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Tissue and Cell 39 (2007) 225240
Amphibian hatching gland cells: Pattern and distribution in anurans
M. Nokhbatolfoghahai a,, J.R. Downie b
a Biology Department, Faculty of Sciences, Shiraz University, Shiraz, Iranb Division of Environmental and Evolutionary Biology, Graham Kerr Building, University of Glasgow, Glasgow G12 8QQ, Scotland, UK
Received 25 September 2006; received in revised form 14 April 2007; accepted 26 April 2007
Available online 21 June 2007
Abstract
The hatching gland (HG) is a transient organ, found in most anuran embryos and early larvae, and located on the dorsal side of the head.The enzymes secreted by hatching gland cells (HGCs) aid the embryos to escape from their enveloping coats. Analysis of HG morphology
and distribution in 20 anuran species from six families using scanning electron microscopy revealed small differences in the shape and pattern
of the gland particularly in the length and width of the posterior mid-dorsal extension of the gland. The four species of foam-nest making
leptodactylids examined had HGs of a somewhat different shape to the others, but otherwise, there was little sign of a relationship between
HG shape and taxonomic position. In the single Eleutherodactylusspecies examined, cells with the appearance and location of HGCs were
transiently present long before the active stage of hatching. No sign of HGCs was seen on the head surface of one species, Phyllomedusa
trinitatis. It seems possible that in this species, hatching is achieved by a mechanical rather than an enzymatic mechanism. The microvilli
characteristic of the surfaces of HGCs were quite variablein density and length from species to species, and at different stages. HGCs remained
at the surface of the embryo for some time after hatching and the possibility of a post-hatching function is briefly discussed.
2007 Elsevier Ltd. All rights reserved.
Keywords: Hatching gland cell; Anuran embryos; Microvilli; SEM
1. Introduction
In the oviparous vertebrates, the egg is surrounded by
a set of enveloping structures formed in the ovary and in
the oviduct. In amphibians, the enveloping structures are the
vitelline membrane (formed in the ovary) and a set of jelly
coats (secreted by the oviduct). The jelly coat varies in com-
plexity and thickness, relating to taxonomic group and the
environment into which the eggs are released (Duellman and
Trueb, 1994; Salthe, 1963).According toMartin (1999),the
end of the embryonic phase and the start of larval life maybe defined by the stage of hatching, though other authors
(e.g. Balon, 1984) regard hatching as occurring at such varied
stages in terms of morphological and functional development
Correspondingauthor at: Biology Department, Faculty of Sciences, Shi-
raz University, Shiraz 71454, Iran. Tel.: +98 7112280916;
fax: +98 7112280916.
E-mail addresses:[email protected], [email protected]
(M. Nokhbatolfoghahai).
that it is preferable to define theonset of exogenousfeeding as
the start of the larval phase. Hatching is the process by which
the developing animal frees itself of its enveloping structures
and fully enters the external environment. The stage at when
this happens is generally regardedas specific to any particular
species but in some amphibians, thestage of hatching canvary
and is responsive to environmental factors (Martin, 1999). For
example, terrestrial embryos of the salamander Amphiuma
meanshatch in response to inundation and the stage at which
this happens can vary considerably (Gunzburger, 2003);in
several anuran species, hatching can occur prematurely inresponse to attack by predators or pathogens (Warkentin,
1995; Vonesh, 2005; Touchon et al., 2006).
Whatever the precise timing, hatching in amphibians is
mediated primarily by the activity of a transient popula-
tion of late embryonic epidermal cells, the hatching gland
cells (HGCs). The hatching gland (HG), sometimes known
as the frontal gland, has generally been described as a Y-
shaped array of cells on the head of the embryo, the arms
of the Y pointing anteriorly (Altig and McDiarmid, 1999).
0040-8166/$ see front matter 2007 Elsevier Ltd. All rights reserved.
doi:10.1016/j.tice.2007.04.003
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226 M. Nokhbatolfoghahai, J.R. Downie / Tissue and Cell 39 (2007) 225240
The activity of these cells is the release of a set of pro-
teolytic enzymes whose role is to weaken or breakdown
the enveloping structures (Yoshizaki and Katagiri, 1975;
Yoshizaki, 1991).Fan and Katagiri (2001)identified two dif-
ferent proteolytic molecules (40 and 60 kDa, respectively)
whichactedco-operatively to hydrolyse the embryo envelope
inXenopus laevis.In many amphibians, hatching is a two-phase process. In
most urodeles, the vitelline membrane breaks down at neu-
rulation, but hatching from the remaining enveloping layers
is much later (Duellman and Trueb, 1994).In anurans, three
basic patterns were describedby Duellman and Trueb (1994).
