A method for assessing the field susceptibility of potato cultivars to blackleg (Erwinia carotovora subsp. atroseptica)

In experiments to develop a method for assessing the field susceptibility of potato cultivars to blackleg (Erwinia carotovora subsp. atroseptica) seed tubers were stab-inoculated near the stolon (attachment end), with a suspension of the bacterium, or with water, before planting. Disease symptoms were recorded in three years (1980–1982) and plant growth and yield in 1982. Estima and Maris Bard were the most susceptible cultivars with many plants failing to emerge and most of those that did showing disease symptoms. Pentland Crown was the most resistant: few plants failed to emerge and few showed blackleg. Nevertheless compared with water-inoculated plants bacterial inoculation of the seed tubers of this cultivar caused loss of yield and differences in tuber size distribution. Cara, Wilja and King Edward showed intermediate reactions.     

Root, shoot tissues of Brassica juncea and Cereal secale promote potato health

Brassica species are increasingly being used as cover crops to suppress soil-borne diseases in potato cropping systems. Experiments were conducted in controlled environments and in the field to evaluate the effects of cover crop root or shoot or a combination of root and shoot tissues on potato root and tuber health. In a lab assay we examined the extent to which volatile compounds released from tissues of two cover crop species, rye (Cereale secale L.) and oriental mustard (Brassica juncea L.), could inhibit mycelium growth of two important potato diseases, Rhizoctonia solani and Pythium ultimum. Twenty-four hours into the lab assay, volatile compounds from all residues suppressed fungal growth. After 48 h, marked suppression of hyphal growth continued in the presence of mustard residues but not in the presence of rye tissues or the control without tissues. A 75 L volume container experiment evaluated the effect of incorporating different quantities of mustard shoot and root tissues (none, comparable to field level and fourfold field level) into R. solani and P. ultimum infested soil on potato growth, root health and tuber disease. In the container study, incorporating mustard shoots at the highest dose increased potato yield by 54% and reduced disease rating to 2.3 compared to a severe rating of 4.4 in the control. In the field trial, potato growth, root health and tuber disease levels were evaluated in plots where disease management involved either incorporation of mustard or rye cover crop roots, shoots and whole plants (roots plus shoots) or standard farmer practice of a fumigated fallow as a control. White root tissue was used as a health indicator, and averaged 58 and 78% in the fumigated control and mustard cover crop treatments, respectively. The highest healthy root tissue status (91%) was recorded where whole plants of mustard were incorporated. In contrast to the visual assessment of root and tuber health, tuber yield in the field was not influenced by cover crop treatment. Across experiments, the incorporation of or exposure to whole mustard plants was consistently effective at suppressing soil-borne fungi and promoting healthy roots and tubers, especially at higher rates of biomass. Mustard should be managed so as to maximize incorporated biomass for effective biofumigation. Multipurpose management requiring removal of mustard shoots is incompatible with promoting potato rhizosphere health.     

土壤灭菌-生物有机肥联用对连作马铃薯及土壤真菌群落结构的影响

甘肃省中部沿黄灌区是全国重要的加工型马铃薯生产基地,然而因集约化生产带来的连作障碍问题已经严重影响到当地马铃薯种植业的健康发展。结合田间试验和相关的室内分析,从马铃薯块茎产量和品质、植株生理特征和土壤真菌群落结构等角度,初步评估土壤灭菌和生物有机肥联用(Ammonia Disinfection plus Bio-organic Fertilizer Regulation,ABR)对马铃薯连作障碍的防控效果。同对照相比,ABR处理的块茎产量和商品薯率分别显著增加约71.1%—152.1%和39.2%—53.3%,但块茎化学品质变化不大。ABR处理叶绿素含量和根系活力较CK均显著增加,而叶片和根系丙二醛含量显著下降。PCR-DGGE分析发现,ABR处理显著影响了马铃薯连作土壤的真菌群落结构,表现为真菌群落的多样性指数较CK相比显著下降。ABR处理还有效抑制了土传病害的滋生,植株发病率和收获后的病薯率较CK分别显著下降约67.2%—82.2%和69.1%—70.5%。采用Real-time PCR评估连作土壤中3种优势致病真菌的数量变化,显示ABR处理下立枯丝核菌、茄病镰刀菌和接骨木镰刀菌的数量在生育期内较CK均有不同程度的下降。综合来看,土壤灭菌和生物有机肥联用技术在防控甘肃省中部沿黄灌区马铃薯连作障碍上具有较大的应用潜力,而对土传病害的抑制和微生物群落结构的改善是其主要的作用机理。     

