Urogenital morphology of dipnoans, with comparisons to other fishes and to amphibians

Wake, Marvalee H.

doi:10.1002/jmor.1051900414

Cited by 17 publications

(4 citation statements)

References 31 publications

(2 reference statements)

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“…In spring, all the tubules of the kidneys were packed with mature spermatozoa. Neoceratodus appears to use the tubules of the entire kidney to convey sperm to the mesonephric duct for transport to the cloaca, a phenomenon described previously by Wake (1987).…”

Section: Testis Histologymentioning

confidence: 75%

In VitroBiosynthesis of Androgens in the Australian Lungfish,Neoceratodus forsteri

Joss

Edwards

Kime

1996

General and Comparative Endocrinology

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Section: Testis Histologymentioning

confidence: 75%

In VitroBiosynthesis of Androgens in the Australian Lungfish,Neoceratodus forsteri

Joss

Edwards

Kime

1996

General and Comparative Endocrinology

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“…The extant representatives of Actinistia and Dipnoi, descendant taxa of sarcopterygiian sister groups of amphibians (Schultze, 1994), possess oviducts (Millot and Anthony, 1960;Wake, 1987) and Latimeria is viviparous (Smith et al, 1975), indicating that fertilization is internal (Fig. 13).…”

Section: Comparative Biologymentioning

confidence: 99%

Sperm storage in the oviduct of the internal fertilizing frog Ascaphus truei

Sever

Moriarty

Rania

et al. 2001

Journal of Morphology

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This study provides the first descriptions of sperm storage at the tissue and cellular levels in a female frog or toad. Oviducal anatomy was studied by light and electron microscopy in Ascaphus truei from north coastal California. Ascaphus truei is one of the few species of anurans in which fertilization is internal. Unlike other anurans with internal fertilization, however, mating in A. truei consists of a unique combination of amplectic and copulatory mechanisms that we term "copulexus." Posterior to a short, aglandular infundibular region, the oviduct possesses: 1) a proximal, convoluted ampullary region where intrinsic tubular glands secrete gelatinous envelopes around eggs; 2) a middle ovisac region where fertilization occurs; and 3) a distal oviducal sinus formed by medial junction of the ovisacs. Sperm storage tubules (SSTs) occur in the anterior portions of the ovisacs and consist of simple tubular glands. SSTs and the rest of the oviducal lining stain positively with the periodic acid-Schiff's procedure for neutral carbohydrates and this reaction is especially intense in reproductively active females. Sperm were found in the SSTs of gravid females as well as some nonvitellogenic females. The sperm are in orderly bundles in the SSTs, and although occasionally sperm nuclei were embedded in the epithelium, no evidence for spermiophagy was found. Oviducal sperm storage in A. truei is homoplastic, with closest structural similarities to squamate reptiles. Oviduct/sperm design constraints appear to limit the options for expression of features associated with oviducal sperm storage.

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“…Soft-tissue analysis can provide valuable information about generic and familial relationships. This has previously been shown for muscle (Rosen et al, 1981) and renal (Wake, 1986) tissues.…”

Section: Discussionmentioning

confidence: 61%

The development of the sturgeon heart

et al. 2004

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This paper presents a sequential analysis of the development of the sturgeon (Acipenser naccarii) heart from the end of gastrulation to the early juvenile stages. At late neurulation, the heart appears as a straight, short tube located over the endoderm that forms the wall of the yolk sac, in front of the developing head. The heart axis is aligned with the axis of the developing head. Subsequently, the heart elongates and adopts a C-shape, and its axis becomes perpendicular to that of the head. Around the time of hatching, the heart loses the loop and appears as a mostly straight tube with the chambers arranged in a craniocaudal sequence: outflow tract, ventricle, atrium, and a small sinus venosus. During the first 4 days post-hatching (dph), the heart starts looping again, adopts a C-shape, and undergoes a counterclockwise movement that brings the atrium to the left of the outflow tract and the ventricle to a caudal position. Thus, a primary and a secondary cardiac loop occur in the sturgeon. Later, the atria come to occupy a middle position behind the outflow tract, and the sinus venosus shifts from a caudal to a dorsal position. A morphological arrangement similar to that found in adult sturgeons is attained in all specimens at days 7-9 dph. The external changes are accompanied by a series of internal modifications that include trabeculation (3-4 dph), development of endocardial cushions in the atrioventricular canal (4 dph) and in the conus arteriosus (3-4 dph), conus (22-24 dph) and atrioventricular (18-20 dph) valve formation, and development of the epicardium (4 dph) and the coronary vessels (10 dph). The main developmental features of the heart have been registered, and a basic body of information, which should be very useful in future developmental studies, has been established. Similarities and dissimilarities between the development of the sturgeon heart and that of other vertebrates are underscored.

show abstract

Urogenital morphology of dipnoans, with comparisons to other fishes and to amphibians

Cited by 17 publications

References 31 publications

In VitroBiosynthesis of Androgens in the Australian Lungfish,Neoceratodus forsteri

In VitroBiosynthesis of Androgens in the Australian Lungfish,Neoceratodus forsteri

Sperm storage in the oviduct of the internal fertilizing frog Ascaphus truei

The development of the sturgeon heart

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