First, early vitelline membrane breakdown followed by later
release from the outer capsules. In the direct-developing
eleutherodactylids, final release is mediated by the egg tooth,
rather than by hatching enzymes. Second, in many aquatic
developing species, the outermost layer of the jelly capsule
ruptures first, probably as a result of differential swelling of
the capsular layers. Vitelline membrane and inner layers are
later brokendowntogetherby hatching gland activity(Carrolland Hedrick, 1974).Third, in others, vitelline membrane and
capsular layers are broken down together with no preliminary
stage.
Detailed descriptions of the hatching process are scarce in
the literature.Bless (1905)account of hatching in X. laevis
indicates that the morphology of the hatching gland may be
important to the process but also that both physical activity
and the cement gland have roles. Bles (1905)noticed that a
mucus thread secreted by the cement gland anchors the head
of the late embryo to a particular point on the inner vitelline
membrane surface. The embryo turns over every 10 min or
so, touching a localised point on the vitelline membrane withits frontal gland (site of HGCs), and presumably releasing the
glands secretion at this point. This leads to a localisedsoften-
ing of the vitelline membrane so that it progressively bulges
outwards under the high fluid pressure within the capsule.
Eventually, the membrane ruptures and the larva is shot out
into thesurroundingwater,remaining attached to thenow col-
lapsed vitelline membrane by its mucus thread.Bles (1905)
confirmed the need for the localisation of the frontal glands
secretion by an experimental manipulation and showed that
a similar process occurred in a Hylaspecies.
Three methods have been employed previously to demon-
strate the distribution of HGCs in amphibian embryos:
immunohistochemistry, histology and scanning electron
microscopy. Drysdale and Elinson (1991) stained whole
mounts ofX. laevis immunohistochemically using an anti-
body to tyrosine hydroxylase. Fan and Katagiri (2001)
employed thesame basic techniquewith an antibody to hatch-
ing enzyme. The only multi-species investigation we can find
of HGC distribution (Meyer et al., 1969)used fixed embry-
onic skin whole mounts with HGCs stained by the periodic
acidSchiff (PAS) method, in order to assessthe HGCpattern
in 40 anuran species.Periodic acidSchiff detects the location
of secretory granules in the apical region of HGCs. Yoshizaki
and Yamamoto (1979) used scanning electron microscopy
(SEM) to follow the appearance and loss of HGCs at the epi-
dermal surface ofRana japonica embryos, identifying HGCs
by their dense array of apical microvilli. Yoshizaki (1991)
made similar observations on HGC appearance inX. laevis
noting particularly changes in the free cell surface area of
HGCs, compared to neighbouring common epidermal cells.
Transmission electron microscopy shows HGCs to beelongated bottle-shaped cells bearing apical microvilli and
containing abundant secretory granules in the apical cyto-
plasm (Fox, 1986).After hatching, the HGCs regress, losing
their position at the epidermal surface, and eventually dis-
appearing, presumably deleted by apoptosis (Yoshizaki and
Yamamoto, 1979).
In the work reported here, we have used SEM to map
the definitive pattern of HGCs in 20 anuran species from
six families. Our aims were to assess whether the pat-
tern of HGCs might have value as a taxonomic character,
and whether the pattern could help in understanding the
mechanism of hatching in the different species, following
Bless (1905)observations demonstrating the importance oflocalised secretion by HGCs.
2. Materials and methods
2.1. Egg collection, incubation, and fixation
All spawn was collected from field sites in Trinidad, Scot-
land and Iran as soon after spawning as was practicable.
Spawn from the many Trinidad species was identified with
the aid ofKenny (1969)andMurphy (1997).The exception
wasX. laevis, provided from a captive population maintainedat the University of St. Andrews.
The 20 species studied are shown inTable 1.Spawn was
incubated at temperatures appropriate to the normal habitat
(Trinidad 2729 C; Scotland 1517 C; Iran 2527 C; X.
laevis, 25 C) either in water (most species) or in air (foam-
nesting species; terrestrial spawners). At appropriate times,
samples were taken for fixation in order to examine hatching
gland morphology. We examined mostGosner (1960)stages
from approximately neurulation (stage 14) to early feed-
ing tadpoles (stage 27). The normal stage at which hatching
occurred in each species was also noted. All specimens were
fixed in 2.5% glutaraldehyde in 0.1 M (pH 7.4) phosphate
buffer for 25 h, then rinsed and stored in the same buffer at
5 C, until further preparation for electron microscopy.
2.2. Specimen staging
The jelly coat and vitelline membrane were removed from
stored pre-hatching specimens using forceps or filter paper.
