Identification of Genes Associated with Morphology in Aspergillus niger by Using Suppression Subtractive Hybridization

The morphology of citric acid production strains of Aspergillus niger is sensitive to a variety of factors, including the concentration of manganese (Mn(2+)). Upon increasing the Mn(2+) concentration in A. niger (ATCC 11414) cultures to 14 ppb or higher, the morphology switches from pelleted to filamentous, accompanied by a rapid decline in citric acid production. The molecular mechanisms through which Mn(2+) exerts effects on morphology and citric acid production in A. niger cultures have not been well defined, but our use of suppression subtractive hybridization has identified 22 genes responsive to Mn(2+). Fifteen genes were differentially expressed when A. niger was grown in media containing 1,000 ppb of Mn(2+) (filamentous form), and seven genes were expressed in 10 ppb of Mn(2+) (pelleted form). Of the 15 filament-associated genes, seven are novel and eight share 47 to 100% identity with genes from other organisms. Five of the pellet-associated genes are novel, and the other two genes encode a pepsin-type protease and polyubiquitin. All 10 genes with deduced functions are either involved in amino acid metabolism-protein catabolism or cell regulatory processes. Northern blot analysis showed that the transcripts of all 22 genes were rapidly enhanced or suppressed by Mn(2+). Steady-state mRNA levels of six selected filament-associated genes remained high during 5 days of culture in a filamentous state and remained low under pelleted growth conditions. The opposite behavior was observed for four selected pellet-associated genes. The full-length cDNA of the filament-associated clone, Brsa-25, was isolated. Antisense expression of Brsa-25 permitted pelleted growth and increased citrate production at concentrations of Mn(2+) that were higher than the parent strain could tolerate. These results suggest the involvement of the newly isolated genes in the regulation of A. niger morphology

Kinetic studies of gas hydrate formation with low-dosage hydrate inhibitors

Pipeline blockage by gas hydrates is a serious problem in the petroleum industry. Low-dosage inhibitors have been developed for its cost-effective and environmentally acceptable characteristics. In a 1.072-L reactor with methane, ethane and propane gas mixture under the pressure of about 8.5 MPa at 4 A degrees C, hydrate formation was investigated with low-dosage hydrate inhibitors PVP and GHI1, the change of the compressibility factor and gas composition in the gas phase was analyzed, the gas contents in hydrates were compared with PVP and GHI1 added, and the inhibition mechanism of GHI1 was discussed. The results show that PVP and GHI1 could effectively inhibit the growth of gas hydrates but not nucleation. Under the experimental condition with PVP added, methane and ethane occupied the small cavities of the hydrate crystal unit and the ability of ethane entering into hydrate cavities was weaker than that of methane. GHI1 could effectively inhibit molecules which could more readily form hydrates. The ether and hydroxy group of diethylene glycol monobutyl ether have the responsibility for stronger inhibition ability of GHI1 than PVP

Continuous Formation Process of CO2 Gas Hydrate via a Vortex and Impinging Stream Reactor

A continuous formation process of CO2 hydrate was investigated ill it vortex and impinging stream reactor (VI R) of 1.76 L with the temperatures ranging front 274.46 to 275.86 K and the pressures ranging from 1.79 to 3.163 MPa. In the VIR, a high-gravity field can be generated, where both centrifugal and impinging forces call intensify the mass transfer ill reactants. There are two distinct steps ill the process. The first step is the Unstable hydrate formation process. The next one is called the stable formation process, which presents the rapid and continuous formation of the CO2 gas hydrate. It is found that the formation rate of CO2 hydrate is Lip to 249.8 mol/h when the Higee factor beta is 390.28