Autonomous Biological System (ABS) experiments.

Three space flight experiments have been conducted to test and demonstrate the use of a passively controlled, materially closed, bioregenerative life support system in space. The Autonomous Biological System (ABS) provides an experimental environment for long term growth and breeding of aquatic plants and animals. The ABS is completely materially closed, isolated from human life support systems and cabin atmosphere contaminants, and requires little need for astronaut intervention. Testing of the ABS marked several firsts: the first aquatic angiosperms to be grown in space; the first higher organisms (aquatic invertebrate animals) to complete their life cycles in space; the first completely bioregenerative life support system in space; and, among the first gravitational ecology experiments. As an introduction this paper describes the ABS, its flight performance, advantages and disadvantages.     

Cell growth and organ differentiation in cultured tobacco cells under spaceflight condition.

The responses of cultured tobacco cells to microgravity were examined. Cultured tobacco cells grew and regenerated shoots under microgravity conditions. However, such growth, especially of stems, was much more heterogeneous than that in the ground control, and the increase in fresh weight of the flight samples was less than that of ground control. In addition, multiple shoot formation was not observed in flight samples. Microscopic observation showed that the meristem of regenerating shoot under microgravity was smaller than that in the ground control. Electron microscopy showed that chloroplasts in the ground control were slightly more developed than those in flight samples and extensive arrays of microtubules were more evident in ground control than in flight samples. Analyses of enzymes involved in primary and secondary metabolism indicated that callus grown on shoot regeneration medium under microgravity conditions had a much lower activity of caffeic acid O-methyltransferase, which is involved in lignin biosynthesis, than those grown on Earth. In addition, two-dimensional polyacrylamide-gel electrophoresis analysis of 35S-labeled proteins suggested that gene expression in the flight samples may be similar to that in the ground control.     

Microorganisms and plant of Autonomous Biological Systems (ABS) samples.

Distribution of microorganisms and cellular structure of an Autonomous Biological Systems (ABS) were studied with a special attention to the effect of space environments. Viable cell densities measured by the direct fluorescence microscopic method were in the order of 10(5) cells/ml for fractions 1 (upper suspension) and 2 (lower suspension), and 10(6) cells/ml for fraction 3 (sediments). These values were 10 to 100 times larger than the values obtained by the classical colony forming unit method. No difference between flight and ground samples was observed in the vertical distribution of viable microorganisms when fractionation and analysis were carried out after recovery. Intracellular distribution of chloroplasts in higher green plants, Ceratophyllum demersum, of flight samples was disturbed after 10 days of flight (24hrs/day light on). After 4 months of flight (Mir/STS-79/81) with 24 hrs light on, Ceratophyllum demersum was completely disintegrated. On the other hand, in the second 4-months-flight experiment with 16 hrs/day light on, Ceratophyllum demersum was only slightly deteriorated.     

Neuromuscular degenerative effects of Ankaferd Blood Stopper® in mouse sciatic nerve model

Purpose: Ankaferd Blood Stopper^® (ABS), a licenced medicinal herbal extract, is commonly used as an effective topical haemostatic agent. This study is designed to investigate whether topical ABS application may cause peripheral nerve degeneration and neuromuscular dysfunction in a mouse sciatic nerve model.

Methods: Twenty mice were randomly divided into two groups; an ABS treated experimental group and a saline-treated control group. Left sciatic nerves were treated with 0.3?ml of ABS in the experimental group and 0.3?ml of sterile saline in the control group for 5?min. Peripheral nerve degeneration and neuromuscular dysfunction were evaluated by behavioural tests, electrophysiological analysis and weight ratio comparison of target muscles.

Results: The motor function, assessed by the sciatic function index, was significantly impaired in ABS-treated animals as compared to the animals treated with saline. Motor coordination, evaluated with the rotarod test, was significantly decreased (–42%) in ABS-treated animals compared to the saline-treated animals. The degree of pain, assessed by the reaction latency to thermal stimuli (hot-plate test), was significantly prolonged (313%) in ABS-treated mice when compared to the saline-treated mice. ABS-treated mice showed a significant reduction in motor nerve conduction velocity (MNCV) (–52%) and the compound muscle action potential (CMAP) (–47%); however, it significantly prolonged onset latency (23%). The gastrocnemius muscles weight ratio of the ABS group was considerably lower than that of the control group.

