Botryllus schlosseri is a colonial marine urochordate in which all adult organisms (called zooids) in a colony die synchronously by apoptosis (programmed cell death) in cyclical fashion. During this death phase called takeover, cell corpses within the dying organism are engulfed by circulating phagocytic cells. The "old" zooids and their organs are resorbed within 24-36 h (programmed cell removal). This process coincides temporally with the growth of asexually derived primary buds, that harbor a small number of undifferentiated cells, into mature zooids containing functional organs and tissues with the same body plan as adult zooids from which they budded. Within these colonies, all zooids share a ramifying network of extracorporeal blood vessels embedded in a gelatinous tunic. The underlying mechanisms regulating programmed cell death and programmed cell removal in this organism are unknown. In this study, we extirpated buds or zooids from B. schlosseri colonies in order to investigate the interplay that exists between buds, zooids, and the vascular system during takeover. Our findings indicate that, in the complete absence of buds (budectomy), organs from adult zooids underwent programmed cell death but were markedly impaired in their ability to be resorbed despite engulfment of zooid-derived cell corpses by phagocytes. However, when buds were removed from only half of the flower-shaped systems of zooids in a colony (hemibudectomy), the budectomized zooids were completely resorbed within 36-48 h following onset of programmed cell death. Furthermore, if hemibudectomies were carried out by using small colonies, leaving only a single functional bud, zooids from the old generation were also resorbed, albeit delayed to 48-60 h following onset of programmed cell death. This bud eventually reached functional maturity, but grew significantly larger in size than any control zooid, and exhibited hyperplasia. This finding strongly suggested that components of the dying zooid viscera could be reutilized by the developing buds, possibly as part of a colony-wide recycling mechanism. In order to test this hypothesis, zooids were surgically removed (zooidectomy) at the onset of takeover, and bud growth was quantitatively determined. In these zooidectomized colonies, bud growth was severely curtailed. In most solitary, long-lived animals, organs and tissues are maintained by processes of continual death and removal of aging cells counterbalanced by regeneration with stem and progenitor cells. In the colonial tunicate B. schlosseri, the same kinds of processes ensure the longevity of the colony (an animal) by cycles of death and regeneration of its constituent zooids (also animals).
Botryllus schlosseri is a colonial ascidian whose asexually derived, clonally modular systems of zooids exhibit developmental synchrony. The blastogenic cycle culminates in a phase of programmed cell and zooid death called takeover, in which all functional zooids die over a 30 hr period, and are replaced by a new generation of individuals. Because of the weekly recurrence and magnitude of visceral death in this model organism, we have begun to characterize the mechanisms that govern takeover. Here we describe a monoclonal antibody (B3F12.9) that recognizes a novel 57 Kd polypeptide (under reducing conditions) localized to the perivisceral extracellular matrix (PVEM) of buds and zooids, as well as blood cells of Botryllus by immunofluorescence and immunogold labeling of tissue sections. During their active feeding phase, zooids exhibited a uniform labeling pattern of PVEM along their anteroposterior (A-P) axis. At the onset of takeover (T = 3 hr), B3F12.9 immunostaining became diffuse or absent at the anterior end, which paralleled the axis of contraction of the dying zooid, whereas the posterior end retained its labeling integrity. During mid (T = 15 hr) to late (T = 28 hr) takeover, issue damage was extensive, large blood macrophages and other B3F12.9 immunoreactive blood cells invaded the peribranchial cavity, whereas PVEM labeling gradually disappeared along the entire A-P axis. These findings indicate that takeover is a dynamic process in which extracellular matrix breakdown proceeds in a polarized fashion, beginning at the anterior end of each zooid and gradually propagating toward the posterior end. o 1992 WiIey-Liss, Inc.
