental and evolutionary implications of labial, Deformed and engrailed expression in the Drosophila head

Author

Diederich, Robert J., Pattatucci, Angela M., and Kaufman, Thomas C.

Abstract

Prior developmental genetic analyses have shown that labial (lab) and Deformed (Dfd) are homeotic genes that function in the development of the embryonic (larval) and adult head. Using antibody probes to reveal the spatial distribution of the lab and Dfd proteins in embryonic and imaginai tissues, we have assessed the respective roles of these genes through an analysis of the correspondence of their expression patterns with their mutant phenotypes. With regard to imaginai develop-ment, lab and Dfd occupy adjacent non-overlapping expression domains in the peripodial cell layer of the eye-antennal disc, in patterns that are consistent with their adult mutant phenotypes and published fate maps. During embryogenesis, lab and Dfd exhibit limited overlapping expression in areas that are of no obvious significance to the development of larval head struc-tures, but also in areas that may have consequences for imaginai development. The head of Drosophila and other cyclorrhaphous Dipterans is characterized by an ex-treme morphological difference between the larval and adult stages. Given this unique ontogenetic and phylo-genetic history and the observation that homeotic transformations produced by the lab, Dfd, and proboscis pedia (pb) loci are manifested only in the adult, we suggest that distinct regulatory paradigms evolved for homeotic gene function in the development of the larval versus adult head. Finally, a detailed examination of the engrailed (en) expression pattern in the embryonic head strengthens the view of insect morphologists that the clypeolabrum evolved from the fusion of paired labral appendages.

Published
1991
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127. A functionally specialized α-tubulin is required for oocyte meiosis and cleavage mitoses in Drosophila

Author

Matthews, Kathleen A., Rees, Dianne, and Kaufman, Thomas C.

Abstract

Three α-tubulin proteins contribute to microtubules during oogenesis and early embryogenesis in Drosophila melanogaster: αTUB84B, αTUB84D, and αTUB67C. αTUB67C is unique in two respects. It is a structurally divergent α-tubulin, sharing only 67% amino acid identity with the generic isotypes αTUB84B and αTUB84D, and its expression is exclusively maternal. The genetic analysis of the Tub67C gene described here demon strates that αTUB67C is required for nuclear division in the oocyte and early embryo. Both meiosis and cleavage-stage mitoses are severely affected by mutations that result in a substantial decrease in the ratio of αTUB67C/ αTUB84B+ αTUB84D. A large increase in this ratio, achieved by increasing the gene dosage of Tub67C, has little or no effect on meiosis, but severely disrupts mitotic spindle function. Thus, both classes of α-tubulin isotype present in the mature oocyte, αTUB67C and αTUB84B/84D, are essential for normal spindle function in early Drosophila development. These α-tubulins provide the first example of tubulin isotypes known to be coexpressed in wild-type animals whose encoded variation is required for the normal function of a microtubule array.

Published
1993
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128. The Tomaj mutant alleles of αtubulin67c reveal a requirement for the encoded maternal specific tubulin isoform in the sperm aster, the cleavage spindle apparatus and neurogenesis during embryonic development in Drosophila

Author

Máthé1, Endre, Boros’, Imre, Jósvay, Katalin, Li, Kaijun, Puro, Jaakko, Kaufman, Thomas C., and Szabad, János

Abstract

The three dominant TomajD and their eleven revertant (TomajR) alleles have been localized to the αTubulin67C gene of Drosophila melanogaster. Although the meiotic divisions are normally completed in eggs laid by TomajD/+, TomajD/-, TomajR/-females, embryogenesis arrests prior to the gonomeric division. The arrest is caused by: (1) the failure of prominent sperm aster formation; and (2) a consequent lack of female pronuclear migration towards the male pronucleus. Concomitant with the sperm aster defect, the four female meiotic products fuse (tetra-fusion), similar to what is seen in eggs of wild-type virgin females. In eggs of females heterozygous for weaker TomajR alleles, embryogenesis comes to a cessation before or shortly after cortical migration of cleavage nuclei. The apparent source of embryonic defect is the cleavage spindle apparatus. One of the three TomajD alleles is cold-sensitive and its cold-sensitive period coincides with the completion of female meiosis and pronuclear migration. Disorganized central and peripheral nervous systems are also characteristic of embryos derived from the temperature-sensitive TomajD/+ females. The Tomaj mutant phenotypes indicate an involvement of the normal αTubulin67C gene product in: (1) the formation of the sperm aster; (2) cleavage spindle apparatus formation/function; and (3) the differentiation of the embryonic nervous system. The TomajD alleles encode a normal-sized αTubulin67C isotype. Sequence analyses of the TomajD alleles revealed the replacement in different positions of a single negatively charged or neutral amino acid with a positively charged one. These residues presumably identify important functional sites.

Published
1998
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129. A functional analysis of 5′, intronic and promoter regions of the homeotic gene proboscipedia in Drosophila melanogaster

Author

Kapoun, Ann M. and Kaufman, Thomas C.