Rhizobacteria that produce auxins and contain 1‐amino‐cyclopropane‐1‐carboxylic acid deaminase decrease amino acid concentrations in the rhizosphere and improve growth and yield of well‐watered and water‐limited potato (Solanum tuberosum)

Plant‐growth‐promoting rhizobacteria (PGPR) utilise amino acids exuded from plant root systems, but hitherto there have been no direct measurements of rhizosphere concentrations of the amino acid 1‐amino‐cyclopropane‐1‐carboxylic acid (ACC) following inoculation with PGPR containing the enzyme ACC deaminase. When introduced to the rhizosphere of two potato (Solanum tuberosum) cultivars (cv. Swift and cv. Nevsky), various ACC deaminase containing rhizobacteria (Achromobacter xylosoxidans Cm4, Pseudomonas oryzihabitans Ep4 and Variovorax paradoxus 5C‐2) not only decreased rhizosphere ACC concentrations but also decreased concentrations of several proteinogenic amino acids (glutamic acid, histidine, isoleucine, leucine, phenylalanine, serine, threonine, tryptophan, tyrosine, valine). These effects were not always correlated with the ability of the bacteria to metabolise these compounds in vitro, suggesting bacterial mediation of root amino acid exudation. All rhizobacteria showed similar root colonisation following inoculation of sand cultures, thus species differences in amino acid utilisation profiles apparently did not confer any selective advantage in the potato rhizosphere. Rhizobacterial inoculation increased root biomass (by up to 50%) and tuber yield (by up to 40%) in pot trials, and tuber yield (by up to 27%) in field experiments, especially when plants were grown under water‐limited conditions. Nevertheless, inoculated and control plants showed similar leaf water relations, indicating that alternative mechanisms (regulation of phytohormone balance) were responsible for growth promotion. Rhizobacteria generally increased tuber number more than individual tuber weight, suggesting that accelerated vegetative development was responsible for increased yield.     

Efficacy of fungicide combinations,phosphoric acid and plant extract from stinging nettle on potato late blight management and tuber yield

Late blight caused by Phytophthora infestans is a major constraint to potato production. Inadequate control of the disease has often resulted in potato yield losses. We assessed the efficacy of fungicides, phosphoric acid and stinging nettle extract combinations for late blight control at two locations in Kenya. Disease severity, relative area under disease progress curves (RAUDPC), pathogen lesions and tuber yield were quantified during the 2008 and 2009 cropping cycles. The application of metalaxyl alternated with phosphate resulted in the greatest suppressive effects on late blight. The average late blight severity ranged from 3.5 to 34% in 2008 and 4.7 to 50% in 2009 at Tigoni location. RAUDPC for the same location ranged from 5 to 40% and 5 to 50% in 2008 and 2009, respectively. Similar levels of late blight severity were recorded at Marimba location in both years. Lesion growth and pathogen lesion numbers on potato plants differed significantly (p < 0.05) among treatments. Fungicides, phosphoric acid and stinging nettle extract varied in late blight control. Potato tuber yield varied among treatments. Phosphoric acid treatment had significantly (p < 0.05) greater tuber yield compared to metalaxyl at both locations. Field plots treated with plant extracts from stinging nettle resulted in the lowest tuber yield compared to other treatments with the exception of the untreated control. Fungicides, phosphoric acid, stinging nettle extract and their combinations can be readily effective in the suppression of late blight severity and pathogen lesions with moderate increases in tuber yield.     

Reduction of Yield Depressions in High Frequency Potato Cropping Soil after Seed Tuber Treatments with Antagonistic Fluorescent Pseudomonas spp.

