Maize Seed Contamination and Seed Transmission of Maize Chlorotic Mottle Virus in Kenya

Maize chlorotic mottle virus (MCMV) causes maize lethal necrosis disease in combination with a cereal infecting potyvirus, leading to high yield losses. There is limited information on seed infection or contamination rate by MCMV and its comparison to transmission rate to maize seedlings. This study was conducted to determine the extent of seed contamination in seed lots from MCMV-infected maize fields in Kenya and the transmission of MCMV from seeds to seedlings. To determine the contamination levels, whole seeds were ground, and the extract tested for the presence of MCMV using double antibody sandwich enzyme-linked immunosorbent assay (DAS-ELISA). Seedling grow-outs were tested for seed transmission of MCMV using DAS-ELISA and real-time reverse transcription polymerase chain reaction (real-time RT-PCR) methods. The seed contamination rates of the four seed lots tested ranged from 4.9 to 15.9%. MCMV transmission frequency for 37,617 seedlings, tested in 820 pools of varying seed amounts by DAS-ELISA, was 0.17%, while a transmission frequency of 0.025% was obtained from 8,322 seedlings tested in 242 pools by real-time RT-PCR. Seeds from plants mechanically inoculated with MCMV had an overall seed transmission rate of 0.04% in 7,846 seedlings tested in 197 pools. The study showed that even with substantial contamination of maize seed with MCMV, the transmission of the virus from the seed to seedlings was low. Nevertheless, even low rates of transmission can be significant under field conditions where insect vectors can further spread the disease from infected seedlings, unless diseased plants are detected in time and properly managed.

Maize catalases localized in peroxisomes support the replication of maize chlorotic mottle virus

Co-infection of maize chlorotic mottle virus (MCMV) with a virus in the Potyviridae family, such as sugarcane mosaic virus, usually leads to maize lethal necrosis (MLN). Over the past decade, MCMV/MLN has emerged in many countries/regions of the world and resulted in serious yield loss in maize production. Although partial functions of some MCMV-encoded proteins have been identified, the host factors related to MCMV replication are poorly understood. Here, we show that maize peroxisomes can form aggregated bodies in MCMV-infected leaf cells. The dsRNA binding-dependent fluorescence complementation assay indicated that the aggregated peroxisomes in maize served as the major replication site of MCMV. In addition, our results revealed that all the three maize catalases were present mostly in peroxisomes in the presence or absence of MCMV. Furthermore, we determined that inhibition of catalase activity or induction of reactive oxygen species (ROS) in maize protoplasts significantly reduced the accumulation of MCMV RNA. In summary, this research reveals the replication site of MCMV and an important role of maize catalases in supporting virus replication. Our results are conducive to understanding the pathogenesis of MCMV and identifying targets for resistance breeding or gene regulation strategies.

Introgression of Maize Lethal Necrosis Resistance Quantitative Trait Loci Into Susceptible Maize Populations and Validation of the Resistance Under Field Conditions in Naivasha, Kenya

Maize lethal necrosis (MLN), resulting from co-infection by maize chlorotic mottle virus (MCMV) and sugarcane mosaic virus (SCMV) can cause up to 100% yield losses in maize in Africa under serious disease conditions. Maize improvement through conventional backcross (BC) takes many generations but can significantly be shortened when molecular tools are utilized in the breeding process. We used a donor parent (KS23-6) to transfer quantitative trait loci (QTL) for resistance to MLN into nine adapted but MLN susceptible lines. Nurseries were established in Kiboko, Kenya during 2015–2017 seasons and BC3F2 progeny were developed using marker assisted backcrossing (MABC) approach. Six single nucleotide polymorphism (SNP) markers linked to QTL for resistance to MLN were used to genotype 2,400 BC3F2 lines using Kompetitive Allele Specific PCR (KASP) platform. We detected that two of the six QTL had major effects for resistance to MLN under artificial inoculation field conditions in 56 candidate BC3F2 lines. To confirm whether these two QTL are reproducible under different field conditions, the 56 BC3F2 lines including their parents were evaluated in replicated trials for two seasons under artificial MLN inoculations in Naivasha, Kenya in 2018. Strong association of genotype with phenotype was detected. Consequently, 19 superior BC3F2 lines with favorable alleles and showing improved levels of resistance to MLN under artificial field inoculation were identified. These elite lines represent superior genetic resources for improvement of maize hybrids for resistance to MLN. However, 20 BC3F2 lines were fixed for both KASP markers but were susceptible to MLN under field conditions, which could suggest weak linkage between the KASP markers and target genes. The validated two major QTL can be utilized to speed up the breeding process but additional loci need to be identified between the KASP markers and the resistance genes to strengthen the linkage.

