Field Evaluation of Experimental Maize Hybrids for Resistance to the Fall Armyworm (Lepidoptera: Noctuidae) in a Warm Temperate Climate
by
, , , , and
Xinzhi Ni
1,*
,
Alisa Huffaker
2,
Eric A. Schmelz
2,
Wenwei Xu
3,
W. Paul Williams
4,
Baozhu Guo
1
,
Xianchun Li
5
and
Fangneng Huang
6 1
United States Department of Agriculture-Agricultural Research Service, Crop Genetics and Breeding Research Unit, Tifton, GA 31793, USA
2
Division of Biological Science, University of California-San Diego, La Jolla, CA 92093, USA
3
Agricultural Research & Extension Center, Texas A&M AgriLife Research, Texas A&M University System, Lubbock, TX 79403, USA
4
United States Department of Agriculture-Agricultural Research Service, Corn Host Plant Resistance Research Unit, Mississippi State, MS 39762, USA
5
Department of Entomology, University of Arizona, Tucson, AZ 85721, USA
6
Department of Entomology, Louisiana State University Agricultural Center, Baton Rouge, LA 70803, USA
*
Author to whom correspondence should be addressed.
Insects 2024, 15(4), 289; https://doi.org/10.3390/insects15040289
Submission received: 5 February 2024
/
Revised: 22 March 2024
/
Accepted: 7 April 2024
/
Published: 19 April 2024
(This article belongs to the Collection Integrated Pest Management of Crop)
Abstract
:Simple Summary
To develop new maize germplasm, and understand the genetic basis of fall armyworm resistance, 12 experimental hybrids (six sets of reciprocal crosses) with diverse genetic backgrounds were compared with four commercial checks. Reciprocal crosses (an inbred line was used in a pair of crosses as male and female parents) were used to determine the maternal effect of an inbred line on fall armyworm resistance. Fall armyworm resistance was assessed using its injury ratings on artificially infested maize plants, and possibly plant attraction to predators of the fall armyworm larvae. Two reciprocal crosses (‘FAW1430’ × ‘Oh43’ and ‘CML333’ × ‘NC358’) showed the least fall armyworm injury. A total of 11 taxa of predators (five lady beetles and five other insect predators, and spiders) were recorded. However, the number of predators was not negatively correlated to fall armyworm injury. The predator data also varied greatly between the two years when the experiment was conducted. In addition, both parents contributed similarly and no maternal effect on fall armyworm resistance was detected.
Abstract
The polyphagous fall armyworm (FAW), Spodoptera frugiperda, has become an invasive pest worldwide in recent years. To develop maize germplasm with multiple pest resistance and understand genetic inheritance, 12 experimental hybrids (six pairs of reciprocal crosses) with diverse genetic backgrounds and four commercial checks were examined for FAW resistance in 2013 and 2014. The experiment utilized a randomized complete block design with four replications as the block factor. FAW injury on maize plants was assessed at 7 and 14 d after the artificial infestation at the V6 stage, and predatory arthropod taxa and abundance on maize seedlings were recorded 7 d after the infestation. Spodoptera frugiperda resistance varied significantly among the 16 hybrids. Two reciprocal crosses (‘FAW1430’ × ‘Oh43’ and ‘CML333’ × ‘NC358’) showed the least FAW injury. Eleven arthropod predators [i.e., six coleopterans, three hemipterans, earwigs (dermapterans), and spiders (or arachnids)] were also recorded; the two most common predators were the pink spotted ladybeetle, Coleomegilla maculata, and the insidious flower (or minute pirate) bug, Orius spp. Predator abundance was not correlated to FAW injury but varied greatly between 2013 and 2014. Principal component analysis demonstrated that, when compared with FAW resistant (or Bt-transgenic) checks (‘DKC69-71’, ‘DKC67-88’, and ‘P31P42’), five pairs of the reciprocal crosses had moderate FAW resistance, whereas a pair of reciprocal crosses (‘NC350’ × ‘NC358’ and NC358 × NC350) showed the same FAW susceptibility as the non-Bt susceptible check ‘DKC69-72’. Both parents contributed similarly to FAW resistance, or no maternal/cytoplasmic effect was detected in the experimental hybrids.
1. Introduction
Biotic and abiotic stresses are the most important impediments to maize production in a warm temperate climate in the southern U.S. states. With exacerbation of the ongoing trend of climate change, the Midwest Corn Belt states are projected to become unsuitable for maize production by 2100 [1]. Maize germplasm that confers resistance to multiple biotic and abiotic stresses are of critical importance. Maize germplasm resistance to individual biotic (e.g., insect and disease) or abiotic (e.g., drought and heat) stress factors has been reported repeatedly, but only a relatively limited number of reports on developing germplasm lines resistant to multiple stress factors are available. Although studies have been conducted in recent decades to examine native resistance to multiple insect species in maize germplasm and hybrids [2,3,4,5,6], few studies have simultaneously examined resistance to both insects and diseases, and reduced mycotoxin contaminations. Of all biotic stresses in a warm temperate/sub-tropical climate, e.g., Tifton, GA (with GPS coordinates of 31.5° N and 83.5° W), in the southern USA, the fall armyworm (FAW) [Spodoptera frugiperda (J.E. Smith) (Lepidoptera: Noctuidae)] is an important foliar-feeding insect, and the corn earworm [Helicoverpa zea (Boddie) (Lepidoptera: Noctuidae)] and occasional S. frugiperda infestations are the key ear-feeding insects at the post-flowering stage. In particular, with climate change, development of maize germplasm lines with resistance to multiple biotic and abiotic stress factors and reduced aflatoxin contamination is not only critically important now to maize production in the southern U.S. states, but also significantly beneficial to future maize production in the northern states, e.g., the Midwest Corn Belt. This is because the biotic and abiotic stress factors currently present in the warm temperate/subtropical climate would likely be encountered by growers in the U.S. Midwest Corn Belt, and other maize production regions worldwide, in less than eight decades, or by 2100 [1].
One of the long-term goals for our research program has been to develop new maize germplasm with resistance to multiple biotic and abiotic stresses, reduced aflatoxin contamination, and good agronomic traits (e.g., yield potential). In addition, parental (maternal/paternal) contributions to insect resistance traits in a hybrid from each parental inbred line in maize could be critical, because resistance to different insect pests in maize can be inherited in different ways based on the literature related to host plant resistance to insects. Disease and insect susceptibility/resistance in crop plants varies with male or female parent, which is also used to assess maternal and cytoplasmic effect. The phenomenon of maternal and cytoplasmic effect has been reported in disease resistance in maize [7], rice [8], durum wheat [9], and olive [10]. Resistance to the southern corn leaf blight (Cochliobolus heterostrophus) and the yellow corn leaf blight (Mycosphaerella zeae-maydis) in maize was associated with the maternally inherited T (Texas source) of male-sterile cytoplasm [7]. However, maize resistance to the northern corn leaf blight, Helminthosporium turcicum, showed no maternal or cytoplasmic effect [11]. Similar phenomena were observed in insect resistance in maize. Pericarp of maize kernels did show a maternal effect in maize weevil resistance [12], but maysin and its analogs in maize that contribute to H. zea resistance did not show a maternal effect [13]. In addition, previous reports suggest a correlation among genes that confer resistance to multiple insects on maize, e.g., genes conferring resistance to foliar-feeding S. frugiperda and the southwestern corn borer, Diatraea grandiosella Dyar (Lepidoptera: Crambidae), and genes conferring resistance to ear-feeding European corn borer, Ostrinia nubilalis (Hübner) (Lepidoptera: Crambidae), and H. zea [2,14,15,16]. Also, tropical maize inbred lines ‘CML71’, ‘CML125’, ‘CML370’ and ‘CKSBL10008’, derived from multiple borer resistant inbred lines, demonstrated that CKSBL10008 and CML71 confer high levels of antibiosis to S. frugiperda [17].
