The legs of ostriches (Struthio) and moas (Pachyornis)

Ostriches were filmed running at maximum speed, and forces on the feet were calculated. Measurements were made of the principal structures in the legs of an ostrich. Hence peak stresses in muscles, tendons and bones were calculated. They lay within the range of stresses calculated for strenuous activities of other vertebrates. The ostrich makes substantial savings of energy in running, by elastic storage in stretched tendons. Pachyornis was a flightless bird, much heavier than ostriches and with massively thick leg bones. These bones are shorter than predicted for its estimated body mass, by extrapolation from allometric equations for flying birds. An attempt is made to calculate the stresses that acted in the leg bones in running, for all possible patterns of leg movement. The stresses were probably rather low, unless Pachyornis was capable of running fast. It is argued that the optimum factor of safety for moo leg bones may have been exceptionally high, as a consequence of the absence of predators.     

Mechanical stresses in erythrocyte membranes (theoretical models)

The type of mechanical stresses that arise in erythrocyte membranes on exposure to catecholamines and steroid hormones is considered. Tensors of mechanical stresses and displacements were obtained for a membrane interacting with hormones. A possible mechanism of membrane rupture under mechanical stresses is discussed. Catecholamines and androgens increase the microviscosity of membranes, and alternating kink and stretching sites occur in the lipid membrane bilayer to produce a checker-wise pattern. The membrane becomes thinner in a stretching site (smectic A → smectic C transition). When tensile stresses increase further and exceed a certain critical value the membrane may rupture. It is possible that a gel phase L_β? → liquid crystalline phase L_α transition takes place in the stretching site of the lipid bilayer prior to disruption. The density of the lipid bilayer decreases in the process, pores form, and then cracks occur.     

Difference Between Salt(NaCl)and Alkaline(Na2CO3)Stresses on Puccinellia tenuiflora(Griseb. )Scribn. et Merr. Plants

Eight-week-old plants of Puccinellia tenuiflora (Griseb.) Scribn. et Merr. growing in pots filled with vermiculite were stressed by treating with 12.5–800 mmol/L solutions of neutral satt(NaC1) or basic salt(Na2CO3). Strain indexes such as relative growth rate etc. were determined. There was a significant difference between the two kinds of stresses. Maximum stress value that P. tenuiflora plants can tolerate is 60 mmol/L for the neutral salt and 200 mmol/L for the basic salt Na2CO3. Under NaCl-stress, great amount of proline accumulated, and citric acid content gradually decreased. But under Na2CO3-stress, proline content did not raise too much and citric acid content obviously increased with the increasing stress value. Under both stress conditions, Na+ content increased and K+ content decreased with the increasing stress value, but the effect of NaCl-stress on K+ content in roots and shoots was much less than that of Na2CO3-stress. In both stresses, the elevation of electrolyte leakage rate of leaf orchestrated with the change of stress value. This finding represented the only similarity among the strain indexes determined in both stresses.     

Tumor necrosis factor alpha (TNFalpha) induces the unfolded protein response (UPR) in a reactive oxygen species (ROS)-dependent fashion, and the UPR counteracts ROS accumulation by TNFalpha

Accumulation of unfolded proteins in the endoplasmic reticulum (ER) causes ER overload, resulting in ER stress. To cope with ER stress, mammalian cells trigger a specific response known as the unfolded protein response (UPR). Although recent studies have indicated cross-talk between ER stress and oxidative stress, the mechanistic link is not fully understood. By using murine fibrosarcoma L929 cells, in which tumor necrosis factor (TNF) alpha induces accumulation of reactive oxygen species (ROS) and cell death, we show that TNFalpha induces the UPR in a ROS-dependent fashion. In contrast to TNFalpha, oxidative stresses by H2O2 or arsenite only induce eukaroytic initiation factor 2alpha phosphorylation, but not activation of PERK- or IRE1-dependent pathways, indicating the specificity of downstream signaling induced by various oxidative stresses. Conversely, the UPR induced by tunicamycin substantially suppresses TNFalpha-induced ROS accumulation and cell death by inhibiting reduction of cellular glutathione levels. Collectively, some, but not all, oxidative stresses induce the UPR, and pre-emptive UPR counteracts TNFalpha-induced ROS accumulation.     

Early ossification in the skeleton of the sucker (Catostomus macrocheilus) and the guppy (Poecilia reticulata)

Catostomus macrocheilus, a sucker, and Poecilia reticulata, a live-bearer, are subjected to dissimilar mechanical stresses while most of their bony structures are forming. Osteogenesis occurs in the sucker when it is a free-living larva, whereas in the livebearer it occurs intrafollicularly. The first-formed bones ofboth species are those that meet functional demands and are subjected to the greatest stresses. These are the movable bones associated with the acts of respiration and feeding, and some of the axial bones. The cranial roof is the last to calcify. The primary differences in osteogenesis of the two species, such as in the vertebral column and caudal fin, can be correlated with differences in stress. Surface forces on calcifiable tissue perhapsassist in the deposition of calcium salts.     

