THE BIOLOGY OF LETTUCE ROOT APHID

Lettuce root aphid, Pemphigus bursarius L., is a pest which sometimes causes considerable and widespread damage to crops of summer lettuce.
Its favourite primary host is Lombardy poplar. On hatching in spring, from eggs that have overwintered on this host, the fundatrices cause the development of hollow, flask-shaped galls on the leaf petioles. A fundatrix becomes enclosed within a gall, where it matures, and gives rise to between 100 and 250 young. These fundatrigeniae are all potential alatae and on developing wings leave the gall and migrate to lettuce and other secondary hosts; they reproduce rapidly.
Lettuce sown between mid-April and the end of May is most severely attacked, while lettuce sown in July escapes attack. The alternative secondary hosts belong to the Compositae, subfam. Liguliflorae, and although lettuce is preferred by the fundatrigeniae, Lapsana communis L. and Sonchus asper (L.) Hill often have big colonies of Pemphigus bursarius on their roots. The size of the mature apterae varies between hosts and is largest on lettuce and Sonchus asper.
All winged alienicolae are sexuparae and fly back to poplar. Thus alternative secondary hosts are not reservoirs for lettuce-infesting alatae.
The sexuparae begin appearing on lettuce from about the last week in August. They generally come up to the soil surface and settle around the 'collar' of the host plant, to mature and develop wings. Having flown back to the primary host, the sexuparae seek out crevices in the bark where they produce arostrate sexuales. The ovipara contains one egg, and after mating she crawls as far into the bark crevice as possible and oviposits.     

Overwintering adaptations in the lettuce root aphid Pemphigus bursarius (L.)

Pemphigus bursarius (L.) is a host alternating root-feeding aphid with a proportion of the population overwintering as asexual hiemalis in the soil. These hiemalis must be sufficiently cold tolerant to survive at the temperatures they would experience in winter, and also be able to overcome a period of prolonged starvation brought about by the absence of secondary host plants. Cold tolerance experiments showed field collected hiemalis to be considerably more cold hardy than laboratory summer apterae, with an LTemp(50) of -13.1 degrees C compared with 2.3 degrees C. In a constant exposure at 0 degrees C some field collected hiemalis survived for 18 days, while no summer apterae survived more than 8 h. Hiemalis, collected from the field in winter and induced in the laboratory, had significantly higher levels of triglycerides, 12.8% fresh weight (39.9% dry wt.) and 11.4% fresh weight (43.7% dry wt.), respectively, compared with summer apterae with a value of 7.1% fresh weight (32.5% dry wt.). These two adaptations of increased cold tolerance and accumulation of energy reserves confirm that the hiemalis morph is adapted for overwintering and hence physiologically distinct from summer morphs, and in turn, contribute to the success of the asexual life cycle strategy in this species.     

STUDIES OF THE BIOLOGY OF SCLEROTIUM CEPIVORUM BERK.

Sclerotia from 6-week-old pure cultures of Sclerotium cepivorum germinated immediately in soil only after abrasion of their rinds, but after burial in soil for a month or more, unabraded sclerotia became capable of germination.
Marked stimulation of germination occurred in the presence of host plants (onion, leek and shallot). Little or no germination occurred in soil alone or in the presence of non-host plants (barley, cabbage, carrot and white clover). Sclerotial germination was observed in a number of soils of widely differing pH and over a wide range of soil water content. Germination of sclerotia on uninjured onion roots was greatest at the tip region. On artificially injured roots sclerotial germination was enhanced but the effect of position was lost.
Sclerotial germination was independent of contact between roots and sclerotia. It was induced by root extracts of all Allium spp. tested, but of no other plants. Boiling or autoclaving root extracts did not destroy the active principle and it is concluded that under field conditions sclerotia are induced to germinate by a thermostable chemical substance from Allium roots.
The process of germination of sclerotia is described.     

Escaping an ecological dead-end: asexual overwintering and morph determination in the lettuce root aphid Pemphigus bursarius L.

