key: cord-0022556-1w52bp6s
authors: Nakayinga, Ritah; Makumi, Angela; Tumuhaise, Venansio; Tinzaara, William
title: Xanthomonas bacteriophages: a review of their biology and biocontrol applications in agriculture
date: 2021-10-25
journal: BMC Microbiol
DOI: 10.1186/s12866-021-02351-7
sha: 56326a8ec7471a24f704bac66e5b10fdd24b0d89
doc_id: 22556
cord_uid: 1w52bp6s

Phytopathogenic bacteria are economically important because they affect crop yields and threaten the livelihoods of farmers worldwide. The genus Xanthomonas is particularly significant because it is associated with some plant diseases that cause tremendous loss in yields of globally essential crops. Current management practices are ineffective, unsustainable and harmful to natural ecosystems. Bacteriophage (phage) biocontrol for plant disease management has been of particular interest from the early nineteenth century to date. Xanthomonas phage research for plant disease management continues to demonstrate promising results under laboratory and field conditions. AgriPhage has developed phage products for the control of Xanthomonas campestris pv. vesicatoria and Xanthomonas citri subsp. citri. These are causative agents for tomato, pepper spot and speck disease as well as citrus canker disease. Phage-mediated biocontrol is becoming a viable option because phages occur naturally and are safe for disease control and management. Thorough knowledge of biological characteristics of Xanthomonas phages is vital for developing effective biocontrol products. This review covers Xanthomonas phage research highlighting aspects of their ecology, biology and biocontrol applications. SUPPLEMENTARY INFORMATION: The online version contains supplementary material available at 10.1186/s12866-021-02351-7.

The genus Xanthomonas; is a well-studied group of plantassociated Gram-negative bacteria that belong to the family Xanthomonadaceae subclass Gammaproteobacteria [1] . An estimated 27 species is pathogenic to approximately 400 plants. These include but not limited to sugar cane, beans, cassava, cabbage, banana, citrus, tomatoes, pepper and rice [2] . The life cycle of Xanthomonas has two stages: epiphytic and endophytic [3] . The epiphytic stage starts once bacteria colonize the surfaces of a new plant using adhesion ligands such as bacteria surface polysaccharides [4] , adhesion proteins [5] , and type IV pili [6] . After colonization comes biofilm formation, which then protects the bacteria from environmental stress factors [7] . The endophytic stage is characterised by bacterial entry into plant tissue via lesions or stomata and eventual movement throughout the vascular system. The bacteria re-emerge onto the plant surfaces once their population reaches the threshold, transmission occurs to new hosts and the infection cycle repeats [3] .

Although Xanthomonas species are well-studied, the genus remains responsible for many crop diseases that cause crop yield losses in economically important crops worldwide [2, 3] .

The current management methods used to control Xanthomonas-associated diseases include de-budding, uprooting, burying and burning of infected plant tissues, sterilization of garden tools, and application of copperbased pesticides and antibiotics such as streptomycin [8] [9] [10] . The concerns raised about ineffective cultural practices, copper-based pesticide, antibiotic resistance problems, and environmental chemical contamination have piqued worldwide interest in Xanthomonas phage research and biocontrol application in agriculture.

Phages are viruses that infect and replicate in bacteria. Phage replication cycles include temperate and lytic pathways with the lytic pathway being the easier and more important pathway for employment in phage biocontrol. In the lytic pathway the phages bind to the surface of bacteria after which they inject their DNA and replicate inside the cell. This results in the production of phage progeny that lyse and kill the bacteria [11] . In the temperate pathway, once the phage has successfully bound and injected its DNA into the host, the phage may either stably integrate into the genome of the bacteria or enter into the lytic life cycle. Using temperate phages in phage biocontrol poses some disadvantages in that, once the phage inserts its genome into the bacterial DNA chromosome, the prophage is transmitted to daughter cells by horizontal gene transfer thereby providing undesirable genes that may aggravate bacterial disease, e.g. filamentous phage CTX Φ that encodes cholera toxin [12] .

