Mos and the mitogen-activated protein kinase do not show cytostatic factor activity in early mouse embryos

Mos and the mitogen-activated protein kinase (MAPK) cascade have been established as crucial regulators of second meiotic metaphase arrest, the so-called CSF arrest, in mammalian oocytes. They are also thought to play a role in regulating mitotic metaphase arrest of early mammalian embryos. In the present study, we examined whether mitotic arrest is induced in early mouse embryos by activation of extracellular signal-regulated kinases (ERKs), which are major MAPKs in mouse eggs, and their substrate, p90Ribosomal S6 kinase (RSK), as reported in Xenopus embryos. Wild-type Mos (wt-Mos), degradation-resistant Mos mutant (P2G-Mos) or constitutive active mutant of MAPK/ERK kinase, MEK (SDSE-MEK), was expressed in early mouse embryos by injecting the respective expression vectors into the pronucleus of fertilized eggs, and the developmental rates were then examined up to 72 h after insemination. Expression of P2G-Mos and SDSE-MEK succeeded in activating ERKs and RSK in developing mouse embryos, while wt-Mos failed to activate them in spite of expression of mos mRNA, indicating that the wt-Mos protein is unstable in early mouse embryos. Although the activated levels of ERKs and RSK in the vector-injected embryos were comparable to those of meiotically arrested mouse oocytes, their developmental rates were identical to those of the control embryos. These results suggest that activation of MAPK and RSK does not induce mitotic arrest in early mouse embryos. The present study indicates that there are large physiological differences between early mouse embryos and mouse oocytes and that CSF arrest of mouse eggs in mitosis should be discussed separately from that in meiosis.     

Cloning, expression, and characterization of the MSP1a and MSP1b recombinant proteins from PR1 Anaplasma marginale strain, Brazil

The Anaplasma marginale is a bacterium that has obligate intraerythrocytic multiplication in cattle causing important economic loss. The A. marginale major surface protein 1 (MSP1) complex, heterodimer composed of MSP1a and MSP1b, has been identified as adhesins for bovine erythrocytes. The objectives of this study were to sequences the msp1β gene and produce and characterize recombinant MSP1a and MSP1b from a Brazilian strain of A. marginale, PR1. The msp1α and msp1β genes from the PR1 strain were cloned and expressed in E. coli BL21 Star using the vectors pET102 and pET101/D-TOPO. Antibodies were produced against the recombinant proteins and were shown to react with rMSP1a and rMSP1b demonstrating a molecular mass of 70 kDa to 105 kDa and 100 kDa, respectively for these proteins. Bovine erythrocytes were agglutinated by BL21/rMSP1a and BL21/rMSP1b and, this agglutination was inhibited by the presence of the IgY anti-rMSP1a, confirming the adhesion function of these proteins. Additionally, using the IgY anti-rMSP1a and rMSP1b in a IFI, the presence of rMSP1a and rMSP1b was confirmed on the outer membrane of the recombinant E. coli BL21. Our results show that the msp1β gene from the PR1 strain has both the conserved region and contain the defined polymorphism regions previously described for other strains of A. marginale. The results from this study confirm adhesive functions for rMSP1a and rMSP1b from PR1 strain in bovine erythrocytes invasion.     

PCR detection of the Cryptococcus neoformans CAPS9 gene from a biopsy specimen from a case of feline cryptococcosis.

A polymerase chain reaction assay was developed to detect Cryptococcus neoformans in biopsy samples. The assay detects the CAP59 gene of Cryptococcus neoformans and was used to substantiate cutaneous cryptococcosis in a 5-year-old cat submitted to the Veterinary Medicine Center at the University of Tokyo.     

Branching Mode of the Middle Rectal Artery from the Prostatic Artery in the Dog

The branching mode of the middle rectal artery from the prostatic artery was studied by gross dissection in 50 male dogs. The prostatic artery arose at the level of the lst-3rd sacral vertebra from the internal pudendal artery, and gave off the ductus deferential and the middle rectal arteries, and supplied the prostate. The middle rectal artery ran caudally along the pelvic peritoneum, and supplied the rectum ampulla. The branching mode of the middle rectal artery could be classified into four types. Nineteen cases on the right side and 22 cases on the left side showed that the middle rectal artery was a first visceral branch of the prostatic artery. Fifteen cases on the right side and 11 cases on the left side showed that it was a second visceral branch of the prostatic artery which gave off the ductus deferential artery as its first visceral branch. Nine cases on the right side and 7 cases on the left side showed that it arose at the prostatic artery ramifying at the surface of the prostate. Seven cases on the right side and 10 cases on the left side showed that it arose at the urethral branch of the prostatic artery.     

Molecular identification of Candida parapsilosis from crop mucosa in a cockatiel.

A 2-month-old cockatiel was evaluated for diarrhea, dyspnea, and death. Histologic examination of lesions in the crop mucosa revealed hyperkeratosis and the presence of blastoconidia and hyphae. Positive immunohistochemical staining of the organisms was achieved with an antibody directed against Candida spp. Polymerase chain reaction amplification of DNA from crop lesion material with internal transcribed spacer 2 (ITS2) primers yielded fragments of approximately 300 bp, which demonstrated 95% DNA homology with the corresponding sequence from a strain of Candida parapsilosis deposited in the GenBank data base. The Candida species in the lesion of the crop mucosa was therefore identified by DNA sequence analysis as C. parapsilosis.     

