Organic or conventional production system and nutrient rate affect the nematode community in carrot production.

Organic and conventional production are common in horticulture crops and each system may exert a different influence on the soil ecosystem, particularly the nematode community. Crop nutrient rate is an important choice in both production systems. The objectives of this study were to assess the impacts of (i) organic and conventional production systems and (ii) nutrient rate in both systems on the nematode community in carrot production. To investigate these objectives, field studies in organic and conventional production - which included fumigation with 1,3-dichloropropene - were conducted in North-Central Florida. In both production systems, nutrient rate treatments were 168, 224, 280, 336, and 392 kg N/ha. Poultry litter was the nitrogen source in organic production whereas synthetic, inorganic fertilizer was used in conventional production. All nematode trophic groups were consistently more abundant in organic than conventional production. The nematode community was more diverse and had greater trophic structure in organic production. Greater rates of organic nutrients increased enrichment opportunists (bacterivores and fungivores), but inconsistently across years. Conventional production had similar results except that only moderate nutrient rates increased fungivore abundances. Extreme enrichment opportunists (Rhabditis spp.) drove bacterivore trends in organic production whereas moderate enrichment opportunists (Cephalobus spp.) drove trends in conventional production. Nutrient rates did not affect omnivore-predators, herbivores, nematode community diversity, or structure in either system. In summary, type of production system, organic or conventional, exerts a strong influence on the nematode community, but nutrient rate has less consistent effects in horticulture production.

First Report of Cucurbit Chlorotic Yellows Virus affecting Watermelon in USA.

Watermelon (Citrullus lanatus) is a high nutrient crop, high in vitamins and very popular in the U.S and globally. The crop was harvested from 101,800 acres with a value of $560 million in the U.S (USDA-NASS, 2020). California, Florida, Georgia and Texas are the four-leading watermelon-producing states in the U.S. During the fall season of 2020, plants in two North Florida watermelon fields, one in Levy County (~20 acres) and one in Suwannee County (~80 acres) with varieties Talca and Troubadour, respectively, exhibited viral-like symptoms. The fields had 100% disease incidence that led to fruit quality issues and yield losses of 80% and above. Symptoms observed in the watermelon samples included leaf crumpling, yellowing and curling, and vein yellowing similar to that of single/and or mixed infection of cucurbit leaf crumple virus (CuLCrV; genus: Begomovirus, family: Geminiviridae), cucurbit yellow stunting disorder virus (CYSDV; genus: Crinivirus, family: Closteroviridae) and squash vein yellowing virus (SqVYV; genus: Ipomovirus, family: Potyviridae), although the vine decline symptoms often associated with SqVYV infection of watermelon were not observed. All three viruses are vectored by whiteflies and previously described in Florida (Akad et al., 2008; Polston et al., 2008; Adkins et al., 2009). To confirm the presence of these viruses, RNA was isolated from 20 symptomatic samples using the RNeasy Plant Mini Kit (Qiagen, USA) as per protocol. This was followed by RT-PCR (NEB, USA) using gene-specific primers described for CuLCrV, CYSDV and SqVYV (Adkins et al., 2009). Amplicons of expected sizes were obtained for all the viruses with the infection of CuLCrV in 17/20, CYSDV in 16/20, and SqVYV in 8/20 samples. In addition, the presence of cucurbit chlorotic yellows virus (CCYV; genus: Crinivirus, family: Closteroviridae) in mixed infection was confirmed in 4/20 samples (3 leaves and 1 fruit) by RT-PCR with primers specific to the CCYV coat protein (CP), heat shock protein 70 homolog (HSP70h) and RNA dependent RNA polymerase (RdRp) designed based on the available CCYV sequences (Sup Table. 1). The RT-PCR amplification was performed using a symptomatic watermelon sample and the amplicons of RdRp, HSP70h and CP were directly sequenced by Sanger method, and the sequences of the amplicons were deposited in GenBank under the accession number: MW527462 (RdRp, 952 bp), MW527461 (HSP70h, 583 bp) and MW527460 (CP, 852 bp). BLASTn analysis demonstrated that the sequences exhibited an identity of 99% to 100% (RdRp and HSP70h, 100%; and CP, 99%) with the corresponding regions of the CCYV isolate Shanghai from China (accession number: KY400636 and KY400633). The presence of CCYV was further confirmed in the watermelon samples by ELISA (Loewe, Germany) using crude sap extracted from the RT-PCR-positive, symptomatic watermelon samples. CCYV was first identified in Kumamoto, Japan in 2004 on melon plants (Gyoutoku et al. 2009). The CCYV was previously reported on melon from Imperial Valley, California (Wintermantel et al., 2019), and more recently on squash in Tifton, Georgia (Kavalappara et al., 2021) and cantaloupe in Cameron, Texas (Hernandez et al., 2021). To our knowledge, this is the first report of CCYV on field watermelon production in the U.S. Continued monitoring of the CCYV in spring and fall watermelon crop, and cucurbit volunteers and weeds will be critical toward understanding the spread of this virus and its potential risk to watermelon in Florida and other regions of the U.S.