The specimens were then staged using Gosners (1960) crite-
ria. We use Gosner staging throughout this paper, and when
referring to stages using other systems in the literature have
converted them to Gosner, using the conversion table in
McDiarmid and Altig (1999). The exception is the direct-
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Table 1
Classification, country of origin, habitat and spawning place of the 20 species of anurans used in this study
Family Species N Country Habitat Spawning place
Bufonidae Bufo beebeiGallardo 20 Trinidad S Temporary pools
B. bufoLinnaeus 25 United Kingdom WT Pools, ponds
B. marinusLinnaeus 20 Trinidad R, E, S Pools, ponds, rivers
B. viridisLaurenti 30 Iran WT Pools, ponds
Pipidae Xenopus laevisDaudin 30 Africa S Ponds
Hylidae Hyla crepitansa Wied-Neuwied 10 Trinidad E, S Pools, ponds
H. boansa (Linnaeus) 15 R Pools at river edge
H. geographicaa Spix 16 R, E Edge of streams
H. microcephala miserab Fouquette 19 S Temporary pool
H. minutab Peters 10 R, E, S Forest and road-side pools
H. minusculab Rivero 10 S Ponds, swamps
Phyllomedusa trinitatisMertens 20 R, E, S Leaves above water
Phrynohyas venulosac (Laurenti) 30 E, S Temporary pools
Leptodactylidae Eleutherodactylus urichid (Boettger) 10 R, E Leaves on ground
Leptodactylus fuscus(Schneider) 40 S Burrow in ground*
L. validusGarman 15 R, E, S On water surface, hidden*
L. bolivianusBoulenger 10 S On water surface, hidden *
Physalaemus pustulosus(Cope) 30 S On water surface, open*Microhylidae Elachistocleis ovalis(Schneider) 10 S/R Temporary pool, ditches
Ranidae Rana temporariaLinnaeus 30 United Kingdom WT Pools, ponds
Habitat codes: R: rainforest; E: forest-edge; S: Savanna; WT: widespread temperate; (*): in foam. Superscript letters refer to taxonomic changes made byFrost
et al. (2006).N= number of specimens examined.a New genusHypsiboas.b New genusDendropsophus.c New genusTrachycephalus.d New family Brachycephalidae.
developing species, Eleutherodactylus urichi where staging
is byTownsend and Stewart (1985).
2.3. Specimen preparation and examination
Glutaraldehyde-fixed specimens were post-fixed in 1%
osmium tetroxide, stained in 0.5% aqueous uranyl acetate,
dehydrated using an acetone series, then critical-point-dried
and coated with gold using a Polaron SC 515. Post-fixation
and staining is used as a standard procedure in our laboratory
to enhance the conductivity of specimens in SEM. Specimens
were examinedusinga Phillips 500SEM over a magnification
range of 1003200and images recorded by Imageslave for
Windows (Meeco Holdings, Australia). SEM photographs at
low and high magnification were taken from the dorsal side
of the head and trunk with focus on the hatching gland cells.
The stages when the HGCs appeared or disappeared at the
surface were distinguished. The stage when the HGCs were
close together and highest in number was determined. A dis-
tribution map of HGCs on the surface was drawn for each
species. The distribution and length of microvilli on HGC
surfaces were measured from SEM photographs (at magni-
fication between 1200 and 5000). At the each stage for
each species, we examined two specimens when they were
available. We assessed the length of microvilli on the HGC
surfaces, by choosing five of the cells randomly, measuring
two microvilli from each cell. Microvilli density, based on
the ratio of microvillated area of the cell surface to non-
microvillated area was classified into three categories as
below. In the data presentation table, we used a star system
to denote the different density categories, as shown.
(1) Dense: the ratio of microvilli area to non-microvillatedarea is greater than or equal to 3:1 (***).
(2) Intermediate: the ratio is between 3:1 and more than 1:1
(**).
(3) Dispersed: the ratio is less than 1:1 (*).
3. Results
3.1. Overview
Several aspects of HGC patterns such as timing of HGC
development, HGC distribution on the surface, HGC shape
(including apical microvilli) as shown by SEM, for each
species investigated in this study, are described inTable 2.