Conclusions: These findings demonstrate that ABS triggers peripheral nerve degeneration and functional impairment and, thus promotes a deterioration of sciatic nerves.     

Independently Controlled Wing Stroke Patterns in the Fruit Fly Drosophila melanogaster

Flies achieve supreme flight maneuverability through a small set of miniscule steering muscles attached to the wing base. The fast flight maneuvers arise from precisely timed activation of the steering muscles and the resulting subtle modulation of the wing stroke. In addition, slower modulation of wing kinematics arises from changes in the activity of indirect flight muscles in the thorax. We investigated if these modulations can be described as a superposition of a limited number of elementary deformations of the wing stroke that are under independent physiological control. Using a high-speed computer vision system, we recorded the wing motion of tethered flying fruit flies for up to 12 000 consecutive wing strokes at a sampling rate of 6250 Hz. We then decomposed the joint motion pattern of both wings into components that had the minimal mutual information (a measure of statistical dependence). In 100 flight segments measured from 10 individual flies, we identified 7 distinct types of frequently occurring least-dependent components, each defining a kinematic pattern (a specific deformation of the wing stroke and the sequence of its activation from cycle to cycle). Two of these stroke deformations can be associated with the control of yaw torque and total flight force, respectively. A third deformation involves a change in the downstroke-to-upstroke duration ratio, which is expected to alter the pitch torque. A fourth kinematic pattern consists in the alteration of stroke amplitude with a period of 2 wingbeat cycles, extending for dozens of cycles. Our analysis indicates that these four elementary kinematic patterns can be activated mutually independently, and occur both in isolation and in linear superposition. The results strengthen the available evidence for independent control of yaw torque, pitch torque, and total flight force. Our computational method facilitates systematic identification of novel patterns in large kinematic datasets.     

The chromaffin granule — Plasma membrane interaction as a model for exocytosis: Quantitative release of the soluble granular content

Bovine adrenal medullary plasma membranes induce the release of soluble components from chromaffin granules in a Ca²⁺ dependent manner. This interaction can be modulated by changing the temperature. Correlation of the concentrations of four released soluble markers (catecholamines, soluble protein, ATP and dopamine-β-hydroxylase) in samples incubated at different temperatures revealed that those markers were liberated simultaneously. Their ratio did not differ significantly from the ratio measured in chromaffin granule lysates. These results suggest the release of the total granular content upon incubation with plasma membranes. Further analysis of the free catecholamines showed a preferential release of adrenalin.     

The identification of foam-forming soluble proteins from wheat (Triticum aestivum) dough

Proteomic methods have been used to identify foam-forming soluble proteins from dough that may play an important role in stabilising gas bubbles in dough, and hence influence the crumb structure of bread. Proteins from a soluble fraction of dough (dough liquor) or dough liquor foam have been separated by two-dimensional gel electrophoresis, and 42 identified using a combination of matrix-assisted laser desorption/ionization-time of flight and quadrupole-time of flight analyses. Major polypeptide components included beta-amylase, tritin and serpins, with members of the alpha-amylase/trypsin inhibitor family being particularly abundant. Neither prolamin seed storage proteins nor the surface-active protein puroindoline were found. Commonly used dough ingredients (NaCl, Na L-ascorbate) had only a minor effect on the 2-DE protein profiles of dough liquor, of which one of the more significant was the loss of 9 kDa nonspecific lipid transfer protein. Many proteins were lost in dough liquor foam, particularly tritin, whilst a number of alpha-amylase inhibitors were more dominant, suggesting that these are amongst the most strongly surface-active proteins in dough liquor. Such proteins may play a role determining the ability of the aqueous phase of doughs, as represented by dough liquor, to form an elastic interface lining the bubbles, and hence maintain their integrity during dough proving.     