On the interaction of UV-B radiation (280–315 nm) with water stress in crop plants

Cowpea ( Vigna unguiculata L. Walp.) seedlings (3-day-old) were subjected to 4 kinds of experimental treatments: (1) control without exposure to any stress (−D-UV), (2) moderate water stress with no UV-B irradiation (+D-UV), (3) no water stress but to UV-B radiation (−D+UV). and (4)moderate water stress and exposure to UV-B (+D+UV). UV-B and drought stress in the combined form elicited beneficial effects on the morphological and growth characteristics, and a few additive inhibitory effects in some functional processes. An increase in the specific leaf weight (SLW) was observed in the combination of stresses, which could be a defence mechanism against UV-B. The combination of stresses promoted the synthesis of anthocyanins and phenolic compounds. The responses of plants to the combination of stresses indicate that during simultaneous exposure of plants to multiple stresses, one form of stress could minimize the damage by the other. The enhancement of superoxide dismutase (SOD) and catalase activities appear to serve as acclimation mechanisms to scavenge the toxic, free radicals of oxygen produced under stress conditions. However, the inhibition in nitrate metabolism was greater in the combined stresses than in either of the stresses imposed separately. The results of this study illustrate that the interaction of stresses during simultaneous multiple stress conditions brings out certain beneficial effects.     

Variations of wood delta(13)C for the past 50 years in declining Siebold's beech (Fagus crenata) forests

Markedly damaged stands have been observed in Siebold's beech (Fagus crenata) forests on the Tanzawa Mountains, Japan, which are located close to densely populated and heavily industrial areas. We measured the delta(13)C records for the past 50 years (1944-1997) in wood cellulose sampled from relatively healthy trees in declining forests on Mt. Hinokiboramaru (1600 m). This may provide information on the history of stresses related to environmental changes, which have caused the decline symptoms. The results showed that, for all of the trees studied, wood delta(13)C has decreased with time. Also, the difference in delta(13)C among trees grew abruptly after the mid-1960s, which almost coincides with the time when the decline symptoms were markedly observed. Some trees with large reduction of wood delta(13)C exhibited the strong decreases in radial growth. This suggests that the reduction of tree growth may have been more greatly influenced by decreasing carboxylation rate than by stomatal limitation. It is unlikely that water stress and SO(2) and O(3) stresses have induced the growth reduction, because those stresses cause increasing wood delta(13)C. This is supported by the facts that wet conditions and relatively low SO(2) and O(3) levels have been observed near Mt. Hinokiboramaru. In addition, analyses of wood Ca showed no evidence that acid fog and soil acidification have affected the wood delta(13)C and growth through effects on the nutrient uptake of trees. However, what type of stresses have induced the large reduction of wood delta(13)C and growth for some of the trees studied remains unknown because of the lack of sufficient data for evaluation. In contrast, lesser reduction of wood delta(13)C from the other trees may be related to an increase in the plant water-use efficiency with increasing atmospheric CO(2) concentration.     

盐（NaCl）与碱（Na2CO3）对星星草胁迫作用的差异

对生长在蛭石中8周龄的星星草(Puccinellia tenuiflora(Criseb.)Scribn.et Merr.)用 12.5—800mmol/L 的中性盐 NaCl或碱性盐 Na_2CO_3进行胁迫处理,测定植物日相对生长率等胁变指标。结果表明星星草的抗盐性高于抗碱性,可耐受的最高浓度分别为:中性盐NaCl 600 mmol/L、碱性盐 Na_2CO_3 200mmol/L_o NaCl胁迫下,随胁强增高,脯氨酸明显积累,柠檬酸含量则逐渐下降;Na_2CO_3胁迫下,脯氨酸仅稍有积累而柠檬酸含量却急剧升高。两种胁迫下都表现出:随胁强增大,Na~ 含量明显上升,K~ 含量下降。但是,NaCl胁迫对K~ 含量影响不大,而Na_2CO_3胁迫则导致根及茎叶中的K~ 含量明显下降。诸胁变指标中唯有叶片电解质外渗率对两种胁迫来说变化特点相似。     

Mechanics of locomotion and jumping in the horse (Equus): in vivo stress in the tibia and metatarsus