Abstract

In Drosophila, the homeotic gene proboscipedia (pb) is required for the formation of the adult mouthparts. To determine the functional significance of putative pb regulatory DNA, we have performed an in vivo analysis of sequences upstream of and within pb using a series of minigenes. Additionally, we have initiated a dissection of pb’s promoter and enhancer elements using lacZ reporter gene constructs. Our results establish that a conserved region located in the second intron is essential for proper formation of the adult mouthparts. A 0.5 kb fragment from this region was shown to direct lacZ expression in a pb pattern in both embryos and third instar labial discs when combined with a 600 bp pb basal promoter sequence. A 32 bp element contained within the 0.5 kb region functions as a labial disc enhancer for pb. Surprisingly, the conserved second intron pb enhancers do not function properly with a heterologous hsp70 promoter, suggesting that promoter-specific interactions occur at the pb locus. We also found redundant and cryptic enhancers in the large introns of pb that are not required for pb function. Finally, we demonstrate that the pb transcription unit does not require sequences upstream of −98 bp to provide pb function in the labial discs. Rather, pb’s upstream DNA appears to contain negative regulatory DNA required for silencing PB accumulation in inappropriate domains of third instar imaginal discs. Thus, we have defined many of pb’s cis-controlling sequences to an experimentally manageable size, thereby making this an attractive system for the discovery of trans-acting proteins and, consequently, for elucidating the mechanisms of homeotic gene regulation.

Published
1995
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130. The Drosophila homeotic target gene centrosomin (cnn) encodes a novel centrosomal protein with leucine zippers and maps to a genomic region required for midgut morphogenesis

Author

Heuer, Josef G., Li, Kaijun, and Kaufman, Thomas C.

Abstract

The products of the homeotic genes in Drosophila are transcription factors that are necessary to impose regional identity along the anterior-posterior axis of the developing embryo. However, the target genes under homeotic regulation that control this developmental process are largely unknown. We have utilized an immunopurification method to clone target genes of the Antennapedia protein (ANTP). We present here the characterization of centrosomin (cnn), one of the target genes isolated using this approach. The spatial and temporal expression of the cnn gene in the developing visceral mesoderm (VM) of the midgut and the central nervous system (CNS) of wild-type and homeotic mutant embryos is consistent with the idea that cnn is a homeotic target. In the VM, Antp and abdominal-A (abd-A) negatively regulate cnn, while Ultrabithorax (Ubx) shows positive regulation. In the CNS, cnn is regulated positively by Antp and negatively by Ubx and abd-A. Characterization of a cDNA encoding CNN predicts a novel structural protein with three leucine zipper motifs and several coiledcoil domains exhibiting limited homology to the rod portion of myosin. Immunocytochemical results demonstrate that the cnn encoded protein is localized to the centrosome and the accumulation pattern is coupled to the nuclear and centrosome duplication cycles of cleavage. In addition, evidence suggests that the expression of the cnn gene in the VM correlates with the morphogenetic function of Ubx in that tissue, i.e., the formation of the second midgut constriction. The centrosomal localization of CNN and the involvement of microtubules in midgut morphogenesis suggest that this protein may participate in mitotic spindle assembly and the mechanics of morphogenesis through an interaction with microtubules, either directly or indirectly.

Published
1995
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131. Evolution of the insect body plan as revealed by the Sex combs reduced expression pattern

Author

Rogers, Bryan T., Peterson, Michael D., and Kaufman, Thomas C.

Abstract

The products of the HOM/Hox homeotic genes form a set of evolutionarily conserved transcription factors that control elaborate developmental processes and specify cell fates in many metazoans. We examined the expression of the ortholog of the homeotic gene Sex combs reduced (Scr) of Drosophila melanogaster in insects of three divergent orders: Hemiptera, Orthoptera and Thysanura. Our data reflect how the conservation and variation of Scr expression has affected the morphological evolution of insects. Whereas the anterior epidermal expression of Scr, in a small part of the posterior maxillary and all of the labial segment, is found to be in common among all four insect orders, the posterior (thoracic) expression domains vary. Unlike what is observed in flies, the Scr orthologs of other insects are not expressed broadly over the first thoracic segment, but are restricted to small patches. We show here that Scr is required for suppression of wings on the prothorax of Drosophila. Moreover, Scr expression at the dorsal base of the prothoracic limb in two other winged insects, crickets (Orthoptera) and milkweed bugs (Hemiptera), is consistent with Scr acting as a suppressor of prothoracic wings in these insects. Scr is also expressed in a small patch of cells near the basitarsal-tibial junction of milkweed bugs, precisely where a leg comb develops, suggesting that Scr promotes comb formation, as it does in Drosophila. Surprisingly, the dorsal prothoracic expression of Scr is also present in the primitively wingless firebrat (Thysanura) and the leg patch is seen in crickets, which have no comb. Mapping both gene expression patterns and morphological characters onto the insect phylogenetic tree demonstrates that in the cases of wing suppression and comb formation the appearance of expression of Scr in the prothorax apparently precedes these specific functions.

Published
1997
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