The blastogenic cycle of the colonial ascidian Botryllus schlosseri concludes in a phase of selective cell and zooid death called takeover. Every week, all asexually derived parental zooids synchronously regress over a 30-h period and are replaced by a new generation. Here we document the sequential ultrastructural changes which accompany cell death during zooid degeneration. The principal mode of visceral cell death during takeover occurred by apoptosis, the majority of cells condensing and fragmenting into multiple membrane-bounded apoptotic bodies. Cytoplasmic organelles (mitochondria, basal bodies, striated rootlets) within apoptotic bodies retained ultrastructural integrity. Dying cells and fragments were then swiftly ingested by specialized blood macrophages or intraepithelial phagocytes and subsequently underwent secondary necrotic lysis. Certain organs (stomach, intestine) displayed a combination of necrotic and apoptotic changes. Lastly, the stomach, which demonstrated some of the earliest regressive changes, exhibited intense cytoplasmic immunostaining with a monoclonal antibody to ubiquitin at the onset of takeover. Affinity-purified rabbit antiserum against sodium dodecyl sulfate-denatured ubiquitin detected a characteristic 8.6-kDa mono-ubiquitin band by Western blot analysis. Collectively, these findings raise the possibility that cell death during takeover is a dynamic process which requires active participation of cells in their own destruction.
The variety of theories that have attempted to defime the mechanisms of aging and life span can be broadly divided into two alternative but nonexclusive viewpoints. The fitrst stipulates that random changes of cellular and molecular structures lead to death following progressive "wear and tear." The second argues that life span is, at least in part, genetically programmed, and therefore aging may also result from time-dependent intrinsic processes. Here we demonstrate that ramets (clonal replicates) experimentally separated from colonies of the ascidian protochordate BobyUus schlosseri died months after their separation, almost simultaneously with their parent colony and sibling ramets. In addition, in experimentally joined chimeras between ramets of senescent and nonsenescent colonies, elements from different parent colonies displayed parent-colony-specific timing of mortality. Thus, the senescent phenotype was simultaneously expressed both in chimeras and in unfused ramets of the parent colony that was undergoing senescence, whereas control ramets from the other partner survived. These rmdings provide experimental evidence for a heritable basis underlying mortality in protochordates, unlinked to reproductive effort and other life history traits of this species.The colonial ascidian Botryllus schlosseri (Tunicata, Ascidiacea) is a cosmopolitan filter-feeding metazoan inhabitant of shallow waters and harbors throughout the world (1). Following settlement, the free-swimming chordate tadpole metamorphoses to a founder individual, the oozooid. Colonies of genetically identical zooids subsequently develop by weekly cycles of asexual budding (blastogenesis), typically forming star-shaped modules called systems, which are embedded in a translucent, gelatinous matrix (tunic) (2). A common vascular network flows between systems comprised of blood vessels connecting individual zooids and terminating into ampullae at the periphery of the colony. Each blastogenic cycle culminates in a phase of programmed cell and module (zooid) death called takeover, in which all zooids in a single colony die and are replaced by a new generation ofzooids (3). Botryllid ascidians possess, as well, a unique histocompatibility system. When two genotypically different laboratory or field colonies come in contact, they either fuse with or reject each other (4). This fusibility/histocompatibility discrimination is controlled by a single gene locus or haplotype (Fu/HC; ref. 5) with multiple codominantly expressed alleles (6,7). After the establishment of a common vascular system between a fusible pair reared in the laboratory, one member of the chimera often is resorbed by its partner (colony resorption) (8)(9)(10) 1ITo whom reprint requests should be sent at the present address. 3546The publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. §1734 solely to indicate this fact.
Regeneration is widely distributed among the metazoans. However, clear differences exist as to the degree of regenerative capacity: some phyla can only replace missing body parts, whereas others can generate entirely new individuals. Ascidians are animals that possess a remarkable regenerative plasticity and exhibit a great diversity of mechanisms for asexual propagation and survival. They are marine invertebrate members of the subphylum Tunicata and represent modern-day descendants of the chordate ancestor; in their tadpole stage they exhibit a chordate body plan that is resorbed during metamorphosis. Solitary species grow into an adult that can reach several centimeters in length, whereas colonial species grow by asexual propagation, creating a colony of genetically identical individuals. In this review, we present an overview of the biology of colonial ascidians as a paradigm for study in stem cell and regenerative biology. Focusing on botryllid ascidians, we introduce the potential roles played by multipotent epithelia and multipotent/pluripotent stem cells as source of asexual propagation and regenerative plasticity in the different budding mechanisms, and consider the putative mechanism of body repatterning in a non-embryonic scenario. We also discuss the involvement of intra-colony homeostatic processes in regulating budding potential, and the functional link between allorecognition, chimerism, and regenerative potential.
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