Principal stresses acting in the midshaft cortices of the tibia and metatarsus of the horse were determined from in vivo rosette strain gauge recordings for overground locomotion at different gaits, as well as for jumping and acceleration. Bone stresses were correlated with limb kinematics and ground reaction forces. The results for these two hind limb bones were compared to earlier determinations of locomotor stress in the forelimb radius and metacarpus (Biewener, Thomason & Lanyon, 1983b). Peak stresses generally increased with increasing speed; however, because of greater bending, stresses in the tibia were substantially higher (45%) than in the metatarsus over the range of steady state speeds. Bending of the tibia resulted from significant off-axis loading by the ground reaction force. In contrast, the metatarsus was loaded in compression due to its close alignment with the ground reaction force. Peak stresses as high as - 53 MPa (caudal cortex) in the tibia and -38 MPa (plantar cortex) in the metatarsus acted at a canter. Increased skeletal stress was matched by a corresponding increase in ground reaction force and a decrease in hind limb duty factor. In both bones, peak stresses were significantly greater and differed in their distribution during jumping and acceleration, compared to peak stresses during steady speed locomotion. Maximal values of - 126 MPa (cranial cortex) in the tibia and - 117 MPa (dorsal cortex) in the metatarsus were developed during jumping. These stresses are similar in magnitude to those reported for a range of different sized mammals during strenuous activity and correspond to a safety factor to yield failure of 1.5 to 3. Though generally consistent within an individual bone, the distribution and magnitude of stresses varied about 20% among individuals. This variation was greater for the metatarsus because of its lesser curvature, which diminishes the bone's ability to control for bending in a fixed direction.     

Mechanics of running of the ostrich (Struthio camelus)

Ostriches have been filmed running fast in their natural habitat. A female ostrich has been dissected and the principal bones, muscles and tendons in a leg have been measured. It is calculated that stresses up to 240 kN m⁻² and 40 MN m⁻², respectively, act in the digital flexor muscles and their tendons during running. Tensile and compressive stresses up to about 70MNm⁻² and 110 MNm⁻² act in the tibiotarsus. A large proportion of the energy which would otherwise be required for running is probably saved by elastic storage in tendons. Comparisons are made with the legs of flying birds and of antelopes.     

On the massive legs of a Moa (Pachyornis elephantopus, Dinornithes)

Pachyornis , which is extinct, was a huge bird with massively thick leg bones. These have been measured, to assess their strength. A mathematical model is used to calculate the forces that must have acted on them, when Pachyornis ran. Hence it is shown that the stresses likely to have acted on them are similar in magnitude to the stresses experienced (in stenuous activities) by bones of modem birds and mammals. The femur and tarsometatanus, however, seem disproportionately strong in comparison with the tibiotanus.     

水稻(Oryza sativa L.)苹果酸酶(OsNADP-ME3)基因在逆境下的表达特性研究

水稻苹果酸酶（NADP-ME）是多基因家族,由3个胞质型NADP-ME和1个质体型NADP-ME构成。本研究针对水稻胞质型成员（命名为NADP-ME3）（NM₀01061367）进行初步的功能解析。克隆获得的NADP-ME3基因的cDNA序列全长为2240bp,其中5’非翻译区为151bp,3’非翻译区为376bp,开放读码框（ORF）长1713bp,编码570个氨基酸。为研究NADP-ME3在逆境胁迫下的表达量变化,Northern blot检测结果显示,在NaCl、NaHCO3和PEG胁迫条件下,NADP-ME3随胁迫处理时间的不同表达量呈现不同程度的变化,推断NADP-ME3可能与非生物胁迫有应答关系,将NADP-ME3转入拟南芥中并通过观察转基因拟南芥在非生物胁迫下表型变化,发现NADP-ME3能够在一定程度上提高植物对非生物胁迫的耐受性。     

Stresses exerted in the hindlimb muscles of common chimpanzees (Pan troglodytes) during bipedal locomotion

Recent studies have indicated that chimpanzee bipedality is mechanically inefficient and dynamically unlike that of humans, thus undermining the chimpanzee analogy for mechanical aspects of the early evolution of hominid bipedalism. This paper continues this theme by measuring the forces and stresses engendered by the muscles during bipedal locomotion, for an untrained chimpanzee and for data from chimpanzees which have been encouraged to walk bipedally, presented in the literature. Peak stresses in the triceps surae were lower for the untrained chimpanzee than for the trained subjects because during the late stance phase, when peak ankle moments occur, the centre of pressure of the ground reaction force on the foot of the untrained chimpanzee stayed close to the ankle joint. In contrast, for the trained subjects it moved closer to the toes, as in human bipedalism. Quadriceps and hip extensor stresses are approximately 30% larger for the untrained chimpanzee than for the trained subjects, because the trained chimpanzees walked with a more erect posture. These results may reflect the way in which muscles can develop in response to training, since research on humans has shown that muscle physiological cross-sectional area increases as a result of exercise, resulting in smaller stresses for a given muscle force. During a slow walk, untrained chimpanzees were found to exert far greater muscle stresses than humans do when running at moderate speed, particularly in the muscles that extend the hip, because of the bent-hip, bent-knee posture.     

The conjugating green alga Zygnema sp. (Zygnematophyceae) from the Arctic shows high frost tolerance in mature cells (pre-akinetes)

Protoplasma - Green algae of the genus Zygnema form extensive mats and produce large amounts of biomass in shallow freshwater habitats. Environmental stresses including freezing may perturb these...