Severe yield depressions observed in high frequency potato cropping caused by microbial factors other than eelworms or known pathogens (narrow rotation effect) were reproduced in pot experiments. Total plant weight in a soil continuously cropped with potatoes was only 69% of that in a similar soil continuously cropped with wheat. Tuber weight in potato-soil was only 13 % and number of tubers only 10% of that in wheat-soil. Seed tuber treatment with cell suspensions of fluorescent antagonistic pseudomonads in carboxymethylcellulose (CMC) raised tuber yield in potato-soil up to 70% (550 % increase), number of tubers up to 93% (934 % increase) and total plant weight up to 90% (31 % increase) as compared with CMC-treatment in wheat-soil. Antagonistic fluorescent Pseudomonas isolates WCS 365, WCS 358 and WCS 374 producing mainly siderophores, with little or no production of other inhibitory substances, were more effective in diminishing the narrow rotation effect than the isolates that produced mainly inhibitory substances of different nature.     

Influence of the StubSNF1 kinase complex and the expression of the yeast TPS1 gene on growth and tuber yield in potato

Expression of the yeast trehalose-6-phosphate synthase-1 (TPS1) gene in potato results in growth aberrations and arrest of development. Recent studies have shown that this phenomenon could be related to the inhibitory effect of trehalose-6-phosphate on SnRK1s, a family of sucrose non-fermenting-1 (SNF1)-related protein kinases that link metabolic and stress signalling in plants. SnRK1s are heterotrimeric enzymes similar to yeast SNF1 and mammalian AMP-activated protein kinases (AMPKs). Previously, we showed that antisense repression of StubGAL83, one of the three subunits of the potato SnRK1 complex, results in a delay in rooting and increases sensitivity to salt stress. Here we report that StubGAL83 is a positive regulator of SNF1 kinase activity in potato and that repression of the kinase subunit of the SnRK1 complex, StubSNF1, reduces growth and tuber yield in potato plants. Co-repression of StubGAL83 and StubSNF1 at a certain level, however, can result in larger plants and increased tuber yield. We found that repression of StubGAL83, but not repression of StubSNF1 attenuated growth aberrations caused by TPS1 expression. We provide evidence that the increased plant size and yield in StubGAL83-StubSNF1 co-repressed plants as well as the attenuation of aberrations caused by TPS1 expression are related to increased nitrate reductase activity.     

类芽孢杆菌QHZ11-gfp在马铃薯植株上的定殖特征及促生效果

[背景] 生防菌在作物根系的有效定殖是其功能发挥的前提,而直观的跟踪技术和有效的定量方法是研究生防菌根系分布规律的重要工具。[目的] 研究马铃薯黑痣病病原菌立枯丝核菌（Rhizo ctonia solani） JT18的拮抗菌QHZ11在马铃薯植株上的定殖特征及对马铃薯的促生效果。[方法] 采用绿色荧光蛋白（Green Fluorescent Protein,GFP）对QHZ11进行标记,将标记菌株菌悬液、生物有机肥和无菌水分别接种至灭菌土壤,通过激光共聚焦显微技术和实时荧光定量PCR等方法观察和测定标记菌株在马铃薯植株不同部位的定殖特征、数量变化及对马铃薯的促生效果。[结果] pHAPII质粒成功导入QHZ11并可稳定遗传40代,记为QHZ11-gfp;菌株标记前后的菌落形态、生长曲线和对R.solani JT18的拮抗能力等基本一致。从第7天开始,相继在马铃薯芽上和根上发现了绿色荧光,说明QHZ11-gfp成功定殖到了马铃薯的芽、根等部位。QHZ11-gfp在根系和匍匐茎的定殖数量均呈现先升高至块茎形成期达到峰值后下降的趋势,并且在整个生育期根系的定殖数量始终大于匍匐茎。菌悬液和生物有机肥处理均显著促进了马铃薯根系的生长,并通过增加株高等农艺性状提高了块茎产量。其中,生物有机肥处理在各部位的荧光强度、定殖数量和对马铃薯的促生效果均显著优于菌悬液。[结论] QHZ11-gfp可在马铃薯植株上成功定殖并对马铃薯有良好的促生效果,将其制成生物有机肥促进了其定殖,使促生效果也更好。     

