Toshihisa Hatta

K-Ras is essential for the development of the mouse embryo

ras genes encode members of the small GTP-binding proteins. Ras protein is highly conserved in various species from yeast to humans and plays a key role in signal transduction. Ras is related to cell proliferation and differentiation. While, in addition, mutations in the ras genes are implicated in a variety of tumors. However, the physiological functions and specific roles of each ras gene, H-ras, K-ras and N-ras, are still not fully understood. To clarify the role of the K-Ras in vivo, we generated K-ras mutant mice by gene targeting. In contrast to the findings that H-Ras-deficient mice and N-Ras-deficient mice are born and grow normally, the K-Ras-deficient embryos die progressively between embryonic day 12.5 and term. At embryonic day 15.5, their ventricular walls are extremely thin. Besides, at embryonic day 11.5, they demonstrate increased cell death of motoneurons in the medulla and the cervical spinal cord. Our results thus indicate K-Ras to be essential for normal development in mice and residual Ras composed of H-Ras and N-Ras cannot compensate for the loss of K-Ras function in the mutant mice.

Mouse Ror2 receptor tyrosine kinase is required for the heart development and limb formation

A mouse receptor tyrosine kinase (RTK), mRor2, which belongs to the Ror‐family of RTKs consisting of at least two structurally related members, is primarily expressed in the heart and nervous system during mouse development. To elucidate the function of mRor2, we generated mice with a mutated mRor2 locus.

Spatio‐temporally regulated expression of receptor tyrosine kinases, mRor1, mRor2, during mouse development: implications in development and function of the nervous system

Drosophila neurospecific receptor tyrosine kinases (RTKs), Dror and Dnrk, as well as Ror1 and Ror2 RTKs, isolated from human neuroblastoma, have been identified as a structurally related novel family of RTKs (Ror‐family RTKs). Thus far, little is known about the expression and function of mammalian Ror‐family RTKs.

Mitochondrial voltage-dependent anion channels (VDACs) as novel pharmacological targets for anti-cancer agents

Recently, it was demonstrated that some anti-cancer agents used mitochondrial voltage-dependent anion channels (VDAC1–3 isoforms) as their pharmacological target. VDACs are expressed more highly in cancer cells than normal cells; thus the VDAC-dependent cytotoxic agents can have cancer-selectivity. Furanonaphthoquinones (FNQs) induced caspase-dependent apoptosis via the production of NADH-dependent reactive oxygen species (ROS) by VDAC1. The ROS production and the anti-cancer activity of FNQs were increased by VDAC1 overexpression. Meanwhile, erastin induced RAS-RAF-MEK-dependent non-apoptotic cell death via VDAC2. On the other hand, VDACs were needed for transporting ATP to hexokinase (HK), which was highly expressed in cancer cells. We hypothesized that the high glycolysis might induce up-regulation of VDAC. In this review, we propose that VDACs are novel candidates for effective pharmacological targets of anti-cancer drugs.

Roles of leptin in prenatal and perinatal brain development

ABSTRACT  Leptin is a hormone that reduces food intake and increases energy expenditure by acting on the arcuate nucleus in the hypothalamus. Recent studies indicated that the neuronal circuit related to food intake in the hypothalamus is formed in the neonatal period and that leptin is necessary for the formation of this circuit. Our studies have further suggested that leptin may act on the fetal cerebral cortex, including the cingulate cortex, which is involved in motor and cognitive processes, and that leptin may affect maintenance and differentiation of neural stem cells, glial‐restricted progenitor cells and/or neuronal lineage cells. These recent studies showed that leptin not only has homeostatic functions in adults, but also regulates brain development in the prenatal and neonatal periods. These findings suggest that leptin is related to formation of the normal brain structure and regenerative potency of neural cells as well as the predisposition to homeostatic dysfunction, low locomotor activity or impairment of cognitive function.

APOPTOSIS DURING INNER EAR DEVELOPMENT IN HUMAN AND MOUSE EMBRYOS : AN ANALYSIS BY COMPUTER-ASSISTED THREE-DIMENSIONAL RECONSTRUCTION

 Apoptosis in the developing inner ear tissue of human (Carnegie stage 14 to 21, approximately 5 to 8 weeks of gestation) and mouse (10.5 to 14 days of gestation) embryos was systematically analyzed by a computer-assisted three-dimensional reconstruction of the serial histological sections and by the TUNEL method. Morphogenetic events such as folding between the utricular portion and endolymphatic duct, constriction of the junction of the saccule with the cochlea and folding of the vestibular portion to form the semicircular ducts were accompanied by a localized distribution of apoptosis. The apoptosis was also related to the innervation of the cochlear and vestibular epithelia from the sensory ganglion of the eighth cranial nerve and the differentiation of the otic epithelia into the sensory epithelia. These results suggest that apoptosis plays an important role in the development of the inner ear.