Maize chlorotic mottle virus.

In Peru, losses in floury and sweet maize varieties due to MCMV have been reported to average between 10 and 15%. In experimental plots, inoculated plant yields were reduced by up to 59% (Castillo, 1976). In Kansas crop losses due to corn lethal necrosis (caused by MCMV and any potyvirus) have been estimated to be between 50 (Uyemoto et al., 1980) and 90% (Niblett and Claflin, 1978) depending on the variety of maize and the year.

Sugarcane mosaic virus (sugarcane mosaic).

Introduction: In the past, SCMV and other SCMD-causal viruses have caused serious losses in various maize and sugarcane-growing regions, including Hawaii, Egypt, Natal (South Africa), Argentina, Puerto Rico, Cuba, Australia, USA (Koike and Gillaspie, 1989; Fuchs and Grüntzig, 1995; Chen et al., 2002) and several other countries in South America (Perera et al., 2012 and references therein). Epidemics have been followed by replacement of susceptible noble-type canes by hybrid canes with tolerance or, better still, resistance and the propagation of resistant maize genotypes (Silva-Rosales et al., 2015 and references therein). The evolution of new strains of SCMV has required a continuing breeding programme to prevent heavy losses. Losses caused by SCMV are mainly (1) a reduced yield of the crop, (2) the need to include mosaic resistance when breeding new cultivars, and (3) the slowing of the interchange of cultivars between countries because of quarantine concerns over the introduction of new strains of SCMV. Crop Losses: Crop losses caused by SCMV depend on many factors, including the susceptibility of the cultivars to the prevailing strains of SCMV, the incidence of infection, the prevailing environmental conditions, the stage of growth when infection occurs, and interaction with other agents affecting the crop. Crop losses can vary from negligible to severe. Some documented instances of heavy losses in sugarcane crops due to mosaic outbreaks are as follows. In the 1980s, losses on some farms in the Isis district of Queensland, Australia, were estimated to be about 50% (Jones, 1987). In some commercial plantings of cv. Q95 from an infected source, the infected plants had fewer tillers and were less vigorous than apparently healthy plants nearby (Ryan and Jones, 1986). In Guatemala in 1974-1976, many stunted stools of mosaic-affected cv. Q83 were responsible for lack of uniformity in fields near Santa Lucia. The cane tonnage in these fields was seriously reduced (Fors, 1978). Estimations of Potential Losses in Experiments: Sugarcane In Natal, South Africa, plots of sugarcane cv. NCo376 (highly susceptible) and N12 (moderately resistant) were established with either infected or healthy cane. The plots were harvested regularly and tested serologically for SCMV to the 6th ratoon. There was a decline in the number of shoots showing mosaic symptoms in both cultivars during the experiment. However, mean yield reductions were 22% for infected NCo376 and 16% for N12 compared with yields of initially healthy cane (Cronje et al., 1994). In Brazil, plots in two locations were planted with 0, 25, 50 and 100% initial SCMV infection. Virus spread was noticeable for cv. CB46/47, but negligible for cv. IAC50/134. For CB46/47 yield losses between initially healthy and 25% infected plots were 27% and 19% in the two locations; with 100% infection, yield reduction was 71% in both areas. For IAC50/134 the only significant difference in yield was between 0 and 100% infection, an 18% reduction in diseased plots in both areas (Matsuoka and Costa, 1974). In Java, Indonesia, field trials with 0 and 100% SCMV-infected seed cane gave sugar yield reductions of 9.3% for POJ3016 and 11.1% for POJ3067 associated with the disease (Kuntohartono and Legowo, 1970). In Spain, when healthy sugarcane was planted between rows infected by SCMV, the cultivars CO62/175 and NA56/79 were sufficiently resistant for commercial production, but losses of 0.4-0.5 t/ha were found for every 1% infection between the 2nd and 4th cutting (Olalla Mercade et al., 1984a). In Pakistan, mosaic-free seed cane gave a significantly higher yield of cane (48.5 t/ha) than mosaic-infected seed cane (44.5 t/ha) (Ahmad et al., 1991). Maize In East Africa, 10 susceptible maize hybrids had yield losses of 18-46% when inoculated with SCMV in the seedling stage (Louie and Darrah, 1980). In Germany, SCMV was more prevalent than MDMV, but had a similar effect on growth and yield of maize. Early infection reduced plant height by 25%, total weight by 38% and ear weight by 27% (Fuchs et al., 1990). Disease Complexes: SCMV and related potyviruses may occur in disease complexes with other plant pathogens; either additive or synergistic effects may occur. In Louisiana, USA, losses in sugarcane caused by Sorghum mosaic virus (formerly called SCMV-H) and ratoon stunting disease (RSD, caused by the bacterium Leifsonia xyli subsp. xyli) were additive in cv. CP67-412, but synergistic (greater than the sum of each disease separately) in CP65-357 (Koike, 1982). In Spain, RSD symptoms were associated with the presence of SCMV, and damage by RSD was greatest in fields with clear mosaic symptoms (Olalla Mercade et al., 1984b). In Thailand, inoculation of the downy mildew-susceptible maize cv. Guatemala with an SCMV-like virus increased susceptibility to Peronosclerospora sorghi only slightly, whereas with the resistant Suwan 1 maize cv., the virus increased susceptibility from 27 to 61% (Sutabutra et al., 1976). In many African (especial East African) countries, SCMV and some of the SCMD-causal viruses may also interact synergistically with Maize chlorotic mottle virus (genus Machlomovirus; family Tombusviridae) to cause maize lethal necrosis disease, an emerging debilitating disease of maize (Niblett and Claflin, 1978; Wangai et al., 2012) that can cause total crop loss.

