Benham E.L. Lockhart

A Single Banana Streak Virus Integration Event in the Banana Genome as the Origin of Infectious Endogenous Pararetrovirus

ABSTRACT Sequencing of plant nuclear genomes reveals the widespread presence of integrated viral sequences known as endogenous pararetroviruses (EPRVs). Banana is one of the three plant species known to harbor infectious EPRVs. Musa balbisiana carries integrated copies of Banana streak virus (BSV), which are infectious by releasing virions in interspecific hybrids. Here, we analyze the organization of the EPRV of BSV Goldfinger (BSGfV) present in the wild diploid M. balbisiana cv. Pisang Klutuk Wulung (PKW) revealed by the study of Musa bacterial artificial chromosome resources and interspecific genetic cross. cv. PKW contains two similar EPRVs of BSGfV. Genotyping of these integrants and studies of their segregation pattern show an allelic insertion. Despite the fact that integrated BSGfV has undergone extensive rearrangement, both EPRVs contain the full-length viral genome. The high degree of sequence conservation between the integrated and episomal form of the virus indicates a recent integration event; however, only one allele is infectious. Analysis of BSGfV EPRV segregation among an F1 population from an interspecific genetic cross revealed that these EPRV sequences correspond to two alleles originating from a single integration event. We describe here for the first time the full genomic and genetic organization of the two EPRVs of BSGfV present in cv. PKW in response to the challenge facing both scientists and breeders to identify and generate genetic resources free from BSV. We discuss the consequences of this unique host-pathogen interaction in terms of genetic and genomic plant defenses versus strategies of infectious BSGfV EPRVs.

Evidence that the proliferation stage of micropropagation procedure is determinant in the expression of Banana streak virus integrated into the genome of the FHIA 21 hybrid (Musa AAAB)

Summary. Banana streak virus (BSV) is causing increasing concern in almost every producing area of banana and plantain (Musa spp.) worldwide. This situation appeared partially linked to some breeding lines and micropropagated hybrids. A complete BSV sequence integrated into the genome of a triploid plantain has been recently characterised and it has been hypothesised that it could give rise to infectious virus via recombination. In this study, we evaluated the effect of a routine micropropagation procedure on the expression of BSV in the FHIA 21 tetraploid hybrid. The widespread presence of integrated sequences and the absence of episomal BSV in thirty FHIA 21 “mother plants” selected for micropropagation were first confirmed by specific PCR and IC-PCR tests. The proliferation stage of the procedure, characterised by an intensive production of neoformed buds, appeared determinant in BSV expression whereas the rooting and acclimatisation stages had little or no effect. The duration in culture and the way of subdividing the clumps of proliferation influenced greatly the percentage of episomal BSV infections, reaching 58% of infected micropropagated lines after six in vitro subcultures. These data suggest that the expression of episomal BSV observed during the in vitro procedure is correlated with the presence of an integrated form.

Characterisation of Banana streak Mysore virus and evidence that its DNA is integrated in the B genome of cultivated Musa

Summary.We have sequenced the complete genome of an isolate of Banana streak virus from banana cv. ‘Mysore’ and show that it is sufficiently different from a previously characterised isolate from cv. ‘Obino l’Ewai’ to warrant recognition as a distinct species, for which the name Banana streak Mysore virus (BSMysV) is proposed. The structure of the BSMysV genome was typical of badnaviruses in general, although ORF I had a non-conventional start codon. Evidence that at least part of the BSMysV genome is integrated in the B genome of cultivated Musa is presented and transmissibility by the mealybug Planococcus citri also demonstrated.