Influence of zoysiagrass rhizosphere fungal isolates on growth and yield of soybean plants

Among 21 rhizosphere fungi tested, eight sterile fungi and oneTrichoderma isolate (GT2-1) from zoysiagrass rhizosphere promoted the overall growth of soybean varieties when grown in the greenhouse. Out of nine effective isolates, GS7-4, GS8-2, GS8-3, GU23-3 (all sterile fungi) and GT2-1 (Trichoderma sp.) promoted plant growth and increased yield of Toyosuzu (variety 1) significantly, while GS8-3, GS10-1, GS10-2 (sterile fungi), and GT2-1 significantly caused plant growth promotion and yield increase of Kitamusume (variety 2). Among these efficient isolates, GS8-3 and GS10-2 induced considerable and consistent increases in length, biomass and yield of plants of varieties 1 and 2, respectively. In the field, however, only GS8-3 and GU23-3 among seven selected isolates, induced consistent and significant increases in plant growth and yield of varieties 1 and 2, while the ability of other isolates decreased. The plant growth promotion by these isolates in the field followed a similar trend to that in the greenhouse, but the effect was less marked. Some isolates which were effective in the greenhouse were less effective in the field. The degree of growth promotion by different isolates depended on the variety of soybean. The nutrient condition of soils used in experiments also seemed to play a vital role, since notable growth promotion by these isolates was observed in nutrient-depleted soil.The author is grateful to Ministry of Education, Science and Culture, Japan, for financial assistance.     

Overexpression of jasmonic acid carboxyl methyltransferase increases tuber yield and size in transgenic potato

Jasmonates control diverse plant developmental processes, such as seed germination, flower, fruit and seed development, senescence and tuberization in potato. To understand the role of methyl jasmonate (MeJA) in potato tuberization, the Arabidopsis JMT gene encoding jasmonic acid carboxyl methyltransferase was constitutively overexpressed in transgenic potato plants. Increases in tuber yield and size as well as in vitro tuberization frequency were observed in transgenic plants. These were correlated with JMT mRNA level––the higher expression level, the higher the tuber yield and size. The levels of jasmonic acid (JA), MeJA and tuberonic acid (TA) were also higher than those in control plants. Transgenic plants also exhibited higher expression of jasmonate-responsive genes such as those for allene oxide cyclase (AOC) and proteinase inhibitor II (PINII). These results indicate that JMT overexpression induces jasmonate biosynthesis genes and thus JA and TA pools in transgenic potatoes. This results in enhanced tuber yield and size in transgenic potato plants.     

The Interactive Approach of Rhizobacteria and l-tryptophan on Growth,Physiology, Tuber Characteristics,and Iron Concentration of Potato (Solanum tuberosum L.)

Iron deficiency is one of the most prevailing micronutrient deficiencies throughout the globe. Iron malnutrition affects billions of people around the world especially children and pregnant women. Its deficiencies can be overcome through microbial biofortification: a process of deliberately increasing desirable nutrients in crop plants. Plant growth-promoting rhizobacteria (PGPR) can improve iron content in edible plant tissues through different direct and indirect mechanisms. Adding plant growth regulators along with rhizobacteria makes it a novel fortification approach. In the current experiment, the interactive effect of two bacterial isolates (O-13 & K-10) alone and in consortium with l-tryptophan in the presence of iron sulfate was evaluated on growth, physiology, tuber characteristics, and iron concentration in potato (Solanum tuberosum L.). Results revealed that inoculation with PGPR and plant growth regulator (PGR) significantly improved the plant height, straw yield, and the number of tubers per plant. Potato (Solanum tuberosum L.) tuber characteristics (starch content, vitamin-C, relative water content) were also improved significantly. O-13, K-10, and l-tryptophan had significantly improved the iron concentration up to 20.59, 33.12, and 28.95%, respectively. However, inoculation with the microbial consortium and l-tryptophan showed a significant increase of up to one-fold in the iron concentration of potato (Solanum tuberosum L.) as compared with uninoculated control. The results suggest that rhizobacteria can help the plant to uptake nutrients from the soil. These findings concluded on the fact that the interactive effect of microbial assisted biofortification and plant growth regulator is a novel, promising, and cost-effective approach to mitigate micronutrient deficiencies especially in resource-limited countries.

