Tsuyoshi Tokusumi
University of Notre Dame
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Publication
Featured researches published by Tsuyoshi Tokusumi.
Journal of Virology | 2003
Makoto Inoue; Yumiko Tokusumi; Hiroshi Ban; Takumi Kanaya; Masayuki Shirakura; Tsuyoshi Tokusumi; Takahiro Hirata; Yoshiyuki Nagai; Akihiro Iida; Mamoru Hasegawa
ABSTRACT A new recombinant Sendai virus vector (SeV/ΔM), in which the gene encoding matrix (M) protein was deleted, was recovered from cDNA and propagated in a packaging cell line expressing M protein by using a Cre/loxP induction system. The titer of SeV/ΔM carrying the enhanced green fluorescent protein gene in place of the M gene was 7 × 107 cell infectious units/ml or more. The new vector showed high levels of infectivity and gene expression, similar to those of wild-type SeV vector, in vitro and in vivo. Virus maturation into a particle was almost completely abolished in cells infected with SeV/ΔM. Instead, SeV/ΔM infection brought about a significant increase of syncytium formation under conditions in which the fusion protein was proteolytically cleaved and activated by trypsin-like protease. This shows that SeV/ΔM spreads markedly to neighboring cells in a cell-to-cell manner, because both hemagglutinin-neuraminidase and active fusion proteins are present at very high levels on the surface of cells infected with SeV/ΔM. Thus, SeV/ΔM is a novel type of vector with the characteristic features of loss of virus particle formation and gain of cell-to-cell spreading via a mechanism dependent on the activation of the fusion protein.
Journal of Virology | 2003
Makoto Inoue; Yumiko Tokusumi; Hiroshi Ban; Takumi Kanaya; Tsuyoshi Tokusumi; Yoshiyuki Nagai; Akihiro Iida; Mamoru Hasegawa
ABSTRACT The formation of nontransmissible virus-like particles (NTVLP) by cells infected with F-deficient Sendai virus (SeV/ΔF) was found to be temperature sensitive. Analysis by hemagglutination assays and Western blotting demonstrated that the formation of NTVLP at 38°C was about 1/100 of that at 32°C, whereas this temperature-sensitive difference was only moderate in the case of F-possessing wild-type SeV. In order to reduce the NTVLP formation with the aim of improving SeV for use as a vector for gene therapy, amino acid substitutions found in temperature-sensitive mutant SeVs were introduced into the M (G69E, T116A, and A183S) and HN (A262T, G264R, and K461G) proteins of SeV/ΔF to generate SeV/MtsHNtsΔF. The use of these mutations allows vector production at low temperature (32°C) and therapeutic use at body temperature (37°C) with diminished NTVLP formation. As expected, the formation of NTVLP by SeV/MtsHNtsΔF at 37°C was decreased to about 1/10 of that by SeV/ΔF, whereas the suppression of NTVLP formation did not cause either enhanced cytotoxicity or reduced gene expression of the vector. The vectors showed differences with respect to the subcellular distribution of M protein in the infected cells. Clear and accumulated immunocytochemical signals of M protein on the cell surface were not observed in cells infected by SeV/ΔF at an incompatible temperature, 38°C, or in those infected by SeV/MtsHNtsΔF at 37 or 38°C. The absence of F protein in SeV/ΔF and the additional mutations in M and HN in SeV/MtsHNtsΔF probably weaken the ability to transport M protein to the plasma membrane, leading to the diminished formation of NTVLP.
Molecular and Cellular Biology | 2007
Ye Tao; Jianbo Wang; Tsuyoshi Tokusumi; Kathleen Gajewski; Robert A. Schulz
ABSTRACT Dorsal vessel morphogenesis in Drosophila melanogaster serves as a superb system with which to study the cellular and genetic bases of heart tube formation. We used a cardioblast-expressed Toll-GFP transgene to screen for additional genes involved in heart development and identified tailup as a locus essential for normal dorsal vessel formation. tailup, related to vertebrate islet1, encodes a LIM homeodomain transcription factor expressed in all cardioblasts and pericardial cells of the heart tube as well as in associated lymph gland hematopoietic organs and alary muscles that attach the dorsal vessel to the epidermis. A transcriptional enhancer regulating expression in these four cell types was identified and used as a tailup-GFP transgene with additional markers to characterize dorsal vessel defects resulting from gene mutations. Two reproducible phenotypes were observed in mutant embryos: hypoplastic heart tubes with misaligned cardioblasts and the absence of most lymph gland and pericardial cells. Conversely, a significant expansion of the lymph glands and abnormal morphology of the heart were observed when tailup was overexpressed in the mesoderm. Tailup was shown to bind to two DNA recognition sequences in the dorsal vessel enhancer of the Hand basic helix-loop-helix transcription factor gene, with one site proven to be essential for the lymph gland, pericardial cell, and Svp/Doc cardioblast expression of Hand. Together, these results establish Tailup as being a critical new transcription factor in dorsal vessel morphogenesis and lymph gland formation and place this regulator directly upstream of Hand in these developmental processes.
