The regeneration capacity of an earthworm, Eisenia fetida, in relation to the site of amputation along the body

It is well known that parts of earthworms can survive if they are cut off. Our aim was to link the regeneration capacity of an earthworm, Eisenia fetida (Oligochaeta, Annelida) with the site of the amputation, so we amputated earthworms at different body segment locations along the length of the body to examine the different survival rates and regeneration lengths of the anterior, posterior, and medial sections.
The greatest survival rates occurred for earthworms with the most body segments remaining after amputation. The anterior regeneration lengths were of two types. The lengths of regeneration of amputated from body segment 6/7 to further down the body posteriorly increased gradually (Type L_I). However, the regeneration lengths of earthworm which were amputated behind the 23rd segment, with less than a quarter of the total segments remaining, did not increase until the blastema and tail bud formation (Type L_II). These treatments were not completely regeneration. There were significant differences in both survival rates and lengths of regeneration lengths between immature earthworms and clitellate adult earthworms during the early stages of regeneration, but not at later stages of regeneration. The immature earthworms had a greater regeneration potential than clitellate adults amputated at the same segment. The survival rates of earthworms were correlated significantly with the number of body segments remaining after amputation, but not with the position of the amputation. The relationships between the survival rates and the numbers of remaining segments could be described by linear regressions. The anterior regeneration lengths were correlated with the position of the amputation, but not with the number of remaining segments; the posterior regeneration lengths, were not correlated with the number of segments remaining nor the amputation position. The anterior regeneration length was not related to the survival rates for all earthworm amputations after 30 days but was related in this way after 60 days.     

The regeneration capacity of an earthworm, Eisenia fetida, in relation to the site of amputation along the body

It is well known that parts of earthworms can survive if they are cut off. Our aim was to link the regeneration capacity of an earthworm, Eisenia fetida (Oligochaeta, Annelida) with the site of the amputation, so we amputated earthworms at different body segment locations along the length of the body to examine the different survival rates and regeneration lengths of the anterior, posterior, and medial sections.
The greatest survival rates occurred for earthworms with the most body segments remaining after amputation. The anterior regeneration lengths were of two types. The lengths of regeneration of amputated from body segment 6/7 to further down the body posteriorly increased gradually (Type L_I). However, the regeneration lengths of earthworm which were amputated behind the 23rd segment, with less than a quarter of the total segments remaining, did not increase until the blastema and tail bud formation (Type L_II). These treatments were not completely regeneration. There were significant differences in both survival rates and lengths of regeneration lengths between immature earthworms and clitellate adult earthworms during the early stages of regeneration, but not at later stages of regeneration. The immature earthworms had a greater regeneration potential than clitellate adults amputated at the same segment. The survival rates of earthworms were correlated significantly with the number of body segments remaining after amputation, but not with the position of the amputation. The relationships between the survival rates and the numbers of remaining segments could be described by linear regressions. The anterior regeneration lengths were correlated with the position of the amputation, but not with the number of remaining segments; the posterior regeneration lengths, were not correlated with the number of segments remaining nor the amputation position. The anterior regeneration length was not related to the survival rates for all earthworm amputations after 30 days but was related in this way after 60 days.     

Morphogenetic control during tail regeneration in Plethodon cinereus: the role of skeletal muscle

The caudal myofibers of Plethodon cinereus do not appear to participate directly in epimorphic tail regeneration following either autotomy or surgical amputation of the tail. The possibility that tail musculature might indirectly influence morphogenesis of the regenerate was tested by unilaterally removing 99% of the lateral muscle mass for five to six caudal segments. Ten days after muscle ablation, tails were amputated through the deficient area. Unlike previous experiences with ambystomid larvae, P. cinereus regulates completely producing a normal tail regenerate and at a rate comparable to that following simple amputation.     