We were unable to collect every stage for every species. For
consistency, these are shown as stage not available in the
Table. At their maximum extent, HGCs tended to form a con-
tinuous patch or line, with no other cells intervening; as the
hatching gland regressed, HGCs became separated from one
another and smaller in individual cell surface area. The stages
when these changes occurred are recorded inTable 2.
HGCs were identifiable by their dense clusters of
microvilli.Table 3provides data on microvillous length and
density. The other two cell types found on the epidermal
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Table 3
Length and density of microvilli of the HGCs in 16 species of anurans
Family Species Stages Length (m, meanS.D.) Density
Bufonidae B. beebei 17 1.75 0.25 ***
B. bufo 19 1.4 0.11 ***
20 1.4 0.11 ***B. marinus 18 1.8 0.32 ***
19 1.75 0.25 ***20 1.7 0.21 **
22 0.8 0.29 **
B. viridis 16 0.6 0.12 **
18 1.1 0.29 ***
20 1 0.2 ***
21 1.1 0.1 ***
24 0.9 0.32 ***
26 0.94 0.13 ***
Pipidae X. laevis 18 2 0.65 **
24 2.1 0.55 **
Hylidae H. crepitans 17 3.6 0.49 **
18 3.2 0.75 **
19 2.7 0.59 **
20 4.1 0.67 **
21 2.6 0.31 **22 3 1 **
H. geographica 17 2.65 0.43 ***
18 2.4 0.49 ***
19 1.74 0.49 ***
20 2.9 0.3 **
22 2.24 0.56 **
H. microcephala 18 1.6 0.14 **
19 1.4 0.36 *
20 1.24 0.19 **
P. venulosa 16/17 0.73 0.25 ***
18 2 0.41 ***
19 1.84 0.44 ***
20 1.7 0.64 ***
21 2.3 0.67 ***
22 2.23 0.39 ***Leptodactylidae E. urichi 6 1 0.14 ***
L. fuscus 18 1.7 0.14 **
20 1.6 0.45 *
21 1.5 0.5 *
22 1.2 0.29 *
23 1.27 0.44 *
L. validus 20 2 0.71 **
23 1.3 0.25 **
L. bolivianus 21 1.94 0.24 ***
22 2 0.38 ***
23 2.5 0.5 **
P. pustulosus 16 1.4 0.48 **
17 1.8 0.13 **
20 1.12 0.32 **
Microhylidae E. ovalis 18 1.15 0.39 *
19 1.5 0.29 *
Ranidae R. temporaria 20 1.7 0.23 **
The staging inE. urichiis based onTownsend and Stewart (1985); the remainder onGosner (1960).
surface in the region of the hatching gland were common
epidermal cells (CEC), generally with microridged surfaces
and secretory micropores; and ciliated cells, easily distin-
guishable by their long cilia.
Observation at low magnification showed that there are
several general HGC patterns and distributions among the
different species of anurans. Examples of the HGC patterns
found are shown inFig. 1.The shape of the HGC apical pro-
files at the epidermal surface changed over the developmental
stages. Different species in a genus or family may have simi-
lar shapes of hatching gland but this was not always the case.
Fig. 2shows the overall pattern of HGCs on the dorsal sur-
face of the various species of anuran embryos we report on
here.Fig. 3gives a frontal view for two species.
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230 M. Nokhbatolfoghahai, J.R. Downie / Tissue and Cell 39 (2007) 225240
3.2. Species descriptions, ordered by family
3.2.1. Bufonidae
The details of HGC pattern were considered for four
bufonid species: Bufo beebei (Figs. 1a and 2a), B. Bufo
(Fig. 1b,c; 2b), B. marinus (Figs. 1d; 2c; 3b)and B. viridis
(Fig. 2d). Common features of all four species were: at aboutstage 16, HGCs appeared on the dorsal side of the head. In all
species, the HGCs were distributed on the front of the head
more widely than on the back of the head or trunk. The cells
were all close together in a strand, distributed from the tip of
the head to the posterior end of the head, except B. marinus,
where all cells were concentrated as a patch on the front of
the head.
