Somite subdomains, muscle cell origins, and the four muscle regulatory factor proteins

We show by immunohistology that distinct expression patterns of the four muscle regulatory factor (MRF) proteins identify subdomains of mouse somites. Myf-5 and MyoD are, at specific stages, each expressed in both myotome and dermatome cells. Myf-5 expression is initially restricted to dorsal cells in all somites, as is MyoD expression in neck somites. In trunk somites, however, MyoD is initially expressed in ventral cells. Myogenin and MRF4 are restricted to myotome cells, though the MRF4-expressing cells are initially less widely distributed than the myogenin-expressing cells, which are at all stages found throughout the myotome. All somitic myocytes express one or more MRFs. The transiently distinct expression patterns of the four MRF proteins identify dorsal and ventral subdomains of somites, and suggest that skeletal muscle cells in somites originate at multiple sites and via multiple molecular pathways.     

小鼠早期胚胎发育期间TGF—β免疫组织化学定位

The distribution of transforming growth factor beta-1 (TGF-beta-1) in the early developing mouse embryos between day 1 and day 12 of gestation was examined by immunohistochemical techniques. Polyclonal rabbit antiserum raised against a synthetic oligopeptide identical to the N-terminal residues 1-29 of TGF-beta-1 from human platelets was used. The following results were obtained: 1. Embryonic cells of early cleavage stages (2, 4 and 8 cells) and late morulae showed positive immunofluorescent reaction without any difference in staining intensity (Plate I, Figs. 1-4). 2. Marked staining of blastocysts in toto or sections with anti-TGF-beta-1 antibodies by either immunofluorescence or immunoperoxidase reaction was also observed. Inner cell mass (ICM) cells and trophoectoderm cells were both reacted, but more intense staining was found in primary endoderm cells differentiated from ICM cells adjacent to blastocoele (Plate II, Fig. 5). 3. Scattered granules stained strongly with immunoperoxidase reaction were present in embryonic ectoderm and visceral endoderm surrounding the forming mesoderm which was only slightly stained (Plate II, Fig. 6). 4. Intense immunoperoxidase staining was also present in mesoderm of visceral yolk sac of day 8 and day 10 embryos (Plate II, Fig. 7). 5. During the formation of somites, neural tube and limb bud, remarkable staining was found in mesenchyme, individual cells of somites, mucous layer of gut tubes, heart and limb buds (Plate III, Figs. 8-10). No significant staining was seen in neural cells per se except the inner surface of neural tube. The results of present studies indicate that abundant TGF-beta-1 is present in preimplantation mouse embryos including cleavage, morulae and blastocyst stages. In postimplantation embryos, TGF-beta-1 appears to play an important role in the differentiation of endoderm and mesoderm, particularly in the development of extraembryonic tissues, and in later morphogenetic and histogenetic events involving mainly mesoderm or mesenchyme cells.     

Neural crest cell migratory pathways in the trunk of the chick embryo

Neural crest cells migrate during embryogenesis to give rise to segmented structures of the vertebrate peripheral nervous system: namely, the dorsal root ganglia and the sympathetic chain. However, neural crest cell arise from the dorsal neural tube where they are apparently unsegmented. It is generally agreed that the somites impose segmentation on migrating crest cells, but there is a disagreement about two basic questions: exactly pathways do neural crest cells use to move through or around somites, and do neural crest cells actively migrate or are they passively dispersed by the movement of somite cells? The answers to both questions are critically important to any further understanding of the mechanisms underlying the precise distribution of the neural crest cells that develop into ganglia. We have done an exhaustive study of the locations of neural crest cells in chick embryos during early stages of their movement, using antibodies to neural crest cells (HNK-1), to neural filament-associated protein in growing nerve processes (E/C8), and to the extracellular matrix molecule laminin. Our results show that Some neural crest cells invade the extracellular space between adjacent somites, but the apparent majority move into the somites themselves along the border between the dermatome/myotome (DM) and the sclerotome. Neural crest cells remain closely associated with the anterior half of the DM of developing somites as they travel, suggesting that the basal lamina of the DM may be used as a migratory substratum. Supporting this idea is our observation that the development of the DM basal lamina coincides in time and location with the onset of crest migration through the somite. The leading front of neural crest cells advance through the somite while the length of the DM pathway remains constant, suggesting active locomotion, at least in this early phase of development. Neural crest cells leave the DM at a later stage of development to associate with the dorsal aorta, where sympathetic ganglia form, and to associate with newly emerging fibers of the ventral root nerve, where they presumably give rise to neuronal supportive cells. Thus we propose that the establishment of the segmental pattern of the peripheral ganglia and nerves depends on the timely development of appropriate substrata to guide and distribute migrating neural crest cells during the early stages of embryogenesis.     

