Effects of Heterospecific Pollen From a Wind-Pollinated and Pesticide-Treated Plant on Reproductive Success of an Insect-Pollinated Species

Arceo-Gómez, Gerardo, Jameel, Mohammad I., Ashman, Tia Lynn

01 May 2018

Premise of The Study: Studies on the effects of heterospecific pollen (HP) transfer have been focused mainly on insect-pollinated species, despite evidence of insect visitation to wind-pollinated species and transfer of their pollen onto stigmas of insect-pollinated plants. Thus, the potential consequences of HP transfer from wind-pollinated species remain largely unknown. Furthermore, accumulation of pesticide residues in pollen of wind-pollinated crops has been documented, but its potential effects on wild plant species via HP transfer have not been tested. Methods: We evaluated the effect of wind-dispersed Zea mays pollen on pollen tube growth of the insect-pollinated Mimulus nudatus via hand pollinations. We further evaluated whether pesticide-contaminated Z. mays pollen has larger effects on M. nudatus pollen success than non-contaminated Z. mays pollen. Key Results: We found a significant negative effect of Z. mays pollen on M. nudatus pollen tube growth even when deposited in small amounts. However, we did not observe any difference in the magnitude of this effect between pesticide-laden Z. mays pollen and non-contaminated Z. mays pollen. Conclusions: Our results suggest that wind-pollinated species can have negative effects as HP donors on insect-pollinated recipients. Thus, their role in shaping co-flowering interactions for wind- and insect-pollinated species deserves more attention. Although we did not find evidence that pesticide contamination increased HP effects, we cannot fully rule out the existence of such an effect, because pollen load and thus the pesticide dose applied to stigmas was low. This result should be confirmed using other HP donors and across a range of HP loads, pesticide types, and concentrations.

heterospecific pollen

Mimulus nudatus

neonicotinoids

pesticide spillover

pesticides

pollinator sharing

wind-pollination

Zea mays

Biological Sciences

Effects of nitric oxide and hydrogen peroxide on antioxidant enzyme activity in zea mays subjected to drought

Kopana, Nolusindiso

January 2021

>Magister Scientiae - MSc / Agricultural practices are significantly affected by drought. Drought is one of the most important plant stresses, causing several physiological, morphological, biochemical, and molecular changes in plants. Drought stress is of great challenge for crop growth, development and yield. Zea mays (maize) is one of the important crops worldwide due to the nutritional profile and other uses such as human consumption, manufacturing and animal feed. Under unfavorable conditions, plants produce high amounts of reactive oxygen species (ROS). Excessive formation of ROS is harmful for plant survival and can induce cell death. Defense mechanisms activated in response to drought in plants include antioxidant enzyme activity and proline accumulation. There is evidence of the use of nitric oxide (NO) donors and hydrogen peroxide (H2O2) at low concentrations to enhance the activity of antioxidant enzymes in stressed plants. Hence, the aim of the study is to examine the role of NO and H2O2 in regulation of antioxidant enzyme activity in maize subjected to water deficit. / 2023

Zea mays

Reactive oxygen species

Nitric oxide

Drought stress

Antioxidant enzyme

Impact of Corn Earworm on Field Corn Yield and Grain Quality

Bibb, Jenny Lee

11 December 2015

Field corn, Zea mays L., has been introduced to the market with pyramided Bacillus thuringiensis (Bt) corn technologies. These technologies reduce kernel damage from ear feeding caterpillar pests, including corn earworm, Helicoverpa zea (Boddie). The first generation Bt traits in field corn demonstrated limited activity on corn earworm feeding on grain in ears. The pyramided corn technologies have greater cumulative protein concentrations and improved expression throughout the plant, so these corn traits should provide an effective management tool against these pests. In addition, reduced kernel injury may also have a direct effect on physical grain quality. The results for this trial showed no relationship between number of damaged kernels and yield was observed for corn hybrid expressing the Herculex®, YieldGard®, or Genuity VT Triple Pro® technologies. A significant relationship between both damaged kernels and test weight and damaged kernels and aflatoxin concentrations was observed in two technologies.