Historically, bacteriophage-based biocontrol specific for phytopathogen Xanthomonas dates back to the early nineteenth century, when a filtrate of decomposing cabbage stopped the spread of cabbage-rot disease caused by Xanthomonas campestris pv. campestris, [13] . Decades later, similar biocontrol success was reported with phage-containing lysates that inhibited bacterial spot disease in peach caused by Xanthomonas campestris pv. pruni [14, 15] . A number of phage applications have progressed from in-vitro experiments to field trials. These include studies on bacterial spot of tomato caused by Xanthomonas campestris pv. vesicatoria [16] ; geranium bacterial blight caused by Xanthomonas campestris pv. pelargonii [17] ; leaf blight of onion caused by Xanthomonas axonopodis pv. allii [18] ; citrus canker and citrus bacterial spot caused by Xanthomonas axonopodis pv. citri and Xanthomonas axonopodis pv. citrumelo [19] ; asiatic citrus canker caused by Xanthomonas axonopodis pv. citri [20] and Xanthomonas citri subsp. citri [21] ; bacterial leaf blight of rice caused by Xanthomonas oryzae pv. oryzae [22, 23] and bacterial leaf blight of welsh onions caused by Xanthomonas axonopodis pv. allii [24] . Two Xanthomonas phage products manufactured by AgriPhage [25] have been shown to successfully control pathogens that cause tomato and pepper spot disease and citrus canker disease.

Owing to the growing interest in using Xanthomonas phages to control the genus Xanthomonas, this review emphasizes the taxonomy, ecology, biology and biocontrol applications.

A total of 168 Xanthomonas phages described to date classify into orders: Caudovirales with 151 phages and Tubulavirales with 17 phages (Additional file 1). According to the International Committee on Taxonomy of Viruses (ICTV), Caudovirales contain 9 families [26] and Xanthomonas phages reported in literature or National Centre for Biotechnology Information (NCBI) database belong to 5 families namely: Podoviridae, Siphoviridae, Myoviridae, Autographiviridae, and Herelleviridae (Additional file 1). A total of 71 Xanthomonas phages belong to Myoviridae, 42 belong to Podoviridae, 34 belong to Siphoviridae, 17 belong to Inoviridae, 3 belong to Autographiviridae and 1 member to Herelleviridae. Order Caudovirales possess tubular tails that can be either long and contractile (Myoviridae), long and noncontractile (Siphoviridae), or short and non-contractile (Podoviridae, Autographiviridae) [26] [27] [28] . The capsids of Caudovirales are non-enveloped, exhibit icosahedral symmetry with a typical diameter of 45 and 170 nm and encapsidate linear double-stranded genomes. Their genome length is between 39,980 and 384,670 nucleotides, carries between 40 and 592 open reading frames and has a guanine-cytosine (GC) content between 40 and 66% (Additional file 1). On the other hand, Tubulavirales consist of one family; Inoviridae. They are filamentous virions that possess helical symmetry and non-enveloped capsid (Additional file 1). The inovirus genomes are small, circular, single-stranded DNA molecules that range between 6000 and 8500 nucleotides. The genome encodes between 9 and 14 open reading frames and has a GC content between 57 and 60% (Additional file 1).

Ecology: geographical distribution, environmental isolation source, host bacteria and plant disease.

The geographical distribution of Xanthomonas phages spans parts of Asia, North America, South America, Europe, Zealandia and North Africa. The countries where the phages are isolated are summarized in Table 1 . The Xathomonas phages are distributed across the world depending on the pathogen that is present in that part of the world.

