Development of the salivary glands in embryos of Ixodes ricinus (Acari: Ixodidae)

We examined Ixodes ricinus embryos between 18 and 28 days of development with light, scanning and transmission electron microscopy. The differences in inner structure attested to establish three successive developmental stages: days 18–20, day 23, and days 26–28. Between 18 and 20 days the embryos are at early stages of organogenesis. Salivary glands cannot be identified at that stage. In 23-day-old embryos salivary glands are already outlined but the structure of alveoles is still different from that in larvae in which the embryonic development has been completed. Gland cells start to form alveoles and become active between 26 and 28 days of the development. This revised version was published online in July 2006 with corrections to the Cover Date.     

鲤鱼发育早期HPG轴和GH/IGF轴相关因子的转录起始分析

采用RT-PCR的方法,以不同发育时期的鲤鱼胚胎和幼鱼为材料,研究了与鱼类生殖相关的HPG轴以及与生长相关的GH/IGF轴中GnRH、GtH以及GH、GHR和IGF重要信号分子的转录起始特征.结果显示,sGnRH、cGnRH、GtH-Ⅰβ卢亚基和GHR于鲤鱼胚胎受精后20h开始转录,IGF-1于受精后23h开始转录,GtH-Ⅱβ亚基于受精后26h开始转录,GtH α亚基于受精后46h开始转录,GH于1dph(孵出后第1天)开始转录.其中,GHR和IGF-1均早于GH开始转录,GtH α亚基和β亚基的转录起始时间不同步.研究结果为揭示鲤鱼生殖与生长间的调控机制积累了重要的科学依据.     

PROLIFERATIVE BEHAVIOR OF DIFFERENTIATING CELLS IN THE DEVELOPING RAT PAROTID GLAND

Parotid glands of litters of rats at age intervals from 20 days in utero to 100 days were assayed for DNA content and examined by light- and electron-microscopy. The age differences in total DNA and DNA concentration indicated that there was a rapid rate of proliferation of parenchymal cells until 25 postnatal days, after which the rate declined rapidly, and that there was a rapid increase in cell size between 18 and 25 days. These findings were substantiated by histologic observations, such as the presence of numerous mitotic figures until 25 days of age, and the rapid maturation of the acinar cells between 18 and 25 days. These data suggest that the acinar cells of the rat parotid gland comprise an expanding cell population. Light- and electron-microscopic observations consistently indicated that cells with mitotic figures were about as well differentiated as other parenchymal cells at all stages of gland development, including mature acinar cells observed at ages 23 and 25 days. These observations support the view that the division of cells in advanced stages of differentiation may be important in the growth of certain organs and tissues.     

Uptake and utilization of14C-glycine by embryos ofSebastes melanops

Synopsis The ability of embryos of the viviparous scorpaenidSebastes melanops to take up nutrients from an exogenous substrate was demonstrated by incubating embryos at various stages of development (18–30 days after fertilization) in¹⁴C-labeled glycine for 24 h. Uptake was highest for embryos at the latest stages (28–30 days) and increased at a linear rate during the incubation period. Nutrient uptake was not time dependent in embryos at the early stages (18–22 days). Nutrient utilization byS. melanops embryos was measured by the oxidation of¹⁴C-labeled glycine to¹⁴CO₂. The amount of respired¹⁴CO₂ by the oldest embryos increased significantly at a linear rate over the 24 h incubation period. There was no evidence of nutrient utilization by the youngest embryos. The developmental changes we observed in the uptake and utilization of exogenous glycine are supported by our previous findings that the oldest embryos have fully developed mouths and guts, and require additional nutrition from intraovarian sources at this stage of development.     

Teratogenic effects of retinoic acid and dimethylsulfoxide on embryonic chick wing and somite

In order to document the stage(s) at which the embryonic chick wing bud is sensitive to vitamin A teratogenesis and the kinds of defects produced by vitamin A insult to the embryonic chick wing, 1-microgram doses of retinoic acid (1 microliter RA in 90% DMSO at a concentration of 1 microgram/microliter) were locally applied to the right wing bud of chick embryos at stages 17-23 (Hamburger and Hamilton: J. Morphol., 88:49-92, '51), and the resulting limb skeleton anatomy was observed at 10 days of incubation. Local application of RA at stages 17-20 resulted in distal wing skeleton defects. There were significantly more wing skeleton defects among embryos treated at these stages with RA solution than among solvent (DMSO)-treated control embryos and than among untreated control embryos. Wings of embryos treated with RA at stages 21-23 were always normal. Scapular and vertebral defects were seen at 10 days of incubation among embryos which had been treated prior to stage 21 with both the RA solution and the solvent control. Statistical analysis and histological data suggest that scapular and vertebral defects were caused by DMSO-induced damage to somites.     

