Expression of P-glycoprotein and breast cancer resistance protein in three cases of canine lymphoma showing drug resistance

In canine lymphoma, drug resistance is the major factor hindering treatment. In this study, we performed immunohistochemical examination of P-glycoprotein (P-gp) and breast cancer resistance protein (BCRP), which are considered as transporters related to multidrug resistance in three recurrent canine lymphomas. All cases were negative for both transporters before anticancer drug administration, but became positive after this administration. The expression was confirmed in capillary endothelial cells, such as in brain capillaries acting as the blood-brain barrier (BBB). It is suggested that both transporters expressed on capillary endothelial cells in lymphoma tissue may inhibit the spread of anticancer drugs into tumor tissues from blood, the same as the BBB. Therefore, capillary endothelial cells could act as a blood-tumor barrier, which might be involved in drug resistance in canine lymphoma.     

Effects of soil temperature and anaerobiosis on degradation of biodegradable plastics in soil and their degrading microorganisms

The bioplastic PHB/HV (copolymer of 3-hydroxybutyrate and 3-hydroxyvalerate) underwent a faster degradation at 30°C than at 52°C in soil under aerobic conditions, while there was no remarkable difference between 30°C and 52°C in the degradation rate of PCL [poly(ε-caprolactone)], PBSA (polybutylene succinate and agipate), and PBS (polybutylene succinate). PHB showed the fastest degree of degradation among the four plastics at 30°C and PBSA the fastest at 52°C. Degradation of all the four plastics was nor observed both at 30°C and 52°C under anaerobic conditions for 50 d. Microorganisms on the degrading plastics appeared to be diverse at 30"C, including bacteria and fungi. However, among the several to ca. 10 kinds of bacterial and fungal strains isolated from the degradation sites of each plastic at 30°C, only one or two fungal strains were able to degrade the respective plastics in vitro. The degraders were identified as Mucor sp. (PHB), Paecilomyces sp. (PCL), Aspergillus sp. (PBSA), and Cunninghamella sp. (PBSA). In contrast, only a single type of fungus was observed at the degradation sites of PCL and PBSA at 52°C. The fungus isolated from PCL and PBSA was identified as Thermomyces sp. This study demonstrated that soil temperature and anaerobiosis exerted significant effects on the degradation of the plastics, and that fungi were mainly responsible for the degradation of the plastics in soil.     

Relationship between Avirulence Genes of the Same Family in Rice Blast Fungus Magnaporthe grisea

A genetic cross between rice-field isolates of Magnaporthe grisea produced progeny segregating for avirulence/ virulence on six rice cultivars among nine race differentials, while on three other cultivars, Shin 2 (Pik-s), Aichi Asahi (Pia) and Ishikari Shiroke (Pii), parental and progeny isolates were all virulent. Based on segregation ratios in 115 progeny isolates, avirulence on Kanto 51 (Pik), Yashiro-mochi (Pita), Fukunishiki (Piz) and Toride 1 (Piz-t) is under monogenic control. On Tsuyuake (Pik-m) and Pi No. 4 (Pita-2), however, a disproportionate ratio in the segregation was observed, suggesting that avirulence on these two cultivars is controlled by two or more genes. Assuming that the avirulence gene AvrPik-m consists of at least two genes, AvrPik-m1 and AvrPik-m2, each of which functions in the whole gene AvrPik-m, and that one of AvrPik-m1 and AvrPik-m2 is AvrPik, we could account for the disproportion in the avirulence/virulence segregation of the progeny. This hypothesis would also be consistently applied for avirulence gene AvrPita-2. There seem to be two types of the avirulence genes : AvrPik-m, that is comprised of the tightly linked genes, AvrPik-ml (=AvrPik) and AvrPik-m2, and AvrPita-2, that is comprised of the loosely linked genes AvrPita-2A (=AvrPita) and AvrPita-2B. As one possible explanation of the rice resistant reaction to blast, multiple specificity was suggested for the first time for the blast fungus. On the contrary, the avirulence genes AvrPiz and AvrPiz-t were inherited independently, despite the corresponding genes for resistance (Piz and Piz-t) being located at the same locus. The cross of rice blast isolates (races 447 and 337) produced only 25 kinds of races in the progeny, although theoretically about 64 kinds of races should be produced if six avirulence genes segregated independently. Because no progeny are with AvrPik (or AvrPita) and without AvrPik-m (or AvrPita-2), the number of races theoretically should be 36 at most. A number of strains, such as races 377 and 737, with a single avirulence gene were obtained from this cross. These strains may be valuable for analysis of resistance genes in rice plant. Received 19 August 2002/ Accepted in revised form 11 November 2002