The environmental isolation source of Xanthomonas phages as well as bacterial host and plant disease are summarized in Table 2 . These viruses establish infection in Xanthomonas pathovars responsible for a range of plant [45] diseases including but not limited to bacterial leaf blight, black rot, bacterial leaf spot and citrus canker ( Table 2 ). The majority of Xanthomonas phages are isolated from infected plant phyllosphere and rhizosphere, while others are isolated from compost, sewage and water (irrigation, pond, freshwater lakes and rivers) ( Table 2) .

Phages with a narrow host range infect one or few of the same bacteria strains, broad host range phages infect multiple strains of the same bacteria, and polyvalent phages infect several species or unrelated genera [77, 78] . A total of 148 Xanthomonas phages described in literature have a narrow, broad or polyvalent host range. Of these 52 have a narrow and 88 have a broad host range. The remaining 8 have a polyvalent host range. The lytic activity of phages with a narrow host range is between 13 and 57% while those with a broad range is between 60 and 100% ( Table 3) . The polyvalent Xathomonas phage Pg125, is lytic to multiple strains from 25 species within the genus Xanthomonas [69] . Others in this category include phage Xcu-Pl, Xcu-P3, Xve-P1, and Xca-P1 which are lytic to Xanthomonas campestris pathovars ( Table 3) . The varied host ranges demonstrated by Xanthomonas phages imply that these lytic viruses can offer viable plant disease management alternatives. The high level of host specificity minimizes the risk of phage attack on beneficial bacteria [50] .

Incubation temperature Xanthomonas phages can maintain their viability over a wide incubation temperature range. For example, Xanthomonas phaseoli phages (1, 20, 22, ΦPS, ΦSD, ΦSL, ΦRS, Φ56, Φ112, Pg60) remain viable between 2 and 28 °C [74] ; Xanthomonas pruni phages (Xp3-A and Xp3-I) and Xanthomonas oryzae phages (Xp12 and φXOF4) between 20 and 50 °C [15, 23, 81] and Xanthomonas euvesicatoria phages (Kφ1-Kφ 15) between 35 and 70 °C [50] . Storage temperature The storage temperature of Xanthomonas phages differs between strains. The initial titer 4 × 10 7 pfu/ml of phage Kφ1, is maintained for 6 months when stored at + 4 °C in nutrient broth, compared to storage at + 20 °C where it declines to 2 × 10 7 pfu/ml within the same period [82] . Similarly, the lytic activity of Xanthomonas trifolii phages is maintained for a month at + 4 °C in phosphate buffer, pH 7 [73] . On the contrary, Xanthomonas arboricora phages (P6, P11, P15, P16, P20) survive poorly at + 4 °C in double distilled water during a one-year storage period. The initial phage titer (1 × 10 8 pfu/ml) drops drastically to 1 × 10 3 pfu/ml. The same phages decline to 8 × 10 4 pfu/ml when maintained at − 34 °C in the same media [52] . Therefore, Xanthomonas phages are maintained longer when stored at + 4 °C in nutrient broth. The appropriate storage conditions for different phages should be determined in order to ensure longevity of their effectiveness during storage and prior to biocontrol applications [83] .

Storage media, ionic strength and pH Phage viability is dependent on the storage media, ionic strength and pH and these have to be optimal to ensure phage longevity.