温度对以截形叶螨为猎物的斯氏钝绥螨生长发育的影响

测定了斯氏钝绥螨Amblyseius swirskii（Athias—Henriot）在14、17、20、23、26、29、32、35℃和RH=85％的条件下,以截形叶螨为猎物各螨态的发育历期,分析发育速率与温度的关系。结果表明,14℃不适宜斯氏钝绥螨的生长发育,存活率仅17．5％;在17～35℃之间其生长发育正常,存活率均100％,各螨态的发育历期与温度均呈负相关关系,发育历期随着温度的升高明显缩短,未成熟期总发育历期从21．36d缩至3．97d。采用线性日度模型拟合温度与发育速率的关系表明,该模型能较好地描述其发育速率在适宜温度范围内随温度升高而加快的现象。斯氏钝绥螨不同发育阶段的发育起点温度和有效积温不同,未成熟期的发育起点温度和有效积温分别为11．92℃和94．69日·度。     

The effect of temperature on the motor activity of the chick embryo and amnion at 5-14 days of development]

It has been shown that cooling the developing eggs from 37.7 degrees C results cessation of motor activity of the amnion in 5-14-day embryos at 36-33 degrees C, whereas motor activity of the embryo remains unaffected up to 31-26 degrees C. Immobilization of the embryo was observed on cooling up to 22-18 degrees C. The recovery of motor activity after cooling during heating takes place in a reverse order. Embryonic movements are observed at 18-23 degrees C, contractions of the amnion--at 28-33 degrees C. These experiments reveal complete independence of embryonic movements from the amnion. Motor activity of the amnion is related to that of the embryo only between the 8th and the 10th day of incubation.     

Effects of oestrous synchronization with altrenogest in gilts on endometrial and embryonic characteristics

The use of altrenogest (ALT) supplementation for oestrous synchronization improves subsequent reproductive performance of gilts and sows. However, the causes of this improvement in reproductive performance after ALT treatment are not fully/clearly understood. The objective of this study was to evaluate the effects of ALT supplementation for oestrous synchronization in gilts on the endometrial glands and embryonic development characteristics at 28 days of pregnancy. Pregnant gilts were divided into two experimental treatments: Control (did not receive ALT; n = 9 gilts) and ALT (ALT feeding at 20 mg/day for 18 days; n = 9 gilts). At 28 days of pregnancy, six gilts from each treatment were slaughtered, and reproductive tracts were immediately evaluated. There was no statistical difference (P > 0.05) between treatments regarding ovulation rate, number of embryos, number of vital embryos and number of non-vital embryos. Embryo weight, length and embryonic vesicle weight were lower in ALT treatment compared with Control (P < 0.01), and it was lower in the cervical uterine region compared with apex uterine region, respectively (P < 0.05). Higher values of gland duct area, gland duct perimeter, percentage of the glandular area and total endometrial area were observed in ALT treatment compared with Control (P < 0.05). The use of ALT during 18 days for oestrous synchronization in gilts increased the gland duct area, perimeter and total endometrial area but did not increase the embryo number and embryo size at day 28 of pregnancy.     

Homocysteine modifies development of neurulation and dorsal root ganglia in chick embryos

BACKGROUND: The formation of the neural tube (neurulation) involves two mechanisms: primary and secondary neurulation. In chicks, there is also an overlap zone, where both mechanisms work together. Homocysteine (Hcy) may have an important teratogenic role in neural tube defects (NTD) when folic acid levels are considered normal. Recently, Hcy capability to generate NTD and modify neural crest cell migration has been demonstrated in chick embryos. This study was aimed to evaluate the effects of Hcy on neurulation and the development of the dorsal root ganglia (DRG). METHODS: Chick embryos were treated with L-Hcy thiolactone 20 micromol to produce the highest rate of survival with embryos carrying neural tube defect (NTD) in the spine. Embryos at stages (st) 3-10 were treated and harvested at st 18-23. Only externally normal embryos or those carrying spinal NTD embryos were considered. RESULTS: Histological sections of Hcy-treated embryos showed: open spina bifida (39% of embryos), more than one tube forming the spinal cord (26%), disorganized spinal cord (26%), always affecting lumbosacral regions, probably in the overlap zone. Additionally, 32% of embryos had small and continuous DRG, associated with a slimmed roof plate. Three-dimensional reconstruction showed unsegmented DRG until the C8 ganglion level. There was a 75% reduction of C3 DRG cells in treated embryos in comparison to untreated ganglia. CONCLUSION: Hcy teratogenicity in avian embryos affected the neural tube in the overlap zone, secondary neurulation and the cervical DRG.     