Expression of the long form of leptin receptor (Ob-Rb) mRNA in the brain of mouse embryos and newborn mice

The long form of the leptin receptor (Ob-Rb) has a cytoplasmic domain which activates the JAK-STAT signal transduction pathway. It is related to appetite and energy expenditure and is expressed in various parts of the brain in adults. In embryos, however, the detailed distribution of Ob-Rb expression sites and the function of the leptin-Ob-Rb system remain unclear, although leptin is detected in human cord plasma and leptin mRNA is detected in mouse embryos. In this study, we investigated the Ob-Rb mRNA expression pattern in the brains of mouse embryos and newborn mice by RT-PCR and in situ hybridization. At embryonic day 10.5 (E10.5), Ob-Rb mRNA was already detected in the brain by RT-PCR. By in situ hybridization, Ob-Rb mRNA was observed in the ventricular zone of the rhombencephalon at E11.5. At E12.5, it was also expressed in the ventricular zone of the telencephalon, mesencephalon and cerebellar primordium. From E14. 5 it was expressed in the cortical plate of the telencephalon and the ventricular zone of the thalamus. At E16.5, it was expressed in the premamillary hypothalamic nucleus, superficial gray matter of the superior colliculus, external germinal and Purkinje cell layers of the cerebellum, and facial nucleus. At E18.5, it was expressed in the arcuate nucleus and ventromedial hypothalamic nucleus. These results suggest that the leptin-Ob-Rb system is related to brain development.

Ror2 is Required for Midgut Elongation During Mouse Development

The receptor tyrosine kinase Ror2 acts as a receptor for Wnt5a to mediate noncanonical Wnt signaling, and it plays essential roles in morphogenesis. Ror2−/− embryos exhibit phenotypes similar to, albeit generally milder than, those of Wnt5a−/− embryos. During mouse embryogenesis, Ror2 is expressed in various organs and regions, although little is known about its expression pattern and roles in the developing gut, while Wnt5a is expressed in the developing gut, where its absence causes abnormal phenotypes. Here, we demonstrated that Ror2 was strongly and differentially expressed in the rostral and middle midgut endoderm from embryonic day (E) 10.5 through embryonic day (E) 12.5. At E11.5, Ror2−/− embryos exhibited a shorter middle midgut with a larger diameter and more accumulation of epithelial cells in the middle midgut than control embryos, while the total cell numbers remained unaltered. These findings suggest that Ror2 plays important roles in midgut elongation by means of an epithelial convergent extension mechanism. Developmental Dynamics 239:941–953, 2010.

Congenital deformities and developmental abnormalities of the mandibular condyle in the temporomandibular joint

ABSTRACT  The temporomandibular joint (TMJ) consists of the mandibular condyle and the articular eminence of the temporal bone. The morphological development of the TMJ during prenatal life lags behind other joints in terms of both the timing of its appearance and its progress. At birth, the joint is still largely underdeveloped. There are many causes of the various growth disturbances and abnormalities of the mandibular condyle and related structures. Growth disturbances in the development of the mandibular condyle may occur in utero late in the first trimester and may result in disorders such as aplasia or hypoplasia of the mandibular condyle. Meanwhile, hyperplasia of the mandibular condyle is not visible at birth and seems to be gradually acquired during growth. In the present review article, the congenital abnormalities of the mandibular condyle are classified morphologically into three major groups and two subgroups from a clinical standpoint: (1) hypoplasia or aplasia of the mandibular condyle, including (i) primary condylar aplasia and hypoplasia, (ii) secondary condylar hypoplasia; (2) hyperplasia; and (3) bifidity. In addition, the molecular‐based etiology of anomalies of the mandibular condyle is also discussed.

Fetal Jaw Movement Affects Condylar Cartilage Development

Using a mouse exo utero system to examine the effects of fetal jaw movement on the development of condylar cartilage, we assessed the effects of restraint of the animals’ mouths from opening, by suture, at embryonic day (E)15.5. We hypothesized that pre-natal jaw movement is an important mechanical factor in endochondral bone formation of the mandibular condyle. Condylar cartilage was reduced in size, and the bone-cartilage margin was ill-defined in the sutured group at E18.5. Volume, total number of cells, and number of 5-bromo-2′-deoxyuridine-positive cells in the mesenchymal zone were lower in the sutured group than in the non-sutured group at E16.5 and E18.5. Hypertrophic chondrocytes were larger, whereas fewer apoptotic chondrocytes and osteoclasts were observed in the hypertrophic zone in the sutured group at E18.5. Analysis of our data revealed that restricted fetal TMJ movement influences the process of endochondral bone formation of condylar cartilage.