Different types of storage media have been investigated to understand their effects on phage viability. SM buffer is a mixture of sodium chloride (100 mM), magnesium sulphate (10 mM), tris-HCL (50 mM, pH 7.5) and gelatin (0.01%). In addition to SM buffer is nutrient broth, water/ chloroform (H 2 O-CHCl 3 ) and nutrient broth/chloroform (NB-CHCl 3 ) combinations [52] . The initial phage titer (1 × 10 10 pfu/ml) of Xanthomonas arboricora phages drops to 1 × 10 6 pfu/ml in SM buffer and to 1 × 10 5 pfu/ ml in nutrient broth and water/chloroform during a oneyear period at + 4 °C. In addition, phage titers decline further down to 1 × 10 4 pfu/ml under nutrient/chloroform combination [52] . In other studies, nutrient broth and SM buffer are favorable storage media for phage viability at + 4 °C for long-term storage. For example, the initial titer, 8 × 10 10 pfu/ml of phage Kφ1 declines slightly to 8 × 10 9 pfu/ml in nutrient broth and SM buffer at + 4 °C during a three-week storage period [82] . Further decline in phage titer of 3 × 10 9 pfu/ml is detected in sterile tap water and 10 mM magnesium sulphate while in distilled water the titers sharply fall to 3 × 10 7 pfu/ml at the same storage temperature and period [82] . Therefore, SM buffer is a better medium for phage survival than nutrient broth, tap water, magnesium sulphate, water/chloroform and nutrient broth/chloroform combinations [52] . The right storage media type will preserve the structural integrity of the phage and retain their infectivity during long-term storage [83] .

The effect of ionic strength (salt concentration in liquid media) and pH on phage viability has been studied for a few Xanthomonas phages. Xp12 and Cf, lytic activity is maintained in distilled water or 0.1 M phosphate buffer, pH 7.0. However, the ability of these phages to lyse bacterial cells is prevented when they are stored in normal saline (0.9% sodium chloride) or 0.1 M citrate phosphate buffer, pH 7.0 [67, 84] . The optimal pH of Xanthomonas phages is between 5 and 11, with a number of phages being stable in acidic conditions such as pH 4 [23, 67, 82, 85] .

The phyllosphere is a hostile environment and many factors such as ultraviolet (UV) irradiation prevent phage persistence and survivability [86] . As with all phages, Xanthomonas phages are inactivated by UV light. Formulations that increase phage survival consist of milk, corn and sucrose, minimizing UV-induced damages that result from the production of thymine dimers [82, 87, 88] .

Chloroform treatment during isolation and enrichment process is used to release phage and kill host bacteria [89] . With the exception of Xf and Cf, many Xanthomonas phages are resistant to chloroform treatment because they lack a lipid envelope that surrounds the capsid. The organic solvent disrupts lipid membranes and inactivates the phage [23, 50, 52, 74, 82, 90] . The ability to resist chloroform denaturation makes non-enveloped Xanthomonas phages easy to isolate, culture and maintained for long-term storage [88] .

Generally, clear plaques on a bacterial lawn could suggest that phages may have lytic life cycles, while turbid plaques represent temperate life cycles [91] . Xanthomonas phages produce both lytic and turbid plaques ( Table 4 ). The latter outcome is due to the absence of bacterial host lysis resulting from phage genome integration into host bacteria chromosomes, causing latent infection [27] . Genome integration is facilitated by host XerC/D recombinases that mediate site-specific recombination of the phage genome into a 15 base-pair dif locus of the bacterial genome [93, 98] . Unlike lytic phages, temperate phages are not suitable for use as biocontrol agents due to their ability to cause lysogenic conversion, induction of superinfection immunity and increased risk of horizontal gene transfer [83] . During adsorption, Xanthomonas phages bind to different bacteria host cell surface receptors [99] . The adsorption of phage ΦL7 onto Xanthomonas campestris pv. campestris requires binding to a complex receptor consisting of lipopolysaccharide and a secondary protein on the outer membrane.

Other filamentous phages such as Cf use the host pili (pilR) to bind to Xanthomonas campestris pv. citri [94, 100] . The phage then penetrates using chaperon proteins such as, TonB, ExbB, and ExbD1 encoded by operon, tonB-exbB-exbD1-exbD2 [101, 102] . The host bacteria are lysed by peptidoglycan glycohydrolase, which is located in the phage tail [103] .