Identification of genetic markers linked to banana streak disease expression in inter-specific Musa hybrids

Abstract.Recently-introduced inter-specific Musa hybrids, bred for improved yield and resistance to diseases, have been found to be widely infected with banana streak virus (BSV), the causal agent of banana streak disease (BSD). One hypothesis suggests: (1) that BSD occurrence in these inter-specific hybrids results from activation of BSV-Ol endogenous pararetrovirus sequences (EPRV) integrated into the Musa genome rather than from external sources of infection, and (2) that the process of genetic hybridisation may be one factor involved in triggering episomal expression of the BSV integrants. In order to test this hypothesis we carried out a genetic analysis of BSD incidence in a F1 triploid (Musa AAB) population produced by inter-specific hybridisation between virus and disease-free diploid Musa balbisiana (BB) and tetraploid Musa acuminata (AAAA) parents. Half of the F1 progeny of this cross expressed BSV particles. Using PCR amplification to determine the presence or absence of BSV-Ol EPRVs, it was determined that this endogenous sequence was specific to the M. babisiana genome and occurred in a homozygous state. Using bulk segregant analysis, ten AFLP markers co-segregating with the absence and/or presence of BSV infection were identified in the M. balbisiana genome, but were absent from the M. acuminata genome. Seven of these markers segregated with the presence of a BSV particle and three with the absence of BSV particles. Analysis of the segregation of these markers using a test-cross configuration allowed the construction of a genetic map of the linkage group containing the locus associated with BSV infection in the F1 hybrid population. These data indicate that a genetic mechanism is involved in BSV appearance, and suggest that a monogenic allelic system confers the role of carrier to the M. balbisiana parent.

Detection of Sugarcane yellow leaf virus in Quarantine and Production of Virus-free Sugarcane by Apical Meristem Culture

Sugarcane yellow leaf virus (SCYLV) was detected for the first time in 1996 in the Centre de Coopération Internationale en Recherche Agronomique pour le Développement (CIRAD) sugarcane quarantine at Montpellier by reverse transcription-polymerase chain reaction (RT-PCR) in varieties from Brazil, Florida, Mauritius, and Réunion. Between 1997 and 2000, the virus was found by RT-PCR and/or tissue-blot immunoassay (TBIA) in additional varieties from Barbados, Cuba, Guadeloupe, Indonesia, Malaysia, Philippines, Puerto Rico, and Taiwan, suggesting a worldwide distribution of the pathogen. An excellent correlation was observed between results obtained for the two diagnostic techniques. However, even though only a few false negative results were obtained by either technique, both are now used to detect SCYLV in CIRADs sugarcane quarantine in Montpellier. The pathogen was detected by TBIA or RT-PCR in all leaves of sugarcane foliage, but the highest percentage of infected vascular bundles was found in the top leaves. The long hot water treatment (soaking of cuttings in water at 25°C for 2 days and then at 50°C for 3 h) was ineffective in eliminating SCYLV from infected plants. Sugarcane varieties from various origins were grown in vitro by apical bud culture and apical meristem culture, and the latter proved to be the most effective method for producing SCYLV-free plants.

Maize Lethal Necrosis (MLN), an Emerging Threat to Maize-Based Food Security in Sub-Saharan Africa

In sub-Saharan Africa, maize is a staple food and key determinant of food security for smallholder farming communities. Pest and disease outbreaks are key constraints to maize productivity. In September 2011, a serious disease outbreak, later diagnosed as maize lethal necrosis (MLN), was reported on maize in Kenya. The disease has since been confirmed in Rwanda and the Democratic Republic of Congo, and similar symptoms have been reported in Tanzania, Uganda, South Sudan, and Ethiopia. In 2012, yield losses of up to 90% resulted in an estimated grain loss of 126,000 metric tons valued at

Impact of Sugarcane yellow leaf virus on Sugarcane Yield and Juice Quality in Réunion Island

52 million in Kenya alone. In eastern Africa, MLN was found to result from coinfection of maize with Maize chlorotic mottle virus (MCMV) and Sugarcane mosaic virus (SCMV), although MCMV alone appears to cause significant crop losses. We summarize here the results of collaborative research undertaken to understand the biology and epidemiology of MLN in East Africa and to develop disease management strategies, including identification of MLN-tolerant maize germplasm. We discuss recent progress, identify major issues requiring further research, and discuss the possible next steps for effective management of MLN.