Caudal regeneration in Tubifex tubifex (Oligochaeta, Tubificidae) following copper exposure

Abstract. The oligochaete, Tubifex tubifex (Oligochaeta, Tubificidae), is capable of the auto-tomization and regeneration of missing body parts. The posterior end of the worm is subject to autotomy (e.g., after predation or after exposure to toxic substances) and can be regenerated thereafter. Despite the ecological importance of T. tubifex , processes of autotomy and regeneration have been little studied. This work describes daily morphological and histological observations of caudal regeneration of this worm. We also compared regeneration processes when autotomy was induced by artificial transsection of the worms (control worms) and by exposure to copper ion, a frequently encountered environmental contaminant. The worms regenerated a functional posterior end (defecation possible) in 7 d as well as a prepygidial zone from which new segments could be regenerated. In T. tubifex , regeneration involved the presence of activated mesoblastocytes in the worm, increased number of neoblasts, and the increased migration of these cells. However, Cu²⁺ did not affect these processes, since no difference could be detected between regeneration of control and Cu-autotomized worms.     

What role do annelid neoblasts play? A comparison of the regeneration patterns in a neoblast-bearing and a neoblast-lacking enchytraeid oligochaete

The term 'neoblast' was originally coined for a particular type of cell that had been observed during annelid regeneration, but is now used to describe the pluripotent/totipotent stem cells that are indispensable for planarian regeneration. Despite having the same name, however, planarian and annelid neoblasts are morphologically and functionally distinct, and many annelid species that lack neoblasts can nonetheless substantially regenerate. To further elucidate the functions of the annelid neoblasts, a comparison was made between the regeneration patterns of two enchytraeid oligochaetes, Enchytraeus japonensis and Enchytraeus buchholzi, which possess and lack neoblasts, respectively. In E. japonensis, which can reproduce asexually by fragmentation and subsequent regeneration, neoblasts are present in all segments except for the eight anterior-most segments including the seven head-specific segments, and all body fragments containing neoblasts can regenerate a complete head and a complete tail, irrespective of the region of the body from which they were originally derived. In E. japonensis, therefore, no antero-posterior gradient of regeneration ability exists in the trunk region. However, when amputation was carried out within the head region, where neoblasts are absent, the number of regenerated segments was found to be dependent on the level of amputation along the body axis. In E. buchholzi, which reproduces only sexually and lacks neoblasts in all segments, complete heads were never regenerated and incomplete (hypomeric) heads could be regenerated only from the anterior region of the body. Such an antero-posterior gradient of regeneration ability was observed for both the anterior and posterior regeneration in the whole body of E. buchholzi. These results indicate that the presence of neoblasts correlates with the absence of an antero-posterior gradient of regeneration ability along the body axis, and suggest that the annelid neoblasts are more essential for efficient asexual reproduction than for the regeneration of missing body parts.     

视黄酸对赤子爱胜蚓再生头尾轴形成的影响

为了探讨视黄酸对蚯蚓再生的影响,用视黄酸处理了从不同部位剪切的蚯蚓体段．观察其存活率、重量和再生长度的变化。结果表明,有头无尾的体段存活率受视黄酸影响较小,而无头有尾的处理受视黄酸影响较大;视黄酸处理后30d,各处理再生长度和存活率均小于对照;视黄酸对蚯蚓再生有明显影响,能延迟和干扰再生,影响头部的形成。视黄酸影响蚯蚓再生的作用方式可能是通过干扰前后体轴的形成,从而影响蚯蚓再生图式形成。     

三种华枝断肢再生的研究

目(竹节虫目)的昆虫具有很强的断肢再生能力。该文通过对华枝属(Sinophasma spp)三种昆虫的实验,表明其再生能力与断肢发生的时间及数量有关。断肢1只或2只的1～4龄虫体发育至成虫期或至若虫末龄时,其再生足的长度与相应的正常足长度相近。若在5龄初时断肢1～2只,也具有再生能力,但至成虫期其再生足的长度则短于相对应的正常足。若在6龄及成虫时断肢,则无再生能力（若6龄时出现断肢再生,则若虫期多为7龄）。实验结果还表明,若断肢为3只或3只以上,则虫体不能存活,且多在断肢后2～3 d内死亡。观察中尚发现,再生足生长速度明显高于正常足。而且,断肢的龄期越高,再生足生长速度越快。再生足的伸长生长与正常足一样,均出现于虫体蜕皮时。     