The replication of phages is studied using the one-step growth experiment which measures the latent period and burst size of a phage on a specific bacterium. These are essential parameters in the description of phage properties. The latent period is the period between initial phage adsorption to a host cell to lysis and release of progeny viruses [91] . Xanthomonas phages have short latent periods ranging from 20 to 45 min to moderate periods, 60 to 90 min (Table 5 ). Very long latent periods ranging from 120 to 210 min occur for P125, Xoo-sp2, Xp12 (Siphorividae) and XTP (Myoviridae) ( Table 5 ). The burst sizes range from 4.6 to 350 virions per infected cell (pfu/cell), with P125 showing the lowest burst size (4.6 pfu/cell) and Xoo-sp2 with the highest burst size (350 pfu/cell) ( Table 5 ).

The multiplicity of infection (MOI) of reported Xanthomonas phages lie between 0.001 to 1, with the lowest observed for phage X2 at 0.001, and highest for X4, X5 and XTP1 at 1 (Table 5 ). It has been reported that phages with short latent period and high burst size have more efficient replication cycles [105] . Also, the optimal temperature and incubation time are essential parameters during phage adsorption. These conditions range between 22 and 30 °C, while incubation times are between 5 and 30 min for Xanthomonas phages (Table 5) .

Phage-bacterial infection induces molecular changes that include DNA methylation, phosphorylation and transcription. DNA methylation is well-studied in phage Xp12 [81] . Upon infection in Xanthomonas oryzae pv. oryzae, Xp12 induces biosynthesis of an unusual base, 5-methylcytosine, that replaces all cytosine residues in the DNA of Xp12 [81] . The rest of the bases; adenine, thymine, and guanine, remain unaltered [67, 81] . DNA methylation confers unique physical and chemical properties upon Xp12 DNA i.e., acquisition of a low buoyant density and high melting temperature, compared to typical DNA [106] . The Xp12 phage-infected bacterial cells produce an enzyme deoxycytidylate methyltransferase, Cp2 Lytic X. axonopodis pv. citri [92] XP3-A Lytic X. pruni [15] XP3-I Lytic X. pruni [15] Kφ1 Lytic X. euvesicatoria [50] Kφ8 Lytic X. euvesicatoria [50] Kφ15 Lytic X. euvesicatoria [50] Kφ1-9 and Kφ15 Lytic X. euvesicatoria [50] Xoo-sp2 Lytic X. oryzae pv. oryzae [30] Xoo-sp1-15 Lytic X. oryzae pv. oryzae [30] Xp12 Lytic X. oryzae pv. oryzae [81] X1 Lytic X. oryzae pv. oryzae [31] X2 Lytic X. oryzae pv. oryzae [31] X3 Lytic X. oryzae pv. oryzae [31] X4 Lytic X. oryzae pv. oryzae [31] X5 Lytic X. oryzae pv. oryzae [31] φXOF4,φXOF1,φXOF 2,φXOF3, φXOT1,φXOT2,φXOM1 Lytic X. oryzae pv. oryzae [23] P4L Cf Temperate/carrier state X. citri [84] φL7 Lytic X. campestris pv. campestris [95] that catalyzes the direct methylation of deoxycytidine monophosphate (dCMP) to 5-methylcytosine, in the presence of tetrahydrofolic acid [107, 108] . Modification of phosphorylation occurs during Xanthomonas phage infection. When Xp12 infects Xanthomonas oryzae pv. oryzae, phosphorylation of three proteins is induced. The phosphorylated proteins 28 kDa, 28.5 kDa and 45 kDa in size are present only on infected cells. This type of molecular modification is suggestive of the existence of a phage specific regulatory mechanism involved during phage infection [109] .

Transcriptional modifications are initiated upon phage-bacterial infection. In phage Xp10, infecting Xanthomonas oryzae pv. oryzae displays complete loss of transcription activity due deactivation of host RNA polymerase resulting from dissociation of the δ subunit from the host core RNA polymerase [110] . Later studies show that Xp10 reverts the transcription process by encoding an anti-termination factor p7 that allows formation of RNA transcripts by host RNA polymerase [111] .