Genesis | 2009
Tsuyoshi Tokusumi; Douglas A. Shoue; Yumiko Tokusumi; Jessica Stoller; Robert A. Schulz
Based on environmental challenges or altered genetic composition, Drosophila larvae can produce up to three types of blood cells that express genetic programs essential for their distinct functions. Using transcriptional enhancers for genes expressed exclusively in plasmatocytes, crystal cells, or lamellocytes, several new hemocyte‐specific enhancer‐reporter transgenes were generated to facilitate the analysis of Drosophila hematopoiesis. This approach took advantage of fluorescent variants of insulated P‐element reporter vectors for multilabeling cell analyses; two additional color variants were generated in these studies. These vectors were successfully used to produce transgenic fly lines that label specific hemocyte lineages with separate colors. Combining three transgene reporters allowed for the unambiguous identification of plasmatocytes, crystal cells, and lamellocytes within a complex hemocyte population. While this work focused on the hematopoietic process, these new vectors can be used to mark multiple cell types or trace complex cell lineages during any chosen aspect of Drosophila development. genesis 47:771–774, 2009.
PLOS ONE | 2012
Yumiko Tokusumi; Tsuyoshi Tokusumi; Douglas A. Shoue; Robert A. Schulz
Hematopoiesis occurs in two phases in Drosophila, with the first completed during embryogenesis and the second accomplished during larval development. The lymph gland serves as the venue for the final hematopoietic program, with this larval tissue well-studied as to its cellular organization and genetic regulation. While the medullary zone contains stem-like hematopoietic progenitors, the posterior signaling center (PSC) functions as a niche microenvironment essential for controlling the decision between progenitor maintenance versus cellular differentiation. In this report, we utilize a PSC-specific GAL4 driver and UAS-gene RNAi strains, to selectively knockdown individual gene functions in PSC cells. We assessed the effect of abrogating the function of 820 genes as to their requirement for niche cell production and differentiation. 100 genes were shown to be essential for normal niche development, with various loci placed into sub-groups based on the functions of their encoded protein products and known genetic interactions. For members of three of these groups, we characterized loss- and gain-of-function phenotypes. Gene function knockdown of members of the BAP chromatin-remodeling complex resulted in niche cells that do not express the hedgehog (hh) gene and fail to differentiate filopodia believed important for Hh signaling from the niche to progenitors. Abrogating gene function of various members of the insulin-like growth factor and TOR signaling pathways resulted in anomalous PSC cell production, leading to a defective niche organization. Further analysis of the Pten, TSC1, and TSC2 tumor suppressor genes demonstrated their loss-of-function condition resulted in severely altered blood cell homeostasis, including the abundant production of lamellocytes, specialized hemocytes involved in innate immune responses. Together, this cell-specific RNAi knockdown survey and mutant phenotype analyses identified multiple genes and their regulatory networks required for the normal organization and function of the hematopoietic progenitor niche within the lymph gland.
Development | 2010
Yumiko Tokusumi; Tsuyoshi Tokusumi; Jessica R. Stoller-Conrad; Robert A. Schulz
The lymph gland is a specialized organ for hematopoiesis, utilized during larval development in Drosophila. This tissue is composed of distinct cellular domains populated by blood cell progenitors (the medullary zone), niche cells that regulate the choice between progenitor quiescence and hemocyte differentiation [the posterior signaling center (PSC)], and mature blood cells of distinct lineages (the cortical zone). Cells of the PSC express the Hedgehog (Hh) signaling molecule, which instructs cells within the neighboring medullary zone to maintain a hematopoietic precursor state while preventing hemocyte differentiation. As a means to understand the regulatory mechanisms controlling Hh production, we characterized a PSC-active transcriptional enhancer that drives hh expression in supportive niche cells. Our findings indicate that a combination of positive and negative transcriptional inputs program the precise PSC expression of the instructive Hh signal. The GATA factor Serpent (Srp) is essential for hh activation in niche cells, whereas the Suppressor of Hairless [Su(H)] and U-shaped (Ush) transcriptional regulators prevent hh expression in blood cell progenitors and differentiated hemocytes. Furthermore, Srp function is required for the proper differentiation of niche cells. Phenotypic analyses also indicated that the normal activity of all three transcriptional regulators is essential for maintaining the progenitor population and preventing premature hemocyte differentiation. Together, these studies provide mechanistic insights into hh transcriptional regulation in hematopoietic progenitor niche cells, and demonstrate the requirement of the Srp, Su(H) and Ush proteins in the control of niche cell differentiation and blood cell precursor maintenance.