Because our approach for new germplasm development has been to utilize both basic and applied research findings on maize germplasm improvement with resistance to multiple stress factors, the reciprocal crosses (as shown in Table 1) were designed and made in 2012 to develop germplasm lines with not only multiple pest resistance, but also to determine maternal and/or cytoplasmic contributions to multiple insect and disease resistance in these experimental hybrids. The experimental hybrids used eight inbred lines and two newly available maize inbred lines with tropical backgrounds (i.e., ‘CML528’ from CIMMYT, and FAW1430 from our program), and six parental inbred lines of the nested association mapping (NAM) populations (or NAM founders). These six NAM founders had high levels of phytoalexins, i.e., kauralexins [18] and zealexins [19]. At the same time, predator survey data were included for assessing negative correlations between the number of predators and plant injury ratings, which could possibly be used as an additional parameter for comprehensively assessing host plant resistance to insects [6,20]. However, the previous findings showed that the results varied greatly from year to year.
Using the 12 experimental hybrids (i.e., six sets of reciprocal crosses) and the four commercial hybrids as the checks (or controls), the four objectives of the current two-year study were to (1) determine S. frugiperda resistance and predator abundance among the hybrids; (2) determine the maternal effect on S. frugiperda resistance and predator abundance; (3) examine the correlation between S. frugiperda injury rating and predator abundance; and (4) identify the best experimental hybrids to be used for new germplasm development. While the results of the evaluation of S. frugiperda resistance in 2013 and 2014 are presented herein, the results of the evaluations of ear- and kernel-feeding insect and disease resistance, and yield, as well as the aflatoxin accumulation levels of these hybrids, will be reported separately in two other manuscripts (Ni et al., in review).
2. Materials and Methods
2.1. Parental Selection for the Breeding Crosses
A total of 12 (or six sets) of reciprocal breeding crosses were made in 2012 utilizing eight inbred lines with unique genetic backgrounds, as shown in Table 1. Of all parental inbred lines, ‘FAW1430’, an S. frugiperda-resistant inbred line (to be released) from our laboratory, is derived from a maize population ‘GT-FAWCC(C5)’, which had been released [22] and subsequently examined [25,26]. ‘CML528’ is a new tropical germplasm line selected from a set of 12 new releases (‘CML524’ − ‘CML535’) that our program procured in 2011 from the CIMMYT (Mexico City, Mexico).
The remaining inbred lines are the six NAM founders with relatively high levels of phytoalexins, i.e., kauralexins [18] and zealexins [19]. The four NAM founders (i.e., ‘B97’, ‘CML333’, ‘NC350’, and ‘NC358’) have relatively high levels of both kauralexins and zealexins. The fifth NAM founder ‘Oh43’ has a relatively high level of kauralexins, but a low level of zealexins [18,19], and Oh43 is also known to be S. frugiperda resistant with a high level of a trypsin inhibitor, or Bowman–Birk inhibitor [21]. The last NAM founder, ‘CML322’ with white kernels (for food corn), was also reported to have relatively low levels of both kauralexins and zealexins [18,19]. In addition, CML322 not only produced grains with consistently low levels of aflatoxin contamination [23], but also showed drought tolerance [27].
In addition, four commercial maize hybrids used as the checks (CKs) for the experiment were ‘DKC69-71’, ‘DKC69-72’, ‘DKC67-88’, and ‘P31P42’. DKC69-71 is a hybrid of the YieldGard Corn Borer® trait with transgenes of Bacillus thuringiensis (Bt), Cry1Ab, for lepidopteran pest control and Roundup Ready 2 (RR2) for herbicide resistance, while DKC69-72 is an isogenic non-Bt hybrid of DKC69-71. DKC67-88 is a hybrid of the Genuity® VT Triple PRO® traits containing two Bt transgenes (Cry1A.105/Cry2Ab2) for managing lepidopteran pests, one Bt gene (Cry3Bb1) for controlling underground coleopteran rootworms, and the RR2 gene for herbicide resistance. P31P42 is a hybrid of Herculex I trait possessing Cry1F Bt gene for controlling lepidopteran pests, and two herbicide resistance genes RR2 and LibertyLink® (LL). The first three hybrids were provided from Bayer Crop Science (formerly Monsanto, St. Louis, MO, USA), while P31P42 was from Corteva Agriscience (formerly Pioneer Hi-Bred International, Inc., Johnston, IA, USA).
2.2. Sources of Insects
The neonate larvae of S. frugiperda used in this study (in both 2013 and 2014) were from two laboratory colonies maintained at the Insectaries of the Corn Host Plant Resistance Research Unit, USDA-ARS, at Mississippi State, MS, USA and the former Plant Protection and Management Research Unit, USDA-ARS, at Tifton, GA. The S. frugiperda colony was established originally using insects collected from maize plants, and feral insects were collected and added annually to the colony to maintain insect colony performance. The larvae of S. frugiperda used in this study were considered as maize strain. All predators recorded in the experimental plots were attracted naturally by the maize seedlings at stages V6 (at the infestation) and V7 (7 d after the infestation) in the springs of 2013 and 2014, respectively.
2.3. Artificial S. frugiperda Infestation and Injury Rating at the Seedling (Whorl) Stage
The S. frugiperda infestation was established by manually infesting the whorl leaf tissue of all maize plants in an experimental plot at 6-leaf (V6) stage using a mixture of newly hatched neonate larvae and corn cob grits (F and S Equipment and Supplies Inc., Birmingham, AL, USA). The artificial infestation dates were 12 May 2013, and 20 May 2014. A modified procedure as previously described [28,29] was used for the artificial infestation of all plants in each experimental plot. Briefly, 25–35 neonate larvae per plant were used with Bazooka insect infestation apparatus. The number of insects (25–35) per 0.2 mL drop of the mixture was produced by a mixing ratio of 1 mL neonate larvae with 30 mL corn cob grits. The levels of insect injury were then rated at 7 and 14 d after the infestation using a modified visual rating scale of 1–9, as described previously [6,28,30]. The modified scale used for the S. frugiperda injury ratings is as follows: 1 = No injury or few pin-holes; 2 = Few short holes (also known as shot holes) on several leaves; 3 = Short holes or lesion up to 1.3 cm on several leaves; 4 = Loss of whorl, only top leaves with most short holes and a few long lesions (≤2.5 cm); 5 = Loss of whorl, only top leaves with more short than long lesions; 6 = Loss of whorl, only top leaves with long lesions; 7 = Loss of whorl, long lesions common on one half of the leaves, loss of portion of top leaves; 8 = Loss of whorl, long lesions common on one half to two thirds of leaves, loss of top leaves; 9 = Loss of whorl, most leaves with long lesions, and complete defoliation was observed. The visual insect injury rating was an overall rating of S. frugiperda injury on all plants in an experimental plot under the field conditions.