Wireworm (Coleoptera: Elateridae) Species Composition and Management in Sweet Potato Grown in North Florida Using Chemical Insecticides and Entomopathogenic Nematodes.

Wireworms are immature stages of click beetles (Coleoptera: Elateridae) and are considered a serious threat to sweet potato production in the southern United States. The major wireworm species collected in North Florida sweet potato fields in 2017 and 2018 were Conoderus scissus, C. rudis, C. amplicollis, and C. falli. These species vary in their behavior and biology. During a 2-yr study period, we conducted two insecticide field trials using eleven insecticides belonging to organophosphates, neonicotinoids, pyrethroids, and botanical classes, and three field trials using entomopathogenic nematode (EPN) species to control wireworms. In 2017, all insecticide treatments significantly reduced new feeding holes and total holes (old + new + other) as compared to the untreated control. In 2018, the result was similar with a few variations. In both years, all insecticides showed a percentage reduction in wireworm damage holes (2017: 34.88-96.19%; 2018: 12.38-97.02%) with the highest by Regent. In the EPN field study, one application of EPN near planting significantly reduced soil insects. In a laboratory study conducted at the Tropical Research and Education Center, UF-IFAS, chlorpyrifos caused higher percentage mortality of C. rudis (55.5%) than C. scissus (22.2%). At the present experiment rates, none of the insecticides caused the mortality of C. amplicollis. Heterorhabditids strain 'FL-2122' was more susceptible to chlorpyrifos than other strains of EPN.

Membrane tethers formed from blood cells with available area and determination of their adhesion energy.

Fundamental to all mammalian cells is the adherence of the lipid bilayer membrane to the underlying membrane associated cytoskeleton. To investigate this adhesion, we physically detach the lipid membrane from the cell by mechanically forming membrane tethers. For the most part these have been tethers formed from either neutrophils or red cells. Here we do a simple thermodynamic analysis of the tether formation process using the entire cell, including tether, as the control volume. For a neutrophil, we show that the total adhesion energy per unit area between lipid membrane and cytoskeleton depends on the square of the tether force. For a flaccid red cell, we show that the total adhesion energy minus the tension in the spectrin cytoskeleton depends also on the square of the tether force. Finally, we discuss briefly the viscous flow of membrane. Using published data we calculate and compare values for the various adhesion energies and viscosities.

Experimental studies of membrane tethers formed from human neutrophils.

Membrane tethers (thin, cylindrical pieces of membrane) have been implicated in the rolling of neutrophils along the endothelium. In our studies, these tethers were formed from passive, stimulated (0.1 microM fMLP), and osmotically swollen (170-180 mOsm) human neutrophils; as well as neutrophils treated with 0.3 microM latrunculin A to disrupt the cytoskeleton. This tether formation was accomplished by micropipette suction of latex beads coated with antibodies to proteins on the neutrophil membrane surface. From plots of force versus velocity for the tether formation process, we calculated adhesion energies per unit area of the lipid membrane to the cytoskeleton and the viscous resistance (effective viscosity) that occurs during the formation of these tethers at finite velocity. Most of the properties of the neutrophil were altered once it had been treated as described above. We were also able to show mechanical reversibility of membrane tethers, as well as an unexpected formation rate at "high" tether forces. Since membrane tethers have been implicated in the rolling of neutrophils, then the changes in tether formation may ultimately alter how these cells roll.