Vertebrate limb regeneration and the origin of limb stem cells

The existence of multipotent cells in the adult tissues and organs of those vertebrates that are capable of regeneration has been accepted for decades. Although studies of vertebrate limb regeneration have yet to identify many of the specific molecules involved in regeneration, numerous tissue grafting experiments and studies of cell lineage have contributed significantly to an understanding of the origin, activation, proliferation and cell-cell interactions of these progenitor cells. This has allowed the development of ideas about the regulation of pattern formation to restore the structure and function of lost tissues and organs. An understanding of the molecular mechanisms controlling these processes has lagged behind the dramatic advances achieved with other model organisms. However, given the intense, new research interest in stem cells over the past few years, there is good reason to be encouraged that insights about the biology of mammalian stem cells will accelerate progress in understanding the biology of regeneration in organisms that can regenerate. Advances in regeneration research will then feed back in terms of devising new strategies for therapies to induce regeneration in organisms such as humans that have traditionally been viewed as incapable of regeneration.     

Vertebrate limb development and possible clues to diversity in limb form

Chick embryos are good models for vertebrate development. The principles that underlie chick wing development have been discovered and there is increasing knowledge about the molecules involved. The importance of identifying molecules is that this provides a direct link to understanding the genetic basis of diversity in form. Chick wing development will be compared with limb development in other vertebrates. Possible mechanisms that could lead to variations in form, including limb reductions and limblessness, differences between fore- and hindlimbs, limb proportions, and interdigital webbing can be suggested.     

Uterine trauma and limb defects

The temporary clamping of the uterine blood vessels on one side of the uterus during late pregnancy in the rat (days 14-16) results in hemorrhage and tissue necrosis in the extremities of the fetuses from the experimental side and occasionally from the control side. A further series of experiments showed that similar fetal hemorrhage followed the temporary clamping (45 minutes) of the uterine wall or uterine fat, excluding major uterine vessels; handling the uterus for 5 minutes; and stretching of the uterine blood vessels. A low incidence of fetal hemorrhage was also associated with laparotomy alone, but the fetuses were unaffected by extensive handling of the uterus through the abdominal wall or by intraperitoneal anesthesia. Fetal hemorrhage was also induced by a short episode of severe maternal hyperthermia but not by a high dose of ethanol given by gavage. These results suggest that a range of uterine trauma may result in fetal hemorrhage, perhaps through a common mechanism.     

The vasculature and limb development

The developing vascular pattern of the embryonic chick limb results from a combination of two properties: the intrinsic self-assembly and branching properties of the vascular cells and the extrinsic information associated with the expanding mitotic population of mesenchymal cells; and the inhibitory factors which restrict the entrance of vessels into particular domains and/or decrease the branching frequency of such vessels. It is hypothesized that an important component of limb pattern formation is the interplay between the dividing population of mesenchymal cells and the intrinsic properties of the vascular cells. It is further asserted that the presence of particular vascular elements may, indeed, be 'positional information'. Two examples are cited involving aspects of limb duplication to support this possibility; it is suggested that vascular vessel size of a host limb may dictate the polarity of duplication events. The presented hypothesis emphasizes that the interplay between the intrinsic properties of self-assembly into tissues and extrinsic factors which establish boundaries and morphologies is involved in both vascular and limb pattern formation.     

The expression pattern of tomoregulin-1 in urodele limb regeneration and mouse limb development

Tomoregulin-1 (TMEFF1) was first identified as a gene implicated in pituitary secretion in Xenopus laevis. The predicted structure of TMEFF1 is that of a transmembrane protein with a highly conserved cytoplasmic tail, two follistatin domains and one modified EGF domain in its extracellular region. We report the cloning of the newt orthologue, and show that the expression of TMEFF1 is upregulated in the blastema during limb regeneration, and is also expressed in mouse embryonic limb development.     

Retinoids and vertebrate limb pattern formation

It has long been suggested that pattern formation depends in part on signalling molecules known as 'morphogens', diffusible substances that determine cell fate in a concentration-dependent way. Retinoic acid, a small hydrophobic molecule that binds to nuclear receptors, is a candidate morphogen for specifying the anteroposterior pattern of vertebrate limbs.     