2.4. Predator Abundance Survey at the Seedling Stage
Both the taxa and abundance of predatory arthropods from each experimental plot were recorded 7 d after the initial S. frugiperda infestation, as described previously [6,20]. Data were collected (on 19 May 2013, and 27 May 2014) by careful visual observation of predators on all plants per single-row plot with minimal disturbance to predator activities. All recorded predators were identified according to their genus or species, except earwigs and spiders, which were also recorded as a single taxon, and no further taxonomic identification was performed in the current study. Total numbers of predators were then calculated. In addition, the numbers of predator taxa recorded on each hybrid entry were also compared to understand the predator diversity among the breeding crosses used in the experiment. Although parasitoids are often associated with S. frugiperda infestations in maize fields [31,32,33], few parasitoids were observed 7 d after the artificial infestations with neonate larvae of S. frugiperda in the spring. Thus, the parasitoids were not included in the sampling.
2.5. Study Site, Experimental Design, and Data Analysis
The experiments were conducted in 2013 and 2014 on the Belflower Research Farm near Tifton, GA, USA (31.5° N, 83.5° W), which is considered to have a warm temperate/subtropical climate. Weather data used for the data analysis were obtained from the Georgia Weather website [http://www.georgiaweather.net/ (accessed on 14 March 2024)]. The same trials were planted on 11 April 2013, and 4 April 2014 for field evaluation. The experiments in both 2013 and 2014 utilized a randomized complete block design with four replications as the block factor. Within each experimental block (or replication), there were randomized single-row plots (approximately 5m × 1m) for each experimental hybrid entry. Due to the limited seed supplies of the 12 selected experimental hybrids, which were originated from a diallel cross plan, a single-row plot was used in the current study. Each experiment conducted in 2013 and 2014 was considered a separate trial.
The S. frugiperda feeding injury ratings and predators recorded on the maize leaves were analyzed using analysis of variance (PROC MIXED procedure) followed by the Fisher’s Protected LSD test (α = 0.05) using statistical analysis software (SAS 9.4, 2016, SAS Institute, Cary, NC, USA). In the PROC MIXED model, the breeding cross entry and year were considered the fixed factors to assess both inherited resistance and genotype by environment (G × E) interactions, whereas four replications within each year were considered the random factor. The predator data were log-transformed because of the high coefficient of variation (or the ration of the standard deviation to the mean) of the predator dataset as shown in Table S1. To further decipher G × E interactions, correlations between predator profiles and S. frugiperda injury ratings at the seedling stage were analyzed to understand the relationships among all 15 parameters assessed in the study (as shown in Table S2). The relationships were assessed using Pearson’s correlation coefficient from the PROC CORR statement of the SAS software. Weather data (i.e., daily high and low temperatures and rainfall) from May in 2013 and 2014 were compared (using paired t-tests) to understand environmental influences on S. frugiperda injury ratings and predator abundance.
To identify the best hybrids with resistance to both S. frugiperda and possible predator attraction at the seedling stage of maize plants, the overall (two-year) means of S. frugiperda injury ratings and log-transformed predator data were subjected to the principal component analysis (PROC PRINCOMP) procedure. To ensure the data were in the same direction for the PROC PRINCOMP, procedure as described in [34], the predator abundance data were transformed by “×(−1)” to convert the predator abundance data to negative values, so that predator data were in the same direction as the insect injury rating data.
Furthermore, because the cytoplasmic/maternal effect is important in understanding parental contributions to pest resistance and, subsequently, the targeted design of breeding crosses and germplasm development, the cytoplasmic/maternal effect on S. frugiperda resistance in the six sets of reciprocal crosses was further examined using paired t-tests (α = 0.05) with the SAS software (version 9.4).
3. Results
3.1. The S. frugiperda Injury at the Seedling Stage
The pooled S. frugiperda injury ratings were significantly different among the hybrids (F = 18.63; df = 15, 220; p < 0.0001), and between the sampling dates (7- and 14-d) (F = 61.82; df = 1, 220; p < 0.0001), and so was hybrid by sampling day (7 or 14 d) interaction (F = 2.22; df = 15, 220; p = 0.007). However, S. frugiperda injury ratings were not different between 2013 and 2014 (F = 1.32; df = 1, 220; p = 0.25). Thus, the data from both years were combined for further analysis.
The combined S. frugiperda injury ratings in 2013 and 2014 showed that S. frugiperda injuries were significantly different among the 16 entries after 7 d (Figure 1A) and 14 d (Figure 1B), as well as for the overall means (Figure 1C). All 12 breeding crosses showed moderate resistance to S. frugiperda, when compared to the susceptible check DKC69-72 and the three transgenic Bt hybrids (DKC69-71, DKC67-88 and P31P42) with Bt toxins. Of the 12 experimental hybrids, FAW1430 × Oh43 and CML333 × NC358 were the two best experimental hybrids (indicated by the asterisks on the bars in Figure 1C), because their S. frugiperda injury ratings were below the mean (2.24 ± 0.06, n = 256) of all 16 hybrid entries (indicated by the horizontal line across the bar graph). At the same time, the S. frugiperda injury ratings from neither set of the reciprocal crosses differed.
In addition, a strong influence of hybrid by year interaction on S. frugiperda injuries at both 7 d (F = 5.19; df = 15, 90; p < 0.0001) and 14 d (F = 2.69; df = 15, 90; p = 0.002) was detected. Because hybrid by sampling day interaction influenced the injury ratings significantly, the 7 and 14 d injury ratings and means from 2013 and 2014 are presented separately, as shown in the supplementary figures (Figure S1 for 2013 data; and Figure S2 for 2014 data). The injury ratings also differed between the two years on the 7 d injury ratings (F = 12.79; df = 1, 6; p = 0.01). In 2013, the 7 d injury rating was 1.81 ± 0.08 (n = 64) (Figure S1A), but in 2014, it was 2.02 ± 0.07 (n = 64) (Figure S2A). However, there was no difference in the 14 d injury rating between 2013 and 2014 (F = 0.03; df = 1, 6; p = 0.87), which are shown in Figure S1B (14 d rating in 2013—2.57 ± 0.14, n = 64) and Figure S2B (14 d rating in 2014—2.55 ± 0.16, n = 64), respectively. Thus, contribution of predator types and abundance on S. frugiperda injury was further evaluated.