Variation in Salamander Tail Regeneration Is Associated with Genetic Factors That Determine Tail Morphology

Very little is known about the factors that cause variation in regenerative potential within and between species. Here, we used a genetic approach to identify heritable genetic factors that explain variation in tail regenerative outgrowth. A hybrid ambystomatid salamander (Ambystoma mexicanum x A. andersoni) was crossed to an A. mexicanum and 217 offspring were induced to undergo metamorphosis and attain terrestrial adult morphology using thyroid hormone. Following metamorphosis, each salamander’s tail tip was amputated and allowed to regenerate, and then amputated a second time and allowed to regenerate. Also, DNA was isolated from all individuals and genotypes were determined for 187 molecular markers distributed throughout the genome. The area of tissue that regenerated after the first and second amputations was highly positively correlated across males and females. Males presented wider tails and regenerated more tail tissue during both episodes of regeneration. Approximately 66–68% of the variation in regenerative outgrowth was explained by tail width, while tail length and genetic sex did not explain a significant amount of variation. A small effect QTL was identified as having a sex-independent effect on tail regeneration, but this QTL was only identified for the first episode of regeneration. Several molecular markers significantly affected regenerative outgrowth during both episodes of regeneration, but the effect sizes were small (<4%) and correlated with tail width. The results show that ambysex and minor effect QTL explain variation in adult tail morphology and importantly, tail width. In turn, tail width at the amputation plane largely determines the rate of regenerative outgrowth. Because amputations in this study were made at approximately the same position of the tail, our results resolve an outstanding question in regenerative biology: regenerative outgrowth positively co-varies as a function of tail width at the amputation site.     

The m. caudifemoralis longus and its relationship to caudal autotomy and locomotion in lizards (Reptilia: Sauna)

Although the phenomenon of tail autotomy has traditionally been viewed in a purely adaptive light, functional constraints imposed by the locomotor system appear to have influenced the presence and extent of autotomy in lizards. Them. caudifemoralis longus is an unsegmented hind limb retractor that originates from the caudal vertebrae. It does not participate in autotomy and thus limits the proximal position of autotomic septa. Variation in the extent of the m. caudifemoralis is correlated with locomotor type. The muscle is large and originates from a long series of caudal vertebrae in fast moving lizards with powerful limb retraction, as exemplified by taxa capable of bipedal running. In slower lizards with sprawling postures, such as geckos, the m. caudifemoralis is small and restricted to the first few postsacral vertebrae. Autotomy is typically restricted or absent in the former lizards, while in the latter only the most proximal vertebrae are incapable of autotomy. In the evolution of existing patterns of caudal autotomy, functional demands intrinsic to the tail may be subservient to locomotor constraints imposed on the tail base by the m. caudifemoralis longus .     

Muscle activity in autotomized tails of a lizard (Gekko gecko): a naturally occurring spinal preparation