Localization of Type IV Collagen in the Myotome Cells during the Somite Differentiation in the Chick Embryo

Type IV collagen is a major structural component of basement membranes which play various roles upon their adjacent cells. In order to better understand roles of type IV collagen during the somite differentiation, we produced anti-rat type IV collagen polyclonal antibodies and demonstrated spacial and temporal distribution of type IV collagen in somites of the chick embryo by immunohistochemical procedure. Type IV collagen was detected in the basal surface and the cytoplasm of epithelial dermatome cells at early stage of the somite differentiation, and then detected in myotome cells overlying apical surface of dermatomes, but not in migratory mesenchymal dermatome cells. With the appearance of type IV collagen-expressing myotome cells, epithelial dermatome cells showed the decrease in immunoreaction with anti-type IV collagen antibodies, the disappearance of their basal-apical polarity and their epithelial shape. From these results, it was suggested that type IV collagen is an early marker for myotome cells, and that type IV collagen and/or other factors co-expressed by myotome cells might provide an accelerative signal for epithelial/mesenchymal conversion of dermatome cells.     

Formation of the dorsal root ganglia in the avian embryo: Segmental origin and migratory behavior of neural crest progenitor cells

The segmental origin and migratory pattern of neural crest cells at the trunk level of avian embryos was studied, with special emphasis on the formation of the dorsal root ganglia (DRG) which organize in the anterior half of each somite. Neural crest cells were visualized using the quail-chick marker and HNK-1 immunofluorescence. The migratory process turned out to be closely correlated with somitic development: when the somites are epithelial in structure few labeled cells were found in a dorsolateral position on the neural tube, uniformly distributed along the craniocaudal axis. Following somitic dissociation into dermomyotome and sclerotome labeled cells follow defined migratory pathways restricted to each anterior somitic half. In contrast, opposite the posterior half of the somites, cells remain grouped in a dorsolateral position on the neural tube. The fate of crest cells originating at the level of the posterior somitic half was investigated by grafting into chick hosts short segments of quail neural primordium, which ended at mid-somitic or at intersomitic levels. It was found that neural crest cells arising opposite the posterior somitic half participate in the formation of the DRG and Schwann cells lining the dorsal and ventral root fibers of the same somitic level as well as of the subsequent one, whereas those cells originating from levels facing the anterior half of a somite participate in the formation of the corresponding DRG. Moreover, crest cells from both segmental halves segregate within each ganglion in a distinct topographical arrangement which reflects their segmental origin on the neural primordium. Labeled cells which relocate from posterior into anterior somitic regions migrate longitudinally along the neural tube. Longitudinal migration of neural crest cells was first observed when the somites are epithelial in structure and is completed after the disappearance of the last cells from the posterior somitic region at a stage corresponding to the organogenesis of the DRG.     

The conduction system and expressions of hyperpolarization-activated cyclic nucleotide-gated cation channel 4 and connexin43 expressions in the hearts of fetal day 13 mice

We investigated the development of the sinus node of the heart conduction system by localizing hyperpolarization-activated cyclic nucleotide-gated cation channel 4 (HCN4) and connexin43 (Cx43) in the hearts of fetal day 13 mice. Horizontal serial sections of day 13 whole fetuses were stained by hematoxylin and eosin and immunofluorescence to identify myocardial cells that express HCN4, hyperpolarization-activated cyclic nucleotide-gated cation channel 2 (HCN2) and Cx43. Expression levels of HCN4 and Cx43 were determined by quantitative RT-PCR in both fetal day 13 and adult mice. We found that both Cx43 and HCN4 expressions were located on the cell membranes in the hearts of fetal day 13 mice, but Cx43 was distributed throughout the myocardial cells. HCN4 expression was concentrated mainly in the left dorsal epicardium of the right atrium where Cx43 expression was low or absent. Quantitative RT-PCR demonstrated that HCN4 expression was significantly higher and HCN2 expression was significantly lower in fetal day 13 mice than in adults. We found no statistically significant difference in Cx43 expression between fetal day 13 mice and adults. HCN4 stained myocardial cells in the left dorsal epicardium of the right atrium are the origin of the sinus node and the remainder of the heart conduction system.     