3.2. Predator Abundance and Diversity Survey
A total of 11 arthropod predators [i.e., six coleopterans, three hemipterans, earwigs (dermapterans), and spiders (or arachnids)] were recorded on maize plants (at the V7 stage) 7 d after the artificial S. frugiperda infestation. The results were similar to the previous reports [6,20]. The five lady beetles were as follows: the convergent lady beetle, Hippodamia convergens (Coleoptera: Coccinellidae), the pink-spotted lady beetle, Coleomegilla maculata (Coleoptera: Coccinellidae); the seven-spotted lady beetle, Coccinella septempunctata (Coleoptera: Coccinellidae), the multicolored Asian lady beetle, Harmonia axyridis (Coleoptera: Coccinellidae), and the dusky lady beetle, Scymnus spp. (Coleoptera: Coccinellidae). The hooded beetle is also known as the flower beetle, Notoxus spp. (Coleoptera: Anthicidae). The three hemipteran predators were the big-eyed bug, Geocoris spp. (Hemiptera: Geocoridae), the insidious flower bug (or minute pirate bug), Orius insidiosus (Hemiptera: Anthocoridae), and the damsel bug, Nabis spp. (Hemiptera: Nabidae). The earwigs were identified as Labidura riparia (Labiduridae), and Doru taeniatum (Forficulidae). All spider species were recoded as one group, and no further identification was made. The pooled data showed that the total number of predators did not vary significantly among the hybrid entries (F = 0.63; df = 15, 90; p = 0.84). Because there were no significant differences among the hybrid entries, except the difference between the two years, the pooled two-year data were not presented.
However, the predators varied significantly between the two years (F = 12.95; df = 1, 6; p = 0.01), although hybrid entry by year interaction did not affect predator abundance (F = 0.71; df = 15, 90; p = 0.77). Although the two most common predators observed on experimental plots in both years were the pink spotted lady beetle and the insidious flower bug, the abundance of all predators recorded in 2013 was only half of that in 2014, as shown in the supplementary table (Table S1). The predators per plot were nearly doubled in 2014 (4.42 ± 0.31, n = 64) when compared to the data from 2013 (2.22 ± 0.17, n = 64) (Table S1).
Although the 7 d injury ratings in 2013 (Figure S1A) was less than in 2014 (Figure S2A), the 14-d injury ratings were not different between 2013 (Figure S1B) and 2014 (Figure S2B). The nearly doubled predator populations recorded at 7 d after the artificial infestation in 2014, when compared to the finding in 2013, suggested that the increased predation resulted in reduced S. frugiperda survival, which might have resulted in no significant difference in 14 d injury ratings between 2013 and 2014, as described previously.
Comparison of weather data for May between 2013 and 2014 showed that the daily high temperature was greater in 2014 (28.66 ± 0.65, n = 31) than in 2013 (26.66 ± 0.70, n = 31), and the difference was 2.01 ± 0.8 °C (n = 31, paired t-test t = 2.5, df = 30, p = 0.02). However, neither daily low temperature nor rainfall differed (p values > 0.13). Thus, lower daily high temperature in May of 2013 than that in 2014 might have caused less feeding by early instar larvae and subsequently lower S. frugiperda injury ratings at day 7 in 2013 (Figure S1A) than in 2014 (Figure S2A). In contrast, the nearly doubled number of predators recorded on day 7 after the artificial infestation in 2014 than in 2013 (Table S1), caused by relatively higher daily high temperature, might have contributed to the reduced S. frugiperda survival, due to predation, and subsequently no significant difference in the 14 d injury ratings between the two years.
3.3. Correlation between S. frugiperda Injury Ratings and among the Predators
Based on the combined two-year data collected on the 16 hybrid entries, the correlation between S. frugiperda injury ratings and predator profile data was not significant (p values > 0.05), except that the number of the hooded beetles was positively correlated to the 14 d and the mean of S. frugiperda injury ratings (r ≥ 0.18, p ≤ 0.03, n = 128) (Table S2). The 7 and 14 d S. frugiperda injury ratings were positively correlated to the overall means of the S. frugiperda injury ratings, as shown in Table S2.
Of all 11 taxa of predators recorded in the experiment in both years, seven predators were significantly correlated to the total number of predators (r values were between 0.20 and 0.9, p values ≤ 0.03, n = 128) (as shown in in last row of Table S2). They were four lady beetles (the convergent, the pink spotted, the seven-spotted, and the multicolored Asian lady beetles), and two hemipteran predators (the big-eyed bug and the minute pirate bug), and the spiders.
3.4. Principal Component Analysis of S. frugiperda Resistance
The principal component analysis using the S. frugiperda injury ratings and predator data showed that Bt transgenic maize hybrids (CK1, CK3, and CK4) without S. frugiperda injury are located in quadrant III (Figure 2). Five reciprocal crosses had only moderate S. frugiperda resistance, which are in quadrants II and IV (Figure 2). However, because of relatively high S. frugiperda injury ratings, the reciprocal crosses between NC350 and NC358 (i.e., experimental hybrid entries 4A and 4B, as shown in Table 1) are in quadrant I with the susceptible check (CK2) (Figure 2). Similarly, the reciprocal crosses between NC358 and CML333 (or experimental hybrids 5A and 5B) are in quadrant II, and experimental hybrids 1A and 1B (reciprocal crosses between Oh43 and FAW1430) are in quadrant IV (Figure 2). Because each of the three reciprocal crosses (i.e., 1A and 1B, 4A and 4B, and 5A and 5B) are in the same quadrants (Figure 2), the principal component analysis confirmed these six experimental hybrids had no maternal/cytoplasmic effect, or the parents contributed similarly to S. frugiperda resistance. In contrast, the other three reciprocal crosses are different. Hybrid entries 2B, 3A, and 6A are in quadrant II, while the 2A, 3B, and 6B are in quadrant IV (Figure 2). Thus, the data for S. frugiperda injury ratings and numbers of predators among these reciprocal crosses were further examined to determine whether a maternal/cytoplasmic effect existed or not.
3.5. Maternal/Cytoplasmic Effect on Spodoptera frugiperda Resistance in Reciprocal Crosses
Based on the paired t-test results, as shown in Table S3, the S. frugiperda injury ratings between each of the six reciprocal crosses were not different (p values ≥ 0.19), which means no maternal or paternal effect of the inbred lines on S. frugiperda resistance existed in any of these experimental hybrids. It is worth noting that there were no S. frugiperda injuries on Bt (DKC69-71), whereas its non-Bt version of its isogenic (sister) hybrid (DKC69-72) showed the highest injury ratings. In addition, the predator survey data recorded 7 d after the initial infestation were not different between each pair of reciprocal crosses (p values ≥ 0.09) (Table S3).
4. Discussion
The S. frugiperda injury rating and predator data showed that the 12 experimental hybrids had relatively moderate resistance to S. frugiperda when compared to the three resistant checks (i.e., DKC69-71, DKC67-88 and P31P42 with transgenic Bt genes) and the susceptible check (non-Bt DKC69-72) of the experiment. Of the 12 experimental hybrids, two of them (i.e., FAW1430 × Oh43 and CML333 × NC358) showed lower S. frugiperda injury ratings than the rest of the 10 experimental hybrids (Figure 1).