This section explores several approaches where Xanthomonas phages are employed as biocontrol agents to manage Xanthomonas species in either greenhouse or field conditions. These methods have been successful at either inhibiting Xanthomonas growth or reducing disease severity. These include, but are not limited to use of monophages or cocktail treatments, phage mixtures with non-pathogenic or with pathogenic bacteria, phage combinations with antibiotics or plant inducers, UVprotectants and phage mutants [16, 21, 24, 30, 88, 112, 113] .

To date, two Xanthomonas phage-based products are commercially available for the biocontrol of tomato, pepper spot and citrus canker [25] . The earliest evidence of Xanthomonas phage application was published in the early nineteenth century by Mallmann & Hemstreet [13] , who determined that filtrate from decomposing cabbage applied to rotting cabbage inhibits the growth of Xanthomonas campestris pv. campestris in infected tissue. Since then, other forms of phage mixtures have been investigated.

Civerolo [114] applied crude lysates of lytic phage cocktail (Xp3-A and Xp3-I) on peach seedling foliage, 1-2 h before infection with Xanthomonas pruni under greenhouse conditions. Only 6-8% of leaves were infected, and the disease significantly reduced to 17-31% compared with 96% recorded on the water-treated control plants.

In addition, application of either Xp3-A or Xp3-I mixed with Xanthomonas pruni and applied immediately before pathogen inoculation resulted in a 51-54% decrease of bacterial spot symptoms in peach seedlings under similar environmental settings. Therefore, the use of the phage cocktail significantly reduced disease severity better than single phage-pathogen mixture. This could be due to the synergy between the replication characteristics of both phages in the cocktail i.e. the latent period of Xp3-A and Xp3-I is 30-45 min and 60-75 min, whereas the burst size is 42-49 and 176-256 pfu/cell [114] . Some studies disagree with the evidence that supports the benefits provided by cocktail phage biocontrol of Xanthomonas associated diseases. In a recent study [24] , spray application of a purified phage cocktail made up of three phages (ɸ16, ɸ17A, ɸ31) failed to inhibit the growth Xanthomonas axonopodis pv. allii, the causative agent of bacterial leaf blight of welsh onions. The cocktail treatment reduced infection of onion leaves to 43.3%, while a monophage phage treatment consisting ɸ31 reduced to 26.6% compared to the untreated, infected control leaves at 67.5% at 9 days after inoculation. Phage ɸ31, family Autographiviridae, had the broadest spectrum and lysed 12 out of 12 Xanthomonas axonopodis pv. allii strains, a trait that may contribute to its biological efficacy [24] .

In another study [23] , the phage φXOF4 inhibited the growth of Xanthomonas oryzae pv. oryzae that causes bacterial leaf blight. The seedlings treated with φXOF4 at a titer of 1 × 10 8 pfu/ml showed no symptoms compared to 73% of the untreated group. Phage φXOF4, Siphoviridae, exhibited a broad host range where it lysed 6 out of 6 Xanthomonas oryzae pv. oryzae strains and had a short latent period between 20 and 30 min and a burst size that yields to the titer 1.8 × 10 7 pfu/ml. There is preference for cocktail phages because of their ability to effectively control pathogenic strains and delay the emergence of resistant strains [115, 116] ; however, studies [23, 24] support the evidence that monophage treatment can be effective at disease reduction or elimination.

Applications of premixed phage-pathogen suspensions are further demonstrated by Dong [30] , who observed low treatment outcomes in rice plants treated with Xoo-sp2 and Xanthomonas oryzae pv. oryzae suspension. The average lesion length in treated plants was 13.31 ± 1.69 cm compared to two control groups treated in sterile water (20.83 ± 2.43 cm) or skimmed milk (19.29 ± 2.07 cm). Phage Xoo-sp2 (Siphoviridae) had a broad host range where it lysed 9 out of 10 Xanthomonas oryzae pv. oryzae strains and had a latent period of 180 min and burst size of 350 pfu/cell. Although the authors considered only Xoo-sp2 out of the 15 phages, a phage cocktail should have been considered to improve biocontrol efficacy since the remaining phages displayed equally a broad host range where they lysed 9 out of 10 of the same strains.