     

Interactions of Ralstonia solanacearum and Pectobacterium carotovorum with Meloidogyne incognita on potato

Effect of interactions of Meloidogyne incognita with Ralstonia solanacearum and interaction of M. incognita with Pectobacterium carotovorum were studied in sequential and simultaneous inoculations on potato (Solanum tuberosum). Inoculation of M. incognita caused a lesser reduction in plant growth than caused by R. solanacearum. Inoculation of M. incognita plus R. solanacearum caused a greater reduction in plant growth than the damage caused by either pathogen. Inoculation of M. incognita prior to R. solanacearum resulted in a greater reduction in plant growth than R. solanacearum was inoculated prior to M. incognita. However, inoculation of M. incognita or P. carotovorum caused similar reduction in plant growth. Inoculation of P. carotovorum prior to M. incognita caused lesser reduction in plant growth than simultaneous inoculation of both pathogens. Inoculation of M. incognita caused galling in potato roots but the size of galls was small. Inoculation of P. carotovorum or R. solanacearum with M. incognita had adverse effect on galling and nematode multiplication. Wilting or soft rot index was 3 when R. solanacearum or P. carotovorum was inoculated alone. In other treatments, where R. solanacearum or P. carotovorum was inoculated with M. incognita, wilting or soft rot indices were 5.     

Response of potato grown under non-inductive condition paclobutrazol: shoot growth, chlorophyll content, net photosynthesis, assimilate partitioning, tuber yield, quality, and dormancy

The effect of foliar and soil applied paclobutrazol on potato were examined under non-inductive condition in a greenhouse. Single stemmed plants of the cultivar BP1 were grown at 35(±2)/20(±2) °C day/night temperatures, relative humidity of 58%, and a 16 h photoperiod. Twenty-eight days after transplanting paclobutrazol was applied as a foliar spray or soil drench at rates of 0, 45.0, 67.5, and 90.0 mg active ingredient paclobutrazol per plant. Regardless of the method of application paclobutrazol increased chlorophyll a and b contents of the leaf tissue, delayed physiological maturity, and increased tuber fresh mass, dry matter content, specific gravity, dormancy period of the tubers. Paclobutrazol reduced the number of tubers per plant. A significant interaction between rates and methods of paclobutrazol application were observed with respect to plant height and tuber crude protein content. Foliar application gave a higher rate of net photosynthesis than the soil drench. Paclobutrazol significantly reduced total leaf area and increased assimilate partitioning to the tubers. The study clearly showed that paclobutrazol is effective to suppress excessive vegetative growth, favor assimilation to the tubers, increase tuber yield, improve tuber quality and extend tuber dormancy of potato grown in high temperatures and long photoperiods.     

Root bacteria from nematicidal plants and their biocontrol potential against trichodorid nematodes in potato

Trichodorid nematodes (Nematoda: Trichodoridae) are vectors of tobacco rattle virus (TRV), one of the causal agents of spraing disease in potato. Root bacteria from nematicidal plants and their control potential against Trichodoridae were the focus of this study. Bacteria isolated from the roots of 12 nematicidal plants and potato were characterized for their production of hydrolytic enzymes, hydrogen cyanide, phenol oxidation ability and antifungal activity towards the potato pathogen Rhizoctonia solani. Based on these functional traits, bacteria isolates were selected and tested in greenhouse conditions on potato (cv. Saturna) for their effect on plant growth, and screened for nematicidal activity against Paratrichodorus pachydermus and Trichodorus primitivus in naturally infested soil. Sixteen bacteria isolates out of 44 reduced nematode densities by 50–100%. Nine selected isolated were further tested by bacterizing potato tubers (cv. King Edward) which were planted in a trichodorid and TRV-infested soil. Four bacterial isolates consistently reduced nematode densities (by 56.7–74.4%) with no visual negative effect on plant growth. These isolates were tentatively identified, partly by fatty acid methyl ester (FAME) analysis as: Stenotrophomonas maltophilia, Bacillus mycoides, Pseudomonas sp., and one unidentified bacterium. The isolates originated from potato, Plantago major, Thymus vulgaris and Asparagus officinalis, respectively. Two Pseudomonas isolates obtained from Zinnia elegans and selected for their strong nematicidal activity in soil screening tests, did not reduce the nematode population when tested on potato. It is concluded that plants releasing nematicidal compounds may harbour nematode-antagonistic bacteria as well.     