Features which differed between the species were: HGCsextended along the trunk as a continuous line inB. bufoand
Fig. 1. Examples of distribution and morphology of HGCs on the mid-dorsal side of the head in anuran embryos/larvae in different species and at different
stages: (a)B. beebei, stage 17; (b) B. bufo, stage 19 low magnification; (c) B. bufo, stage 19 high magnification; (d) B. marinus, stage 20; (e)B. viridis, stage
26; (f) X. laevis, stage 17/18; (g) H. crepitans, stage 21; (h) H. geographica, stage 17; (i) H. geographica, stage 22; (j) H. microcephala, stage 18; (k) H.
microcephala, stage 20; (l) H. microcephala, stage 21; (m) H. minuta, stage 20; (n)P. venulosa, stage 19; (o)L. fuscus, stage 18; (p) L. fuscus, stage 23; (q)L.
bolivianus, stage 22 low magnification; (r) L. bolivianushigh magnification, stage 22; (s) L. validus, stage 19 low magnification; (t) L. validus, stage 19 high
magnification; (u)P. pustulosus, stage 17; (v)E. urichi, stage 8/9; (w)E. ovalis, stage 18; (x)E. ovalis, stage 19. Scale bars: a, d, f, g, h, m,v, w, and x = 15m;
c, e, j, k and n = 8m; e, l= 60m; i, o, p, and u = 35m; q and s= 19m; r= 6m; t= 3m; b= 250m. Arrow head: HGC; arrow: ciliated cell; (*): common
epidermal cell.
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232 M. Nokhbatolfoghahai, J.R. Downie / Tissue and Cell 39 (2007) 225240
Fig. 1. (Continued)
B. viridis. InB. beebei, a few HGCs were scattered individ-
ually on the trunk, and in B. marinus, HGCs were present
only on the head. At hatching stage, HGCs were very densly
packed inB. beebei andB. bufo especially on the head, and in
B. viridisand B. marinusthe density of HGCs was interme-
diate. Microvilli were very densely packed on the HGCs of
B. beebeiandB. bufoand dense inB. viridisandB. marinus.
HGCs remained at the surface up to stage 25/26 inB. viridis,
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Fig. 1. (Continued)
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Fig. 1. (Continued)
while they disappeared at stage 22 in B. bufoandB. marinusand at stage 23 inB. beebei. The shape of the HGCs changed
with stage, but we described the shape when HGCs reached
their maximum size. In B. beebei HGCs were round, in B.
bufo oval and in B. viridis elongated. HGCs in B. marinus
were four-sided or round.
3.2.2. Pipidae (X. laevis only)
X. laevis (Fig.1f and 2e): at stage 1718, most HGCs were
in a straight band, 36 cells wide, along the median line of
the dorsal side of the head and extending back much of the
length of the trunk. Two branches of cells extended from a
large patch at the tip of the head to the anterior-rostral sideof the head. The apical surfaces of the HGCs were highly
microridged at this stage. At stage 18 (hatching), microvilli
had grown on the surfaces of the HGCs especially on the
dorsalside of thehead.At stage 20,the HGCs were separating
from each other and at stage 22, only a few traces of HGCs
could be seen.
3.2.3. Hylidae
The details of HGC pattern were considered for eight
hylid species: Hyla crepitans (Fig. 1g; 2f), H. boans
(Fig. 2g), H. geographica (Fig 1h, i; 2h), H. microcephala
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Fig. 1. (Continued).
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Fig. 2. Distribution patterns of HGCs on the dorsal surface of the different species of anuran embryos: (a)B. beebei, stage 17; (b)B. bufo, stage 18/19; (c) B.
marinus, stage 20; (d)
B. viridis, stage 18; (e)
X. laevis, stage 18/19; (f)
H. crepitans, stage 17; (g)
H. boans, stage 18; (h)
H. geographica, stage 17/18; (i)
H.
microcephala, stage 18; (j)H. minuta, stage 18; (k)H. minuscula, stage 19; (l) P. venulosa,stage 18; (m) L. fuscus, stage 18; (n)P. pustulosus, stage 18; (o)L.
validus, stage 20; (p) L. bolivianus, stage 21; (q) E. urichi, stage 7/8 (r) E. ovalis, stage 18; (s) R. temporaria, stage 17/18. Drawings made to summarize cell
patterns observed when HGCs were present at their maximum extent.
(Figs. 1j, k, l, 2i), H. minuta (Fig. lm; 2j), H. minuscula
(Fig. 2k),Phyllomedusa trinitatisand Phrynohyas venulosa
(Fig. 1n; 2l).
Of the eight species, P. trinitatis was unique: by normal
criteria, we could find no HGCs on the head surface in this
species. Stages examined were 1823.