Bt

grain quality

yield

Zea mays

corn

Helicoverpa zea

corn earworm

Improving Phosphorus Use Efficiency Through Organically Bonded Phosphorus

Hill, Micheal W

07 December 2012

Current maximum efficiency of phosphorus (P) fertilizers that is utilized by plants in the same year of application ranges from near zero to thirty percent. Despite low utilization of P in crop production, yields are often limited by P deficiencies. Innovative technology is requisite to achieve greater efficiency as fertilizer demands are increasing, while phosphorus mineral resources are rapidly being depleted. A growing environmental concern for nutrient pollution of surface waters also carries significant weight. A novel new product, Carbond® P, is promising technology to increase P use efficiency. Research is needed to understand its capabilities and the functioning mechanisms imbedded within its technology. Several research studies were conducted to evaluate Carbond® P (CBP) against traditional fertilizers ammonium polyphosphate (APP) and monoammonium phosphate (MAP). A soil column leaching study was conducted to determine P mobility through three soils, at two rates (20 and 30 kg P ha-1) in either a banded or mixed soil application. Mobility of P was evaluated at 24, 48, 110 and 365 d after fertilization. CBP showed significantly greater total P leachate values across all soil types and application rates averaged across all readings taken until 365 daf for both application types. In the banded applications, CBP generally produced significantly greater solubility than MAP or APP up until 110 daf. For applications mixed with soil, CBP and MAP had greater solubility than APP at 24 days after application, but by the later evaluation dates (48 and 110 daf) the CBP was significantly higher than both MAP and APP. No statistical significance was found in the leachate P 365 daf in either the banded or mixed applications. One glasshouse study on maize (Zea mays L.) grown in three soils were conducted at 0, 5, 10, 20, 40, 80, and 160 kg P ha-1 comparing CBP and APP fertilizer impacts on early season growth. CBP produced significantly more biomass in two soils when averaged across rates (and at the 20 kg P ha-1 rate in a third soil), increased petiole P in one soil and thicker stems in another. Two field trials showed similar physiological advantages with CBP over APP at later growth stages. CBP maize responded with significantly more biomass and P uptake at the V12-V18 growth stages in one field, as well as plant height in another. At the R2-R3 growth stages, CBP also produced thicker stalks in both fields than APP. These growth enhancements were strongest in medium to highly calcareous soil (6-12 %) low in P (7 mg kg-1). These observations warrant the use of CBP and further investigation to understand its benefits and limitations.

phosphorus

P

organic acid

Carbond P

maize

Zea mays

fertilizer

phosphorus use efficiency

PUE

Animal Sciences

The Bacterial AvrE-Family Type-III Effector Proteins Modulate Plant Immunity via Targeting Plant Protein Phosphatase 2A Complexes

Jin, Lin

07 September 2016

No description available.

Plant Pathology

Molecular Biology

Some Aspects of Proline Metabolism During Germination in Zea Mays

Barnard, Anne Ruth

January 1968

Master of Science (MSc)

proline metabolism

germination

Zea mays

Biology

Long-term copper availability and adsorption in a sludge-amended Davidson clay loam

Anderson, Martha Ann

02 October 2007

A single application of aerobically digested sewage sludge was applied by Rappaport et al. (1988) in 1984 at rates up to 210 dry Mt ha⁻¹ on a Davidson clay loam (clayey, kaolinitic, thermic, Rhodic KandiuduIts). The heavily contaminated sludge supplied up to 760 kg Cu and 620 kg Zn ha⁻¹, which are below current cumulative limits, but above annual loading limits for these metals (USEPA, 1993). Rappaport et al. (1988) reported an increase in DTPA extractable Cu and Zn with increasing sludge rate. They observed a linear increase in com yields with an increase in sludge rate, which was attributed to high levels of available N supplied by the sludge. In the present residual study, conducted at the same research site, DTPA extractable Cu and Zn followed the trend observed by Rappaport et at. (1988). However, a linear decrease in corn and sorghum yields was observed with increasing sludge rate. The sludge-related decrease in yields was attributed to phytotoxicity (probably a combination of Al, Cu, Mn, and Zn) induced by low soil pH levels. Whole plant tissue concentrations of eu and Zn at the high sludge rates were above the normal range, however grain concentrations were within the normal range. An adsorption study was conducted, in which soils were amended with Ca(OH)₂ and Al₂(S0₄)₃, to ascertain the effect of decreased pH on Cu adsorption on the soil. Copper adsorption maxima decreased with a reduction in soil pH in all treatments. The effect of ionic strength on Cu adsorption was also investigated. Regardless of pH or ionic strength, Cu adsorption increased with an increase in sludge rate. This adsorption increase was attributed to the higher organic matter content of the sludge treatments. The organic matter at the highest sludge rate was approximately double that of the control after 11 years. The adsorption study shows that sludge amendment has long-term effects on metal retention in soils and the field study reveals that careful management of sludge-amended soils is necessary to prevent phytotoxicity. / Ph. D.

adsorption

zinc

sludge

copper

Zea mays L.

