不同肠段中氨基酸螯合锌吸收特点的研究

用 50日龄Wistar纯系雄性大鼠 ,以体内原位结扎肠段灌注技术结合放射性同位素示踪技术 ,通过与氯化锌比较 ,研究了十二指肠和空肠对氨基酸螯合锌 (以赖氨酸螯合锌和蛋氨酸螯合锌为代表 )的吸收特点。试验中观察了向结扎肠段灌注含不同形态锌的灌注液后 ,不同时间 (5 ,1 5 ,30 ,60 ,90 ,1 2 0min)血液中6 5Zn比放射性的动态变化 ,1 2 0min (试验结束 )时结扎肠段6 5Zn的消失率 ,不同组织器官中6 5Zn的比放射性的变化。试验结果表明 ,和空肠相比 ,十二指肠对 3种锌源的吸收率高 ;和氯化锌相比 ,十二指肠和空肠对 2种氨基酸螯合锌的吸收率高     

不同氮磷锌施肥水平对盐碱地牧草生物产量的影响

［目的］优化氮磷锌肥配比施用量。［方法］选择苜蓿、草木樨、星星草、沙打旺、羊草等耐盐牧草,采用311-A最优回归设计,比较氮磷锌施肥水平。 ［结果］最高产草量16 534.10 kg/hm^2,相应的氮肥、磷肥、锌肥用量分别为116.55 、121.35 、31.20 kg/hm^2;最佳经济效益牧草产量16 233.90 kg/hm^2,相应的氮肥、磷肥、锌肥用量分别为116.40、121.20、30.90 kg/hm^2,纯收益为2 472.40元/hm^2。［结论］对牧草产量影响的顺序依次是磷肥、氮肥和锌肥。     

磷水平对土壤锌铁铜有效性的影响

红黄壤、黄棕壤、砂姜黑土三类不同性质的土壤,用9个磷(P)水平(0-150ppm,均以P_2O_5计算).分别处理15天及30天.结果发现,几乎在所有P水平处理下的土壤,其有效锌(Zn)前15天表现抑制,含量低于本底值;30天后,都有不同程度的回升,似乎受到促进,但因土质、pH值、本底Zn含量的不同,差异较大. 红黄壤的有效Zn含量与P水平在前15天呈极显著直线负相关,而黄棕壤和砂姜黑土则呈极显著直线正相关;30天后,红黄壤回升到2-3ppm,相关性不显著,而黄棕壤和砂姜黑土则呈显著直线正相关.三种土壤的有效铁(Fe)含量,无论是15天和30天,均与P水平呈极显著的直线负相关,即表现抑制.有效铜(Cu)含量,在红黄壤和砂姜黑土,前15天以任何P水平处理均降到临界值以下,表现抑制;30天后,都有不同程度的回升,略高于临界值,在黄棕壤,前15天呈极显著直线正相关,30天后则相关性不显著,其含量均高于本底值,表现促进,但低于临界值,属严重缺Cu.     

日粮锌与维生素A水平对维生素A代谢的影响

以216只VC-Ⅱ生长獭兔为研究对象,研究了日粮中锌与维生素A的不同水平对獭兔体内维生素A代谢的影响。结果表明:日粮锌水平可显著影响血清维生素A含量,而不影响肝脏维生素A含量;日粮维生素A水平可显著影响血清及肝脏维生素A含量。证明日粮锌与维生素A水平在血清维生素A浓度上存在互作效应。     

高压静电回收氯化锌废气设备的研究

本文用生产规模的单管高压静电设备。对回收氯化锌法活性炭生产过程中产生的氯化锌废气进行了研究;对影响锌回收率的各因子进行了讨论。研究结果表明,工业生产中产生的氯化锌废气可以用高压静电法回收,当二次交流电压为3·5万伏,管内废气流速保持一定值,锌回收率可达98％以上,回收液的浓度29°Be′/36℃。设备性能稳定,运行可靠,不需要冷却水,工艺流程短,运行费用低,经济效果显著,是目前国内同行业中光进的回收设备。     

十和田近等基因系糙米锌含量QTL定位

以十和田为轮回亲本,丽粳2号为供体亲本培育出糙米锌含量近等基因系群体BC5F6为材料,从遍布水稻12条染色体上的600对引物中筛选到一个与糙米锌含量有关的SSR标记RM4608.根据其在水稻染色体上的位置,结合PCR扩增结果又发现了与糙米锌含量有关的4个SSR标记(RM19491,RM19489,RM6119和RM19487).用MAPMAKER3.0软件做出了这5个标记的连锁群,最后采用混合线性模型定位法找到了糙米锌含量的QTL位点.QTL分析结果显示:该位点位于6号染色体上RM4608和RM6119标记之间,贡献率为5%,为新发现的与糙米锌含量有关的微效基因位点,暂命名为qZINC-6.同时与糙米铬和镁含量有关的QTL位点也被发现,其中糙米铬含量QTL位于标记RM19489和RM19491之间,贡献率为9%,是一个主效基因;糙米镁含量QTL位于标记RM4608-RM6119之间,是一个微效基因,贡献率为4%.     

