棉田多虫复合危害互作效应及“两红”复合防治指标应用研究

针对长江中游棉区棉花多虫复合危害问题,设计了６种害虫４种组合的复合危害系统．运用通径分析方法,定量描述了多种害虫对棉花的侵害及其间的互作效应．通过多种害虫对棉花产量和品级的直接影响效应和间接影响效应分析,认为当多虫复合危害时,害虫间的相互作用就其对作物的侵害而言,表现为增强效应和减弱效应．在此基础上,研究并制定了“两红”（棉红铃虫和朱砂叶螨）复合危害动态防治指标,经验证、示范及推广应用,取得了显著的经济、生态和社会效益．     

C3和C4植物叶片对光氧化响应的日变化

田间生长的C3植物花生和C4植物玉米分别于晴天上午9：00、中午12：00、下午15：00取样。中午12：00花生叶片的Fv／Fm较早上9：见下降16％,出现了光抑制现象,玉米叶片的Fv／Fm则未下降。不同时间取样的花生和玉米叶片经甲基紫精（MV） 强光的人为光氧化处理,叶绿素和类胡萝卜素出现不同程度的氧化降解,中午12：00降解幅度最大,15时降幅最小。植物叶片的抗氧化能力与其SOD活性相关,而与PEPCase的活性没有明显的相关性。光氧化处理后,花生和玉米的叶绿素荧光参数FV／Fm、qp、pSII都下降,花生在12：00的降幅最小,玉米的降幅最大。光氧化引起花生的qN和热耗散系数（KD）上升,玉米则都下降．结果显示C3植物花生和C4植物玉米对光氧化的响应可能存在不同的机制。     

表没食子儿茶素没食子酸酯研究进展

近些年发现,茶叶中的表没食子儿茶素没食子酸脂具有降低血脂、除去胆固醇、抑制细菌和病毒、抗氧化、抗突变、抗肿瘤等多方面的重要生理功能。     

人腺苷酸环化酶激活多肽cDNA克隆和序列分析

以人睾丸组织总ＲＮＡ为材料,用ＲＴ－ＰＣＲ方法合成了人腺苷酸环化酶激活多肽（ＡＣＡＰ）编码区（５３０ｂｐ）和全长ｃＤＮＡ（１９３０ｂｐ）片段．并分别将这些ｃＤＮＡ片段克隆入ｐＵＣ１８载体的ＳｍａⅠ限制性内切酶位点．对重组质粒分别采用直接ＤＮＡ双链末端终止法和在核酸外切酶Ⅲ和核酸酶Ｓ１作用下连续缺失ＤＮＡ后,相继克隆,构成一系列连续缺失的缺失体的方法,测定了全部核苷酸顺序．结果表明：ＡＣＡＰ编码区的ｃＤＮＡ顺序与已报道的有１２处碱基的改变,其中１１处碱基顺序的改变不引起编码的氨基酸变化,只有第３８５位的Ｔ→Ａ后,才引起其编码的氨基酸由Ｓｅｒ→Ｔｈｒ,但由于Ｓｅｒ和Ｔｈｒ的理化性质极其相似,这一变化可能并不导致蛋白质的生物活性的变化．这些改变可能是由于种族、群体或个体的差异．     

CO2激光治疗子宫内膜异位症的临床分析

采用ＣＯ２激光对１２例分布于宫颈、阴道及外阴的子宫内膜异位症病人进行病灶切除碳化治疗,并对其随访了３￣７年、无１例复发、局部留下瘢痕。认为外阴子宫内膜异位症采用激光治疗可靠、简便、更优于传统手术治疗。     

Determination of naringenin and its glucuronide conjugate in rat plasma and brain tissue by high-performance liquid chromatography

An isocratic high-performance liquid chromatographic method with ultraviolet detection was utilized for the investigation of the pharmacokinetics of naringenin and its glucuronide conjugate in rat plasma and brain tissue. Plasma and brain tissue were deproteinized by acetonitrile, then centrifuged for sample clean-up. The drugs were separated by a reversed-phase C₁₈ column with a mobile phase consisting of acetonitrile–orthophosphoric acid solution (pH 2.5–2.8) (36:64, v/v). The detection limits of naringenin in rat plasma and brain tissue were 50 ng/ml and 0.4 μg/g, respectively. The glucuronide conjugate of naringenin was evaluated by the deconjugated enzyme β-glucuronidase. The naringenin conjugation ratios in rat plasma and brain tissue were 0.86 and 0.22, respectively, 10 min after naringenin (20 mg/kg, i.v.) administration. The mean naringenin conjugation ratio in plasma was approximately four fold that in brain tissue.     

Gibberellin: inhibitor of an inhibitor of...?