Analyses of the regulatory mechanism of porcine WEE1B: the phosphorylation sites of porcine WEE1B and mouse WEE1B are different

WEE1B, an oocyte-specific kinase, phosphorylates the CDC2 inhibitory site and maintains the meiotic arrest of oocytes at the first meiotic prophase in several mammalian species. However, the molecular mechanisms controlling WEE1B activity have not been fully examined in species other than mice. In the present study, we analyzed the regulation mechanisms of porcine WEE1B (pWEE1B), focusing on the cAMP-dependent protein kinase (PKA) phosphorylation site and intracellular localization. As the PKA phosphorylation site in mouse WEE1B (mWEE1B) was not conserved in pWEE1B, we predicted that four serine residues would be phosphorylatable by PKA in pWEE1B (Ser77, Ser118, Ser133 and Ser149) and constructed FLAG-tagged replaced-pWEE1Bs, in which each of the PKA-phosphorylatable serines was mutated into a non-phosphorylatable alanine. We injected one of their mRNAs into porcine immature oocytes and found that the Ser77-replaced pWEE1B lost the WEE1B function, whereas the wild-type and other replaced-pWEE1Bs could maintain the meiotic arrest of oocytes. Next, the localization of pWEE1B was examined by immunohistochemistry, and exclusive nuclear localization was revealed in the fully grown oocytes. We generated a nuclear localization signal (NLS)-deleted pWEE1B (ΔNLS-pWEE1B) and then overexpressed it in porcine immature oocytes. We found that ΔNLS-pWEE1B was distributed uniformly in the cytoplasm and could not maintain the meiotic arrest of porcine oocytes. These results suggest that pWEE1B is activated after phosphorylation of the Ser77 residue, which is different from the phosphorylation site that activates mWEE1B; that pWEE1B is localized in the nucleus; and that the nuclear localization is essential for its function.     

Preimplantation-embryo-specific cell-cycle regulation is attributable to a low expression of retinoblastoma protein rather than its phosphorylation

Mammalian preimplantation embryos enter the S phase immediately after the end of the M phase; their cell cycle lacks a substantial G1 phase. Previously, we suggested that the absence of the G1 phase was attributable to a loss of retinoblastoma protein (RB) function, which is required for suppression of S phase entrance and that this loss of RB function in turn was attributable to the low RB expression level during preimplantation development in mouse embryos. The present study aimed to examine whether or not RB inhibition by CDK4/6-cyclin D-dependent phosphorylation is involved in the loss of RB function in preimplantation mouse embryos by the expression of p16(INK4a), a potent endogenous inhibitor of CDK4/6-cyclin D. First, the decrease in RB expression between the four-cell and morula stages was confirmed in in vivo-derived mouse embryos. We then examined the efficiency of the p16(INK4a) expression vector in inhibiting RB phosphorylation and cell cycle progression using NIH-3T3 cells and obtained gradual RB dephosphorylation and a significantly lower proliferation rate in p16(INK4a)-transfected cells than in control cells. This indicated the successful p16(INK4a) effects on cell-cycle progression by the vector used. On the other hand, the development rate of mouse embryos injected with the p16(INK4a) expression vector was the same as that of the control embryos, although p16(INK4a) expression was detected at mRNA and protein levels in the former group but not in the control group. These results suggest that RB phosphorylation is not involved in RB dysfunction or in the lack of a G1 phase in mouse embryos and that the decrease in RB expression is important for preimplantation-embryo-specific cell-cycle regulation. Moreover, the present study indicates the similarity between preimplantation embryos and cancer cells, which p16(INK4a) expression does not arrest at the G1 phase.     

Comparison of the rooting ability of virus infected and virus-free cuttings of sweet potatoes (Ipomoea batatas Poir.) and an anatomical comparison of the roots

Summary

The rooting abilities of the filamentous virus infected and the virus-free cuttings of sweet potato (Ipomoea batatas Poir.) were compared, with an anatomical comparison of the root. The diameters of the pith and the vascular bundle cylinder at the node of the virus-free cutting were larger than in those of virus infected ones. Thicker and more vigorous roots were initiated in the virus-free cutting. The diameter of the central cylinder and the thickness of the cortical layer of the root were larger in the virus-free cutting than in the virus infected one. Larger and more numerous vessels developed, and larger and more distinct meristematic tissues surrounding the protophloem poles also developed in a fan form in the root of the virus-free cutting. The weight of the leaf and stem of the plant 80.d after planting in the field were larger in the virus-free cutting than in the virus infected cutting. From these results, the following assumptions on roots in the virus-free cutting can be made. Thicker roots with larger vessels and thicker meristematic tissues develop in the virus-free cutting because the meristematic activity is high in the tissues in the vicinity of the vascular bundle cylinder at the node, due to the recovery of normal physiological function by removal of the virus. There are fewer roots in the virus-free cutting because the smaller total area of the root is sufficient to absorb the nutrient elements owing to superior development of the vessels and meristematic tissues in the root. In the field, the larger weight of the leaf and stem in the virus-free cutting is caused by the high absorption ability of nutrient elements from the root.