Tuber Formation and Growth of in vitro Cultivated Transgenic Potato Plants Overproducing Phytochrome B

We studied the effect of the ectopic expression of the Arabidopsis PHYB gene, which encodes the phytochrome B (phyB) apoprotein, under the control of cauliflower mosaic virus 35S promoter on the photoperiodic response of tuberization and growth of potato (Solanum tuberosum L., cv. Désirée) transformed lines. Stem cuttings of transformed and control plants were cultured on Murashige and Skoog nutrient medium containing 5 or 8% sucrose in the phytotron chambers at 20°C under conditions of a long day (16 h), a short day (10 h), or in darkness. We showed that the overexpression of the PHYB gene enhanced the inhibitory effect of the long day on tuberization. In addition, tuber initiation in these transformed plants occurred at a higher sucrose concentration. The insertion of the PHYB gene decreased plant and tuber weights and shortened stems and internodes. Thus, we demonstrated the complex result of the PHYB gene insertion: it affected the photoperiodic response of tuberization, the control of tuber initiation by sucrose, and the growth of potato vegetative organs.     

Mesh crop covers improve potato yield and inhibit tomato potato psyllid and blight: The roles of mesh pore size and ultraviolet radiation

Crop losses caused by the tomato potato psyllid (TPP; Bactericera cockerelli) and blight (Alternaria solani; Phytophthora infestans) continue to be major concerns for potato (Solanum tuberosum) growers worldwide, and commercial crops often require frequent use of agrichemicals to maintain tuber yield and quality. Nevertheless, a paradigm shift is unfolding in crop protection where new tools, such as physical barriers and light‐modifying filters, are being used to develop chemical‐free approaches for pest and disease control. In this study, we examined the use of crop covers as a non‐chemical method for controlling TPP and reducing blight in field potatoes. Our study demonstrated that those plants grown under mesh covers exhibited reduced levels of blight, TPP and associated psyllid yellows. Additionally, potatoes grown under mesh covers exhibited increased yield (91.4 ± 6.9 SD t/ha) compared with both uncovered control plants (75.0 ± 11.8 t/ha) and plants grown using agrichemical pest control (84.5 ± 10.8 t/ha). The plants grown under mesh produced fewer smaller tubers, with increased average and maximum tuber size, so that marketable yield (tubers ≥60 g) was also increased (83.5 ± 7.5 t/ha), compared with that achieved for uncovered control plants (60.0 ± 8.3 t/ha) and plants grown using agrichemicals (69.6 ± 9.2 t/ha). A second field experiment suggested that the incidence of TPP foliage damage and the development of blight were lowest when the passage of ambient ultraviolet (UV) radiation through the crop cover was reduced. This hypothesis was supported by a third trial where potatoes grown outdoors in pots exhibited reduced TPP foliage damage and fewer resident TPP when grown under UV‐blocking plastic screens. The results of these experiments suggest that the use of mesh covers offers new opportunities to sustainably protect potato crops both by acting as a physical barrier and by modifying the wavelength of light incident on the crop.     