Diminished FAD binding in the Y459H and V492E Antley-Bixler syndrome mutants of human cytochrome P450 reductase

Numerous mutations/polymorphisms of the POR gene, encoding NADPH:cytochrome P450 oxidoreductase (CYPOR), have been described in patients with Antley-Bixler syndrome (ABS), presenting with craniofacial dysmorphogenesis, and/or disordered steroidogenesis, exhibiting ambiguous genitalia. CYPOR is the obligate electron donor to 51 microsomal cytochromes P450 that catalyze critical steroidogenic and xenobiotic reactions, and to two heme oxygenase isoforms, among other redox partners. To address the molecular basis of CYPOR dysfunction in ABS patients, the soluble catalytic domain of human CYPOR was bacterially expressed. WT enzyme was green, due to air-stable FMN semiquinone (blue) and oxidized FAD (yellow). The ABS mutant V492E was blue-gray. Flavin analysis indicated that WT had a protein:FAD:FMN ratio of approximately 1:1:1, whereas approximately 1:0.1:0.9 was observed for V492E, which retained 9% of the WT k(cat)/K(m) in NADPH:cytochrome c reductase assays. V492E was reconstituted upon addition of FAD, post-purification, as shown by flavin analysis, activity assay, and near UV-visible CD. Both Y459H and V492E were expressed as membrane anchor-containing proteins, which also exhibited FAD deficiency. CYP4A4-catalyzed omega-hydroxylation of prostaglandin E1 was supported by WT CYPOR but not by either of the ABS mutants. Hydroxylation activity was rescued for both Y459H and V492E upon addition of FAD to the reaction. Based on these findings, decreased FAD-binding affinity is proposed as the basis of the observed loss of CYPOR function in the Y459H and V492E POR mutations in ABS.     

Aerial locomotion in flies and robots: kinematic control and aerodynamics of oscillating wings

Flight in flies results from a feedback cascade in which the animal converts mechanical power produced by the flight musculature into aerodynamic forces. A major goal of flight research is to understand the functional significance of the various components in this cascade ranging from the generation of the neural code, the control of muscle mechanical power output, wing kinematics and unsteady aerodynamic mechanisms. Here, I attempted to draw a broad outline on fluid dynamic mechanisms found in flapping insect wings such as leading edge vorticity, rotational circulation and wake capture momentum transfer, as well as on the constraints of flight force control by the neuromuscular system of the fruit fly Drosophila. This system-level perspective on muscle control and aerodynamic mechanisms is thought to be a fundamental bridge in any attempt to link the function and performance of the various flight components with their particular role for wing motion and aerodynamic control in the behaving animal. Eventually, this research might facilitate the development of man-made biomimetic autonomous micro air vehicles using flapping wing motion for propulsion that are currently under construction by engineers.     

Effects of microgravity on organ development of the neonatal rat.

We analyzed various organs in the same rats to study effects of gravitational condition on organ development of the neonatal rat in this study. Eight-day old and 14-day old Sprague-Dawley rats were flown for 16 days on the Space Shuttle Columbia (April 17-May 3, 1998). The organs were weighed and the ratio of the organ weight to the body weight (organ weight ratio; OBR) was calculated. Tissues were analyzed using anatomical, immunohistochemical and molecular biological technique. Six animals of the 8-day old group were reared on the ground for 30 more days after landing. The differences between flight and control rats in 8-day group were drastic. The lung, heart, kidney and adrenal glands in flight rats were significantly larger than that of control rats in OBR comparison. However, only the lung and kidney were still larger after 30 more days on ground. The kidney in flight rats performed pelvis expansion with down-regulation of aquaporin-2 expression confirmed by immunohistochemistry. The thymus, spleen, mesentery and pancreas were smaller in OBR. But the thymus in flight rats was heavier after 30 more days. The organs in flight rats which had no differences in OBR showed normal characteristics in histological analysis. We also found that the number of unmyelinated fibers of the aortic nerve in flight rats of 8-day group was smaller than that in control rats. In flight rats of the 14-day group, only the kidney was heavier and the ovary was lighter as compared to the controls. These results implied the second week of life was important for development during spaceflight. And the sensitivity and the critical period on neonatal development under microgravity might differ in each organ.     