The timing of appearance and disappearance of HGCs
was similar across the remainder of the hylid species, from
stage 1516 to stage 2225. Where hatching occurred rel-
atively late (H. microcephala, H. minuscula, stage 2021),
HGC disappearance was also relatively late (stage 23,25).
The pattern of HGCs showed similarities, but also some
differences (Fig. 2fl). At the anterior end, the cells were
in a narrow line across the head, to a variable extent; the
HGCs then extended as a line mid-dorsally backwards, also
to a variable extent: very short in H. minuta; longest in P.
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Fig. 3. Distribution patterns of HGCs in a frontal view of the head in (a)L. bolivianus, stage 21; and (b) B. marinus, stage 20.
venulosa. The line was relatively straight with short lateral
extensions inH. minuscula.
There appeared to be small differences in surface morphol-
ogy of HGCs between species. For example,H. crepitans had
long microvilli compared toH. geographicaandP. venulosa
(Fig. 1g,h,n) and HGC shape ranged from essentially oval to
polygonal with sharply angled sides.
3.2.4. Leptodactylidae
The details of HGC pattern were considered for fiveleptodactylid species:Leptodactylus fuscus(Figs.1o,p; 2m),
Physalaemus pustulosus (Figs. 1u; 2n), L. validus
(Figs. 1s, t; 2o), L. bolivianus (Fig. 1q, r; 2p; 3a) and
Eleutherodactylus urichi(Fig. 1v; 2q).
Of the five species,E. urichiwas unique in having direct
development to the froglet stage, with no free-swimming
tadpole. Hatching occurs with the aid of an egg tooth at
Townsend and Stewart (1985) stage 15. However, we did
find cells with the normal morphology of HGCs at two much
earlier stages, stages 4 and 8/9; no such cells were visible
at stage 14 (we lacked stages between 9 and 14). The cells
were oval or round with their apical surfaces covered in short
microvilli (Fig. 1v), and were single, not in groups, located
on the dorsal head surface.
In L. fuscus, L. validus and L. bolivianus, HGCs were
arranged as a broad loosely connected patch on the dor-
sal surface of the head, with no posterior linear extension.
P. pustulosus had a pattern intermediate between this and
the other groups studied: a broad band of HGCs anteriorly,
narrowing posteriorly, but only extending to the back of
the head.
As in the other groups, the first appearance of HGCs well
preceded hatching time; hatching occurred around the stage
when HGCs were separated from one another; HGCs disap-
pearedfrom thesurface a few stagesafterhatching, latestinL.
fuscus. Cell shapes were similar to those of other groups, oval
to round, with surface microvilli, though rather less dense
than in some other groups (Table 3).InL. fuscusHGCs were
oval, inL. validus oval or four sided and inL. bolivianus three
or four sided.
3.2.5. Microhylidae (Elachistocleis ovalis only)
E. ovalis (Figs. 1w,x; 2r): at stage 18,HGCs were observed
on the median line of the dorsal head, from the dorsal tip ofthe head to a short distance posteriorly. They were distributed
in one or two rows along the dorsal median line. They were
concentrated on the dorsal tip of the head, with some gaps
between different parts of the line. At stage 19, the HGCs
were separating. The cell apices were dispersed, elevated,
circular or oval in shape with short microvilli on their sur-
faces. At stage 2122, no sign of HGCs could be seen on the
dorsal head, but on the tip of the head, there was one patch
with slightly microvillated cell surfaces. At stage 23,at the tip
of the head, HGCs were still attached together, with slightly
microvillated surfaces.
3.2.6. Ranidae (Rana temporaria only)
R. temporaria(Fig. 2s): at stage 17, HGCs were observed
on the median line of the dorsal head and some parts of the
trunk. The HGCs were distributed along the median line with
patches alongside the line. The boundaries between HGCs
were not distinguishable, but they were slightly microvil-
lated on their surfaces. At stage 18, HGCs were slightly
elongated with very short surface microvilli. At stage 22,
HGCs were separated from each other. Small and often four
sided HGCs with microvilli were observed on the tip of
the head. At about stage 26, HGCs disappeared from the
surface.