1. Pemphigus bursarius exhibits a host-alternating life-cycle, overwintering as eggs on the primary host plant (poplar) before migrating in summer to the secondary host plant (mainly annual Compositae). A proportion of the population does not produce return migrants (sexuparae) in the autumn but remains in the soil and overwinters as asexual apterae, even after the annual plants have died in early winter. Laboratory and field experiments investigated the biology and overwintering success of these asexual apterae. 2. Both temperature and photoperiod are important in morph determination. The highest number of apterae (approximately 50% of progeny) was produced in a 20 °C, LD 18 : 6 h regime. Very few apterae were produced in an alatae-inducing environment (15 °C, LD 12 : 12 h), but the proportion increased over successive generations. 3. Apterae remaining in the soil in the autumn overwintered successfully in large numbers and were able to reinfest directly the root systems of newly planted lettuce grown in the same field in the following growing season. 4. Overwintered asexual populations also produced alates in July, which were able to colonise other lettuce plants, indicating that they were not sexuparae. Hence, P. bursarius can avoid the ecological dead-end that would occur through local patch extinction. Clones can therefore persist indefinitely as both asexual apterae and alatae without the need to return to poplar and undergo the sexual phase of the life-cycle.     

THE SPREAD OF DISEASES CAUSED BY SPECIES OF VERTICILLIUM

An investigation has been made of the spread of Verticillium disease of tomato and antirrhinum by root contact between diseased and healthy plants, and by the growth of the fungi through the soil. V. alboatrum and V. Dahliae spread rapidly by root contact, while V. tricorpus, V. nigrescens and V. nubilum showed no appreciable spread. Where the tomato and antirrhinum hosts wilted and died the causal organism was invariably isolated from the soil near the roots of the dead plants, but where the inoculated host harboured species without showing disease symptoms, as in the case of V. tricorpus and V. nubilum in antirrhinum, the parasite was never obtained from the soil. Moreover, these species in antirrhinum, and V. nigrescens and V. nubilum in tomato would appear to be mild pathogens since when they were already well established V. alboatrum was later actually found to enter and parasitize the respective hosts and bring about its own typical disease symptoms.
Spread through the soil in the absence of hosts was tested by the insertion into it of infected wheat grains followed by later attempts to isolate the fungi at varying distances from the point of infection. V. alboatrum, V. Dahliae and V. tricorpus showed little or no growth through the soil, whereas V. nigrescens and V. nubilum spread saprophytically to some extent, though never attaining sufficient concentration to cause appreciable infection of later planted tomatoes.
The conclusion is reached that spread of disease caused by species of Verticillium takes place mainly by root contact, with a rapidity relatively proportional to that of the death of the host. This finding, together with the lack of spread from antirrhinum plants infected with the non-lethal V. tricorpus and V. nubilum , suggests that the parasites remain in the vascular tracts until the death of the hosts.     

Host-associated populations in the lettuce root aphid, Pemphigus bursarius (L.)

Pemphigus bursarius is a host-alternating aphid in which annual rounds of sexual reproduction on its primary host, Populus nigra, are interspersed with parthenogenesis on a range of secondary hosts. Evidence was sought for the existence of genetically distinct populations, associated with different secondary hosts, in P. bursarius. Microsatellite markers revealed that genetically distinct populations were present on three different secondary host species. Microsatellites were also used, in conjunction with mitochondrial DNA sequence variation, to investigate the relationships between aphids on Populus, following sexual reproduction, and those on the secondary hosts. Evidence was found for a distinct, cyclically parthenogenetic population that exploited Lactuca sativa as its secondary host. In contrast, populations associated with Matricaria inodora appeared to be largely composed of obligate parthenogens or may even have been another species of Pemphigus. Populations on Lapsana communis appeared to be a mixture of cyclical and obligate parthenogens and were more genetically heterogeneous than those on other secondary hosts, possibly due to founder effects. Experiments to measure the performance of P. bursarius clones on different secondary hosts were inconclusive, failing to demonstrate either the presence or absence of adaptations to secondary hosts.     