The effect of two endogeic earthworm species on zinc distribution and availability in artificial soil columns

The objective of this study was to determine the impact of earthworm bioturbation on the distribution and availability of zinc in the soil profile.Experiments were carried out with Allolobophora chlorotica and Aporrectodea caliginosa in 24 perspex columns (∅ 10 cm), filled with 20-23 cm non-polluted soil (OM 2%, clay 2.9%, pH 0.01 M CaCl₂ 6.4), that was covered by a 3-5 cm layer of aged zinc spiked soil (500 mg Zn/kg dry soil) and another 2 cm non-polluted soil on top. After 80 and 175 days, columns were sacrificed and each cm from the top down to a depth of 15 cm was sampled. Earthworm casts, placed on top of the soil, were collected. Each sample was analyzed for total and CaCl₂-exchangeable zinc concentrations.Effects of earthworm bioturbation were most pronounced after 175 days. For A. chlorotica, total and CaCl₂-exchangeable zinc concentrations in the polluted layers were lower with than without earthworms. Total zinc concentrations in the non-polluted layers were higher in columns with earthworms. Casts of A. chlorotica collected on the soil surface showed slightly higher total zinc concentrations than non-polluted soil. Casts were found throughout the whole column. For A. caliginosa there were no differences in total zinc concentration between columns with and without earthworms. CaCl₂-exchangeable zinc concentrations in the polluted layers were lower for columns with earthworms. Casts were mainly placed on top of the soil and contained total zinc concentrations intermediate between those in non-polluted and polluted soil layers.This study shows that different endogeic earthworm species have different effects on zinc distribution and availability in soils. A. chlorotica transfers soil throughout the whole column, effectively mixing it, while A. caliginosa decreases metal availability and transfers polluted soil to the soil surface.     

Soybean response to iron‐deficiency stress as related to iron supply in the growth medium

The Fe‐inefficient T203 and the Fe‐efficient A7 and Pioneer 1082 (P1082) soybeans (Glycine max (L.) Merr.) were grown hydroponically with no (0 mg Fe L^‐1 ; ‐Fe) and a minute level (0.025 mg Fe L^‐1 ; +Fe) of Fe to (a) compare their responses to Fe‐deficiency stress and (b) relate Fe‐efficiency in soybeans to their ability to initiate the Fe‐stress‐response mechanism at low levels of Fe. With no Fe in solution, P1082 released similar levels of H⁺ ions, but released less reductant from their roots and there was less reduction of Fe³⁺ to Fe²⁺ by their roots than by A7 roots. These responses were also one day later and occurred after a more severe chlorosis and a lower leaf Fe had developed in P1082 than in A7. With 0.025 mg L^‐1 of solution Fe, it was not necessary for the Fe‐stress response mechanism to be fully activated to make Fe available in A7 soybean, whereas a strongly enhanced Fe stress response was observed in P1082. Increased Fe uptake and regreening of leaves immediately succeeded initiation of the Fe stress response in both cultivars and at both levels of Fe. Thus, P1082 was slightly less efficient than A7 soybean, but would be classed more efficient than the previously studied soybean cultivars A2, Hawkeye, Bragg, Pride, Anoka, and T203. These results support the hypothesis that the most efficient soybeans are those which can initiate the Fe‐stress response mechanism with little or no Fe in the growth medium. The near simultaneous occurrence of the factors in the Fe‐stress response mechanism (H ion and reductant release, reduction of Fe to Fe by roots), and the immediate increase in leaf Fe and chorophyll contents following that response suggest that all these factors act in concert, not independently, to aid in the absorption and transport of Fe to plant tops.     

The effect of Lumbricus rubellus and Lumbricus terrestris on zinc distribution and availability in artificial soil columns

This study investigated the impact of epigeic and (epi)anecic earthworms on the distribution and availability of zinc in the soil profile. Experiments were carried out with Lumbricus rubellus and Lumbricus terrestris in perspex columns (Ø 10 cm), filled with 20 to 23 cm non-polluted soil [organic matter 2%, clay 2.9%, pH 6.4 (0.01 M CaCl₂)], that was covered by a 3- to 5-cm layer of aged zinc-spiked soil (500 mg Zn/kg dry soil) and another 2 cm non-polluted soil on top. After 80 days, columns were sacrificed and sampled in a depth profile. Earthworm casts, deposited on top of the soil, were collected. Each sample was analyzed for total and 0.01 M CaCl₂-exchangeable zinc concentrations. L. rubellus did not go deeper than 3 cm into the soil and therefore no effect on zinc distribution in the soil could be detected. For L. terrestris, total zinc concentrations in the non-polluted layers were slightly but significantly higher in columns with earthworms, and so were the CaCl₂-exchangeable zinc concentrations in the polluted layers of these columns. Casts of L. terrestris collected from the soil surface showed higher total zinc concentrations than those from non-polluted soil. Casts were mainly placed on top of the soil. This study showed that these epigeic and (epi)anecic species have only a slight effect on zinc availability, and that deep burrowing species, like L. terrestris, are able to transport polluted soil from deeper layers to the soil surface.     

Solubilization of zinc phosphate by a strain of Pseudomonas fluorescens isolated from a forest soil

 A strain of Pseudomonas fluorescens, able to solubilize zinc phosphate, was isolated from a forest soil. Colonies of the microorganism produced clear haloes on solid medium incorporating zinc phosphate, but only when glucose was provided as the carbon source. Solubilization of zinc phosphate occurred by both an increase in the H⁺ concentration of the medium, probably a consequence of ammonia assimilation, and the production of gluconic acid. High concentrations of gluconic acid were produced when P. fluorescens 3a was cultured in the presence of zinc phosphate. Although under some conditions gluconic acid is purportedly able to solubilize metals by the formation of chelates, no evidence of zinc chelation was obtained in our experiments. Furthermore, the increased Zn²⁺ concentration caused by the solubilization process resulted in the manifestation of toxic effects on the culture. A sample of the culture, sonicated to disrupt cells, still possessed the ability to produce gluconic acid from glucose, in the presence and absence of zinc phosphate. The lack of gluconic acid overproduction in cultures of P. fluorescens 3a which were not amended with zinc phosphate suggests that at least some of the glucose oxidation required for the zinc solubilization occurred as a result of the toxic stress caused by the high Zn²⁺ concentration. Received: 16 December 1997