Further comparisons between each pair of the six reciprocal crosses (or the 12 experimental hybrids) showed that, because no difference was detected between an inbred line as male or female parent in each set of the reciprocal crosses, male and female parents in the reciprocal cross contributed similarly to S. frugiperda resistance, or no maternal/cytoplasmic effect was observed. This is different from the previous report on maize weevil resistance, and maize weevil resistance in maize kernels is inherited maternally [12]. At the same time, the findings on S. frugiperda resistance from the current study are similar to the previous report that H. zea resistance was not related to maysin content in corn silk [13]. The previous study also reported that high levels of the maysin and its analogs that contributed to H. zea resistance did not show a maternal effect of parental inbred lines. The findings are valuable in developing maize germplasm with resistance to multiple biotic and abiotic stresses by targeting parental inbred lines with complementary traits of a specific parent (maternal or paternal) in designing the new crosses for both hybrid production and new germplasm development.
The nearly two-times higher number of predators recorded in 2014 when compared to 2013 suggests that the predation of S. frugiperda might have contributed to no difference in 14 d S. frugiperda injury ratings between the two years, given that the 7 day S. frugiperda injury ratings in 2013 were lower than in 2014. Such phenomena might not occur in northern states because of high latitudes with relatively low temperatures at the seedling stage of maize plants. In addition, although the current study confirmed previous reports that predator abundance during the experimental period is influenced greatly by weather conditions (e.g., temperature and rainfall) from year to year [6,20], further detailed studies are critical. Such studies would elucidate the tri-trophic interactions (i.e., maize genotype, S. frugiperda genotype, and predator abundance) modulated by the changing climate conditions and decipher the mechanisms or broad basis of host plant resistance to multiple biotic and abiotic factors. In particular, the use of four-row (or multiple-row) plots accompanied with a skip row spacing, instead of the continuous single-row plot as described in the current experiment, could be valuable in discerning dispersal/movement patterns, and the possible attraction of predators by a maize hybrid. The dataset from sampling the middle rows in multiple-row plots would represent predator abundance in a maize field with precision. In general, predator abundance in reducing foliar- and ear-feeding insects has been reported in warm climates in the recent literature. For example, both the pink spotted lady beetle and the insidious flower bug were abundant on maize plants at leaf stages 4–5 (V4 to V5), and natural enemies have the potential to be utilized for managing S. frugiperda in the subtropical lowlands of Mexico [35]. Earwigs were effective predators for the S. frugiperda larvae in Argentina [36]. The high survival rates of Eriopis connexa (Germar) (Coleoptera: Coccinellidae) fed with eggs of the S. frugiperda show the potential use of this prey in the laboratory rearing of lady beetles [37]. At the same time, earwigs, as the most abundant predators, should be further examined at the reproduction growth stage of maize plants for reducing kernel-destroying insect populations, e.g., Helicoverpa zea [38].
Regarding insect resistance mechanisms, the six pairs of reciprocal crosses were made by utilizing parents with relatively high levels of kauralexins and zealexins [18,19]. The two experimental hybrids showing the best S. frugiperda resistance were made by using three NAM founders (i.e., CML333, NC358, and Oh43), which have high levels of both phytoalexins (kauralexins and/or zealexins), and FAW1430, a newly developed inbred line from our program. Thus, the relationship of the phytoalexins (i.e., kauralexins, and zealexins) to foliar resistance to S. frugiperda, as well as the resistance mechanism of FAW1430 to S. frugiperda feeding, need to be further examined. In addition, plant-volatile (E)-β-caryophyllene, a terpenoid compound, is associated with S. frugiperda resistance in maize inbred line Mp708 [39]. The 4 d old S. frugiperda larvae preferred the whorl tissue Tx601 (susceptible control) over the Mp708 (resistant) tissue [39], which suggested non-preference (or antixenosis) of Mp708 as one of the possible resistance mechanisms. For multiple insect resistance mechanisms, by examining tropical maize inbred lines CML71, CML125, CML370, and CKSBL10008, with known resistance to multiple stem borers, revealed that CKSBL10008 and CML71 show high level of antibiosis to S. frugiperda [17]. In addition, by using extensive phenotyping data on S. frugiperda injury ratings from 289 maize germplasm lines, seven genes and multiple pathways associated with its feeding damage were identified [40]. This finding is critical to deciphering the molecular basis for further discerning the maternal/cytoplasmic effect of inbred parents on maize resistance to S. frugiperda and other key pests in hybrids, and subsequently to developing maize germplasm with resistance to multiple biotic and abiotic stress factors.
The current study also demonstrated that the three commercial maize hybrids with Bt transgenes were effective for controlling S. frugiperda (in quadrant III of Figure 2), while five of the six reciprocal crosses showed moderate resistance (in quadrants II and IV of Figure 2). The findings confirmed previous reports which showed that utilizing transgenic and native insect resistance could synergistically decelerate or even reverse Bt resistance in S. frugiperda and other lepidopteran pests in transgenic Bt maize production ([41,42], F.H., unpublished data).
In summary, the current study of unique reciprocal crosses determined that FAW1430 × Oh43 and CML333 × NC358 are the best performing hybrids. The two experimental hybrids will be further examined and utilized for developing new maize germplasm with resistance to multiple biotic and abiotic stresses. Comprehensive evaluation of S. frugiperda injury and predator abundance, as well as other ecological service factors at the seedling stage would be essential in understanding the ecological genetics of both plants and insect pests and their interactions with environmental factors. Given the current trend of increasing frequency and severity of abiotic stresses (e.g., heat and drought) in maize production, deciphering the genetic basis of dynamic plant responses to multiple biotic stress factors (e.g., insect infestations, phytopathogen infections, and subsequent mycotoxin accumulation) throughout the field season is essential to accelerating germplasm development, and ultimately minimizing losses of yield and quality in maize production.
Supplementary Materials
The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/insects15040289/s1, Figure S1: The S. frugiperda injury rating data from 2013 at 7 d (A) and 14 d (B) after the artificial infestation; Figure S2: The S. frugiperda injury rating data from 2014 at 7 d (A) and 14 d (B) after the artificial infestation; Table S1: Predator type and number from the 12 experimental hybrids and four commercial checks*; Table S2: The Pearson’s correlation coefficients among the S. frugiperda injury ratings and predators recorded (n = 128); Table S3: Paired t-test results for S. frugiperda and predator survey data from 2013 and 2014 (n = 8).
Author Contributions
Conceptualization, methodology, investigation, data collection, proofing and validation, and formal analyses, X.N., A.H., E.A.S., W.X., W.P.W., B.G., X.L. and F.H.; resources, X.N.; data curation, X.N.; writing—original draft preparation, X.N., A.H., E.A.S., W.X., W.P.W., B.G., X.L. and F.H.; writing—review and editing, A.H., E.A.S., W.X., W.P.W., B.G., X.L., F.H. and X.N.; visualization, X.N.; supervision, X.N.; project administration, X.N. The whole process from initiation to completion of this field study has been a truly inspiring team effort amongst us. All authors have read and agreed to the published version of the manuscript.