LD5655.V856 1997.A534

The role of cover crops in agroecosystem functioning

Seman-Varner, Rachel Nicole

22 November 2016

Current interest in cover cropping is focused on enhancing ecosystem services beyond soil conservation. Cover crop (CC) species function uniquely in their effects on ecosystem services when grown in monoculture or mixtures. This research integrated field experiments and a literature synthesis to evaluate the role of cover crops in improving nitrogen (N) management and simultaneously providing multiple ecosystem services. Legume CC fertilized with poultry litter (PL) could replace 101 to 117 kg N ha-1 of fertilizer in corn (Zea mays L.) production. Rye (Secale cereale L.) CC fertilized with PL had a negligible effect on corn production. Biculture fertilizer equivalence ranged between -12 to +75 kg N ha-1. Fertilizer equivalence of legume-containing treatments increased across time. Without CC, fall-applied PL failed to supply N to corn. Ecosystem services of CC and PL illustrate complex species functions. Bicultures produced more total biomass than monocultures in year 1 but less than rye in year 2. Bicultures were as effective in suppressing weeds as rye, produced corn yield similar to legume, and by the second year had similar amounts of available soil N as the legume. Poultry litter effects and interspecific effects cover crop species biomass differed. Rye yield increased, while legume yield decreased slightly in biculture. Poultry litter increased legume N content and a decrease in legume C:N, while rye N content and C:N were unaffected. The synthesis corroborates that mixed and biculture cover crops yield more than the individual component species. Overyielding was transgressive in 60% of cases studied. Mixture effects varied by species: rye and brassica yield increased, while legume decreased in mixtures. The effect of mixed CC on crop yields varied by crop species and management practices, though generally crops increased 8 to 18% overall. This work can be applied to the design of complex CC and PL systems that optimize individual species functions to enhance ecosystem services. / Ph. D.

cover crop

N conservation

corn

Zea mays

fertilizer equivalence

N credits

rye

hairy vetch

Stink bug-Fusarium interactions and mitigation of associated mycotoxin contamination of corn in the mid-Atlantic, U.S.

Opoku, Joseph

22 May 2020

Stink bugs, including native brown stink bug (Euschistus servus) and invasive brown marmorated stink bug (Halyomorpha halys), cause damage to a variety of crops including field corn (Zea mays). Frequency and size of stink bug infestations have increased in corn fields in the Mid-Atlantic U.S., and there are growing concerns that these infestations may contribute to reductions in grain quality including increased mycotoxin concentrations. Prior research on native and invasive stink bugs has focused on understanding their biology, the damage they cause, and elucidating effective and economic management strategies. However, few studies examined the potential for stink bugs to facilitate fungal infection and mycotoxin contamination of corn grain. Thus, the objectives of this research were to: 1) assess the relationship between invasive brown marmorated stink bug (H. halys) feeding injuries and fumonisin contamination of field corn in the Mid-Atlantic U.S., 2) determine if stink bugs are a vector for mycotoxigenic Fusarium spp. in corn, and 3) evaluate the efficacy of pesticides for mitigating stink bug feeding injury and associated mycotoxin contamination in field corn. A correlation between H. halys feeding injury and fumonisin concentrations was identified, and the ability of H. halys to increase F. verticillioides infection and fumonisin concentrations in corn was demonstrated in field experiments. Fusarium species including fumonisin-producing F. verticillioides and F. proliferatum were isolated from field-collected stink bugs, and in laboratory experiments, E. servus was able to transmit F. verticillioides to non-infected corn ears after feeding on F. verticillioides-infected corn. In field studies, both fungicide and insecticide reduced stink bug-associated mycotoxin concentrations in corn, but levels of control were inconsistent. Thus, additional tactics that target both the stink bug and Fusarium should be implemented to mitigate risks of mycotoxin contamination in corn. / Doctor of Philosophy / Native and invasive stink bugs can severely damage crops including field corn. Frequency and size of stink bug infestations in Mid-Atlantic U.S. corn fields have increased, and there is growing concern that this may contribute to reductions in grain quality. Insect feeding injury is a risk factor for fungal infection and mycotoxin contamination in corn. Mycotoxins are toxic chemicals produced by certain fungi that have detrimental health effects on animals including livestock and humans. The relationship between stink bug feeding injuries and mycotoxin contamination in corn grain is not well understood, and management strategies to minimize the risk of mycotoxin contamination in corn need to be identified. The main goal of this research was to characterize interactions between stink bugs and mycotoxin-producing fungi and identify tactics for controlling both the insect pest and pathogen. Specific objectives were to: 1) assess the relationship between invasive brown marmorated stink bug (H. halys) feeding injuries and fumonisin contamination of field corn in the Mid-Atlantic U.S., 2) determine if stink bugs are a vector for mycotoxin-producing Fusarium spp. in corn, and 3) evaluate the efficacy of pesticides for mitigating stink bug feeding injury and associated mycotoxin contamination in field corn. Results from this work indicated that stink bugs have the ability to cause feeding injuries which facilitate invasion of mycotoxin-producing Fusarium species, leading to increases in mycotoxin concentrations in corn grain. Studies also demonstrated that stink bugs can vector Fusarium species during feeding and increase Fusarium infection of corn resulting in subsequent mycotoxin contamination. Field studies indicated that pesticide applications targeting both the stink bugs and mycotoxigenic fungi may be needed to minimize risk of mycotoxin contamination in corn. However, under low pest pressure, application of pesticides is unlikely to be profitable.