Alternative control approaches using non-pathogenic bacteria and phage suspensions are demonstrated by Nagai [112] . The combination of non-pathogenic Xanthomonas strain (npX, AXCB1201) and phage (pXS, XcpSFC211) was sprayed on broccoli plants before inoculation of Xanthomonas campestris pv. campestris. The npX-pXS mixture significantly reduced disease severity to 18.9% compared with 86.2% by pXS alone and 93.7% of water-treated control plants in greenhouse settings. Field trials showed a decrease in disease severity albeit lower than the results from the greenhouse experiments. The npX-pXS mixture reduced the symptoms by 74% compared to 98% of water treated control plants or 86% of copper treated plants [112] .

Integration of Xanthomonas phages with antimicrobials or UV-protectants has been explored as a disease management option. Borah [117] found that the combination of phage (XMP-1) and antibiotic (streptomycin) suppressed leaf spot of mungbean caused by Xanthomonas axonopodis pv. vignaeradiatae to 4% compared with 68% of the untreated seedlings. Moreover, seed germination increased to 86% in comparison to 75% in the untreated group. Furthermore, Balogh [88] applied formulated phages on tomato plants infected with bacterial spot incited by Xanthomonas campestris pv. vesicatoria. The phages were mixed with either 0.5% pregelatinized cornflour (PCF), casecrete NH-400 with 0.25% PCF, or 0.75% powdered skim milk with 0.5% sucrose. Phage treatment improved plant yield by 62% (skim milk), 51% (Casecrete), and 30% (PCF) compared to unformulated phages at 1% in greenhouse experiments. Under field experiments, phage treatment increased plant yield by 18% (skim milk), 32% (casecrete) and 23% (PCF) compared to unformulated phages at 14%. Therefore, skim milk gave better results in greenhouse experiments while casecrete performed better in the field. Similarly, Tewfike and Shimaa [66] found that formulated phages in skim milk controlled better bacterial halo blight symptoms of pepper caused by Xanthomonas axonopodis than with corn flour by 20.5 and 18.3% in the greenhouse and 19.5 and 32.2% in field conditions. Some studies have shown that unformulated phages can control better plant diseases. Balogh [19] applied unformulated phages to citrus leaves infected with asiatic citrus canker and recorded an average of 59% reduction in disease severity in five greenhouse experiments. The same phage mixture in skim milk was not effective at controlling disease under similar environmental settings. In nursery experiments, unformulated phage treatment also reduced disease, but was less effective than copper-mancozeb, a chemical bactericide. Moreover, mixing the unformulated phages with copper-mancozeb achieved comparable results to unformulated phages alone [19] . Therefore different field settings (greenhouse, open field and nursery beds) should be considered during biocontrol studies because there is a possibility that phage efficacy depends on the field settings.

Plant inducers successfully control plant diseases, and therefore form an integral part of disease management practices. The application of mixtures of phages in skim milk/sucrose with Acibenzolar-S-methyl (ASM), a plant inducer, decrease the bacterial spot of tomato caused by Xanthomonas campestris pv. vesicatoria under field conditions. The fruit yield of the formulated phage/ASM mixture was 67.9% compared to 60.8% of untreated control when applied twice biweekly in the first year [113] . Equally, Ibrahim [21] applied mixtures containing ASM and phages in skim milk/sucrose on citrus leaves for 4 days triweekly before inoculation of Xanthomonas citri subsp. citri, causative agent of asiatic citrus canker. Disease severity was reduced to 18.3% compared to 75.2% of the untreated control under greenhouse conditions. This observation agrees with results from field experiments where ASM/phages in skim milk/sucrose reduced disease to 12.5%, compared to 70.2% of the untreated control. When ASM was applied alone in the soil by drenching method, the disease was reduced to 38.2%, compared to 74.3% of the water-treated group after spraying 7 times triweekly before pathogen inoculation.

