Spatially unique Shh-Fgf8 distribution in regenerating limb guarantees consistent limb morphogenesis in different limb sizes and contributes to axolotl specific digit patterning.

Limb regeneration in Ambystoma mexicanum occurs in various sizes of fields and can recreate consistent limb morphology. It was not known what mechanism supports such stable limb morphogenesis regardless of size. Limb regeneration in urodele amphibians has been basically considered to recapitulate the limb developmental processes. Many molecules in the limb developmental processes are conserved with other tetrapods. SHH and FGF8 play important roles in the morphogenesis of limbs among them. Focusing on these two factors, we investigated the detailed expression pattern of Shh and Fgf8 in the various sizes of blastema in axolotl limb regeneration. Fgf8 is expressed in the anterior side of a blastema and Shh is expressed in the posterior side. These are maintained in a mutually dependent manner. We also clarified that the size of Shh and Fgf8 expression domains were scaled as the size of the blastemas increased. However, it was found that the secretion and working range of SHH were kept constant. We also found that the consistent SHH secretion range contributed to promoting cell proliferation and the first digital cartilage differentiation near the Shh expression domain. This would be a reasonable system to guarantees constant limb morphogenesis regardless of the blastema size. We also showed that the Shh-Fgf8 expression domain was shifted posteriorly as the digital differentiation progressed. Consistently, slowing the timing of blocking Shh signaling resulted in morphological defects that could be observed in only posterior digits. The revealed posteriorly shifting Shh-Fgf8 domain might explain urodele specific digit formation, in which digits are added posteriorly.

Excisional biopsy and radiotherapy for management of an olfactory neuroblastoma in an axolotl (Ambystoma mexicanum)

CASE DESCRIPTION A 4-year-old sexually intact male leucistic axolotl (Ambystoma mexicanum) was presented with a 2-week history of dysrexia and difficulty swallowing. CLINICAL FINDINGS Physical examination revealed a 1-cm-diameter intraoral mass on the rostral aspect of the palate and swelling of the left nasal fossa. Local invasion into the left nasal fossa was suspected during oral examination. The lesion was marginally excised, and an incompletely excised olfactory neuroblastoma was diagnosed histologically. Five weeks later, physical examination revealed persistent erythema, delayed healing of the rostral portion of the palate, and a mild facial deformity associated with a white mass in the nasal cavity. TREATMENT AND OUTCOME 6 weeks after excision, adjuvant electron (6-MeV) beam radiotherapy was initiated for treatment of the incompletely excised olfactory neuroblastoma and likely presence of a recurrent mass. The protocol consisted of 4 weekly fractions of 8 Gy each (total, 32 Gy) with the axolotl under anesthesia. No acute adverse radiation effects were noted following radiotherapy. The oral erythema resolved after the third session. No recurrence was observed 2 months after treatment, and the owners reported no abnormal signs at home. The axolotl died 3.5 months after radiotherapy was completed (8 months after marginal excision of the tumor) secondary to an environmental management failure. Postmortem histologic evaluation showed no evidence of neoplasia. CLINICAL RELEVANCE In axolotls, olfactory neuroblastoma should be considered in the differential diagnosis of intraoral palatal masses. This report describes the first application of radiotherapy for treatment of an olfactory neuroblastoma in an axolotl.

Novel Expansion of Matrix Metalloproteases in the Laboratory Axolotl (Ambystoma mexicanum) and Other Salamander Species

Matrix metalloprotease (MMP) genes encode endopeptidases that cleave protein components of the extracellular matrix (ECM) as well as non-ECM proteins. Here we report the results of a comprehensive survey of MMPs in the laboratory axolotl and other representative salamanders. Surprisingly, 28 MMPs were identified in salamanders and 9 MMP paralogs were identified as unique to the axolotl and other salamander taxa, with several of these presenting atypical amino acid insertions not observed in other tetrapod vertebrates. Furthermore, as assessed by sequence information, all of the novel salamander MMPs are of the secreted type, rather than cell membrane anchored. This suggests that secreted type MMPs expanded uniquely within salamanders to presumably execute catalytic activities in the extracellular milieu. To facilitate future studies of salamander-specific MMPs, we annotated transcriptional information from published studies of limb and tail regeneration. Our analysis sets the stage for comparative studies to understand why MMPs expanded uniquely within salamanders.