Immunohistochemical evidence of Muc1 expression during rat embryonic development

During embryonic development, studies on mouse and human embryos have established that Muc1/MUC1 expression coincides with the onset of epithelial sheet and glandular formation. This study aimed therefore at evaluating the temporal and spatial expression of Muc1 at different stages of rat development. In this experiment, 80 animals were included: 64 rat foetuses at 13, 14, 15, 16, 17, 18, 19 and 20 days of gestation from pregnant females (WKAH/Hok), 8 embryos each stage. Standard immunohistochemistry was performed using anti-MUC1 cytoplasmic tail polyclonal antibody (CT33). The reaction was considered positive when more than 5% of the cells were stained; reaction patterns were: L = linear, membrane, C = cytoplasmic and M = mixed; nuclear staining was also recorded. Intensity was graded as negative (-), low (+), moderate (++) and strong (+++). Muc1 expression was observed with a low intensity on 13th day (13 d) in the stomach, lung and kidney; at 14 d, small intestine and pancreas were also reactive; at 16 d, liver and esophagus and at 18 d, trachea and salivary glands. During the development, intensity increased while the pattern of expression changed: at the first days of gestation, it was predominantly linear and apical while during further development an increase in cytoplasmic expression was observed. Trachea, stomach, kidney and lung epithelia were the more reactive tissues. In specimens belonging to neonates and adults, all tissues analyzed showed similar Muc1 expression. The findings of this study assess that Muc1 is highly expressed in the epithelial rat embryonic development.     

Regeneration of the tail bud in Xenopus embryos.

In an attempt to solve some aspect of the long-standing controversy about the regenerative ability of appendages in vertebrate embryos, the tail bud of Xenopus laevis embryos has beenamputated at stage sranging from St. 26 to St. 32 and its ability to regenerate duringa culture period of 2-3 days has been studied. At amputation stages 26-28,the tail bud consisted only undifferentialted mesoderm and ectoderm, but at stage 32 it had afully differentiated neural tube, a vaculotaed notochord and segmented somites. A total of 137amputations at differnt stages gace consistent results: a tail formed in all the operated larvacand it had normal, well-developed axial tissues in most cases. The relatively few cases with abnormal tail struture were stunted, oedematour larvae with defects in the trunk region as well. It is concluded from these experiments that cells near the original tail budare able to differentiate into tialbud tissues and to replace the amputated regoin, even at these late embryoic stages. The implications of these findings for comparative studies on regeneration in vertebrates are discussed.     

A pair of rosette glands in the embryo and zoeal larva of an estuarine crab Sesarma haematocheir, and classification of the tegumental glands in the embryos of other crabs

A pair of rosette glands (one of the tegumental glands in crustaceans) is present at the root of the dorsal spine of the thorax in mature embryos of the estuarine crab Sesarma haematocheir. Each rosette gland is spherical, 45-50 microm in diameter. This gland consists of three types of cells: 18-20 secretory cells, one central cell, and one canal cell. The secretory cells are further classified into two types on the basis of the morphology of secretory granules. There are 17-19 a cells, and only one b cell per rosette gland. An a cell contains spherical secretory granules of 2-3 microm in diameter. The granules are filled with highly electron-dense materials near the nucleus but have lower electron-density near the central cell. The secretory granules contained in the b cell have an irregular shape and are 1-1.5 microm in diameter. The density of the materials in the granules is uniform throughout the cytoplasm. The secretory granules contained in both the a and b cells are produced by the rough endoplasmic reticulum. Materials in the granules are exocytotically discharged into the secretory apparatus inside the secretory cell, sent to the extracellular channels in the central cell, and secreted through the canal cell. The rosette gland can be distinguished from the epidermal cells 2 weeks after egg-laying and the gland matures just before hatching. Materials produced by this gland are secreted after hatching and secretion continues through five stages of zoeal larvae. These rosette glands were never found in the megalopal larva. Rosette glands are found in the embryos of Sesarma spp. and Uca spp. In other crabs, tegumental glands are also found at the same position as in the embryo of S. haematocheir, but the fine structure of their glands is largely different from that of the rosette gland. On the basis of the morphology of secretory cells (a-g cell types), the tegumental glands of a variety of crab embryos can be classified into four types, including rosette glands (type I-IV). The function of these tegumental glands is not yet known, but different types of the gland seem to reflect the phylogeny of the crabs rather than differences of habitat.     