Genomic copy number of intracellular bacterial symbionts of aphids varies in response to developmental stage and morph of their host

Buchnera, endosymbiotic bacteria of aphids possess many genomic copies per cell. In this study, we estimated genomic copy number per Buchnera cell from host insects at various developmental stages and of two different morphs, apterae and alatae, by fluorimetry and real-time quantitative PCR. The results indicated that the genomic copy number of Buchnera increased during postembryonic development of insects to adulthood, and that it decreased during the host's ageing. In Buchnera from alatae, the genomic copy number per cell was about twice as many as in those from apterae. DAPI-staining showed that the distribution of the genomic DNA in the Buchnera cells from old insects tended to aggregate, suggesting that intracellular structure of the genomic DNA of Buchnera varies in response to the physiological conditions of their host.     

BROWN ROOT ROT OF TOMATOES: II. THE FUNGAL FLORA OF THE RHIZOSPHERE

The fungal populations of soil and of the rhizosphere of tomatoes in steamed, fallowed and unsteamed plots were compared. Steaming greatly reduced the numbers of fungi in the soil, but fallowing had little effect. Soil bacteria were greatly reduced by steaming but increased to the level in the unsteamed plots after heavy watering. Outer rhizosphere fungal populations in unsteamed plots in July were larger than in the steamed plots, but by October this difference had disappeared, although roots in the unsteamed soil showed the greater development of disease.
Root surface counts indicated that the populations on actively growing roots in July in steamed and unsteamed plots reached similar levels, and there was a slight fall in numbers in both types of plot in October. Fungal infection of roots increased noticeably in unsteamed plots between July and October, although root surface numbers showed a decrease.
Of the fungal species isolated Colletotrichum atramentarium showed a distribution between soil and root surface which suggested that it was a root inhabiting fungus. Cephalosporium spp. were also found on the root surface and in roots, especially those from steamed soil.     

THE RESISTANCE OF INSECT PARASITOIDS TO THE DEFENCE REACTIONS OF THEIR HOSTS

Some of the following propositions are to be read as suggestions or hypotheses, supported by circumstantial or direct evidence, but not yet rigorously demonstrated. An estimate of the significance to be attached to each should be gathered from the body of the paper rather than from the following brief statements. 1.The problem is posed: how do endophagous parasitoids counteract the haemocytic defence reactions of their usual hosts? 2.It has been demonstrated that the egg and young first-instar larva of Nemeritis canescens have a coating on their surface which enables them to escape the attention of the haemocytes of their usual host, and to develop without exciting a defence reaction. The coating is applied to the egg before it is laid, and to the cuticle of the larva before it hatches. A little evidence suggests that some other ichneumon wasps of the subfamily Ophioninae may use this mechanism of resistance. 3.Older first-instar larvae, and the second and later instars, of many parasitoids, both hymenopterous and dipterous, probably overcome the haemocytic reaction of their host by rapid feeding, which depletes its blood both of cells and of nutrients, and so drains its resources that haematopoiesis is prevented and encapsulation becomes impossible. 4.The common habit of parasitoids of lingering in the first instar, before ingesting much food, while the host goes on developing to another stage or undergoes diapause, may enable the larva to retain a protective coating that would have become ineffective if it had grown. When at length the larva does feed and grow, the preceding mechanism (3) comes into play. 5.The teratocytes and pseudogerms formed by many species in several families of Hymenoptera absorb nutrients on a large scale from the blood of the host. They act quickly, as soon as the larva hatches. I suggest that by their attrition of the host's reserves of food, and its consequent debility, they prevent an effective haemocytic reaction to the young parasitoid. 6.Some dipterous and hymenopterous parasitoids first inhabit the intestine of their host, and do not penetrate the body cavity until they are ready to overwhelm the defence reactions by rapid and gross feeding. 7.Parasitoids that live temporarily inside an organ of the host may there acquire a coating which protects them from reaction by the blood cells. 8.Species of parasitoids that occupy an organ of the host for a long period, and develop inside it, escape a defence reaction because they live within the connective tissue covering the organ, to which the blood cells do not react. 9.Eggs of hymenopterous parasitoids laid within the embryos of their hosts may be treated by the embryonic blood cells as a developing organ, and become covered with connective tissue as those organs are. Thereafter they would not be recognized as foreign bodies. 10.Parasitoid eggs laid in the eggs or the young larvae of their host may be coated with host substances, or covered by connective tissue (9), before the blood of the host be comes capable of vigorousdefence reactions. They would there after escape recognition as foreign bodies. This may be the advantage of the habit of the so-called egg-larval parasitoids. 11.Reasons have been given by Schneider (1950) for his belief that the serosa of the ichneumon wasp Diplazon fissorius secretes something that locally inhibits the defence reactions of its hosts. The trophamnion and pseudoserosa of some parasitoid eggs may have this function. 12. Some parasitoids, especially second- and third-instar larvae of Tachinidae, physically repulse the haemocytes of their host, moulding them into a capsule that serves the maggot as a respiratory sheath.     

