榄仁树的生理和生物学特性

为了解榄仁树(Terminalia catappa)的生理生态特性,对西沙群岛永兴岛上自然生长的榄仁树的叶片形态、生理特征、营养元素含量以及根际土壤特征进行了研究。结果表明,榄仁树具有比叶面积低、叶片厚、气孔密度小等形态特征。叶绿素a/b为2.25∶1,低于理论值3∶1。叶片的SOD和POD活性较低,脯氨酸和ABA含量较高。植物体内养分含量较高,适生土壤养分含量低。这说明榄仁树叶片的吸收利用光能能力较强,保水能力较好,有较强的抗干旱和抗逆能力,适生于贫瘠的土壤并保持较高的叶片营养。因此,榄仁树是一种能够适应高温、干旱、贫瘠等恶劣生境条件的树种,可作为热带珊瑚岛植被恢复的工具种和园林绿化树种。     

干旱胁迫对大豆生长的影响及抗旱性评价方法与指标筛选

2014-2015年在年降雨量不足40 mm的敦煌市,设干旱和正常灌水两个处理,通过测定12份大豆品种的8个形态指标(株高、主茎节数、有效分枝数、单株荚数、单株粒数、单株粒重、单株生物量和百粒重)及小区产量,采用改进抗旱指数法及权重隶属函数值D对其进行抗旱性评价,并筛选出3份不同抗旱类型的大豆品种进行生理指标测定,验证该方法和指标。结果显示,与灌水处理(CK)相比较,干旱胁迫下的8个形态指标及产量,2014年除有效分枝数及百粒重差异不显著外,其余考察性状均达到了极显著差异,2015年所有考察表型性状均达到极显著差异;两年权重隶属函数法评价结果显著相关,小区产量与两年两种评价方法极显著相关;两种处理下,中度抗旱(中黄24)、弱抗旱品种(WDD00172)的SOD活性、POD活性、CAT活性、丙二醛含量、可溶性糖含量差异极显著,且与权重隶属函数值D显著相关,而强抗旱品种(晋豆21号)中SOD活性、POD活性、脯氨酸含量差异不显著,且6个生理指标与权重隶属函数值D均不相关。因此,权重隶属函数法和小区产量可作为大豆抗旱性评价单一可靠的方法与指标。     

Addition of aluminum oxide microparticles to Trichoderma viride My preculture enhances cellulase production and influences fungal morphology

Morphological engineering techniques have recently become popular, since they are used to increase the production of a variety of metabolites and enzymes when fungi are grown in submerged cultures. This study aimed to facilitate cellulase production by adding aluminum oxide to Trichoderma viride My precultures.

The results showed that the highest cellulase activity was achieved when aluminum oxide at 10 g/L was used, and the activities of cellulase for filter paper and endoglucanase activity assays increased from 519.11 to 607.35 U/mL by 17.1%, and from 810.08 U/mL to 917.59 U/mL by 13.3%, compared with the control, respectively. Addition of aluminum oxide decreased the size of T. viride My pellets and increased the final pH. The changes in pellet diameter after the addition of different concentrations of aluminum oxide were fitted using a modified exponential decay model, which could precisely predict the pellet size by controlling aluminum oxide concentration.

The optimum concentration of microparticles, and therefore pellet size, could significantly improve cellulase production, which is an encouraging step towards commercial cellulase production.

     

Natsumushi: Image measuring software for entomological studies

Natsumushi is a free image analysis software that offers easy handling and quick measurement, designed especially for entomologists as the main users. The software enables measurement of: (i) color features of a specific region; (ii) area size; (iii) length of simple lines or polylines; and (iv) number of points or their x–y coordinates. Users can specify the region for measurement either manually or automatically by using image thresholding operations. The software is freely available at the website https://staff.aist.go.jp/t-fukatsu/Natsumushi.html .     

Measurement of immunoglobulin synthesis using the ELISPOT assay

We describe a method for the detection of specific antibody-producing cells from either in vitro or in vivo immunization. These techniques are especially useful for detecting antibodies from developing hybridomas. We have successfully used the system to detect isotype-specific antibodies to a variety of bacterial antigens which were produced by heterohybridomas.     

Growth models and the expected distribution of fluctuating asymmetry

Multiplicative error accounts for much of the size-scaling and leptokurtosis in fluctuating asymmetry. It arises when growth involves the addition of tissue to that which is already present. Such errors are lognormally distributed. The distribution of the difference between two lognormal variates is leptokurtic. If those two variates are correlated, then the asymmetry variance will scale with size. Inert tissues typically exhibit additive error and have a gamma distribution. Although their asymmetry variance does not exhibit size-scaling, the distribution of the difference between two gamma variates is nevertheless leptokurtic. Measurement error is also additive, but has a normal distribution. Thus, the measurement of fluctuating asymmetry may involve the mixing of additive and multiplicative error. When errors are multiplicative, we recommend computing log  E ( l ) − log  E ( r ), the difference between the logarithms of the expected values of left and right sides, even when size-scaling is not obvious. If l and r are lognormally distributed, and measurement error is nil, the resulting distribution will be normal, and multiplicative error will not confound size-related changes in asymmetry. When errors are additive, such a transformation to remove size-scaling is unnecessary. Nevertheless, the distribution of l  −  r may still be leptokurtic.  © 2003 The Linnean Society of London, Biological Journal of the Linnean Society , 2003, 80, 57–65.     

A system to simulate gas exchange in humans to control quality of metabolic measurements

We have developed a gas exchange simulation system (GESS) to assess the quality control in measurements of metabolic gas exchange. The GESS simulates human breathing from rest to maximal exercise. It approximates breath-by-breath waveforms, ventilatory output, gas concentrations, temperature and humidity during inspiration and expiration. A programmable motion control driving two syringes allows the ventilation to be set at any tidal volume (V _T), respiratory frequency (f), flow waveform and period of inspiration and expiration. The GESS was tested at various combinations of V _T (0.5–2.5 l) and f (10–60 stroke · min⁻¹) and at various fractional concentrations of expired oxygen (0.1294–0.1795); and carbon dioxide (0.0210–0.0690) for a pre-set flow waveform and for expired gases at the same temperature and humidity as room air. Expired gases were collected in a polyethylene bag for measurement of volume and gas concentrations. Accuracy was assessed by calculating the absolute and relative errors on parameters (error = measured−predicted). The overall error in the gas exchange values averaged less than 2% for oxygen uptake and carbon dioxide output, which is within the accuracy of the Douglas bag method. Accepted: 4 June 1998