Morphological alterations induced by sodium valproate on somites and spinal nerves in rat embryos

The antiepileptic drug valproic acid is a well-known teratogenic agent; its main target organ is the neural tube, though skeletal malformations have also been described. In our recent work, respecifications of vertebrae were described in rat fetuses after treatment with 400 mg/kg of sodium valproate at specific somitogenic stages. The observed malformations were stage-dependent. Morphological segmental respecification was observed at the level of segments in formation at the moment of exposure and at the level of more posterior segments. Recently, specific alterations in the development of cranial nerves and ganglia were described in mouse embryos after in vitro exposure to VPA. The aim of the present work was to analyze dysmorphogenetic effects of VPA on embryonic metameric structures: somites, spinal and cranial nerves, and ganglia. Sodium valproate (400 mg/kg) was subcutaneously injected at specific gestational times corresponding to embryonic stages: presomitic or at about 2, 6, 10, 14, 18, or 22 somites. Females were sacrificed on the day 12 post coitum, and embryos were examined. Morphological examination of somites was performed by staining with acridine orange. Morphological examination of nerves and ganglia was performed by immunostaining, using monoclonal antibodies to the 160-kD neurofilament protein. No abnormalities were observed in the cranial nerves and ganglia. Specific and stage-dependent alterations were observed both at the level of the somites and at the level of the spinal nerves. The following characteristic malformations were observed: fusions, duplications, and reductions of somites and corresponding spinal nerves and ganglia. Our morphological data suggest a morphogenetic action of VPA at the level of the axial segments, with a possible respecification of the identity of the interested segments and their derivatives.     

Development of VIP in the peripheral nervous system of avian embryo

The distribution of the VIP containing structures was studied in the gut and in the paravertebral sympathetic ganglia of the quail and chick embryos by immunocytochemistry. In the gut, development of peptidergic nerves followed a craniocaudal gradient. Immunoreactive fibres were first visible in the oesophagus at day 9 in the quail and day 10 in the chick, at 12 days they extended over the whole length of the gut. Cell bodies were localized at day 9 in the foregut and observed in the mid- and hind-gut just before hatching. Transplantations on the chorioallantoic membrane of fragments of various parts of the digestive tract clearly demonstrated that VIP nerve cell bodies belonged to the intrinsic innervation of the gut. Besides the gut, sympathetic paravertebral ganglia contained cells with VIP immunoreactivity detected at day 9 and 10 in quail and chick respectively. In order to find out whether VIP containing neurons differentiated normally in chick embryos in which quail neural crest cells had been implanted at an early stage of development we looked for the appearance of peptidergic neurones in the following situations: when the quail neural primordium had been grafted orthotopically and isochronically into chick host (1) at the adrenomedullary (somites 18-24) and (2) at the vagal (somites 1-7) levels of the neural axis. In all conditions VIP immunoreactivity was observed in quail cells located either in the sympathetic paravertebral ganglia of the trunk at the level of the graft or in the enteric ganglia according to the graft was made at the adrenomedullary and vagal levels respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Change of Rat Embryos from a Ventrally Concave U-Shape to a Ventrally Convex C-Shape

In an early stage of development in murine embryos, axial rotation occurs and the body axis changes from a ventrally concave U-shape to a ventrally convex C-shape. In this study, axial rotation in Sprague-Dawley rat embryos occurred in about 5 h in vitro (from 27 h to 32 h in cultures of head-fold stage embryos). In sagittal sections, the somites in the mid-region of the body changed from a trapezoidal shape with a short dorsal side and long ventral side to the reverse trapezoidal shape with a long dorsal side and a short ventral side. The dorsal part of these somites acquired the ability to react with actin-specific antibody and developed into dermatome. On treatment with 0.1 μg/ml cytochalasin D during this 5 h period, embryos became ventrally concave with two lordosis bends. The somites in the bends had a short dorsal side, which did not show any evidence of dermatome or intense immunocytochemical staining. These results suggest that the increase in length of the dorsal side of the somites is a cause of the axial rotation and that the organization of actin filaments plays an important role in the conformational change of the somites.     