VARIETAL RESISTANCE OF LETTUCE TO ATTACK BY THE LETTUCE ROOT APHID, PEMPHIGUS BURSARIUS (L.)

Striking varietal differences in susceptibility to attack by the lettuce root aphid, Pemphigus bursarius L., were first found in lettuces grown at Wellesbourne in 1955. Subsequent work has confirmed that White Favourite and Imperials E-4 and 19551-M are highly resistant; Imperial 45634-M, Continuity and Iceberg are markedly resistant. Midas, Salad Bowl and Imperial 4164 each appear to be a mixture of susceptible and resistant plants.
Immigrant winged forms of P. bursarius showed no preference for colonizing any particular variety of lettuce, and it seems that resistance to attack results from antibiosis.
It is suggested that varietal differences in the composition of root sap may account for the differences in susceptibility to lettuce root aphid, but analyses of water and alcohol extracts of root sap from resistant and susceptible lettuce varieties have not shown consistent differences.     

豆蚜有翅蚜产生的原因

本文研究拥挤、寄土质量、温度和蚜型等因子对大豆蚜(Ahis glyeines)有翅蚜产生的影响。结果表明：1.大豆蚜无翅胎生成好个体间的拥挤是有翅蚜产生的主要原因。在低密度下拥挤反应随密度增大而增强,但过度拥挤会导致反应的降低。无翅若好间的拥挤不能导致其本身发育为有翅胎生蚜。 2.寄主质量能改变无翅胎生成蚜对拥挤的反应。每笼2头经成熟叶片处理的无翅胎生成蚜后代中有姻蚜的比例高于幼嫩叶片和对照(无叶片)处理,且饥饿不能促进有翅蚜的产生。3.温度能影响有翅蚜的产生。较高的温度(30℃和25℃)较21℃对有翅胎生蚌的产生有较强的抑制作用。4.不同母蚜型产生有翊蚜的能力不同。有翅胎生蚜间的拥挤也能使其在后代中产生少量的有翊蚜,但对拥挤的敏感程度低于无翅胎生蚜。     

THE INFECTION OF PLANTS BY VIRUSES THROUGH ROOTS

Roots of young tomato plants became infected when inoculated with tomato bushy stunt, tobacco mosaic, and potato X viruses. Root infections also occurred when these viruses were added to soil or culture solutions in which plants were growing.
The viruses were sometimes localized around their initial entry points in roots; sometimes they invaded the root system but not the shoots, and sometimes they produced full systemic infection of roots and shoots. In some experiments, but not all, systemic infections were more frequent when the upper tap root or superficial roots were inoculated than when fibrous roots were inoculated.
In both tomato and potato, virus X spread from diseased to healthy plants sharing the same culture solution, if their roots were in contact, but not otherwise. Infection of the roots of potato plants by inoculation, produced only one plant with virus-infected haulms, although several had infected tubers.     