Maize lethal necrosis disease.

Maize lethal necrosis disease (MLND) is a serious threat to maize production. In Kansas, crop losses due to MLND have been estimated to be 50-90% (Niblett and Claflin, 1978; Uyemoto et al., 1980) depending on the variety of maize and the year. In Peru, losses in floury and sweet maize varieties due to Maize chlorotic mottle virus have been reported to average between 10 and 15%.

Maize yellow mosaic virus interacts with maize chlorotic mottle virus and sugarcane mosaic virus in mixed infections, but does not cause maize lethal necrosis

A maize-infecting polerovirus, variously named maize yellow dwarf virus RMV2 (MYDV RMV2), MYDV-like, and maize yellow mosaic virus (MaYMV), is frequently found in mixed infections in plants also infected with maize chlorotic mottle virus (MCMV) and sugarcane mosaic virus (SCMV), known to synergistically cause maize lethal necrosis (MLN). MaYMV was discovered in deep sequencing studies precipitated by recent maize lethal necrosis (MLN) emergence and is prevalent at global locations with MLN, but its role in or contribution to disease was not known. We examined how MaYMV impacted disease development in mixed infections with MCMV, SCMV, and both MCMV and SCMV compared to mock inoculated plants. Results demonstrated that MaYMV symptoms included stunting as well as leaf reddening in single and mixed infections. MaYMV did not recapitulate MLN synergistic disease in double infections in which either MCMV or SCMV was missing (MaYMV + MCMV or MaYMV + SCMV), but did significantly enhance stunting in mixed infections, and suppressed titers of both MCMV and SCMV in double infections. Interestingly, MaYMV strongly suppressed the SCMV-induced titer increase of MCMV in triple infections, but MLN symptoms still occurred with the reduced MCMV titer. These data indicate the potential disease impact of this newly discovered ubiquitous maize virus, alone and in the context of MLN.