An immunofluorescence analysis of the ontogeny of myeloid, T, and B lineage cells in mouse hemopoietic tissues

The population dynamics of granulopoietic cells, B-lineage cells, and T lymphocytes were analyzed by immunofluorescence in mouse hemopoietic tissues as a function of age. Mac-1+ myeloid cells were present on day 11 of gestation in the liver, where they peaked shortly after birth and declined subsequently. Waves of myeloid population growth began in spleen and bone marrow by days 15 and 19, respectively. Mac-1+ cells increased in number to relatively low plateau levels in spleen by the 3rd wk after birth, whereas in the bone marrow higher plateau levels were reached around 3 mo of age. The 14.8 monoclonal antibody was utilized as one marker of B-lineage precursor cells. 14.8+ cells were detected in the liver on day 11 of gestation, reached peak numbers during the first week after birth and decreased thereafter. On day 15 and 19, 14.8+ cells were found in spleen and bone marrow, respectively, and progressively increased in numbers to reach plateau levels in both sites by 3 mo of age. Mu+ pre-B cells appeared in significant numbers in the 13-day fetal liver, reached a peak shortly after birth, and disappeared from the liver by the end of the second postnatal week. Pre-B cells were found in the spleen and bone marrow on days 15 and 19, respectively. In the spleen pre-B cells reached peak values at birth and disappeared 2 wk later. In spite of the sequential appearance of mu+ pre-B cells in fetal liver, spleen, and bone marrow, their sIgM+ B cell progeny appeared in all these hemopoietic tissues on day 17 of gestation. In the liver, sIgM+ B cells reached their peak at birth and declined thereafter. In the spleen and bone marrow, B cells increased to plateau levels between 1 and 4 mo of age. Thy-1.2+ T cells were relatively late acquisitions in all three hemopoietic tissues. Finally, the expression of the 14.8 antigen by mu+ cells was examined as a function of gestational age. While pre-B cells from day-13 fetuses had no detectable 14.8 antigen, the antigen was weakly expressed on the vast majority of the mu+ pre-B cells by day 17 of gestation. Newborn liver cells expressing 14.8 antigen were found to include a small proportion of cells with peroxidase+ granules. Thus, demonstration of rearrangement and expression of immunoglobulin genes may be required for precise identification of cells of B lineage early in ontogeny.     

Muscular derivatives of the cranialmost somites revealed by long-term fate mapping in the Mexican axolotl (Ambystoma mexicanum)

The fate of single somites has not been analyzed from a comparative perspective with modern cell-marking methods. Most of what we know is based on work using quail-chick chimeras. Consequently, to what degree cell fate has been conserved despite the anatomical differences among vertebrates is unknown. We have analyzed the cell fate of the cranialmost somites, with the focus on somite two, in the Mexican axolotl (Ambystoma mexicanum). Somite cells were marked by injection of dextran-fluorescein and detected using immunofluorescence after 2 months of development in paraffin sections. Our data confirm and extend earlier studies based on classical histology in salamanders. We show that somite two contributes to different muscles, skeletal elements, and connective tissues of the head and cranial trunk region. Cells from somites two and three migrate latero-ventrally and contribute to the hypobranchial muscles mm. geniohyoideus and rectus cervicis. We provide evidence that the specific formation of the hypobranchial musculature from ventral processes of the somites might be variable in different classes of vertebrates. We further demonstrate that mm. cucullaris and dilatator laryngis, which were earlier thought to have a branchial origin, arise from somitic material in a manner very similar to the findings in quail-chick chimeras. Our findings indicate that the pattern of somitic derivatives is highly conserved within tetrapods.     

Changes in the muscle ultrastructure and electrolyte composition of rats in embryogenesis. II. X-ray spectrum microanalysis of the intracellular concentrations of potassium, sodium and phosphorus in skeletal and heart muscle

Concentrations of K, P and Na were determined in skeletal and cardiac muscle cells of rat embryos. High K and P levels--133 and 166 mmole/kg wet weight, resp.,--were found in skeletal muscles of 13 day old embryos, the concentration of Na in these cells being 81 mmole/kg w. w. On the 18th day of development, K and P in skeletal muscle cells decreased down to 79 and 118 mmole/kg w. w., resp., while the concentration of Na increased to 165 mmole/kg w. w. In 19 day old embryos, the concentrations of K and P increased, although they did not reach the level typical of skeletal muscles of adult rats. The concentrations of K and P in cardiac muscle cells of 13 day embryos were found equal to 100 and 108 mmole/kg w. w., resp., on the 19th day of development these concentrations reached the level typical of the cardiac muscle cells of adult rats.     

