A cyclical, developmentally‐regulated death phenomenon in a colonial urochordate

Lauzon, Robert J.; Ishizuka, Katherine J.; Weissman, Irving L.

doi:10.1002/aja.1001940109

Cited by 83 publications

(89 citation statements)

References 47 publications

(62 reference statements)

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“…Of particular relevance, we observed significant up-regulation in genes related to autophagy, proteolysis, programmed cell death, and phagocytic clearance of cellular corpses (Dataset S1). These findings support prior observations showing intensive phagocytosis of apoptotic cells underlying colony-wide recycling between senescent zooids and developing buds during the takeover period (11,26,27).…”

Section: Significancesupporting

confidence: 82%

“…Insight has been gained into fusion-partner resorption from observational studies showing physical similarities with the developmental period known as "takeover," or blastogenic stage D (4, 10). B. schlosseri colonies are composed of clonogenic individuals, termed "zooids," that undergo weekly cycles of death and regeneration, culminating in a massive wave of programmed cell death and removal, or takeover (11). These studies support the involvement of activated phagocytes in the elimination of tissues of the "losing" partner.…”

mentioning

confidence: 67%

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Developmental cell death programs license cytotoxic cells to eliminate histocompatible partners

Corey

Rosental

Kowarsky

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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In a primitive chordate model of natural chimerism, one chimeric partner is often eliminated in a process of allogeneic resorption. Here, we identify the cellular framework underlying loss of tolerance to one partner within a natural Botryllus schlosseri chimera. We show that the principal cell type mediating chimeric partner elimination is a cytotoxic morula cell (MC). Proinflammatory, developmental cell death programs render MCs cytotoxic and, in collaboration with activated phagocytes, eliminate chimeric partners during the "takeover" phase of blastogenic development. Among these genes, the proinflammatory cytokine IL-17 enhances cytotoxicity in allorecognition assays. Cellular transfer of FACS-purified MCs from allogeneic donors into recipients shows that the resorption response can be adoptively acquired. Transfer of 1 × 10 5 allogeneic MCs eliminated 33 of 78 (42%) recipient primary buds and 20 of 76 (20.5%) adult parental adult organisms (zooids) by 14 d whereas transfer of allogeneic cell populations lacking MCs had only minimal effects on recipient colonies. Furthermore, reactivity of transferred cells coincided with the onset of developmental-regulated cell death programs and disproportionately affected developing tissues within a chimera. Among chimeric partner "losers," severe developmental defects were observed in asexually propagating tissues, reflecting a pathologic switch in gene expression in developmental programs. These studies provide evidence that elimination of one partner in a chimera is an immune cell-based rejection that operates within histocompatible pairs and that maximal allogeneic responses involve the coordination of both phagocytic programs and the "arming" of cytotoxic cells.T he colonial marine species, Botryllus schlosseri, offers a unique platform to study mechanisms underlying loss of tolerance in a natural model system. Colonies undergo a genetically controlled histocompatibility reaction that can result in vascular fusion of distinct genotypes, creating a chimera (1, 2). Natural history studies among fused colonies show that partners rarely exist as stable chimeras (3-7). One chimeric partner is often eliminated in a process of allogeneic resorption, suggesting a break in immunological nonreactivity. Moreover, the eliminated partner may still persist, and even parasitize the nonresorbed partner, but at the level of the cell lineage (8, 9). Insight has been gained into fusion-partner resorption from observational studies showing physical similarities with the developmental period known as "takeover," or blastogenic stage D (4, 10). B. schlosseri colonies are composed of clonogenic individuals, termed "zooids," that undergo weekly cycles of death and regeneration, culminating in a massive wave of programmed cell death and removal, or takeover (11). These studies support the involvement of activated phagocytes in the elimination of tissues of the "losing" partner.Here, we study the progression by which fused colonies eliminate chimeric partners and show that partner eliminatio...

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Section: Significancesupporting

confidence: 82%

mentioning

confidence: 67%

Developmental cell death programs license cytotoxic cells to eliminate histocompatible partners

Corey

Rosental

Kowarsky

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

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“…During the shrinkage of adult zooids, the epidermis and peribranchial epithelium contract and play a special role in compressing the underlying organs: a wave of contraction moves anteroposteriorly along the body (Burighel and Schiavinato, 1984;Lauzon et al, 1992). The pharynx and peribranchial cavities collapse, the branchial walls disintegrate, and circulating phagocytes massively infiltrate senescent tissues and rapidly ingest effete cells (Burighel and Schiavinato, 1984;Cima et al, 2003).…”

Section: Filter-feeding Adult Stagementioning

confidence: 99%

“…Intermediate or mid-cycle stages, as defined by Lauzon et al (1992), correspond to stages 9/8/2 to 9/8/4 (Table 2).…”

Section: Bud Development and Colonial Blastogenetic Cyclementioning

confidence: 99%

“…Embryogenesis is rapid, and larvae for dispersal of new colonies can be obtained within a week from fertilization. In addition, it is already known as a valid model organism for studying natural apoptosis and clearance of effete cells (Burighel and Schiavinato, 1984;Lauzon et al, 1992Lauzon et al, , 1993Lauzon et al, , 2002Cima et al, 2003), allorecognition (Sabbadin, 1962(Sabbadin, , 1982Sabbadin and Astorri, 1988;Ballarin et al, 1995Ballarin et al, , 2002aRinkevich et al, 1998a;Cima et al, 2004a;De Tomaso et al, 2005;Nyholm et al, 2006), immunobiology (Ballarin et al, 1994(Ballarin et al, , 2002bBallarin and Burighel, 2006), and regeneration (Berrill, 1951;Zaniolo and Trentin, 1987;Laird et al, 2005a).…”

Section: Introductionmentioning

confidence: 99%

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