Allatectomy and flight performance in maleLocusta migratoria

Summary Flight performance in locusts is a function of age, with its peak value at 18 days after emergence. While allatectomy retards the normal development of flight capability, it also has the effect of slowing down the decline in flight performance characteristic of operated control locusts as they age. Periodic topical application of synthetic juvenile hormone remedies the initial effect of allatectomy but its effectiveness wears off with age. The period of optimum flight performance is prolonged in locusts allatectomised when mature.A characteristic features of the flight pattern of immature-allatectomised and matureallatectomised locusts when flown about one week after the operation is a rapid decline in flight speed during the first 20 minutes of flight. Eventually, as the allatectomised locusts age, they assume the flight pattern of normal locusts and subsequent differences in flight performance between operated and normal locusts are confined to differences in flight intensity.Allatectomy has no marked effect on the preflight haemolymph total lipid and carbohydrate levels, the mobilisation of lipid and the amount of carbohydrate depleted. The quantity of lipid mobilised is, however, related to flight performance in both allatectomised and operated control locusts. Locusts which fly faster mobilise more lipid. The lipids mobilised by the adipokinetic hormone are 1618; 1818 and 1616 diglycerides in order of abundance. Allatectomy has no effect on the nature of these diglycerides released during flight.     

The effect of exposure to microgravity on the development and structural organisation of plant protoplasts flown on Biokosmos 9

Preparatory experiments for the IML-1 (International Microgravity Laboratory) mission to be flown on the Space Shuttle in January, 1992, were performed on a 14 day flight on Biokosmos 9 (Kosmos 2044) in September 1989. The purpose of the experiment was to study the effect of weightlessness on protoplast regeneration. Problems with late access to the space vehicle meant that the newly isolated protoplasts from hypocotyl cells of rapeseed (Brassica napus L. cv Niklas) and suspension cultures of carrot (Daucus carota L, cv Nobo) had to be stored at 4 degrees C for 36 h prior to the launch of the biosatellite, in order to delay cell wall regeneration until the samples were in orbit. In the flight samples and the ground controls, a portion of the total number of protoplasts regenerated cell walls. The growth of flight rapeseed cells was only 56% compared to the ground control; the respective growth of carrot cells in orbit was 82% of the ground control. Analysis demonstrated that the peroxidase activity and the amount of protein was lower in the flight samples than in the ground controls. The number of different isoenzymes was also decreased in the flight samples. A 54% decrease in the production of cellulose was found in rapeseed, and a 71% decrease in carrot. Hemicellulose production was also decreased in the flight samples compared to the ground controls. Ultrastructural analysis of the cell aggregates from the protoplasts cultured in orbit, demonstrated that hydrolysis and disappearance of reserve starch occurred in the flight cell plastids. The mitochondria were more varied in appearance in the flight samples than in the ground control cells. An increased frequency of the occurrence of folds formed by the plasmalemma together with an increase in the degree of complexity of these folds was also observed. Fluorescence analysis showed a decrease of the calcium content in cell cultures under space flight compared to the ground controls. One general effect of the stay onboard the space vehicle was a retardation of the regeneration processes. Callus cultures obtained from the flight samples grew very slowly compared to callus regenerated from the ground controls, and two years after the Biokosmos 9 flight there appears to be no further growth in the samples exposed to microgravity. Callus cultures from the ground controls, however, continue to grow well. A simulation experiment for IML-l performed in January 1990 at ESTEC (European Space Technology Center), The Netherlands, has resulted in regenerated plants. These observations are discussed and compared to the results obtained on Biokosmos 9.     