PLOS ONE | 2009
Tsuyoshi Tokusumi; Richard Paul Sorrentino; Mark Russell; Roberto Ferrarese; Shubha Govind; Robert A. Schulz
Drosophila has emerged as an excellent model system in which to study cellular and genetic aspects of hematopoiesis. Under normal developmental conditions and in wild-type genetic backgrounds, Drosophila possesses two types of blood cells, crystal cells and plasmatocytes. Upon infestation by a parasitic wasp or in certain altered genetic backgrounds, a third hemocyte class called the lamellocyte becomes apparent. Herein we describe the characterization of a novel transcriptional regulatory module, a lamellocyte-active enhancer of the misshapen gene. This transcriptional control sequence appears to be inactive in all cell types of the wild-type larva, including crystal cells and plasmatocytes. However, in lamellocytes induced by wasp infestation or by particular genetic conditions, the enhancer is activated and it directs reporter GFP or DsRed expression exclusively in lamellocytes. The lamellocyte control region was delimited to a 140-bp intronic sequence that contains an essential DNA recognition element for the AP-1 transcription factor. Additionally, mutation of the kayak gene encoding the dFos subunit of AP-1 led to a strong suppression of lamellocyte production in tumorous larvae. As misshapen encodes a protein kinase within the Jun N-terminal kinase signaling pathway that functions to form an active AP-1 complex, the lamellocyte-active enhancer likely serves as a transcriptional target within a genetic auto-regulatory circuit that promotes the production of lamellocytes in immune-challenged or genetically- compromised animals.
Development | 2011
Tsuyoshi Tokusumi; Yumiko Tokusumi; Dawn W. Hopkins; Douglas A. Shoue; Lauren Corona; Robert A. Schulz
Bag of Marbles (Bam) is a stem cell differentiation factor in the Drosophila germ line. Here, we demonstrate that Bam has a crucial function in the lymph gland, the tissue that orchestrates the second phase of Drosophila hematopoiesis. In bam mutant larvae, depletion of hematopoietic progenitors is observed, coupled with prodigious production of differentiated hemocytes. Conversely, forced expression of Bam in the lymph gland results in expansion of prohemocytes and substantial reduction of differentiated blood cells. These findings identify Bam as a regulatory protein that promotes blood cell precursor maintenance and prevents hemocyte differentiation during larval hematopoiesis. Cell-specific knockdown of bam function via RNAi expression revealed that Bam activity is required cell-autonomously in hematopoietic progenitors for their maintenance. microRNA-7 (mir-7) mutant lymph glands present with phenotypes identical to those seen in bam-null animals and mutants double-heterozygous for bam and mir-7 reveal that the two cooperate to maintain the hematopoietic progenitor population. By contrast, analysis of yan mutant lymph glands revealed that this transcriptional regulator promotes blood cell differentiation and the loss of prohemocyte maintenance. Expression of Bam or mir-7 in hematopoietic progenitors leads to a reduction of Yan protein. Together, these results demonstrate that Bam and mir-7 antagonize the differentiation-promoting function of Yan to maintain the stem-like hematopoietic progenitor state during hematopoiesis.
Genesis | 2012
Paul T. Kroeger; Tsuyoshi Tokusumi; Robert A. Schulz
Eater is a transmembrane protein that mediates phagocytosis in Drosophila. eater was identified in a microarray analysis of genes downregulated in S2 cells, in which Serpent had been knocked down by RNAi. The gene was shown to be expressed predominantly in plasmatocytes after embryonic development. We have extensively analyzed the transcriptional enhancer controlling eater expression with the following findings: the enhancer reproduces the plasmatocyte expression pattern of the gene as verified by anti‐P1 antibody staining and a 526‐basepair DNA region is active in lymph gland and hemolymph plasmatocytes. This DNA contains several GATA elements that serve as putative‐binding sites for Serpent. Site‐directed mutagenesis of two of these GATA sites abolishes eater expression in both lymph gland and hemolymph plasmatocytes. This suggests that Serpent regulates eater expression by binding these GATA sites, which was confirmed by gel shift analysis. These analyses allowed us to use eater‐Gal4 to force plasmatocyte to lamellocyte differentiation. genesis 50:41–49, 2012.
Biochemical and Biophysical Research Communications | 2014
Victoria Lam; Tsuyoshi Tokusumi; Yumiko Tokusumi; Robert A. Schulz
The Drosophila hematopoietic system is utilized in this study to gain novel insights into the process of growth control of the hematopoietic progenitor niche in blood development. The niche microenvironment is an essential component controlling the balance between progenitor populations and differentiated, mature blood cells and has been shown to lead to hematopoietic malignancies in humans when misregulated. MicroRNAs are one class of regulators associated with blood malignancies; however, there remains a relative paucity of information about the role of miRNAs in the niche. Here we demonstrate that bantam miRNA is endogenously active in the Drosophila hematopoietic progenitor niche, the posterior signaling center (PSC), and functions in the primary hematopoietic organ, the lymph gland, as a positive regulator of growth. Loss of bantam leads to a significant reduction in the PSC and overall lymph gland size, as well as a loss of the progenitor population and correlative premature differentiation of mature hemocytes. Interestingly, in addition to being essential for proper lymph gland development, we have determined bantam to be a novel upstream component of the insulin signaling cascade in the PSC and have unveiled dMyc as one factor central to bantam activity. These important findings identify bantam as a new hematopoietic regulator, place it in an evolutionarily conserved signaling pathway, present one way in which it is regulated, and provide a mechanism through which it facilitates cellular proliferation in the hematopoietic niche.