两种生境条件下差不嘎蒿细根寿命

细根寿命对细根周转具有重要影响, 是生态系统C分配格局和养分循环研究的重要内容。该文利用微管法研究了流动沙地和固定沙地生长的差不嘎蒿(Artemisia halodendron)灌丛细根生长的动态过程, 通过Kaplan-Meier方法估计了细根存活率和中位值寿命, 并做存活曲线, 用对数轶检验比较了不同生境、不同土壤层次和不同月出生细根寿命的差异程度, 同时分析了不同样地细根寿命同土壤全氮、有机质、体积含水量和容重的相关关系。结果表明, 流动沙地和固定沙地差不嘎蒿细根具有相似的存活曲线, 但在各观测点, 流动沙地的细根累积存活率均高于固定沙地, 流动沙地细根中位值寿命(47 d)显著高于固定沙地(35 d)。细根寿命同各样地的土壤全氮和土壤容重呈显著的负相关关系, 同土壤水分呈显著的正相关关系, 但多元回归分析表明, 土壤水分是引起细根寿命变异的关键因素。土层深度对流动沙地细根寿命没有显著影响, 但两生境深层30~50 cm的细根寿命均显著高于上层(10~30 cm)。不同出生月的细根寿命显著不同, 流动沙地和固定沙地细根寿命具有相似的季节变化规律, 春季(4、5月)细根的寿命最长(71 d), 秋季(8、9月)次之(61 d), 夏季(6、7月)最短(39 d)。     

THE INFLUENCE OF HEAT ON SOME APHIDS

The thermal death-points of five species of aphids removed from their host plants lay between 38 and 41°C., when tested for 1 hr. at 60% r.h . Many aphids alive after 1 hr. at high temperatures died within the next day; no Myzus persicae recovered and reproduced after 1 hr. above 37.5°C. Third and fourth instars and adult apterae withstood heat better than first and second instars and alatae. More aphids died at 90% r.h . than at 60% r.h , and more at 60% than at 30% r.h . Aphids kept at 15% r.h . for 4 hr. before being heated showed a higher mortality than those kept at 95% r.h . Aphids on plants withstood temperatures higher than their thermal death-point off the plant. Presumably aphids can continue to cool themselves by evaporation while feeding; also lower temperatures on the surface of transpiring plant tissues will aid survival.     

HOST ALTERNATION IN APHIS FABAE SCOP.

Experiments on the feeding preferences and relative fecundity of Aphis fabae among leaves of different ages and kinds were extended to the comparison of different forms of the aphid: apterous and alate virginoparae and gynoparae.
All three forms showed a preference for the primary host, Euonymus , over a secondary host, sugar beet, but this preference was strongest in the gynoparae, weaker in the alate virginoparae and weakest in the apterae. The relative fecundity of the aphids on the two kinds of leaf paralleled their feeding preferences most closely in the gynoparae, less so in the alate virginoparae and least in the apterae.
All three forms also showed some preference for growing over mature leaves of the same kind, but this preference was strongest in the apterous virginoparae, weaker in the alate virginoparae and weakest in the gynoparae. The relative fecundity of the aphids on the two ages of leaf paralleled their feeding preferences most closely in the apterae, less so in the alate virginoparae and least in the gynoparae.
The physiological, ecological and evolutionary significance of the results is discussed in the light of the dual discrimination theory of aphid host selection.     

The cowpea aphid, shape Aphis craccivora, host plant odours and pheromones

Olfactometer experiments were conducted with apterae and alatae of the cowpea aphid, Aphis craccivora, Koch (Hom.:Aphidoidea). The occurrence of density dependent related pheromones and odour response to their host plant Vigna unguiculata was studied. Apterae responded with positive anemotaxis to air passed over both small groups of apterae and alatae (10 individuals) but negatively to air that passed over a bigger group (20 individuals). Alatae responded in the same way to groups of apterae but were repelled by alatae independent of the size of the group applied as odour source in the olfactometer, except when exposed to air passing ten alatae feeding on cowpea leaves. This may be due to interaction between aphid pheromones and host plant odour. Both apterae and alatae showed a general attraction to green plants and were also able to distinguish between other host plants and cowpea, which was the original host of the aphid clone used in the experiments. When attacked by aphids, the cowpea plant responded with a temporal increase in attractivity that reached a maximum after 48 h and had disappeared after one week.     