Food quality, nutrient limitation of secondary production, and the strength of trophic cascades

Recent meta‐analyses confirm that the strength of trophic cascades (indirect positive effects of predators on plant biomass through control of herbivores) varies among ecosystem types. In particular, most terrestrial systems show smaller cascades than most aquatic ones. Ecologists still remain challenged to explain this variation. Here, we examine a food quality hypothesis which states that higher quality plants should promote stronger trophic cascades. Food quality involves two components: digestion resistance of plants and magnitude of stoichiometric imbalance between plants and herbivores (where stoichiometry involves ratios of nutrient:carbon ratio of tissues). Both factors vary among ecosystems and could mediate conversion efficiency of plants into new herbivores (and hence control of plants by herbivores). We explored the food quality hypothesis using two models, one assuming that plant stoichiometry is a fixed trait, the other one allowing this trait to vary dynamically (but with a minimal nutrient:carbon ratio of structural mass). Both models produce the same suite of results. First, as expected, systems with more easily digested plants promote stronger cascades. Second, contrary to expectations, higher (fixed or minimal) nutrient:carbon ratio of plants do not promote stronger cascades, largely because of the net result of ecosystem feedbacks. Still, the model with dynamic stoichiometry permits positive correlations of realized plant nutrient:carbon ratio and cascade strength (as predicted), mediated through digestion resistance. Third, lower nutrient:carbon ratio of herbivores promotes stronger cascades. However, this result likely cannot explain variation in cascade strength because nutrient:carbon stoichiometry of herbivores does not vary greatly between terrestrial and aquatic ecosystems. Finally, we found that predation promotes nutrient limitation of herbivores. This finding highlights that food web processes, such as predation, can influence stoichiometry‐mediated interactions of plants and herbivores.     

航天搭载对武夷名丛相关生理及生长特性的影响

以神舟八号飞船搭载的6种武夷名丛种子SP₁代株系为材料, 探讨航天搭载对武夷名丛SP₁代株系叶片形态、光合色素含量、叶绿素荧光参数、可溶性糖和蛋白质含量以及茶叶品质成分含量的影响, 分析航天搭载后武夷名丛生长和生理特性的变化, 从中筛选优良突变株。结果表明, 航天搭载后6个武夷名丛SP₁代植株的叶长、叶宽、节间长度和叶面积均发生变化, 其中, 雀舌、肉桂和奇丹的叶面积显著增加; 航天搭载显著提高雀舌、奇丹、肉桂和金毛猴的叶绿素及类胡萝卜素含量, 瞬时叶绿素荧光(F_t)和光量子效率(Qy)也有所增加, 这有利于提高光合效率; 武夷名丛航天搭载后表现出可溶性糖含量增加而蛋白质含量减少, 氨基酸和茶多酚含量下降, 儿茶素和咖啡碱含量上升。综合各项指标, 航天搭载后6个武夷名丛中雀舌可以作为有益变异株系加以选育。     

Brassica rapa plants adapted to microgravity with reduced photosystem I and its photochemical activity

The photosynthetic apparatus contains several protein complexes, many of which are regulated by environmental conditions. In this study, the influences of microgravity on PSI and PSII in Brassica rapa plants grown aboard the space shuttle were examined. We found that Brassica plants grown in space had a normal level of growth relative to controls under similar conditions on Earth. Upon return to Earth, cotyledons were harvested and thylakoid membranes were isolated. Analysis of chlorophyll contents showed that the Chl a/b ratio (3.5) in flight cotyledons was much higher than a ratio of 2.42 in the ground controls. The flight samples also had a reduction of PSI complexes and a corresponding 30% decrease of PSI photochemical activity. Immunoblotting showed that the reaction centre polypeptides of PSI were more apparently decreased (e.g. by 24-33% for PsaA and PsaB, and 57% for PsaC) than the light-harvesting complexes. In comparison, the accumulation of PSII complex was less affected in microgravity, thus only a slight reduction in D1, D2 and LHCII was observed in protein blots. However, there was a 32% decrease of OEC1 in the flight samples, indicating a defective OEC subcomplex. In addition, an average 54% increase of the 54 kDa CF1-beta isoform was found in the flight samples, suggesting that space-grown plants suffered from certain stresses, consistent with implications of the increased Chl a/b ratio. Taken together, the results demonstrated that Brassica plants can adapt to spaceflight microgravity, but with significant alterations in chloroplast structures and photosynthetic complexes, and especially reduction of PSI and its activity.     