Scanning electron microscopy substantiates histology in showing the inadequacy of the existing theories on the development of the proximal coronary arteries and their connections with the arterial trunks

Development of proximal coronary arterial segments and coronary arterial orifices was studied by scanning electron microscopy in 20 rat embryos and by light microscopy in serial sections of 20 human and another 18 rat embryos. Neither by scanning electron microscopy nor by light microscopy did we observe more than two coronary arterial orifices. These coronary orifices were always situated in the sinuses of the aorta that faced the pulmonary artery. In the human embryos the coronary orifices emerged between 37-39 days of gestation (16-19 mm crown-rump length, Streeter horizon XVIII-XIX) and were invariably present beyond 39 days (19 mm crown-rump length, Streeter horizon XIX). In rat embryos, the coronary orifices emerged in both scanning electron microscopy and light microscopy at 15-17 days of gestation (13-17 mm crown-rump length) and were invariably present beyond 17 days (17 mm crown-rump length). In both human and rat embryos, either by scanning electron microscopy and light microscopy, the left coronary orifice was observed significantly earlier. In all the investigated embryos, human as well as rat, septation at arterial orifice level was complete, including the earliest stages studied. Light microscopy showed that at the emerging stages of the coronary orifices, the proximal epicardial segments of the left and right coronary arteries could already be identified in a peritruncal ring of epicardial vasculature, before the coronary orifice was observed. This was the case in human as well as in rat embryos. Thus, a coronary orifice was never seen in the absence of a proximal coronary artery. The present theories on development of the proximal coronary arteries and coronary orifices do not offer an adequate explanation for either these data or the known possible congenital abnormalities of the coronary arteries. Our study supports dual proximal coronary arterial development. These two proximal coronary arteries develop out of a peritruncal ring of vascular structures on to the aorta. The process by which the coronary orifices actually develop remains to be explained.     

Development of cerebrospinal fluid and the blood-cerebrospinal fluid barrier in rabbits.

Blood plasma and cerebrospinal fluid (CSF) samples were collected from adult female rabbits (New Zealand White), newborn, and embryos at 18, 20, 24, and 28 days of gestation. Samples were analyzed for total protein using the Folin phenol reagent. During development, mean total protein of blood plasma rose sharply from 12.45 to 12.51 mg/ml at 18 to 20 days to 37.56 mg/ml at 28 days. Levels further increased to 54.06 mg/ml in the newborn and to 66.18 mg/ml in the adult. The protein concentration of cerebrospinal fluid was constant at 5.20 to 5.29 mg/ml between 18 and 20 days of gestation, but steadily decreased to 3.53 mg/ml at 28 days. By birth, the CSF protein concentration was further reduced to 2.08 mg/ml, and this level differed only slightly (P < 0.05) from CSF protein values determined for adults. These data indicate that the blood-cerebrospinal fluid barrier to proteins begins to function by 18 to 20 days of gestation, and the protein concentration of cerebrospinal fluid approaches the normal adult value soon after birth.     

Electron microscopy of neurosecretory nerve fibres in the neural lobe of the embryonic mouse

Summary Nerve fibres of the neurosecretory hypothalamo-hypophyseal tract were studied in embryonic C3H mouse neural lobes; at least four glands at each gestational day 15–19 were examined.Single axons and small bundles of fibres are visible at gestational days 15 and 16. By day 17 large fibre bundles penetrate between glial cells. They increase in number during the next two days.Electron-lucent and electron-dense vesicles are seen in the fibres of the 15th and 16th gestational days. In the 17–19 day-old embryos development is characterized by a successive rise in the number of the two types of vesicles. The mean diameter of the electron-lucent vesicles is approximately unchanged in all the stages examined (50 nm). The electron-dense vesicles increase in size from approximately 80–90 nm at days 15–16 to 140 nm at the 19th gestational day.By day 19 contacts between neurosecretory fibre terminals and the outer basement membrane of internal and peripheral capillaries are occasionally observed. The possibly adrenergic nature of a few terminals contacting peripheral vascular structures in 17 and 18 day-old embryos is suggested.This investigation was supported by grant No. 2180-020 from the Swedish Natural Science Research Council. The skilful technical assistance of Mrs. Ulla Wennerberg is gratefully acknowledged.     