THE EFFECTS OF NITROGEN SUPPLY UPON THE VERTICILLIUM WILT OF ANTIRRHINUM

Isolates of Verticillium albo-atrum, V. dahliae and V. nigrescens grown on media adequately supplied with sodium nitrate induced wilt rather more rapidly in antirrhinum plants growing in soils with a normal and an excessive amount of nitrogen than in plants in nitrogen-deficient soil, though plants became diseased in all soils. Similarly treated isolates of V. nubilum and V. tricorpus induced a greater incidence of wilt in plants in soil supplied with heavy dressings of organic nitrogenous fertilizer than in plants in soil deficient in nitrogen, although V. tricorpus from a medium containing much sodium nitrate, in contrast to V. nubilum , was pathogenic to plants in such deficient soil. The ability of the nitrogen-starved isolates to penetrate the host plant was significantly diminished, and even when wound-inoculated into stems their effect upon the host was much reduced.     

Population genetic structure of the lettuce root aphid,Pemphigus bursarius (L.), in relation to geographic distance,gene flow and host plant usage

Microsatellite markers were used to examine the population structure of Pemphigus bursarius, a cyclically parthenogenetic aphid. Substantial allele frequency differences were observed between populations on the primary host plant (collected shortly after sexual reproduction) separated by distances as low as 14 km. This suggested that migratory movements occur over relatively short distances in this species. However, the degree of allele frequency divergence between populations was not correlated with their geographical separation, indicating that isolation by distance was not the sole cause of spatial genetic structuring. Significant excesses of homozygotes were observed in several populations. Substantial allele frequency differences were also found between aphids on the primary host and those sampled from a secondary host plant after several parthenogenetic generations at the same location in two successive years. This could have been due to the existence of obligately parthenogenetic lineages living on the secondary host or genetically divergent populations confined to different secondary host plant species but sharing a common primary host.     

Cd、Zn、Pb及其相互作用对烟草、小麦的影响

烟草对Cd、Zn、Pb是一种敏感性作物,Cd、Zn、Pb对烟草的影响比对小安、水稻都大。 Cd、Zn、Pb在烟草各器官中的累积随土壤Cd、Zn、Pb浓度的增高而增大。 Cd、Zn、Pb在烟草各器官中含量的次序为:茎叶>根>籽粒。它们在根中受阻,而较易转移到茎叶和籽粒中。 烟草对Pb的吸收比对Zn和Cd明显地低。Pb仍然是一种低吸收性元素。 土壤Zn增加,减低了烟草对Cd的吸收,而土壤Pb的增加,则促进了烟草对Cd的吸收。     

STUDIES ON THE HOST RANGE, PROPERTIES AND MODE OF TRANSMISSION OF BEET RINGSPOT VIRUS

An apparently undescribed mechanically transmissible virus has been named beet ringspot virus (BRV). It occurs naturally in Scotland in sugar-beet, turnip, swede, potato and many kinds of weed plants. BRV is readily distinguished from raspberry ringspot virus by the symptoms produced in Chenopodium amaranticolor , French bean, tobacco and Petunia hybrida plants. BRV lost infectivity when heated for 10 min. at 63°C. but not at 60°C.: at 20°C. its longevity in vitro was about 3 weeks. BRV was precipitated by ammonium sulphate, ethanol and acetone.
Protection experiments with tobacco plants, and serological tests, gave no evidence that BRV was related to tobacco ringspot, raspberry ringspot, potato bouquet or tobacco rattle viruses, but showed that viruses isolated from different host plants and from different localities were strains of BRV.
BRV is soil-borne: in glasshouse experiments sugar-beet, beetroot, potato, turnip, swede, French bean, Fragaria vesca , oat and wheat plants often became systemically infected when grown in soil from the site of a disease outbreak, but the virus was restricted to the roots of many infected plants. When sugar-beet seedlings were grown in virus-containing soil, BRV was first detected in their roots, where its concentration increased, before progressively increasing amounts of virus were found in the shoots.
Soils from five localities were found to contain BRV. BRV has been found only where the soil is light in texture, and often in fields where raspberry ringspot virus occurs.