Valores hematológicos y bioquímicos del axolotl (Ambystoma mexicanum) mantenidos en cautiverio en Lima, Perú

El axolotl o ajolote es un anfibio caudado utilizado en numerosos estudios biomédicos por su capacidad regenerativa. Actualmente se encuentra en la categoría de peligro crítico de extinción a consecuencia de la contaminación acuática, caza indiscriminada e introducción de especies invasoras en su medioambiente natural. El objetivo del presente estudio fue determinar los rangos de parámetros hematológicos y bioquímicos de axolotls cautivos en Lima, Perú, para que puedan ser utilizados como referencia durante la evaluación clínica en laboratorios biomédicos y consultorios veterinarios de especies no convencionales. El estudio se realizó en una colección privada de axolotls en el distrito de San Juan de Miraflores, Lima. Se emplearon 27 axolotls, los cuales fueron restringidos químicamente para realizar la colecta de sangre, lográndose establecer rangos referenciales para 13 parámetros hematológicos y 10 bioquímicos.

The single-cell transcriptional landscape of the axolotl

The Mexican axolotl (Ambystoma mexicanum) is a promising tetrapod model for regeneration and developmental studies. Remarkably, neotenic axolotls may undergo metamorphosis, during which their regeneration capacity and lifespan gradually decline. However, a system-level single-cell analysis of molecular characteristics in neotenic and metamorphosed axolotls is still lacking. Here, we developed a single-cell RNA-seq method based on combinatorial hybridization to generate a tissue-based transcriptomic atlas of the adult axolotl. We performed gene expression profiling of over 1 million single cells across 19 tissues to construct the first adult axolotl cell atlas. Comparison of single-cell transcriptomes between the tissues of neotenic and metamorphosed axolotls revealed the heterogeneity of structural cells in different tissues and established their regulatory network. Furthermore, we described dynamic gene expression patterns during limb development in neotenic axolotls. These data serve as a resource to explore the molecular identity of the axolotl as well as its metamorphosis.

Detailed morphological analysis of axolotl sperm

The axolotl has extraordinary regeneration capacity compared to other vertebrates. This remarkable potential has been attributed to its life-long neoteny, characterized by the exhibition of embryonic characteristics at the adult stage. A recent study provided a detailed morphological analysis of the sperm morphology of the Ambystoma mexicanum using routine and detailed histological techniques. The primary purpose of the present study is to describe a simple and inexpensive method for evaluating the morphology of axolotl sperm. In this study, spermatophore structures were collected and spread on slides and air-dried. The slides were stained with periodic acid Schiff, toluidine blue, Masson’s trichrome, Giemsa, Spermac, and Diff-Quik dye for a morphological examination. The slides were coated with gold/palladium for a scanning electron microscopy examination. The sperm of the axolotl consisted of an elongated head, a neck, and a flagellum covered with an undulating membrane. The lengths of the midpiece, tail, and head were 8.575 µm, 356.544 µm, and 103.661 µm, respectively. In the flagellum part, the wavy membrane structure, whose function has not been explained, surrounds the tail. The data obtained from this study will constitute an important step in designing future research on the reproductive and regeneration capacity of the axolotl.

Ambystoma mexicanum, a model organism in developmental biology and regeneration: a colombian experience

Ambystoma mexicanum is a urodele amphibian endemic to Xochimilco Lake in Mexico, it belongs to the salamander family Ambystomatidae. This species has frequently been used as model organism in developmental biology and regeneration laboratories around the world due to its broad regenerative capacities and adaptability to laboratory conditions. In this review we describe the establishment of the first colony of axolotls in Colombia to study tissue regeneration and our perspectives on the use A. mexicanum as a model organism in Colombia are discussed emphasizing its possible uses in regeneration and developmental biology

Fluctuation of cellular differentiation in limb regeneration is regulated by Pde4b in urodele amphibians

Urodele amphibians, Pleurodeles waltl and Ambystoma mexicanum, have organ level regeneration capability, such as limb regeneration. Multipotent cells are induced by an endogenous mechanism in amphibian limb regeneration. It is well known that dermal fibroblasts receive regenerative signals and turn into multipotent cells, called blastema cells. However, the induction mechanism of the blastema cells from matured dermal cells was unknown. We previously found that BMP2, FGF2, and FGF8 (B2FF) could play sufficient roles in blastema induction in urodele amphibians. Here, we show that B2 FF treatment can induce dermis derived cells that can participate in multiple cell lineage in limb regeneration. We first established a newt dermis derived cell line and confirmed that B2FF treatment on the newt cells provided plasticity in cellular differentiation in limb regeneration. Interspecies comparative analysis clarified that Pde4b upregulation by B2FF specifically took place in the newt cells. Blocking P DE4B signaling by Rolipram suppressed dermis to cartilage transformation and the mosaic knockout animals showed consistent results . Our results are a valuable insight into how dermal fibroblasts acquire multipotency during the early phase of limb regeneration via an endogenous program in amphibian limb regeneration.