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4. Discussion
4.1. Hatching gland cell shape and pattern
There have been few previous comparative surveys of
hatching gland morphology.Meyer et al. (1969)described
the HG of Alytes obstetricans in detail, but also examined39 other species, 13 European and 27 from elsewhere. Their
method used stained whole mount preparations of embryonic
dorsal skin. They found some relationship between HG mor-
phology and anuran taxonomic relationships, but their paper
lacks detailed figures of the different species examined. The
stained whole-mount method is laborious and is not capable
of fine resolution of individual cells. More recently whole-
mount immunohistochemistry has been used to visualise the
HG and to map molecular expression patterns in the gland
(Cheng et al., 2002),mainly in X. laevis. This method also
does not resolve the detail of individual cells.
We have followed Yoshizaki and Yamamoto (1979) in
using scanning electron microscopy to map the HG. Themethod has the advantage of allowing the complete pattern
of HG cell apices to be seen in a single specimen, but also of
allowing visualisation of individual HGC apical specializa-
tions at high magnification. Since HGCs are surface active,
SEM is also reliable in easily detecting the appearance and
disappearance of HGCs from the embryo surface. SEM does
not detect HGCs once they disappear from the embryo sur-
face, but it is likely that, once this happens, the cells are no
longer functional and are undergoing degenerative changes
(Yoshizaki and Katagiri, 1975).
Fig. 2 summarises the pattern of HGCs in the species stud-
ied andTable 2synthesises our data on the timing of HGCdevelopment and regression. The patterns show an overall
general similarity, with a concentration of cells at the dor-
sal anterior part of the head, then a row of cells extending
back along the dorsal mid-line. Because we have concen-
trated on the dorsal side, our figures do not generally show
the Y shaped pattern seen in the frontal region in Xenopus
(see, for example,Cheng et al., 2002).In most species, the
pattern of HGCs on the anterior-most part of the head shows
a T or Y shape in dorsal view (Fig. 2)and we have confirmed
this with frontal views of two species (Fig. 3). However, there
are also clearly differences, especially in the extent of the dor-
sal mid-line row. It would be of interest to investigatewhether
these differences have functional significance.Bless (1905)
investigation of hatching in X. laevis, which seems not to
be been repeated for other species, suggests that the action
of the HGCs may be highly localised, where the HG makes
contact with the overlying vitelline membrane. The ideal pat-
tern of HGCs in a particular species may therefore be related
to the geometry of this interaction. Detailed examination of
hatching in a range of species is neededto test this hypothesis.
Examination ofTable 2andFig. 2hints at a relationship
between gland cell distribution and hatching stage: those
species with long posterior extensions of the gland (Fig. 2
b,d,e,g,l,s) hatch at stages 18 or 19; those where the gland
is restricted to the head region with only a short posterior
extension(Fig.2 a,c,h,j,m,n,o,p,r) hatch over a wider range of
stages, 1720. This is small difference and possibly biased by
the relatively large number of leptodactylid species in the lat-
ter category, but there may be some relationship here between
the overall shape of the embryo at hatching, and the detailed
hatching mechanism.Meyer et al. (1969)suggested some level of relationship
between HG pattern and taxonomic position. Our survey may
be too limited to discern such relationships, but some patterns
emerge e.g. in leptodactylids, the HG is mainly a wide ante-
rior patch, with little posterior extension; in the hylids, the
posterior extension tends to be a narrow, sometimes zig-zag,
line of cells.
Table 2 shows that thoughthere is some variability in onset
and disappearance of HGCs, there is perhaps less than might
be expected, given the variability in hatching stage. SEM fea-
turesdo notnecessarilytell uswhen cells areactive. Yoshizaki
and Katagiri (1975) assessed HGC function at differentstages
by culturing embryos in medium, then measuring the prote-olytic activity of the medium, taken to be mainly derived
from HGC secretions. Activity was low in medium exposed
to stage 1719 embryos, but high after exposure to stage 21
(hatching stage) and stage 22 embryos. Unfortunately, they
did not test later stage embryos. This result at least indi-
cates that release of proteolytic enzymes persists some time
afterhatching. Yoshizaki (1991) detected intra-cellular prote-
olytic activity inXenopusHGCs over a wide range of stages
(Nieuwkoop and Faber stages 2441, equivalent to Gosner
1722) including post-hatching. Whether this has functional
significance is unclear: see discussion on L. fuscus, below.
The fact that the HG appears at the embryo surface sometime beforehatchingoccurs (by 12 Gosner stages, generally:
Table 2)and disappears well after hatching (by 34 Gosner
stages) may pre-dispose some species towards the evolution
of hatching in response to external stimuli (Martin, 1999).
