Quantification of Cry1Ac and Cry1F Bacillus thuringiensis insecticidal proteins in selected transgenic cotton plant tissue types.

Quantitative enzyme-linked immunosorbent assays were used to characterize the geographical (locations) and temporal (through 6 wk) expression of CrylAc, from Bacillus thuringiensis variety kurstaki, and Cry1F, from B. thuringiensis variety aizawai, in transgenic cotton, Gossypium hirsutum L., plant structures. Terminal leaves, squares (flower buds), flowers, bolls (fruit), and mature leaves located five and eight nodes below the terminal apex were sampled during weeks 2, 4, and 6 after the initiation of anthesis. The effect of location (environment) significantly influenced protein expression levels, although similar trends were observed across locations. Cry1F was expressed at levels greater (1.1-29.0-fold) than that for CrylAc in all structures with exception to flowers. In contrast, the level of CrylAc in flowers was generally greater than Cry1F. Within each sampling period, concentrations of Cry1F in mature leaves (five and eight node) were greater than that for other structures. Expression was also greater for older, eight-node mature leaves than younger, five-node mature leaves. CrylAc expression in bolls was lowest compared with terminal leaves, squares, flowers, and mature leaves, which expressed at similar concentrations. Cry1F expression increased through time for mature leaves and terminal leaves; whereas, a decline in Cry1Ac protein concentration was observed for terminal leaves and bolls. The data presented here provides a means to understand observed levels of efficacy (patterns of insect damage) by comparing the spatial and temporal dynamics of expression for Cry1Ac and Cry1F in PhytoGen 440W transgenic cotton.

Spontaneous genetic hypertension in the rat and its relationship to reduced ac cochlear potentials: implications for preservation of human hearing.

We present controlled laboratory studies of the spontaneously hypertensive rat which indicate that hypertension is an important pathophysiological risk factor in age-related hearing loss. Our results are in concert with previous retrospective clinical studies that pointed to this possibility in man. Hypertension as a risk factor for hearing loss is within the bounds of known measures of diagnosis, treatment, and even prevention, with monitoring early in life. Because hypertension is such a major public health problem in the United States, in view of our results it is possible that its treatment and early diagnosis will benefit a significant number of people who would otherwise lose their hearing with advancing age. We compared the round window ac cochlear potential-sensitivity and -intensity functions in 10 female spontaneously hypertensive rats and 10 female normotensive Wistar-Kyoto control rats. The animals were all 12 months old and weighed between 170 and 250 g. The normotensives had higher maximum cochlear potential-intensity values compared with the hypertensives: 1,000 Hz (P less than 0.005), 5,000 Hz (P less than 0.005), and 10,000 Hz (P less than 0.01). One-microvolt isopotential cochlear potentials for the low frequencies of the normotensives showed greater sensitivity than those of the hypertensives: 100 Hz (P less than 0.05), 200 Hz (P less than 0.10), 290 Hz (P less than 0.05), and 2,000 Hz (P less than 0.10). Blood pressure of the hypertensive group was significantly greater than that of the normotensive rats (P less than 0.001). The hearts and aortas of the hypertensive group were hypertrophied. Autonomic imbalance, platelet aggregation, decreased arterioles, and natriuretic hormone were discussed as possible etiologies for the measured sensory hearing loss.