Funding
This research received no external funding.
Data Availability Statement
The data presented in this study are available within the article.
Acknowledgments
The current comprehensive field study (of evaluating multiple insect and disease resistance, aflatoxin reduction, and yield potential) is designated in memory of E.A.S. for his dedication, intellectual prowess, and contagiously inspiring and kindred spirit in science. Mention of trade names or commercial products in this article is solely for the purpose of providing specific information and does not imply recommendation or endorsement by the U. S. Department of Agriculture. We would like to express our gratitude to P. Tapp and undergraduate research assistants (Tyler Lusk, Austin Overton, Aaron Pryor, Jonathan Roberts, and Xing Wei) for their assistance in conducting the experiments. We are also indebted to the constructive reviews of a previous version of this manuscript by Sandra Woolfolk (USDA-ARS, Corn Host Plant Resistance Research Unit, Mississippi State, MS), Osariyekemwen Uyi (Department of Entomology, University of Georgia-Tifton Campus, Tifton, GA), and Xiangbing Yang (USDA-ARS, Subtropical Horticulture Research Station, Miami, FL).
Conflicts of Interest
The authors declare no conflicts of interest.
References
- Burchfield, E.K. Shifting cultivation geographies in the Central and Eastern US. Environ. Res. Lett. 2022, 17, 054049. [Google Scholar] [CrossRef]
- Thome, C.R.; Smith, M.E.; Mihm, J.A. Leaf feeding resistance to multiple insect species in a maize diallel. Crop Sci. 1992, 32, 1460–1463. [Google Scholar] [CrossRef]
- Abel, C.A.; Wilson, R.L.; Wiseman, B.R. Conventional resistance of experimental maize lines to the corn earworm (Lepidoptera: Noctuidae), the fall armyworm (Lepidoptera: Noctuidae), the southwestern corn borer (Lepidoptera: Crambidae), and the sugarcane borer (Lepidoptera: Crambidae). J. Econ. Entomol. 2000, 93, 982–988. [Google Scholar] [CrossRef]
- Ni, X.; Xu, W.; Krakowsky, M.D.; Buntin, G.D.; Brown, S.L.; Lee, R.D.; Coy, A.E. Field screening of experimental maize hybrids and inbred lines for multiple ear-feeding insect resistance. J. Econ. Entomol. 2007, 100, 1704–1713. [Google Scholar] [CrossRef] [PubMed]
- Ni, X.; Krakowsky, M.D.; Buntin, G.D.; Rector, B.G.; Guo, B.; Snook, M.E. Identification of multiple ear-colonizing insect and disease resistance in CIMMYT maize inbred lines with varying levels of silk maysin. J. Econ. Entomol. 2008, 101, 1455–1465. [Google Scholar] [CrossRef]
- Ni, X.; Chen, Y.; Hibbard, B.E.; Wilson, J.P.; Williams, W.P.; Buntin, G.D.; Ruberson, J.R.; Li, X. Foliar resistance to fall armyworm in corn germplasm lines that confer resistance to root- and ear-feeding insects. Fla. Entomol. 2011, 94, 971–981. [Google Scholar] [CrossRef]
- Pring, R.D.; Lonsdale, M. Cytoplasmic male sterility and maternal inheritance of disease susceptibility in maize. Ann. Rev. Phytopath. 1989, 27, 483–502. [Google Scholar] [CrossRef]
- Habarurema, I.; Asea, G.; Lamo, J.; Gibson, P.; Edema, R.; Séré, Y.; Onasanya, R.O. Genetic analysis of resistance to rice bacterial blight in Uganda. Afr. Crop Sci. J. 2012, 20, 105–112. [Google Scholar]
- Hassine, M.; Bnejdi, F.; Bahri, B.A.; Tissaoui, S.; Mougou-Hamdane, A.; Guesmi, M.; Baraket, M.; Slim-Amara, H. Detection of maternal and cytoplasmic effects on resistance to Zymoseptoria tritici in durum wheat. BioMed Res. Int. 2022, 8497417. [Google Scholar] [CrossRef]
- Valverde Caballero, P.; Trapero Ramírez, C.; Barranco Navero, D.; López-Escudero, F.J.; Gordon Bermúdez-Coronel, A.; Díez, C.M. Assessment of maternal effects and genetic variability in resistance to Verticillium dahliae in olive progenies. Plants 2021, 10, 1534. [Google Scholar] [CrossRef]
- Welz, H.G.; Geiger, H.H. Genes for resistance to northern corn leaf blight in diverse maize populations. Plant Breed. 2000, 119, 1–14. [Google Scholar] [CrossRef]
- García-Lara, S.; Bergvinson, D.J.; Burt, A.J.; Ramputh, A.I.; Díaz-Pontones, D.M.; Arnason, J.T. The role of pericarp cell wall components in maize weevil resistance. Crop Sci. 2004, 44, 1546–1552. [Google Scholar] [CrossRef]
- Widstrom, N.W.; Snook, M.E. Genetic variation for maysin and its analogues in crosses among corn inbreds. Crop Sci. 1998, 38, 372–375. [Google Scholar] [CrossRef]
- Bohn, M.; Groh, S.; Khairallah, M.M.; Hoisington, D.A.; Utz, H.F.; Melchinger, A.E. Re-evaluation of the prospects of marker-assisted selection for improving insect resistance against Diatraea spp. in tropical maize by cross validation and independent validation. Theor. Appl. Genet. 2001, 103, 1059–1067. [Google Scholar] [CrossRef]
- Cardinal, A.J.; Lee, M.; Sharopova, N.; Woodman-Clickeman, W.L.; Long, M.J. Genetic mapping and analysis of quantitative trait loci for resistance to stalk tunneling by the European corn borer in maize. Crop Sci. 2001, 41, 835–845. [Google Scholar] [CrossRef]
- Brooks, T.D.; Bushman, B.S.; Williams, W.P.; McMullen, M.D.; Buckley, P.M. Genetic basis of resistance to fall armyworm (Lepidoptera: Noctuidae) and southwestern corn borer (Lepidoptera: Crambidae) leaf-feeding damage in maize. J. Econ. Entomol. 2007, 100, 1470–1475. [Google Scholar] [CrossRef] [PubMed]
- Nuambote-Yobila, O.; Bruce, A.Y.; Okuku, G.O.; Marangu, C.; Makumbi, D.; Beyene, Y.; Mahungu, N.-M.; Prasanna, B.M.; Marion-Poll, F.; Calatayud, P.-A. Assessment of resistance mechanisms to fall armyworm, Spodoptera frugiperda in tropical maize inbred lines. Agronomy 2003, 13, 203. [Google Scholar] [CrossRef]
- Schmelz, E.A.; Kaplan, F.; Huffaker, A.; Dafoe, N.J.; Vaughan, M.M.; Ni, X.; Rocca, J.R.; Alborn, H.T.; Teal, P.E.A. Identity, regulation and activity of inducible diterpenoid phytoalexins in maize. Proc. Natl. Acad. Sci. USA 2011, 108, 5455–5460. [Google Scholar] [CrossRef] [PubMed]
