Calcification of Cartilage from the Lamprey <i>Petromyzon marinus</i> (L.) <i>in vitro</i>

Langille, Robert M.; Hall, Brian K.

doi:10.1111/j.1463-6395.1993.tb01218.x

Cited by 28 publications

(15 citation statements)

References 34 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Rather, the earliest representation of the vertebrate "skeletal system" relates entirely to feeding and respiration. To an extent, this conflates skeletonization with calcification, but the distinction between the two is hard to draw (e.g., Langille and Hall, 1993;Meunier and Huysseune, 1992) since they are interdependent, as can be evidenced by the fact that in most jawed vertebrates development of the embryonic endoskeleton proceeds without calcification until much of the structure has been established. Until the origin of the dermoskeleton, to which all the existing hypotheses relate, the evolution of skeletonization within the vertebrate lineage was all endoskeletal, and almost entirely splanchnocranial.…”

Section: Origin Of the Vertebrate Skeletonmentioning

confidence: 97%

“…The controversy surrounding conodont and thelodont oral skeletal elements notwithstanding, lampreys are the earliest members of the vertebrate lineage to exhibit evidence of endoskeletal calcification (Langille and Hall, 1993), in both the neurocranium and splanchocranium, although there is little more than circumstantial evidence to indicate that this extends beyond in vitro conditions (e.g., Bardack and Zangerl, 1971). There is equivocal evidence of a mineralized endoskeleton among the heterostracomorphs: globular calcified cartilage is found in association with one of the heterostracomorphs, Eriptychius ( Fig.…”

Section: Gnathostome Stem-lineagementioning

confidence: 98%

“…Lampreys afford the earliest evidence of skeletal calcification within the vertebrate lineage (Langille and Hall, 1993).…”

Section: Basal Vertebrates and The Invertebratementioning

confidence: 99%

See 2 more Smart Citations

Origin and early evolution of vertebrate skeletonization

Donoghue

Sansom

2002

Microscopy Res & Technique

200

255

View full text Add to dashboard Cite

Data from living and extinct faunas of primitive vertebrates imply very different scenarios for the origin and evolution of the dermal and oral skeletal developmental system. A direct reading of the evolutionary relationships of living primitive vertebrates implies that the dermal scales, teeth, and jaws arose synchronously with a cohort of other characters that could be considered unique to jawed vertebrates: the dermoskeleton is primitively composed of numerous scales, each derived from an individual dental papilla; teeth are primitively patterned such that they are replaced in a classical conveyor-belt system. The paleontological record provides a unique but complementary perspective in that: 1) the organisms in which the skeletal system evolved are extinct and we have no recourse but to fossils if we aim to address this problem; 2) extinct organisms can be classified among, and in the same way as, living relatives; 3) a holistic approach to the incorporation of all data provides a more complete perspective on early vertebrate evolution. This combined approach is of no greater significance than in dealing with the origin of the skeleton and, combined with recent discoveries and new phylogenetic analyses, we have been able to test and reject existing hypotheses for the origin of the skeleton and erect a new model in their place.

show abstract

Section: Origin Of the Vertebrate Skeletonmentioning

confidence: 97%

Section: Gnathostome Stem-lineagementioning

confidence: 98%

See 1 more Smart Citation

Origin and early evolution of vertebrate skeletonization

Donoghue

Sansom

2002

Microscopy Res & Technique

200

255

View full text Add to dashboard Cite

show abstract

“…Agnathan statoliths are composed from an amorphous (polyhydroxyl) calcium phosphate, which is highly unstable and dissolves in a solution of pH 8 or less (R. W. Gauldie, personal communication). Lamprey biomineralization is similarly restricted to the formation of statoliths, although under the right conditions (in vivo or in vitro) lampreys are capable of skeletal biomineralization, in particular, calci¢-cation of cartilage (Langille 1987;Langille & Hall 1993;Bardack & Zangerl 1971).…”

Section: (A) Lamellar Crown Tissuementioning

confidence: 99%

Growth and patterning in the conodont skeleton

Donoghue

1998

Phil. Trans. R. Soc. Lond. B

109

146

View full text Add to dashboard Cite

Recent advances in our understanding of conodont palaeobiology and functional morphology have rendered established hypotheses of element growth untenable. In order to address this problem, hard tissue histology is reviewed paying particular attention to the relationships during growth of the component hard tissues comprising conodont elements, and ignoring a priori assumptions of the homologies of these tissues. Conodont element growth is considered further in terms of the pattern of formation, of which four distinct types are described, all possibly derived from a primitive condition after heterochronic changes in the timing of various developmental stages. It is hoped that this may provide further means of unravelling conodont phylogeny. The manner in which the tissues grew is considered homologous with other vertebrate hard tissues, and the elements appear to have grown in a way similar to the growing scales and growing dentition of other vertebrates.

show abstract

“…The mean E of aged pericardial cartilage was found to be statistically larger than the mean E of young and aged annular cartilage, young pericardial cartilage, as well as bovine auricular cartilage tested in tension and compression. Since lamprey cartilage has demonstrated the ability to calcify in vitro (Langille and Hall, 1993), the 'crisp' consistency of aged lamprey pericardial cartilage suggested a possible deposition of calcium within the cartilage ECM, within the chondrocytes or, possibly, within the inter-fibrillar spaces of perichondrial collagen fibers. However, staining with alizarin red was inconclusive; young and aged pericardial cartilages gave staining patterns that were virtually identical (both with and without EDTA treatment).…”

Section: Stiffnessesmentioning

confidence: 99%

Comparative equilibrium mechanical properties of bovine and lamprey cartilaginous tissues

Courtland

Wright

Root

et al. 2003

Journal of Experimental Biology

View full text Add to dashboard Cite

SUMMARY In contrast to all other vertebrate cartilages, the major extracellular matrix protein of lamprey cartilages is not collagen. Instead, there exists a unique family of noncollagenous structural proteins, the significance of which is not completely understood. A custom-built uniaxial testing apparatus was used to quantify and compare equilibrium stress-relaxation behavior(equilibrium moduli, stress decay behavior, recovery times and relaxation times) of (1) lamprey pericardial cartilages with perichondria tested in tension (young adult and aged), (2) annular cartilages without perichondria tested in compression (young adult and aged) and (3) bovine auricular cartilage samples without perichondria tested in both tension and compression. Results of this study demonstrated that all cartilages were highly viscoelastic but with varying relaxation times; approximately 120 min for annular and pericardial cartilages and 30 min for bovine auricular cartilages. For mean equilibrium moduli, young adult lamprey annular cartilages (0.71 MPa)and pericardial cartilages (2.87 MPa) were found to be statistically different. The mean moduli of all bovine auricular cartilages were statistically identical to lamprey cartilages except in the case of aged adult pericardial cartilages, which were statistically larger than all other cartilages at 4.85 MPa. Taken together, the results of this study suggest that lamprey cartilages are able to exhibit mechanical properties largely similar to those of mammalian cartilages despite unique structural proteins and differences in extracellular matrix organization.

show abstract

Calcification of Cartilage from the Lamprey Petromyzon marinus (L.) in vitro

Cited by 28 publications

References 34 publications

Origin and early evolution of vertebrate skeletonization

Origin and early evolution of vertebrate skeletonization

Growth and patterning in the conodont skeleton

Comparative equilibrium mechanical properties of bovine and lamprey cartilaginous tissues

Contact Info

Product

Resources

About