Pattern regulation in the embryonic chick limb: Supernumerary limb formation with anterior (non-ZPA) limb bud tissue

The formation of supernumerary limbs and limb structures was studied by juxtaposing normally nonadjacent embryonic chick limb bud tissue. A “wedge” (ectoderm and mesoderm) of anterior or mid donor right wing bud (stage 21) was inserted in a slit made in a host right limb bud (stage 21) at the same position as its position of origin or to a more posterior position. The AER of the donor tissue and host wing bud were aligned with each other. Donor tissue was grafted with its dorsalventral polarity the same as the host's limb bud or reversed to that of the host's. Depending on the position of origin of the donor limb bud tissue and the position to which it was transplanted in a host, supernumerary wings or wing structures formed. Furthermore, depending on the orientation of the graft in the host, supernumerary limbs with either left or right asymmetry developed. The results of experiments performed here are considered in light of two current models which have been used to describe supernumerary limb formation: one based on local, short-range, cell-cell interactions and the other based on long-range positional signaling via a diffusible morphogen.     

Lipotyphla limb myology comparison

Fore- and hindlimb muscles were dissected in four species of Lipotyphla: the western European hedgehog Erinaceus europaeus (Erinaceidae, Erinaceinae); the moonrat Echinosorex gymnura (Erinaceidae, Hylomyinae or Galericinae); the tailless tenrec Tenrec ecaudatus (Tenrecidae, Tenrecinae); and the common European white-toothed shrew Crocidura russula (Soricidae, Soricinae). This work completely reviews the limb musculature of these walking mammals. Twelve myological characters were evaluated in order to disclose phylogenetic relationships. The cladogram obtained supported previous ones based on cranial and dental characters. This study shows that myological characters are valuable in phylogenetic analyses.     

Hyaluronan in limb morphogenesis

Hyaluronan (HA) is a large glycosaminoglycan that is not only a structural component of extracellular matrices, but also interacts with cell surface receptors to promote cell proliferation, migration, and intracellular signaling. HA is a major component of the extracellular matrix of the distal subapical mesenchymal cells of the developing limb bud that are undergoing proliferation, directed migration, and patterning in response to the apical ectodermal ridge (AER), and has the functional potential to be involved in these processes. Here we show that the HA synthase Has2 is abundantly expressed by the distal subridge mesodermal cells of the chick limb bud and also by the AER itself. Has2 expression and HA production are downregulated in the proximal central core of the limb bud during the formation of the precartilage condensations of the skeletal elements, suggesting that downregulation of HA may be necessary for the close juxtaposition of cells and the resulting cell-cell interactions that trigger cartilage differentiation during condensation. Overexpression of Has2 in the mesoderm of the chick limb bud in vivo results in the formation of shortened and severely malformed limbs that lack one or more skeletal elements. Skeletal elements that do form in limbs overexpressing Has2 are reduced in length, exhibit abnormal morphology, and are positioned inappropriately. We also demonstrate that sustained HA production in micromass cultures of limb mesenchymal cells inhibits formation of precartilage condensations and subsequent chondrogenesis, indicating that downregulation of HA is indeed necessary for formation of the precartilage condensations that trigger cartilage differentiation. Taken together these results suggest involvement of HA in various aspects of limb morphogenesis.     

Distal trisomy 10q and limb defects

Analysis of the literature showed that hypoplasia (or aplasia) of tibiae was found at least in six persons with trisomy 10q25.2-qter. Therefore, these defects should be considered as a characteristic manifestation of the distal trisomy 10q. In most of these patients, tibial abnormalities were associated with other defects of the lower extremities (hypoplastic femora, ectrodactyly, preaxial polydactyly). Upper limbs were affected in one patient (as well as in her sib without tibial defects). Most likely, segment 10q25.2-qter contains a gene which (when triplicated) leads to maldevelopment of the limbs, and tibial malformations are only one manifestation of this field defect.     

Are limb development and limb regeneration both initiated by an integumentary wounding?: A hypothesis

It is proposed that, whereas an actual wound to a salamander limb may initiate limb regeneration, a local and developmentally programmed integumentary wound may initiate limb development. The electrophysiological changes induced by these lesions of the skin may be a common denominator linking limb regeneration and limb development. Such early electrical events are considered to initiate or guide the early accumulation of cells, and to help to produce the local environment in which a limb will arise. This scheme provides a self-limiting positive-feedback mechanism for the production of a localized area where other developmental mechanisms act in concert with endogenous electrical fields (or in their complete absence), thereby leading to limb differentiation. This hypothesis may not be restricted to limb formation; it may be of more general significance, i.e. in the process of organogenesis in embryos. One might reasonably suggest that, by such a mechanism, any developing placode (for example, auditory or olfactory placodes) might form and localize.