Adhesion molecules during somitogenesis in the avian embryo

In avian embryos, somites constitute the morphological unit of the metameric pattern. Somites are epithelia formed from a mesenchyme, the segmental plate, and are subsequently reorganized into dermatome, myotome, and sclerotome. In this study, we used somitogenesis as a basis to examine tissue remodeling during early vertebrate morphogenesis. Particular emphasis was put on the distribution and possible complementary roles of adhesion-promoting molecules, neural cell adhesion molecule (N-CAM), N-cadherin, fibronectin, and laminin. Both segmental plate and somitic cells exhibited in vitro calcium-dependent and calcium-independent systems of cell aggregation that could be inhibited respectively by anti-N-cadherin and anti-N-CAM antibodies. In vivo, the spatio-temporal expression of N-cadherin was closely associated with both the formation and local disruption of the somites. In contrast, changes in the prevalence of N-CAM did not strictly accompany the remodeling of the somitic epithelium into dermamyotome and sclerotome. It was also observed that fibronectin and laminin were reorganized secondarily in the extracellular spaces after CAM-mediated contacts were modulated. In an in vitro culture system of somites, N-cadherin was lost on individual cells released from somite explants and was reexpressed when these cells reached confluence and established intercellular contacts. In an assay of tissue dissociation in vitro, antibodies to N-cadherin or medium devoid of calcium strongly and reversibly dissociated explants of segmental plates and somites. Antibodies to N-CAM exhibited a smaller disrupting effect only on segmental plate explants. In contrast, antibodies to fibronectin and laminin did not perturb the cohesion of cells within the explants. These results emphasize the possible role of cell surface modulation of CAMs during the formation and remodeling of some transient embryonic epithelia. It is suggested that N-cadherin plays a major role in the control of tissue remodeling, a process in which N-CAM is also involved but to a lesser extent. The substratum adhesion molecules, fibronectin and laminin, do not appear to play a primary role in the regulation of these processes but may participate in cell positioning and in the stabilization of the epithelial structures.     

Demonstration, by means of electron microscopy, of the penetration of somitic cells into the mesoblast of the limb buds of reptile embryos (Anguis fragilis, Lacerta viridis)]

An electron microscopic study of the components of anterior limb buds of the slow-worm (Anguis fragilis) and of the green lizard (Lacerta viridis) (embryos of Anguis whose allantoic bud reach 0,7 to 4 mm of length; embryos of Lacerta 2 to 7 days old) provides data on the cytological characteristics of the components of the limb bud at these early stages. 1. The cells of the distal extremity of the somitic processes extending in the limb bud of Anguis and Lacerta, are elongated cells with ovoid nuclei containing large nucleolus; they possess mitochondria always thin and with dense matrix; they are rich in lipid droplets; they possess cilia; they are devoid of myofilaments; endoplasmic reticulum, free ribosomes and polyribosomes are abundant. Golgi networks display signs of activity. These characteristics are also observed in the cells of the "dermatome" layer of the dermo-myotome; and so, it appears probable that the cells of the "dermatome". Furthermore, in Anguis embryos, the cells of the distal extremities of the somitic processes possess numerous lysosomes and a certain number of cells among them, degenerate early. 2. The somatopleural mesoblastic cells of the limb bud of Anguis and Lacerta embryos keep the characters of the cells of the mesodermic layer of lateral plate from which they originate; they have rounded nuclei, cilia, and their mitochondria are always larger and more transparent to electrons, than the ones of cells of the somitic processes and of cells of the epiblastic apical crest. Golgi networks are well developped, endoplasmic reticulum is abundant, lipid droplets are rare. 3. The processes of somites which extend in the dorsal part of the limb bud of Anguis embryos are cords of cells with thin lumina; at the stage of the allantoic bud of 0,6 to 0,8 mm long, the distal extremity of these processes dislocate in group of cells which afterwards dissociate, releasing individual somitic cells which are integrated among the mesoblastic somatopleural cells. In young lizard embryos (2 to 4 days old) the distal extremity of the somitic processes enlarges into a vesicle from which cells are released and penetrate in the mesoblast of the limb bud. 4. The somitic cells released from the somitic processes of Anguis and Lacerta keep--at least at early stages--the cytological characteristics they displayed when they were still in situ in the somitic processes: grounded on the presence or absence of lipid droplets, on the width and density of the mitochondria, the distinction, at these stages, between the somitic and mesoblastic somatoplerual cells is possible; and it is also possible to observe the integration of the somitic cells into the mesoblast. This study brings the demonstration of the cellular contribution of the somites to the formation of the limb bud in Reptiles. 5...     

