Analysis of biochemical compounds and differentially expressed genes of the anthocyanin biosynthetic pathway in variegated peach flowers.

Variegated plants are highly valuable in the floricultural market, yet the genetic mechanism underlying this attractive phenomenon has not been completely elucidated. In this study, we identified and measured different compounds in pink and white flower petals of peach (Prunus persica) by high-performance liquid chromatography and liquid chromatography/mass spectrometry analyses. No cyanidin-based or pelargonidin-based compounds were detected in white petals, but high levels of these compounds were found in pink petals. Additionally, we sequenced and analyzed the expression of six key structural genes in the anthocyanin biosynthesis pathway (CHI, CHS, DFR, F3'H, ANS, and UFGT) in both white and pink petals. Quantitative real-time polymerase chain reaction revealed all six genes to be expressed at greatly reduced levels in white flower petals, relative to pink. No allelic variations were found in the transcribed sequences. However, alignment of transcribed and genomic sequences of the ANS gene detected alternative splicing, resulting in transcripts of 1.071 and 942 bp. Only the longer transcript was observed in white flower petals. Since ANS is the key intermediate enzyme catalyzing the colorless leucopelargonidin and leucocyanidin to substrates required for completion of anthocyanin biosynthesis, the ANS gene is implicated in flower color variegation and should be explored in future studies. This article, together with a previous transcriptome study, elucidates the mechanism underlying peach flower color variegation in terms of the key structural genes involved in anthocyanin biosynthesis.

Detection of acute cerebral hemorrhage in rabbits by magnetic induction.

Acute cerebral hemorrhage (ACH) is an important clinical problem that is often monitored and studied with expensive devices such as computed tomography, magnetic resonance imaging, and positron emission tomography. These devices are not readily available in economically underdeveloped regions of the world, emergency departments, and emergency zones. We have developed a less expensive tool for non-contact monitoring of ACH. The system measures the magnetic induction phase shift (MIPS) between the electromagnetic signals on two coils. ACH was induced in 6 experimental rabbits and edema was induced in 4 control rabbits by stereotactic methods, and their intracranial pressure and heart rate were monitored for 1 h. Signals were continuously monitored for up to 1 h at an exciting frequency of 10.7 MHz. Autologous blood was administered to the experimental group, and saline to the control group (1 to 3 mL) by injection of 1-mL every 5 min. The results showed a significant increase in MIPS as a function of the injection volume, but the heart rate was stable. In the experimental (ACH) group, there was a statistically significant positive correlation of the intracranial pressure and MIPS. The change of MIPS was greater in the ACH group than in the control group. This high-sensitivity system could detect a 1-mL change in blood volume. The MIPS was significantly related to the intracranial pressure. This observation suggests that the method could be valuable for detecting early warning signs in emergency medicine and critical care units.

Detection of acute cerebral hemorrhage in rabbits by magnetic induction

Acute cerebral hemorrhage (ACH) is an important clinical problem that is often monitored and studied with expensive devices such as computed tomography, magnetic resonance imaging, and positron emission tomography. These devices are not readily available in economically underdeveloped regions of the world, emergency departments, and emergency zones. We have developed a less expensive tool for non-contact monitoring of ACH. The system measures the magnetic induction phase shift (MIPS) between the electromagnetic signals on two coils. ACH was induced in 6 experimental rabbits and edema was induced in 4 control rabbits by stereotactic methods, and their intracranial pressure and heart rate were monitored for 1 h. Signals were continuously monitored for up to 1 h at an exciting frequency of 10.7 MHz. Autologous blood was administered to the experimental group, and saline to the control group (1 to 3 mL) by injection of 1-mL every 5 min. The results showed a significant increase in MIPS as a function of the injection volume, but the heart rate was stable. In the experimental (ACH) group, there was a statistically significant positive correlation of the intracranial pressure and MIPS. The change of MIPS was greater in the ACH group than in the control group. This high-sensitivity system could detect a 1-mL change in blood volume. The MIPS was significantly related to the intracranial pressure. This observation suggests that the method could be valuable for detecting early warning signs in emergency medicine and critical care units.

Effects of tetrandrine on changes of NMDA receptor channel in cortical neurons of rat induced by anoxia.

AIM: To study the effects of tetrandrine (Tet) on the changes of NMDA receptor channels in cortical neurons induced by anoxia. METHODS: Cell-attached configuration of patch-clamp techniques. Anoxia was produced by perfused cells with 95% N2 + 5% CO2 gassed bath solution. RESULTS: During anoxia, the open time constant (tau 2), open probability (Po) of 35-pS and 100-pS channels increased. Tet 7.5 mumol.L-1 reduced the Po of 35-pS and 100-pS channels, 15 and 30 mumol.L-1 inhibited open of 100-pS channel fully, and changed the open time constant of 35-pS from two to single exponential distribution. CONCLUSION: Tet inhibition of the open of NMDA receptor channels induced by anoxia was one of its protective mechanisms.

Protective effects of panaxadiol saponins on cardiac functions in burned rats.

AIM: To study the effects of panaxadiol saponins (PDS) on burn rat heart functions and try to find its mechanisms. METHODS: A 35% skin-full-thickness burn was produced by using napalm in Wistar rats. PDS 30 mg kg-1 was injected i.p. to rats immediately after burn and repeated 2 h before examination. Using the isolated perfused working heart and biochemistry methods, heart rate (HR), cardiac output (CO), coronary flow (CF), left ventricular pressure (LVP), aortic pressure (AP), +/- dp/dtmax, and content of malondialdehyde (MDA), activity of superoxide dismutase (SOD) in ventricular myocardium homogenate were examined 8 h after burn. RESULTS: After burn, HR, CO, CF, LVP, AP, +dp/dtmax, -dp/dtmax, and SOD activity decreased from 206 bpm, 92 mL min-1 g-1, 26 mL min-1 g-1, 7 kPa, 5.9 kPa, 149 kPa s-1, 73 kPa s-1, 2.9 NU/mg protein to 162 bpm, 72 mL min-1 g-1, 14 mL min-1 g-1, 4 kPa, 2.2 kPa, 77 kPa s-1, 44 kPa s-1, 1.7 NU/mg protein, respectively, and MDA content raised from 0.77 nmol/mg protein to 1.35 nmol/mg protein (P all < 0.05). But in PDS-treated group, above decreased or increased dates restored to 202 bpm, 91 mL min-1 g-1, 25 mL min-1 g-1, 6 kPa, 4.1 kPa, 112 kPa s-1, 62 kPa s-1, 2.8 NU/mg protein, 0.91 nmol/mg protein, respectively (P all < 0.05 vs burn). CONCLUSION: PDS exerts definite protective effects on the cardiac functions after burn injury possibly through its enhancement of SOD activity and the reduction of both the levels of free radicals and lipid peroxides (LPO) of the myocardium.