Gibberellin is an endogenous plant growth regulator. Here, we describe our present understanding of how gibberellin regulates plant growth, using recent results gained from studies of gibberellin-signalling mutants of Arabidopsis. These results show that a signalling pathway represses plant growth and that gibberellin releases this repression. In consequence, the well-known growth-promoting properties of gibberellin are due to its activity as an "inhibitor of an inhibitor" [Brian Pw. Sym Soc. Exp Bio 1957; 11:166-182 (Ref. 1)] of plant growth.     

The Evolutionarily Conserved Eukaryotic Arginine Attenuator Peptide Regulates the Movement of Ribosomes That Have Translated It

Translation of the upstream open reading frame (uORF) in the 5′ leader segment of the Neurospora crassa arg-2 mRNA causes reduced initiation at a downstream start codon when arginine is plentiful. Previous examination of this translational attenuation mechanism using a primer-extension inhibition (toeprint) assay in a homologous N. crassa cell-free translation system showed that arginine causes ribosomes to stall at the uORF termination codon. This stalling apparently regulates translation by preventing trailing scanning ribosomes from reaching the downstream start codon. Here we provide evidence that neither the distance between the uORF stop codon and the downstream initiation codon nor the nature of the stop codon used to terminate translation of the uORF-encoded arginine attenuator peptide (AAP) is important for regulation. Furthermore, translation of the AAP coding region regulates synthesis of the firefly luciferase polypeptide when it is fused directly at the N terminus of that polypeptide. In this case, the elongating ribosome stalls in response to Arg soon after it translates the AAP coding region. Regulation by this eukaryotic leader peptide thus appears to be exerted through a novel mechanism of cis-acting translational control.     

Identification of rCop-1, a New Member of the CCN Protein Family,as a Negative Regulator for Cell Transformation

By using a model system for cell transformation mediated by the cooperation of the activated H-ras oncogene and the inactivated p53 tumor suppressor gene, rCop-1 was identified by mRNA differential display as a gene whose expression became lost after cell transformation. Homology analysis indicates that rCop-1 belongs to an emerging cysteine-rich growth regulator family called CCN, which includes connective-tissue growth factor, CYR61, CEF10 (v-src inducible), and the product of the nov proto-oncogene. Unlike the other members of the CCN gene family, rCop-1 is not an immediate-early gene, it lacks the conserved C-terminal domain which was shown to confer both growth-stimulating and heparin-binding activities, and its expression is lost in cells transformed by a variety of mechanisms. Ectopic expression of rCop-1 by retroviral gene transfers led to cell death in a transformation-specific manner. These results suggest that rCop-1 represents a new class of CCN family proteins that have functions opposing those of the previously identified members.Oncogenic conversion of a normal cell into a tumor cell requires multiple genetic alterations (12). Of particular interest is the fact that mutations in both ras oncogenes (3) and the p53 tumor suppressor gene cooperate in transformation of mammalian cells (11). Mutations in both ras and the p53 gene were also found at high frequencies in a variety of human cancers, including those of the colon, lung, and pancreas (2, 18). It has been proposed that both p53 and Ras function, whether directly or through other signaling molecules, to control expression of genes that are important for cell growth and differentiation (13, 17, 37). To this end, several ras target genes (10) and p53 target genes, including those encoding p21/CIP1/WAF1, an inhibitor of G₁ cyclin-dependent kinase (9); Mdm-2, a negative regulator of p53 (1); GADD45, a protein involved in DNA repair (36); and Bax, which promotes apoptosis (28), have been identified. Most of these genes, except p21/CIP1/WAF1, which was cloned by subtractive hybridization, were identified by the candidate gene hypothesis. Recently, more p53 target genes have been isolated by the differential display technique, including those coding for cyclin G (31); MAP4, a microtubule-associated protein negatively regulated by p53 (29); and PAG608, a novel nuclear zinc finger protein whose overexpression promotes apoptosis (14). Functional characterizations of these genes have shed light on the role of p53 in cell cycle control and apoptosis. However, genes that mediate tumor suppression activity by p53 remain elusive.The fact that neither the inactivation of p53 nor the activation of Ras alone is able to transform primary mammalian cells (34), whereas both mutations together can do so, suggests that genes regulated by p53 and Ras cooperate in upsetting normal cell growth control cells (11). Using differential display (22), we set out to identify genes whose expression is altered by both mutant ras and p53 by comparing the mRNA expression profiles of normal rat embryo fibroblasts (REFs) and their derivatives transformed by either a constitutively inactivated or a temperature-sensitive mutant p53 in cooperation with the activated H-ras oncogene (11, 27). In this report we describe the identification and give a functional characterization of rCop-1, a gene whose expression is abolished by cell transformation. By sequence homology, rCop-1 was found to belong to an emerging cysteine-rich growth regulator family called CCN (which stands for connective-tissue growth factor [CTGF], CEF10/Cyr61, and Nov) (4). Here we show that rCop-1 may represent a novel class of CCN family proteins based on its unique cell cycle expression pattern, its lack of the C-terminal (CT) domain conserved in all CCN proteins, its loss of expression in all transformed cells analyzed, and its ability to confer cytotoxicity to the transformed cells.