Colonization of root tissues and protection against Fusarium wilt of rye (Secale cereale) by nonpathogenic rhizosphere strains of Fusarium culmorum

Colonization of rye (Secale cereale) tissues by nonpathogenic rhizosphere Fusarium culmorum isolates DEMFc2 and DEMFc5 and a pathogenic strain DEMFc37, and their effect on plant fresh weight were studied in pot experiments. Both rhizosphere isolates colonized the epidermis and the cortex but were not found in vessels, while the pathogen colonized all three layers of root cells. The numbers of pathogen CFU isolated from plant tissues were much higher than those of the rhizosphere isolates in spite of the same number of macroconidia used as inoculum (1 × 10⁵ g⁻¹ of soil). Inoculation of seedlings with DEMFc2 resulted in a 20% increase, with DEMFc5 in more than a 20% reduction, and with DEMFc37 in a 38% reduction of shoot fresh weight of 14-day-old plants. Pre-colonization of plants with (either of) the rhizosphere isolates and subsequent inoculation with the pathogen resulted in plant weights the same as those observed in plants inoculated with the rhizosphere strain alone. The disease severity index for shoots of plants pre-colonized with DEMFc2 was reduced from class 4 (86% diseased plants) observed for plants inoculated with the pathogen alone to class 2 (average of 8% diseased plants) when pre-treated with the rhizosphere strain. The CFU number of the pathogen isolated from the interior of roots of plants pre-colonized with the rhizosphere isolates was as low as 10% of the number isolated from plants inoculated with the pathogen alone. A study of in vitro interactions between the rhizosphere isolates and the pathogen suggests that changes in plant colonization by the pathogen and its effect on fresh weight of plants pre-colonized with the rhizosphere isolates were not connected with inhibition of its growth by a direct action of the rhizosphere isolates. The results suggest that strain DEMFc2 can be considered as a potential biocontrol agent.     

Effect of waterlogging yam vines on vegetative growth and tuber yield

The effect of waterlogging the vines of two yam varieties for 24, 48 and 72 hours at two stages of growth, with or without fertiliser application, was studied in the field. Waterlogging caused a progressive degeneration of the leaf starting with the development of fresh lesions on the lower leaf surface, through necrotic spots or portions, to complete leaf necrosis. The degree of leaf damage was greater with Um 680 (Dioscorea alata) than with Obiaoturugo (D. rotundata). Waterlogging also caused the breakdown of the apical buds of the vines. The degree of damage increased with the duration of waterlogging. Younger plants suffered more damage than older plants, and plants treated with fertiliser suffered more than plants without fertiliser. Waterlogging ultimately hastened the final senescence of the yam vine. Waterlogging vines for 24 h had no effect on tuber yield, while waterlogging for 48 and 72 h reduced tuber yield by 32.4% and 43.2% respectively (P< 0.01). Waterlogging vines at the early growth stage produced 47.6% (P <0.01) less yield than waterlogging at a later stage. It is suggested that short-term or long-term waterlogging of the yam vine, or parts thereof, is the main cause of reduced leaf area and low yield in unstaked compared with staked yarn crops. Waterlogging may also be a predisposing factor to disease infection of yam vines by soil-borne micro-organisms.     

Effect of Plant Oligoadenylates on Viral Infection and Antistress and Growth-Regulating Properties in Potato Plants Grown in vitro

Biological properties of plant oligoadenylates (POA) were studied in in vitro grown potato (Solanum tuberosum L.) plants. POA were synthesized by ATP polymerization in the presence of an enzyme preparation isolated from leaves of wild potato Solanum chacoense Bitt. treated with resistance inducers. The concentration of viral antigen was determined by the method of immunoenzyme analysis. In the course of virus elimination by the apical meristem method, pretreatment of potato tuber sprouts with POA increased the survival rate of meristem explants and, in several cultivars, enhanced morphogenesis and increased the yield of virus-free regenerants. Prolonged application of POA in the nutrient medium for microcutting of potato tube plants infected in vitro with X-, S-, and M-viruses increased their height due to internode lengthening. The effect of this treatment on virus reproduction was ambiguous: various combinations of virus species, the duration of growth on POA-containing media, and POA concentration resulted in either statistically significant inhibition or a significant enhancement of virus reproduction. Possible mechanisms of the antistress effect of POA, in connection with their effect on virus reproduction, are discussed.