We quantified muscle activity in tails of lizards (Gekko gecko) during running and after autotomy of the tail. We chose different animals and varied where we broke the tails in order to obtain three experimental preparations having: no regenerated tissue or prior tail loss (non-regenerated), a large regenerated portion and a few original caudal vertebrae (partially regenerated), and only regenerated tissue (fully regenerated). All observed axial motor patterns were rhythmic. During running of intact animals, muscles in non-regenerated tails were activated in an alternating, unilateral pattern that was propagated posteriorly. After autotomy, non-regenerated tails had unilateral muscle activity that alternated between the left and right sides and propagated anteriorly. Autotomized, partially regenerated tails had unilateral, alternating muscle activity that lacked any longitudinal propagation. Autotomized, fully regenerated tails had periodic muscle activity that occurred simultaneously for both left and right sides and all longitudinal positions. Neither tactile stimulation nor removal of the tail tip prior to autotomizing the tail affected the motor pattern. Several features of the motor pattern of autotomized tails changed significantly with increased time after autotomy. Autotomized tails with one or more spinal segments moved longer and more vigorously than autotomized tails consisting entirely of regenerated (unsegmented) tissue.Abbreviations AREA rectified integrated area - CYCDUR cycle duration or time between the onsets of successive bursts for a single channel - DUTY duty factor = EMG duration/CYCDUR - EMG electromyogram - EMGDUR EMG duration - INTENSITY = AREA/EMGDUR - ISPL intersegmental phase lag = PLAG/number of intervening muscle segments - LAG among site lag time = difference in onset times of adjacent ipsilateral electrode sites - PLAG phase lag = LAG/CYCDUR - RELISPL relative intersegmental phase lag = RELPLAG/number of intervening muscle segments - RELPLAG relative phase lag = LAG/EMGDUR     

Morphological and biochemical analyses of original and regenerated lizard tails reveal variation in protein and lipid composition

Caudal autotomy, or voluntary self-amputation of the tail, is a common and effective predator evasion mechanism used by most lizard species. The tail contributes to a multitude of biological functions such as locomotion, energetics, and social interactions, and thus there are often costs associated with autotomy. Notably, relatively little is known regarding bioenergetic costs of caudal autotomy in lizards, though key morphological differences exist between the original and regenerated tail that could alter the biochemistry and energetics. Therefore, we investigated lizard caudal biochemical content before and after regeneration in three gecko and one skink species. Specifically, we integrated biochemical and morphological analyses to quantify protein and lipid content in original and regenerated tails. All lizards lost significant body mass, mostly protein, due to autotomy and biochemical results indicated that original tails of all species contained a greater proportion of protein than lipid. Morphological analyses of two gecko species revealed interspecific differences in protein and lipid content of regenerated lizard tails. Results of this study contribute to our understanding of the biochemical consequences of a widespread predator evasion mechanism.     

Fragmenting oligochaete Enchytraeus japonensis: A new material for regeneration study

Enchytraeus japonensis, a recently described terrestrial oligochaete, reproduces asexually by fragmentation and subsequent regeneration. Taking notice of its high potential as a new material for regeneration study, detailed studies were undertaken on the regeneration and reproduction of E. japonensis. The full-grown body divided into 6-13 fragments that regenerated into complete individuals in 4 days, grew to full length in 10 days, and then fragmented again. Regeneration of the head and tail was epimorphic, involving blastema formation, while old segments in the regenerating fragment morphallactically transformed into the appropriate segments to retain the proper body proportions, which could be visualized by histochemistry for alkaline phosphatase. Artificially cut fragments regenerated either normally or into dicephalic monsters with biaxial heads depending on the conditions. Fragmentation could be induced by decapitation, and sexual reproduction was also found inducible in the laboratory. These findings, together with its simple metameric morphology and ease of culture and handling, suggest that E. japonensis is an excellent material for studying animal regeneration.     

Morphological,cellular and molecular characterization of posterior regeneration in the marine annelid Platynereis dumerilii

Regeneration, the ability to restore body parts after an injury or an amputation, is a widespread but highly variable and complex phenomenon in animals. While having fascinated scientists for centuries, fundamental questions about the cellular basis of animal regeneration as well as its evolutionary history remain largely unanswered. Here, we present a study of regeneration of the marine annelid Platynereis dumerilii, an emerging comparative developmental biology model, which, like many other annelids, displays important regenerative abilities. When P. dumerilii worms are amputated, they are able to regenerate the posteriormost differentiated part of their body and a stem cell-rich growth zone that allows the production of new segments replacing the amputated ones. We show that posterior regeneration is a rapid process that follows a well reproducible path and timeline, going through specific stages that we thoroughly defined. Wound healing is achieved one day after amputation and a regeneration blastema forms one day later. At this time point, some tissue specification already occurs, and a functional posterior growth zone is re-established as early as three days after amputation. Regeneration timing is only influenced, in a minor manner, by worm size. Comparable regenerative abilities are found for amputations performed at different positions along the antero-posterior axis of the worm, except when amputation planes are very close to the pharynx. Regenerative abilities persist upon repeated amputations without important alterations of the process. We also show that intense cell proliferation occurs during regeneration and that cell divisions are required for regeneration to proceed normally. Finally, 5-ethynyl-2’-deoxyuridine (EdU) pulse and chase experiments suggest that blastemal cells mostly derive from the segment immediately abutting the amputation plane. The detailed characterization of P. dumerilii posterior body regeneration presented in this article provides the foundation for future mechanistic and comparative studies of regeneration in this species.     