A gene with sequence similarity to Drosophila engrailed is expressed during the development of the neural tube and vertebrae in the mouse

The mouse genes En-1 and En-2 display sequence similarity, in and around the homeobox region, to the engrailed family in Drosophila. This paper describes their pattern of expression in the 12.5-day mouse embryo as determined by in situ hybridization. En-2 is expressed in a subset of cells expressing En-1. Both genes are expressed in the developing midbrain and its junction with the hindbrain. In addition, En-1 is expressed in the floor of the hindbrain, a restricted ventrolateral segment of the neural tube throughout the trunk and anterior part of the tail, the dermatome of tail somites, the centrum and costal processes in developing vertebrae, a restricted region of facial mesenchyme and the limb-bud ectoderm. Supplementary studies of 9.5-day and 10.5-day embryos showed that the same pattern of expression pertained in the neural tube, but that expression in the somites is at first confined to the dermatome and later found at a low level in restricted sclerotomal regions. Both genes are expressed in restricted domains which do not cross tissue-type boundaries. In several instances, however, boundaries of expression lie within morphologically undifferentiated tissue. These results suggest that En-1 and En-2 may be involved in the establishment or maintenance of the spatial integrity of specific domains within developing tissues.     

The contribution made by cells from a single somite to tissues within a body segment and assessment of their integration with similar cells from adjacent segments

Somites represent the first visual evidence of segmentation in the developing vertebrate embryo and it is becoming clear that this segmental pattern of the somites is used in the initial stages of development of other segmented systems such as the peripheral nervous system. However, it is not known whether the somites continue to contribute to the maintenance of the segmental pattern after the dispersal of the somitic cells. In particular, the extent to which cells from a single somite contribute to all of the tissues of a single body segment and the extent to which they mix with cells from adjacent segments during their migration is not known. In this study, we have replaced single somites in the future cervical region of 2-day-old chick embryos with equivalent, similarly staged quail somites. The chimerae were then allowed to develop for a further 6 days when they were killed. The cervical region was dissected and serially sectioned. The sections were stained with the Feulgen reaction for DNA to differentiate between the chick and quail cells. The results showed that the cells from a single somite remained as a clearly delimited group throughout their migration. Furthermore, the sclerotome, dermatome and myotome portions from the single somites could always be recognised as being separate from similar cells from other somites. The somitic cells formed all of the tissues within a body segment excluding the epidermis, notochord and neural tissue. There was very little mixing of the somitic cells between adjacent segments. The segmental pattern of the somites is therefore maintained during the migration of the somitic cells and this might be fundamental to a mechanism whereby the segmentation of structures, such as the peripheral nervous system, is also maintained during development.     

动物体节发生模型及其相关基因研究进展

脊椎动物在胚胎发育的过程中沿身体前后轴形成一定数目的暂时性结构—体节（somite）,随着胚胎的继续发育每个体节分化成为生骨节,生皮节和生肌节,继而生成各种组织。近三十年来,研究者们就体节的发生和发育提出了多种解释模型,这包括时钟波阵面模型,反应扩散模型,时钟诱导模型,时钟痕迹模型等,虽然这些模型能从不同角度不同程度来解释动物体节发生和发育的不同现象, 但无一能够解释体节发生和发育的全部。然而,大多数模型都提出了时钟分割（segmental clock）这一概念。鸡胚中的c-hairy1和c-hairy2,鸡胚、小鼠中的lunatic fringe以及斑马鱼中的her1, Delta C等几种基因的表达图式的研究为模型中分割时钟的存在提供了分子生物学上的有力证据。