A yellows disease system with differing principal host plants for the obligatory pathogen and its vector

A stolbur‐type phytoplasma is the putative pathogen of grapevine yellows disease that causes economic damage to vineyards in most growing areas around the world. The pathogen is known to be transmitted to vines by two planthoppers, Hyalesthes obsoletus and Reptalus panzer; the latter is found in Europe but has not yet been observed in Israel. The establishment of a vector–pathogen–plant relationship requires that the pathogen and the vector meet on a shared host plant. This does not happen in the ecosystem examined here, where two different principal host plants for the obligate pathogen and its vector exist: the pathogen is established on vines, while its vector, H. obsoletus, develops on Vitex agnus‐castus. The present study verified that: (i) the vector cannot complete its life cycle on vines; (ii) V. agnus‐castus does not grow in the immediate vicinity of vines, and does not harbour the pathogen; and (iii) the pathogen is not vertically transmitted from mother to offspring. Moreover, in a thorough search of plants in vine growing areas, no other plants were found that host both the vector and the pathogen. However, it was found that the planthopper can acquire the phytoplasma from infected vines. Nonetheless, this does not prove the ability of the planthopper to further transmit the pathogen to vines and does not explain the presence of the vector on the non‐preferred vines. Thus, the enigma of the pathogen–vector–host triangle in this system remains unresolved.     

Characterization of Onthophagus sellatus as the major intermediate host of the dog esophageal worm Spirocerca lupi in Israel

A total of 750 faecal samples of dairy calves at up to 2 months of age kept in various housing systems were screened for Cryptosporidium spp. infection using the aniline-carbol-methyl violet staining method. DNA was extracted from Cryptosporidium positive samples and from 150 randomly selected microscopically negative samples. Nested PCR was performed to amplify the partial SSU rRNA gene of Cryptosporidium that was subsequently digested by SspI, VspI and MboII restriction enzymes to determine the present Cryptosporidium species and genotype. In addition, the samples characterized as Cryptosporidium parvum were subsequently analyzed at the GP60 gene to determine the distribution of zoonotic subtypes. Sequence analyses and RFLP identified C. parvum in 137, Cryptosporidium andersoni in 21 and Cryptosporidium bovis in 3 samples. Neither mixed infections nor Cryptosporidium ryanae was detected. Sequencing of the GP60 gene from C. parvum-positive samples revealed all five subtypes of family IIa (A15G2R1, A16G1R1, A22G1R1, A18G1R1, and A15G1R1). The obvious management-associated distribution of Cryptosporidium spp. was demonstrated. Direct contact with adult animals was found to be a risky factor for C. andersoni and C. bovis infection. IIaA15G2R1 and IIaA16G1R1 were detected as major subtypes, whereas only the IIaA16G1R1 subtype was found in animals kept in boxes. Three of the five detected subtypes were previously associated with human cryptosporidiosis, and moreover, the IIaA15G1R1 subtype, previously reported in humans only, was detected in calves for the first time.     

Responses of apple fruit size to tree water status and crop load

The combined effects of irrigation rate and crop load on apple yield and fruit size were examined in two commercial apple orchards (cv. Golden Delicious) in a semi-arid zone. The irrigation rates applied were 1, 3 and 7 mm day(-1), and the two fruit thinning treatments involved adjusting crop load to 100 and 300 fruits per tree at Ortal and 50 and 150 fruits per tree at Matityahu. Unthinned trees served as the control. The fruit from each tree was picked separately, and fruit size distribution was determined with a commercial grading machine. Midday stem water potentials varied from -0.9 to -2.8 MPa, crop load varied from 80,000 to 1,900,000 fruit ha(-1) and crop yield varied from 10 to 144 Mg ha(-1). Midday stem water potential decreased with increasing crop load in all irrigation treatments at Matityahu, but only in the 1 mm day(-1) treatment at Ortal. The extent of the lowering of midday stem water potential by crop load decreased with increasing soil water availability. At both orchards, a similar response of total crop yield to crop load on a per hectare basis was observed. Mean fruit mass and relative yield of fruit > 70 mm in diameter increased with midday stem water potential, with the low crop loads having similar but steeper slopes than the high crop load. The responses of mean fruit mass and relative yield of fruit > 70 mm in diameter to midday stem water potential were similar at both orchards, perhaps indicating that thresholds for irrigation scheduling are transferable to other orchards within a region. Factors that may limit the transferability of these thresholds are discussed.     

Irrigation influences on growth, yield, and water use of persimmon trees

A 3-year irrigation trial provided basic information on the response of persimmon (Diospyros kaki cv. Triumph) water use and development to irrigation levels. Constant experimental factors applied to recommended “baseline” crop factors resulted in ratios of irrigation (I) to FAO56 reference crop evapotranspiration (ET₀) ranging from 0.35 to 1.14. Vegetative and reproductive growth, sap flow, stem water potential (SWP), and local climate were monitored. An overall increase in yield and vegetative growth in response to irrigation was found, which suggests a potential yield increase for higher irrigation levels (40 tons/ha for annual irrigation of 1,000 mm). At high irrigation, the yield response curve levelled off and the marginal contribution of additional water declined. The up to threefold increase in number of fruits with irrigation, with no influence on natural abscission, suggests that differences in fruit quantities stem from response to irrigation at the earlier growth stages. Mean fruit size and fruit quality, as indicated by the ratio of rejected fruit, increased with irrigation up to I/ET₀ of ~0.8. Relative yield increased linearly with relative transpiration. However, post-harvest quality was not influenced. SWP, sap flow, and non-transpirable water fractions indicated that the seasonal irrigation tables were not well tuned. Initial adjustments were made during the final season of the experiment and a new table was developed based on our results. The new table should be a basis for further trials.     