- Huffaker, A.; Kaplan, F.; Vaughan, M.M.; Dafoe, N.J.; Ni, X.; Rocca, J.R.; Alborn, H.T.; Teal, P.E.A.; Schmelz, E.A. Novel acidic sesquiterpenoids constitute a dominant class of pathogen-induced phytoalexins in maize. Plant Physiol. 2011, 156, 2082–2097. [Google Scholar] [CrossRef]
- Ni, X.; Xu, W.; Blanco, M.H.; Williams, W.P. Evaluation of fall armyworm resistance in maize germplasm lines using visual leaf injury rating and predator survey. Insect Sci. 2014, 21, 541–555. [Google Scholar] [CrossRef]
- Johnson, E.T.; Skory, C.; Dowd, P.F. Identification of a bioactive Bowman-Birk Inhibitor from an insect-resistant early maize inbred. J. Agric. Food Chem. 2014, 62, 5458–5465. [Google Scholar] [CrossRef] [PubMed]
- Widstrom, N.W.; Williams, W.P.; Wiseman, B.R.; Davis, F.M. Registration of GT-FAWCC(C5) maize germplasm. Crop Sci. 1993, 33, 1422. [Google Scholar] [CrossRef]
- Betran, F.J.; Isakeit, T.; Odvody, G. Aflatoxin accumulation of white and yellow maize inbreds in diallel crosses. Crop Sci. 2002, 42, 1894–1901. [Google Scholar] [CrossRef]
- Cook, J.P.; McMullen, M.D.; Holland, J.B.; Tian, F.; Bradbury, P.; Ross-Ibarra, J.; Buckler, E.S.; Flint-Garcia, S.A. Genetic architecture of maize kernel composition in the nested association mapping and inbred association panels. Plant Physiol. 2012, 158, 824–834. [Google Scholar] [CrossRef] [PubMed]
- Wiseman, B.R.; Davis, F.M.; Williams, W.P.; Widstrom, N.W. Resistance of a maize population, FAWCC(C5), to fall armyworm larvae (Lepidoptera: Noctuidae). Fla. Entomol. 1996, 79, 329–336. [Google Scholar] [CrossRef]
- Van Rensburg, J.B.J. Evaluation of plant resistance to the maize stalk borer, Busseola fusca (Fuller) in maize germplasm improved for resistance to other borer species. South Afr. J. Plant Soil 1998, 15, 34–37. [Google Scholar] [CrossRef]
- Song, K.; Kim, K.; Kim, H.; Moon, J.; Kim, J.; Baek, S.; Kwon, Y.; Lee, B. Evaluation of drought tolerance in maize seedling using leaf rolling. Korean J. Crop Sci. 2015, 60, 8–16. [Google Scholar] [CrossRef]
- Davis, F.M.; Ng, S.S.; Williams, W.P. Visual rating scales for screening whorl-stage corn for resistance to fall armyworm. Tech. Bull. Miss. Agric. For. Exp. Stn. 1992, 186, 9. [Google Scholar]
- Davis, F.M.; Wiseman, B.R.; Williams, W.P.; Widstrom, N.W. Insect colony, planting date, and plant growth stage effects on screening maize for leaf-feeding resistance to fall armyworm (Lepidoptera: Noctuidae). Fla. Entomol. 1996, 79, 317–328. [Google Scholar] [CrossRef]
- Smith, C.M.; Khan, Z.R.; Pathak, M.D. Evaluation of plants for insect resistance. In Techniques for Evaluating Insect Resistance in Crop Plants; Smith, C.M., Khan, Z.R., Pathak, M.D., Eds.; CRC Press: Boca Raton, FL, USA, 1991; pp. 17–114. [Google Scholar]
- Meagher, R.L.; Nuessly, G.S.; Nagoshi, R.N.; Hay-Roe, M.M. Parasitoids attacking fall armyworm (Lepidoptera: Noctuidae) in sweet corn habitats. Biol. Control 2016, 95, 66–72. [Google Scholar] [CrossRef]
- Abbas, A.; Ullah, F.; Hafeez, M.; Han, X.; Dara, M.Z.N.; Gul, H.; Zhao, C.R. Biological control of fall armyworm, Spodoptera frugiperda. Agronomy 2022, 12, 2704. [Google Scholar] [CrossRef]
- Pal, S.; Bhattacharya, S.; Dhar, T.; Gupta, A.; Ghosh, A.; Debnath, S.; Gangavarapu, N.; Pati, P.; Chaudhuri, N.; Chatterjee, H.; et al. Hymenopteran parasitoid complex and fall armyworm: A case study in eastern India. Sci. Rep. 2024, 14, 4029. [Google Scholar] [CrossRef]
- Der, G.; Everitt, B.S. Principal components analysis and factor analysis: Olympic decathlon and statements about pain. In A Handbook of Statistical Analyses Using SAS, 3rd ed.; CRC Press: Boca Raton, FL, USA, 1991; pp. 295–315. [Google Scholar]
- Hoballah, M.E.; Degen, T.; Bergvinson, D.; Savidan, A.; Tamò, C.; Turlings, T.C.J. Occurrence and direct control potential of parasitoids and predators of the fall armyworm (Lepidoptera: Noctuidae) on maize in the subtropical lowlands of Mexico. Agric. For. Entomol. 2004, 6, 83–88. [Google Scholar] [CrossRef]
- Sueldo, M.R.; Bruzzone, O.A.; Virla, E.G. Characterization of the earwig, Doru lineare, as a predator of larvae of the fall armyworm, Spodoptera frugiperda: A functional response study. J. Insect Sci. 2010, 10, 38. [Google Scholar] [CrossRef]
- Silva, R.B.; Cruz, I.; Zanuncio, J.C.; Figueiredo, M.D.L.C.; Zanuncio, T.V.; Serrão, J.E. Spodoptera frugiperda (J.E. Smith) (Lepidoptera: Noctuidae) eggs as alternative food for rearing of lady beetles Eriopis connexa (Germar) (Coleoptera: Coccinellidae). Biol. Control 2013, 64, 101–105. [Google Scholar] [CrossRef]
- Silva, G.A.; Picanço, M.C.; Ferreira, L.R.; Ferreira, D.O.; Farias, E.S.; Souza, T.C.; Rodrigues-Silva, N.; Pereira, E.J.G. Yield losses in transgenic Cry1Ab and non-Bt corn as assessed using a crop-life-table approach. J. Econ. Entomol. 2018, 111, 218–226. [Google Scholar] [CrossRef]
- Smith, W.E.C. Detection and Characterization of a Volatile Compound as a Response to Fall Armyworm (Spodoptera frugiperda) Feeding in Maize (Zea mays). Master’s Thesis, Mississippi State University, Starkville, MS, USA, 2010. [Google Scholar]
- Warburton, M.L.; Woolfolk, S.W.; Smith, J.S.; Hawkins, L.K.; Castano-Duque, L.; Lebar, M.D.; Williams, W.P. Genes and genetic mechanisms contributing to fall armyworm resistance in maize. Plant Genome 2023, 16, e20311. [Google Scholar] [CrossRef]
- Ni, X.; Lei, Z.; He, K.; Li, X.; Li, X.; Xu, W. Integrated pest management is the lucrative bridge connecting the ever-emerging knowledge islands of genetics and ecology. Insect Sci. 2014, 21, 537–540. [Google Scholar] [CrossRef]
- Huang, K.; He, H.; Wang, S.; Zhang, M.; Chen, X.; Deng, Z.; Ni, X.; Li, X. Sequential and simultaneous interactions of plant allelochemical flavone, Bt toxin Vip3A and insecticide emamectin benzoate in Spodoptera Frugiperda. Insects 2023, 14, 736. [Google Scholar] [CrossRef]
Figure 1.