Axonal pathfinding in organ-cultured embryonic avian retinae

Eye cups from stage 14-28 (E2 to E5) chick and quail embryos consisting of neural retina, lens, and vitreous body were cultured for 1 or 2 days. These eyes expanded by proliferation of the retinal cells and the surface areas of the retinae increased several-fold. The area covered by ganglion cells and axons also expanded in vitro. [3H]Thymidine labeling showed extensive proliferation of the neuroepithelial cells including the formation of new ganglion cells. Culturing eyes from embryos before stage 17 results, as in vivo, in the generation of the first ganglion cells of the retina, but unlike in the in vivo situation, the outgrowing axons always formed a random fiber net in the central portion of the retina. A defined axonal pattern identical to the in vivo developed only in specimens from embryos of stage 17 and older. Some aberrant axons, however, were also observed at the retinal periphery in specimens from embryos of more advanced stages (20-24), but only during the second day of culturing. Axons in retinae from embryos of stages 23 to 26 heading toward the optic fissure often crossed the fissure and, in contrast to the situation in vivo, invaded the opposite retinal side. These axons of wrong polarity followed the pathways of axons growing centripetally but in reverse direction. This suggests that the polarity of growing nerve fibers and their course are determined by different factors. Culturing the eyes of embryos from stages 20 to 25 in the presence of antibodies showed that the antibodies penetrated the entire retina with 6 hr. Neither anti-N-CAM nor the T-61 antibody--both recognizing membrane proteins of retinal cells--affected the growth of the eyes in vitro. The development of the axonal pattern in vitro was not affected by incubation with N-CAM-antibodies at concentrations up to 500 micron/ml, whereas the T-61 antibody which is known to block neurite extention in vitro (S. Henke-Fahle, W. Reckhaus, and R. Babiel (l984). "Developmental Neuroscience: Physiological, Pharmacological, and Clinical Aspects," pp. 393-398. Elsevier, Amsterdam/New York) showed inhibition of axonal growth in retina cultures at 50 micron/ml. These results indicate that the eye cultures can be used as a test system for antibodies against antigens which could be involved in axon extension and neurite pathfinding in situ.     

Accumulation of a specific subset of D. melanogaster heat shock mRNAs in normal development without heat shock

During normal development in D. melanogaster, messenger RNAs for three of the seven heat shock proteins (hsp83, hsp28 and hsp26) accumulate in adult ovaries and are abundant in embryos until blastoderm. The three mRNAs appear to originate in nurse cells and subsequently pass, during stages 10-11, into the oocyte. Little if any of the four other heat shock mRNAs is present in unshocked ovaries or embryos at any time examined. Pre-blastoderm embryos fail to accumulate these heat shock mRNAs even if subjected to heat shock. The accumulation in normal oogenesis of mRNAs for only three of the seven heat shock proteins indicates the existence of differential, possibly multiple controls of heat shock gene expression, and suggests that heat shock proteins hsp83, hsp28 and hsp26 function in the oocyte or early embryo.     

Actin filament distribution in blocked and developing pig embryos

Actin filaments play an important role in cell division. The present study was designed to examine the relationship between actin filament distribution and pig embryo development. When in vivo matured and fertilised pig oocytes were cultured in TCM 199 or NCSU 23, in various proportions, 45-65% of inseminated oocytes developed to the 2- to 4-cell stages but blastocyst development was observed only in NCSU 23 (34%) or NCSU 23 containing 10% TCM 199 (7%). Supplementation of NCSU 23 medium with 20% or more TCM 199 resulted in no blastocyst formation. Examination of actin filaments indicated that microfilaments were distributed in the cortex, at the junction of blastomeres and in the perinuclear area in the embryos cultured in NCSU 23, but perinuclear actin filaments were not observed in embryos cultured in TCM 199. When 2- to 4-cell stage embryos obtained from TCM 199 were transferred to NCSU 23 medium at 36 h after in vivo fertilisation, 57% of the cleaved embryos developed to blastocysts, which was no different from the proportion obtained after culture in NCSU 23 alone (56%). In addition, when 2- to 4-cell stage embryos obtained from TCM 199 were transferred to NCSU 23, most embryos showed perinuclear actin filaments within 6h. The results indicate that the composition of the culture medium plays an important role in the polymerisation of actin filaments, which in turn influences embryo development. It is possible that pig embryo development was blocked by some components in TCM 199 which prevented actin filament polymerisation.