Ultrastructural changes in skeletal muscle of the tail of the lizard Hemidactylus mabouia immediately following autotomy

Araújo, T.H., Faria, F.P., Katchburian, E. and Freymüller, E. (2009). Ultrastructural changes in skeletal muscle of the tail of the lizard Hemidactylus mabouia immediately following autotomy. —Acta Zoologica (Stockholm) 91 : 440–446. Although autotomy and subsequent regeneration of lizard tails has been extensively studied, there is little information available on ultrastructural changes that occur to the muscle fibers at the site of severance. Thus, in the present study, we examine the ultrastructure of the musculature of the remaining tail stump of the lizard Hemidactylus mabouia immediately after autotomy. Our results show that exposed portions of the skeletal muscle fibers of the stump that are unprotected by connective tissue bulge to produce large mushroom‐like protrusions. These exposed portions show abnormal structure but suffer no leakage of cytoplasmic contents. Many small and large vesicular structures appeared between myofibrils in the interface at this disarranged region (distal) and the other portion of the fibers that remain unchanged (proximal). These vesicles coalesce, creating a gap that leads to the release of the mushroom‐like protrusion. So, our results showed that after the macroscopic act of autotomy the muscular fibers release part of the sarcoplasm as if a second and microscopic set of autotomic events takes place immediately following the macroscopic act of autotomy. Presumably these changes pave the way for the formation of a blastema and the beginning of regeneration.     

Limb regeneration and apolysis in the tick, Ornithodoros tartakovskyi.

Limb regeneration potential and the apolysis process were investigated in the argasid tick, Ornithodoros tartakovskyi. Developmental instars received single or multiple amputations and were subsequently allowed to undergo single or multiple apolyses. Amputated ticks regenerated complete normal limbs but only after four successive apolyses. Following a single apolysis, the majority of regenerated limbs were essentially miniature duplicates of normal legs but commonly lacked normal chaetotaxy and/or tarsal hump(s). The site of amputation distal to the coxa-trochanter joint, number of limbs removed from an individual, and instar amputated did not consistently influence the extent of regeneration. Coagulation and clot formation were observed.The limbs of the tick apolysed within the old leg hulls. Larvae and nymphs amputated relatively early during the period of apolyses regenerated limbs; late amputations precluded regeneration. The process of apolysis was irreversible and not obviously affected by amputations.     

中华真地鳖的断足再生

报道了中华真地鳖Eupolyphaga sinensis Walker的断足再生特征。研究结果表明,不同虫龄期的若虫都有断足再生能力;足的不同部位断足后均能再生;断掉不同数量的足后,只要能成活均可再生。断足再生后,继续断掉再生足的原位或其他部位也可以再生。再生足的跗节均比正常的少一节,具有再生不完整性。断足后,只要经1～2次蜕皮,均可再生。断掉一对足的腿节后,再生足出现大小不一的现象,小的一般发育不全,断足数量多容易出现再生足发育不全。再生足比正常足要小,但生长速度要快,断掉足的腿节或跗节后的再生足经过2次蜕皮后基本可恢复到正常足大小。     

Behavioral plasticity and central regeneration of locomotor reflexes in the freshwater oligochaete, Lumbriculus variegatus. I: Transection studies