Halyomorpha halys

Euschistus servus

Zea mays

ear rot

Fusarium verticillioides

Fusarium proliferatum

Fusarium graminearum

fumonisin

aflatoxin

<b>Assessment of corn yield and physiological performance via fungicide placement and intensive management strategies</b>

Malena Bartaburu Silva (19260820)

31 July 2024

<p dir="ltr">In response to fluctuating corn (<i>Zea mays</i> L.) prices, climatic variability, and emerging diseases, farmers are increasingly adopting diverse and intensive management practices to enhance yield and profitability. This research investigates the performance of various inputs and management practices on corn production across multiple site-years, with a focus on yield components, grain fill duration, kernel development, disease severity, and economic outcomes. A multi-state research trial was established to evaluate the impact of seven inputs and management practices across multiple locations and environments in Indiana, Kentucky, and Michigan in 2022 and 2023. Each location included eight treatments: 1) control treatment (C) based on Purdue University seed rate and nitrogen (N) fertilizer recommendations (Camberato et al., 2022; Nielsen et al., 2022): 30K seeds per acre and N fertilizer application as starter (2x2) and V5 growth stage sidedress. Total N rates ranged between 180 and 200 lbs N per acre and agronomic optimum nitrogen rates (AONR) were used, 2) C + banded (2x2) fungicide, 3) C + 20% increase in corn seeding rate, 4) C + sulfur (S) fertilizer, 5) C + foliar micronutrients, 6) C + late-season N fertilizer application (V10-12 growth stage), 7) C + R1 foliar fungicide, and 8) intensive treatment (all additional inputs/management practices applied). The intensive treatment significantly increased yield by 16.4 and 18.4 bu ac^-1 in 2022 and 2023, respectively when compared to the control across locations, but did not enhance net profit across multiple corn price scenarios due to high application costs. Conversely, R1 fungicide applications increased yield by 16.2 and 16.7 bu ac^-1 in 2022 and 2023, respectively, and S applications increased yield by 12.9 bu ac^-1 in 2023, when compared to the control, with both treatments improving net profit under multiple corn price scenarios. In addition, kernel development studies in West Lafayette, IN, during 2022 and 2023 revealed that banded fungicide applications at planting and foliar fungicide applications at the R1 growth stage can reduce leaf disease severity by 3.2% to 6.6%, extend grain fill duration by 3.5 to 4.5 days, and increase maximum dry kernel weight at plant maturity by 5.7 to 9.4%, respectively, leading to further insights into the yield response mechanisms. Furthermore, a meta-analysis of 24 at-plant flutriafol fungicide placement trials across Indiana (2020 – 2023) highlighted the effectiveness of at-plant fungicides, with banded (2x2 or 2x0) applications leading to the highest yield increase of 7.8 bu ac^-1 and both banded and in-furrow applications reducing disease severity on corn ear leaves at the R5 growth stage by 2.1 - 2.3% when compared to the control. These findings suggest both at-plant banded and R1 foliar fungicide applications have the potential to reduce disease severity, extend corn grain fill duration, and improve yield when conditions are conducive for a response (e.g., foliar disease presence). Overall, this research highlights the ability of targeted input applications for improving both corn yield and profitability when examined across diverse environments and locations, rather than prophylactic applications of multiple inputs and increased management intensities.</p>

Agronomy

zea mays

fungicide

corn yield

fungicide placement

sulfur

micronutrients

grain filling period