4.2. Special cases
4.2.1. E. urichi
Hatching in all eleutherodactylids involves the use of an
egg tooth which mechanically tears apart the investing jelly
coat of the egg, to allow the froglet to emerge. However, as
Salthe (1963) noted,eleutherodactylids hatchearly from their
vitelline membranes. Presumably, this process is mediated by
the HGCs we found at Townsend and Stewart stages 48/9.
4.2.2. P. trinitatis
ItispuzzlingtohavefoundnosignofHGCsinthisspecies.
Hatching occurs late in Phyllomedusa, but we would have
expected HGCs still to have a role. It may be that the cells
have different morphology, or a different location from other
species, but we were unable to find HGCs in this species
either in SEM or in sections. Kenny (1968) reported that from
about one third of the 7.5 days incubation period onwards, the
vitelline membrane becomes progressively distended with
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M. Nokhbatolfoghahai, J.R. Downie / Tissue and Cell 39 (2007) 225240 239
fluid, reaching a diameter of 4 mm from an initial 2.3 mm.
Hatching can occur over a small range of stages and seems to
be stimulated by the hatching of neighbouring embryos: their
hatching leads to violent wiggling of unhatched embryos,
then sudden rupture of their vitelline membranes. It seems
possible, therefore, that in this species, there is some advan-
tage in synchronous hatching, and that this is achieved by amechanical rather than an enzymatic mechanism.
4.2.3. L. fuscus
Downie (1994) reported that hatching occurs at stage
1819 in this species and that larvae remain in the foam
nest and generate a new kind of foam. He followed HGC
regression both in larvae that remained in the foam nest and
in individuals transferred to water and allowed to feed. The
results showed that HGC regression was slower in larvae that
remained in the foam nest, and Downie suggested that the
HGCs may retain some function in these foam-dwelling lar-
vae. However, HGC presence was detected only in sections,
and it may be that the HGCs were no longer functional. How-ever, this is a possible example where post-hatching activity
of HGCs may occur. Our SEM results show that in nor-
mal development, HGC appearance at the embryo surface
remains till a relatively late stage.
4.3. Conclusion
Our previous studies on anuran embryonic and early larval
surface structure, on ciliated cell patterns and cement gland
morphology respectively (Nokhbatolfoghahai et al., 2005;
Nokhbatolfoghahai and Downie, 2005)have revealed con-
siderable diversity, related both to taxonomic position andto mode of development. Since our earlier work appeared,
Frost et al. (2006)have proposed a considerable revision of
amphibian taxonomy, some of it provisional, given the rela-
tively small number of species sampled in parts of the tree. To
allow continuity with our earlier papers, we have not changed
any the names in our descriptions, but we have noted the
changes in Table 1. Thework reported here on HG pattern and
cellsurface ultra-structure shows some fine scale diversity but
little obvious relationship to taxonomy (seeFrost et al., 2006
for family relationships) or to developmental mode, other
than some similarityin overall shape among the foam-nesting
leptodactylid species examined. The most surprising results
were the absence of HGCs from P. trinitatis and their pres-
ence at early stages inE. urichi, long before actual hatching.
P. trinitatis belongs to the same hylid sub-family as Agaly-
chnis(Duellman and Trueb, 1994),whereWarkentin (1995)
has demonstrated facultative hatching in response to exter-
nal stimuli.Warkentin (1999)reported on several aspects of
Agalychnishatchling morphology, but made no comment on
the presence or absence of HGCs.
Callery et als. (2001) investigation of the evolutionary
changes that have led to direct development in Eleuthero-
dactylus showed that remnants of the ancestral pattern of
development, such as late stage responsiveness to thyroid
hormone, remained. Our results suggest that HGC function
at an early stage is one of these remnants, allowing internal
hatching of the embryo from the vitelline membrane, even
though full hatching occurs only much later and by a different
mechanism.
Acknowledgments
We thank Margaret Mullin, Eoin Robertson and Ian Mont-
gomery for technical assistance and advice. Students in
University of Glasgow expeditions to Trinidad helped col-
lected specimens. Bernard Zonfrillo providedRana andBufo
spawn from the Glasgow area and Simon Merrywest of the
University of St Andrews providedXenopusspawn. The late
Professor Peter Bacon and colleagues at the University of
the West Indies kindly provided laboratory space and the
Trinidad Government Wildlife section provided collection
permits. J.R.D.s fieldwork in Trinidad was supported by the
Carnegie Trust. M.N. thanks the University of Shiraz, IslamicRepublic of Iran for financial support.
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