Combined two-year S. frugiperda injury rating data at the seedling stage: (A) 7 d rating data, (B) 14 d rating data, and (C) overall means from both ratings (7 and 14 d) of both years (2013 and 2014). The bars with * in (C) denote the experimental hybrids with the least S. frugiperda injury ratings.
Figure 1.
Combined two-year S. frugiperda injury rating data at the seedling stage: (A) 7 d rating data, (B) 14 d rating data, and (C) overall means from both ratings (7 and 14 d) of both years (2013 and 2014). The bars with * in (C) denote the experimental hybrids with the least S. frugiperda injury ratings.
Figure 2.
Identification of the best experimental maize hybrids from the six sets of reciprocal crosses and four commercial controls based on the principal component analysis results. The data on 14 d after S. frugiperda infestation, and predator survey data were used for the analysis. Principal component one (Prin1) contributed 52%, and principal component two (Prin2) contributed 48% of the overall variation in the experiment. The non-Bt commercial hybrid CK2 (DKC69-72) and 4A and 4B with the high S. frugiperda injury rating are in quadrant (I), whereas five hybrids (i.e., entries 2B, 3A, 5A and 5B, and 6A as shown in Table 1) are in quadrant (II). Three commercial hybrid checks (CKs) with transgenic Bt genes (i.e., CK1, CK3, and CK4 as shown in Table 1) are in quadrant (III) without S. frugiperda injury. Five hybrids (i.e., entries 1A and 1B, 2A, 3B, and 6B) are in quadrant (IV). The quadrants (I–IV) are labeled with the order used in mathematics.
Figure 2.
Identification of the best experimental maize hybrids from the six sets of reciprocal crosses and four commercial controls based on the principal component analysis results. The data on 14 d after S. frugiperda infestation, and predator survey data were used for the analysis. Principal component one (Prin1) contributed 52%, and principal component two (Prin2) contributed 48% of the overall variation in the experiment. The non-Bt commercial hybrid CK2 (DKC69-72) and 4A and 4B with the high S. frugiperda injury rating are in quadrant (I), whereas five hybrids (i.e., entries 2B, 3A, 5A and 5B, and 6A as shown in Table 1) are in quadrant (II). Three commercial hybrid checks (CKs) with transgenic Bt genes (i.e., CK1, CK3, and CK4 as shown in Table 1) are in quadrant (III) without S. frugiperda injury. Five hybrids (i.e., entries 1A and 1B, 2A, 3B, and 6B) are in quadrant (IV). The quadrants (I–IV) are labeled with the order used in mathematics.
Table 1.
The list of 12 experimental hybrids (or six pairs of reciprocal breeding crosses marked as A and B) and four commercial hybrids as the controls of the experiment in 2013 and 2014.
Table 1.
The list of 12 experimental hybrids (or six pairs of reciprocal breeding crosses marked as A and B) and four commercial hybrids as the controls of the experiment in 2013 and 2014.
| Entry | Pedigree (Female × Male) | References |
|---|---|---|
| 1A | Oh43 × FAW1430 | Oh43: [18,19,21] |
| 1B | FAW1430 × Oh43 | FAW1430: derived from FAW CC(C)5 [22] |
| 2A | FAW1430 × CML322 | CML322: [18,23,24] |
| 2B | CML322 × FAW1430 | |
| 3A | NC358 × FAW1430 | NC358: [18,19] |
| 3B | FAW1430 × NC358 | |
| 4A | NC350 × NC358 | NC350: [18,19] |
| 4B | NC358 × NC350 | |
| 5A | NC358 × CML333 | CML333: [18,19] |
| 5B | CML333 × NC358 | |
| 6A | B97 × CML528 | B97: [18,19] |
| 6B | CML528 × B97 | CML528: tropical inbred (procured from CIMMYT in 2011) |
| CK1 | DKC69-71 | Commercial check, Bt transgenic (Bayer, Monsanto) |
| CK2 | DKC69-72 | Commercial check, non-Bt control (Bayer, Monsanto) |
| CK3 | DKC67-88 | Commercial check, Bt transgenic (Bayer, Monsanto) |
| CK4 | P31P42 | Commercial check, Bt transgenic (DuPont, Pioneer) |
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content. |
© 2024 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Share and Cite
MDPI and ACS Style
Ni, X.; Huffaker, A.; Schmelz, E.A.; Xu, W.; Williams, W.P.; Guo, B.; Li, X.; Huang, F. Field Evaluation of Experimental Maize Hybrids for Resistance to the Fall Armyworm (Lepidoptera: Noctuidae) in a Warm Temperate Climate. Insects 2024, 15, 289. https://doi.org/10.3390/insects15040289
AMA Style
Ni X, Huffaker A, Schmelz EA, Xu W, Williams WP, Guo B, Li X, Huang F. Field Evaluation of Experimental Maize Hybrids for Resistance to the Fall Armyworm (Lepidoptera: Noctuidae) in a Warm Temperate Climate. Insects. 2024; 15(4):289. https://doi.org/10.3390/insects15040289
Chicago/Turabian StyleNi, Xinzhi, Alisa Huffaker, Eric A. Schmelz, Wenwei Xu, W. Paul Williams, Baozhu Guo, Xianchun Li, and Fangneng Huang. 2024. "Field Evaluation of Experimental Maize Hybrids for Resistance to the Fall Armyworm (Lepidoptera: Noctuidae) in a Warm Temperate Climate" Insects 15, no. 4: 289. https://doi.org/10.3390/insects15040289
APA StyleNi, X., Huffaker, A., Schmelz, E. A., Xu, W., Williams, W. P., Guo, B., Li, X., & Huang, F. (2024). Field Evaluation of Experimental Maize Hybrids for Resistance to the Fall Armyworm (Lepidoptera: Noctuidae) in a Warm Temperate Climate. Insects, 15(4), 289. https://doi.org/10.3390/insects15040289
Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.