Tight regulation of allene oxide synthase (AOS) and allene oxide cyclase-3 (AOC3) promote <Emphasis Type="Italic">Arabidopsis</Emphasis> susceptibility to the root-knot nematode <Emphasis Type="Italic">Meloidogyne javanica</Emphasis>

Biosynthesis of the oxylipin jasmonic acid (JA) in Arabidopsis thaliana is catalyzed by a single allene oxide synthase (AOS)-encoding gene and four genes encoding four functional allene oxide cyclase (AOC) polypeptides (AOC1, AOC2, AOC3, and AOC4). To elucidate the biological activities of the JA pathway in regulating the plant defense response to plant-parasitic nematodes, transgenic lines carrying the GUS reporter gene under the control of individual AOC or AOS promoters were examined. Upon penetration by second-stage juveniles (J2 s), promoter activities of AOC1, AOC3 and AOC4 appeared in the root tip and root-elongation zone, with AOC3 demonstrating highest induction. At 5 days AOC3 activity continued to be highly pronounced in the stele and root cortex, associated with nematode invasion throughout gall initiation and maturation. AOS expression appeared 3 days postinfection and accompanied all later infection stages. Mutant lines were analyzed: disruption in AOS rendered plants more resistant to nematode infection, as reflected by the decreased number of females produced on this line; loss-of-function of AOC3 rendered plants more susceptible to nematode infection. Oxylipins derived from the 9- and 13-lipoxygenase pathways were assayed for their direct inhibitory activity toward M. javanica J2 s. Clear nematicidal activity of the bioactive 9- and 13-hydroperoxides was observed. Oxylipins produced by divinyl ether synthase, colneleic acid, colnelenic acid and ω5(Z)-etherolenic acid demonstrated strong inhibitory activity. These data, along with those of other assayed oxylipins, suggest that temporal and spatial fine tuning of the JA route allowing nematodes parasitism on plant host.     

CD44 is highly expressed on milk neutrophils in bovine mastitis and plays a role in their adhesion to matrix and mammary epithelium

Mastitis, inflammation of the mammary gland, is a common and economically important disease in dairy animals. Mammary pathogenic organisms, such as Escherichia coli, invade the teat canal,milk ducts, and mammary alveolar space, replicate in mammary secretions, and elicit a local inflammatory response characterized by massive recruitment of blood polymorphonuclear neutrophil leukocytes (PMN) into the alveoli and milk ducts. CD44 is a trans-membrane glycoprotein previously shown to play a role in mediation and control of blood PMN recruitment in response to inflammatory signals. Here we show, for the first time, increased expression of CD44 on recruited milk PMN in bovine mastitis and the expression of a CD44 variant, CD44v10, on these PMN. Furthermore, we demonstrate that CD44 mediates specific adhesion of bovine blood PMN to hyaluronic acid and mammary epithelial cells. Our results suggest that in mastitis CD44 plays a role in recruiting blood PMN into the mammary glands, the exact nature of this role needs to be elucidated.     

The inherent variability of water stress indicators in apple, nectarine and pear orchards, and the validity of a leaf-selection procedure for water potential measurements

The following two topics were examined: (1) The variability in the measurement of leaf water potential (LWP), stem water potential (SWP), maximum daily trunk shrinkage (MDS), and soil water tension (SWT) in apple, nectarine and pear orchards; and (2) The validity of a leaf-selection procedure for SWP measurements in commercial apple orchards. 27 trees were selected in an apple orchard, 27 in a nectarine orchard, and 30 in a pear orchard. The trees were close to each other. The measurements comprised of: midday SWP in apple, nectarine and pear; midday LWP in apple; MDS in apple and nectarine; and SWT in pear. The mean and standard errors (SEs) of each water status indicator in each species were calculated for an increasing sample size. The sample sizes required for stable averages were: SWP – 4, 5, and 8 trees for apple, nectarine and pear, respectively; MDS – 17 and 16 trees for apple and nectarine, respectively; SWT – 21 for pear trees. The relative SEs (i.e. percent of population mean) were 2.4, 6.1 and 10.1% in SWP/LWP, MDS and SWT, respectively. Possible explanations for the differing variability of the various water status indicators are discussed. The results show that smaller samples were sufficient to represent SWP and LWP properly than what was required for MDS and SWT. 9 commercial apple plots were selected and about 25 randomly selected leaves were used for midday SWP measurements in each plot (i.e. experimental sets). About 5 leaves on closely adjacent “representative” trees were selected in each of the commercial plots (i.e. commercial sets) and midday SWP was measured. The average difference in SWP between the experimental and the commercial sets was –0.127 MPa. The choice of closely adjacent trees increased the deviation from the experimental sets. The use of a reasonable sample size (n=7) may enable midday SWP to be measured within ±0.15 MPa in most commercial orchards.