The sugarcane bacilliform badnavirus promoter is active in both monocots and dicots

Sugarcane yellow leaf virus (SCYLV) was first detected in sugarcane of Réunion Island in 1997. A field experiment was undertaken to assess the potential impact of this virus on sugarcane production. The agronomic characteristics of SCYLV-infected plants were compared to those of virus-free plants of three sugarcane cultivars (R570, R577 and R579) which occupy more than 90% of the cultivated sugarcane area on Réunion Island. In the plant crop, significant losses in stalk weight (28%) and in sugar content (11%) were detected for cultivar R577, but not for either of the two other cultivars. In the first ratoon crop, yield reduction was detected for cultivar R577 (37%), but also for cultivar R579 (19%). Cultivar R577 also showed significant losses in sugar content (12%) due to reduced amount and quality of extracted cane juice. No yield reduction was found for cultivar R570, although stalk height and diameter were reduced in SCYLV-infected canes of this cultivar in the first ratoon crop. Leaf yellowing was observed at harvest of plant and ratoon crops when sugarcane was no longer irrigated, and 10–59% of symptomatic stalks could be attributed to the presence of SCYLV. The most severe yellowing symptoms were related to infection of sugarcane by the virus.

Suggestions for a nomenclature of endogenous pararetroviral sequences in plants

Regions of the sugarcane bacilliform badnavirus genome were tested for promoter activity. The genomic region spanning nucleotides 5999–7420 was shown to possess promoter activity as exemplified by its ability to drive the expression of the coding region of the uidA gene of Escherichia coli, in both Avena sativa and Arabidopsis thaliana. In A. sativa, the promoter was active in all organs examined and, with the exception of the anthers where the expression was localized, this activity was constitutive. In A. thaliana, the promoter activity was constitutive in the rosette leaf, stem, stamen, and root and limited primarily to vascular tissue in the sepal and the silique. The transgene was inherited and active in progeny plants of both A. sativa and A. thaliana.

Molecular characterization of banana streak acuminata Vietnam virus isolated from Musa acuminata siamea (banana cultivar).

IntroductionThe term ‘‘pararetrovirus’’ was introduced by Temin [1] foranimal (Hepadnaviridae) and plant viruses (Caulimoviri-dae) that, in contrast to retroviruses, have a DNA genomeand do not integrate into the host genome for replication.Like retroviruses, pararetroviruses use a reverse transcrip-tase for their replication.Endogenouspararetroviruses(EPRVs)inplantsrepresentcounterparts of members of the virus family Caulimoviridaeintegrated in their host’s genome. Despite the non-integra-tive replication cycle of members of the Caulimoviridae,agrowing number of integrated viral sequences have beenreported and are still being identified in various plantgenomes [2–5].Most of the integrants are silent, repetitive genomecomponents. However, some of these sequences may stillbe able to replicate and initiate viral infection undercertain conditions, according to their structural andsequence integrity and their genomic and/or epigeneticcontext.Suggestions for a uniform nomenclature of endogenousvirus sequencesFacing the rapidly growing diversity of EPRVs discoveredin plant genomes, the need for a uniform nomenclature isobvious. According to the multi-copy nature of EPRVs,important differences in sequence composition and struc-ture of integrants have been observed.It would be highly desirable for a nomenclature system(1) to distinguish endogenous from episomal caulimoviridsequences, (2) to discriminate potentially functional inte-grants from passive and pseudogene host genome compo-nents and (3) to describe the element’s viral activity in aspecific genomic context.In some genomes, a wide variety of EPRVs has beenidentified, comprising viral sequences with or withoutexogenous virus counterparts [6, 7] as well as rearrangedand functional forms of a specific virus genome [3].Like their exogenous counterparts, EPRVs can beclassified as petuvirus-like elements, badnavirus-likeelements or as members of the genera Caulimovirus,Cavemovirus or Tungrovirus according to the numberand arrangement of open reading frames (ORFs) andnucleotide sequence homologies with episomal viruses(see Table 1).