生态系统保护现状及保护等级评估——以江西省为例

基于生态系统的保护是防止生物多样性丧失的重要手段,已成为保护生物学研究的热点。对生态系统保护等级进行划分,确定局域、区域和全球尺度上生态系统保护的优先性,可为制定生态系统保护方案提供重要依据。目前,生态系统保护等级划分的常用指标包括面积流失率、幅度和代表性。以江西省生态系统为例,基于20世纪80年代的江西省植被图、生态系统图、2010年土地利用图和自然保护区图,在GIS环境下进行图层叠加运算和重分类,再进行定量评估和归一化,将江西省生态系统划分为极重要、重要和一般3个级别。结果表明:过去的30年间江西省自然生态系统面积共减少了82613.83km2,减少率超过了60%。全省的37个自然生态系统类型中有19个类型建有国家级自然保护区,但得到保护的面积比例较低。森林生态系统中极重要、重要和一般生态系统类型分别占省国土面积的16.7374%、5.5310%和3.8242%,受国家级自然保护区保护的比例分别为0.51%、3.73%和5.76%;灌丛生态系统中极重要、重要和一般生态系统类型分别占0.0975%、0.9335%和0.0100%,保护比例分别为1.72%、0.17%和0.70%;草地生态系统中极重要、重要和一般生态系统类型分别占0.2647%、0.0005%和0.1064%,保护比例分别为0.21%、0.00%和3.49%;湿地生态系统中极重要、重要和一般生态系统类型分别占0.3532%、0.0345%和1.5650%,保护比例分别为1.87%、0.00%和18.01%。从各级生态系统空间分布来看,极重要生态系统分布范围最广,主要分布在江西省的东南部和西北部;重要生态系统主要分布在西北部和东北部;一般生态系统分布范围最小,主要分布在北部。中部地区的自然生态系统多数由于经济发展而退变为农田、城市等人工生态系统。结合江西省生态系统现状,将极重要的生态系统作为重点保护范围,因而占江西省国土面积17.46%的生态系统应该得到优先保护。这一结果为有效地开展生态系统管理,制定有针对性的生态系统的保护规划具有重要参考价值。     

Geophysiological modeling: new ideas on modeling the evolution of ecosystems.

Living organisms evolve within ecological associations (from ecosystems to the biosphere) that are constituted by a biological component and a physico-chemical component. It is generally supposed that interactions such as competition and predation between the biological components of ecosystems are the main cause for the observed organization of ecosystems. We believe that in the search for a more comprehensive theory of evolution a much greater attention should be paid to the ways in which living organisms interact with the physico-chemical environment. To test our ideas, we develop a mathematical model to study the evolution of ecosystems, and we apply it to the study of hydrothermal vents. The model proposed is still a qualitative model. It tries to study, in a first approximation, the behaviours of the biological and chemical components. In the following we hope to develop and to improve it so to give a more realistic model.     

Eavesdropping on plant volatiles by a specialist moth: significance of ratio and concentration