Abstract. Access to the ventral nerve cord in living specimens of Lumbriculus variegatus , an aquatic oligochaete, is normally impossible because surgical invasion induces segmental autotomy (self-fragmentation). We show here that nicotine is a powerful paralytic agent that reversibly immobilizes worms, blocks segmental autotomy, and allows experimental access to the nerve cord. Using nicotine-treated worms, we transected the ventral nerve cord and used non-invasive electrophysiological recordings and behavioral analyses to characterize the functional recovery of giant nerve fibers and other reflex pathways. Initially, after transection, medial giant fiber (MGF) and lateral giant fiber (LGF) spikes conducted up to, but not across, the transection site. Reestablishment of MGF and LGF through-conduction across the transection site occurred as early as 10 h (usually by 20 h) after transection. Analyses of non-giant-mediated behavioral responses (i.e., helical swimming and body reversal) were also made following nerve cord transection. Immediately after transection, functional reorganization of touch-evoked locomotor reflexes occurred, so that the two portions of the worm anterior and posterior to the transection site were independently capable of helical swimming and body reversal responses. Similar reorganization of responses occurred in amputated body fragments. Reversion back to the original whole-body pattern of swimming and reversal occurred as early as 8 h after transection. Thus, functional restoration of the non-giant central pathways appeared slightly faster than giant fiber pathways. The results demonstrate the remarkable plasticity of locomotor reflex behaviors immediately after nerve cord transection or segment amputation. They also demonstrate the exceptional speed and specificity of regeneration of the central pathways that mediate locomotor reflexes.     

Asexual Reproduction and Segmental Regeneration, but not Morphallaxis, are Inhibited by Boric Acid in Lumbriculus variegatus (Annelida: Clitellata: Lumbriculidae)

Body fragmentation, in some animal groups, is a mechanism for survival and asexual reproduction. Lumbriculus variegatus (Müller, 1774), an aquatic oligochaete worm, is capable of regenerating into complete individuals from small body fragments following injury and reproduces primarily by asexual reproduction. Few studies have determined the cellular mechanisms that underlie fragmentation, either regenerative or asexual. We utilized boric acid treatment, which blocks regeneration of segments in amputated fragments and blocks architomic fission during asexual reproduction, to investigate mechanistic relationships and differences between these two modes of development. Neural morphallaxis, involving changes in sensory fields and giant fiber conduction, was detected in amputated fragments in the absence of segmental regeneration. Furthermore, neural morphallactic changes occurred as a result of developmental mechanisms of asexual reproduction, even when architomy was prevented. These results show that fragmentation in L. variegatus, during injury or asexual reproduction, employs developmental and morphallactic processes that can be mechanistically dissociated by boric acid exposure. In regeneration following injury, compensatory morphallaxis occurred in response to fragmentation. In contrast, anticipatory morphallaxis was induced in preparation for fragmentation during asexual reproduction. Thus, various forms of regeneration in this lumbriculid worm can be activated independently and in different developmental contexts.     

Regulation of proximal-distal intercalation during limb regeneration in the axolotl (Ambystoma mexicanum)

Intercalation is the process whereby cells located at the boundary of a wound interact to stimulate proliferation and the restoration of the structures between the boundaries that were lost during wounding. Thus, intercalation is widely considered to be the mechanism of regeneration. When a salamander limb is amputated, the entire cascade of regeneration events is activated, and the missing limb segments and their boundaries (joints) as well as the structures within each segment are regenerated. Therefore, in an amputated limb it is not possible to distinguish between intersegmental regeneration (formation of new segments/joints) and intrasegmental regeneration (formation of structures within a given segment), and it is not possible to study the differential regulation of these two processes. We have used two models for regeneration that allow us to study these two processes independently, and report that inter- and intrasegmental regeneration are different processes regulated by different signaling pathways. New limb segments/joints can be regenerated from cells that dedifferentiate to form blastema cells in response to signaling that is mediated in part by fibroblast growth factor.