We investigated the role that the ratio and concentration of ubiquitous plant volatiles play in providing host specificity for the diet specialist grape berry moth Paralobesia viteana (Clemens) in the process of locating its primary host plant Vitis sp. In the first flight tunnel experiment, using a previously identified attractive blend with seven common but essential components ("optimized blend"), we found that doubling the amount of six compounds singly [(E)- & (Z)-linalool oxides, nonanal, decanal, β-caryophyllene, or germacrene-D], while keeping the concentration of other compounds constant, significantly reduced female attraction (average 76% full and 59% partial upwind flight reduction) to the synthetic blends. However, doubling (E)-4,8-dimethyl 1,3,7-nonatriene had no effect on female response. In the second experiment, we manipulated the volatile profile more naturally by exposing clonal grapevines to Japanese beetle feeding. In the flight tunnel, foliar damage significantly reduced female landing on grape shoots by 72% and full upwind flight by 24%. The reduction was associated with two changes: (1) more than a two-fold increase in total amount of the seven essential volatile compounds, and (2) changes in their relative ratios. Compared to the optimized blend, synthetic blends mimicking the volatile ratio emitted by damaged grapevines resulted in an average of 87% and 32% reduction in full and partial upwind orientation, respectively, and the level of reduction was similar at both high and low doses. Taken together, these results demonstrate that the specificity of a ubiquitous volatile blend is determined, in part, by the ratio of key volatile compounds for this diet specialist. However, P. viteana was also able to accommodate significant variation in the ratio of some compounds as well as the concentration of the overall mixture. Such plasticity may be critical for phytophagous insects to successfully eavesdrop on variable host plant volatile signals.     

隔离降雨对马尾松针叶非结构性碳水化合物和碳、氮、磷的影响

植物叶片中的非结构性碳水化合物(NSC)和碳(C)、氮(N)、磷(P)含量可反映植物和生态系统对水分亏缺环境的响应及适应程度。以福建省长汀县25a马尾松(Pinus massoniana)为对象,原位观测分析了3年持续100%隔离降雨对成年马尾松针叶NSC与C、N、P的影响。结果表明：(1)持续隔离降雨导致马尾松针叶NSC含量先显著增加后减少,最终导致针叶NSC含量季节变化消失;且针叶可溶性糖含量、可溶性糖/淀粉比值在后期显著增加;(2)持续隔离降雨使马尾松针叶N含量、P含量、N∶P均表现为前期与对照组差异不显著,后期显著高于对照组;(3)马尾松针叶NSC含量、可溶性糖含量、P含量、N∶P与土壤水分含量呈显著或极显著相关,且均与P含量显著或极显著相关,与N素无相关性。以上研究结果表明,随着土壤水分含量的持续减少马尾松可通过调整针叶中NSC含量的积累及分配和提高针叶N、P含量来适应缺水环境,P含量的增加对NSC含量波动及可溶性糖和淀粉的相互转化起促进作用。     

Flying the North American Adirondack whitetail on instruments: A multi-parameter modeling approach to ecosystem-based wildlife management

We compare ecosystem-based wildlife management to instrument flight of aircraft. Airplanes cannot be controlled without visual ground reference, or if this is impossible to a cluster of flight instruments. Instrument pilots are trained to develop a rhythmic scan of the cluster to monitor and correct flight path and attitude. The untrained tendency is to fixate on a single gauge. Then, the aircraft deviates from its desired attitude and trajectory, and control may be lost. Fixation is like single-factor management wherein variables like habitat quality, recruitment, predator control, or harvest rates are singled out for adjustment without considering the others.

Ungulate populations are no less complex than aircraft in flight. They are multifactorial and move through time and space. To be managed effectively they must be guided in these movements through the monitoring and control instruments nature has provided. These are not necessarily proximate because populations are embedded in ecosystems and cannot be isolated from systemic complexity. Holistic management is needed, which requires a suite of monitoring and control parameters analogous to those in instrument flight.

We hold that every institution serving the interests of wise resource use should employ comprehensive, large-scale, ecosystem-based models built, tested, and perfected as a committed institutional activity over long periods of time. We call this Institutionalized Model-Making (IMM), and see models drawn from the collective expertise of scientists and their data in the same relation to nature as flight simulators are to actual aircraft. They mimic responses to control actions, and enable training in multifactorial management analogous to the instrument scans and control actions of the instrument pilot.

A model comprehensive enough for institutional use has not been built. We call attention to our efforts to develop such a model at the Huntington Wildlife Forest in New York's Adirondack Mountains. This is a model of the North American whitetail deer (Odocoileus virginianus Miller). It is too complex and incomplete for use in this paper, so a smaller-scale model is employed to make the case. In simulation trials parameters are ranked as to control sensitivity, then manipulated singly and multiply to demonstrate the superiority of the multiparameter approach.