Mutated phages in formulations provide modest protection against plant disease compared with unformulated phages. The h-mutant phage mixtures (PMh; P4L, P43M, P23M1) in skim milk reduced bacterial blight disease of rice incited by Xanthomonas oryzae pv. oryzae to 18.1%, and wild type phage mixtures (PM; P4L, P43M, and P23M1) in the same formulation reduced the disease to 19.2%, compared to 39.1% of the untreated group. The mixtures were sprayed three times within an interval of 10 days. These tailed phages belong to the family Myoviridae and possess broad host range properties. Phage P4L lysed 33 out of 47, while P43M and P23M1 lysed 47 out of 47 Xanthomonas oryzae pv. oryzae strains [22] . Treatment with tecloftalam wettable powder, an agrochemical, demonstrated better results, with the disease symptoms reduced to 5% [22] . Therefore integration of tecloftalam wettable powder in plant protection could be a promising strategy for managing bacterial blight disease. On the contrary, agrochemicals have proved to be less effective than phages in controlling plant diseases. In a two-year greenhouse experiment, formulated phage DB1 in skim milk demonstrated improved black rot control by 71.1% while copper-based pesticide by 59.1%. Thus black rot caused by Xanthomonas campestris pv. campestris on cabbage seedlings can be successfully controlled by phage application [49] .

Unformulated mutants reduce disease severity in infected plants. Flaherty [16] applied a mixture of host range mutant phages on tomato seedlings infected with Xanthomonas campestris pv. vesicatoria and symptoms of bacterial spot of tomato reduced to 0.9% compared to 40.5% of the untreated in the greenhouse. It increased the total weight of extra-large fruit by 14.9 and 24.2% in 1997 and 1998, respectively. Similarly, the severity of geranium bacterial blight declined when unformulated phage mutant mixtures were applied daily by foliar sprays on potted and seedling geraniums in greenhouse conditions [17] .

Biofilm degradation is essential for the control of bacterial pathogenicity. The phage X3 causes 53% degradation of exopolysaccharide production and 43% biofilm degradation caused by Xanthomonas oryzae pv. oryzae that causes bacterial blight of rice [31] . When phage X3 was sprayed on rice plant foliage and seeds before pathogen inoculation, the plants improved by 83.1 and 95.4%. The phage X3 did not perform well when applied after pathogen inoculation, with results recorded between 28.9 and 73.9% [31] . Phage X3, family Myoviridae, had the broadest host range, lysed 22 out of the 23 Xanthomonas oryzae pv. oryzae strains tested and had the most extended latent period of 40 min with a burst size of 50 pfu/cell [31] . Likewise, infection of XacF1 (Inoviridae), a temperate phage, pathogenic to Xanthomonas axonopodis pv. citri, causing asiatic citrus canker, inhibits xanthan production, a component of extracellular polysaccharide that exacerbates the disease. The lesions on leaves sprayed with XacF1 reduced to 1 mm in width compared to 6.5 mm in untreated leaves. Therefore, the reduction in xanthan production caused by XacF1 phage reduces disease symptoms [20] .

The frequency of phage spray and contact time on plant surfaces are factors investigated to improve the efficacy of phage applications. Lang [18] showed that multiple applications, i.e. biweekly or weekly applications of phages, effectively reduce symptoms of leaf blight of onion caused by Xanthomonas axonopodis pv. allii to 50%. Similar results were obtained when copper hydroxide-mancozeb was sprayed weekly on onion plants. Furthermore, biweekly application of Acibenzolar-S-methyl and phages reduced the disease by up to 50%. Hence, biweekly spray schedules are a promising strategy for sustainable control of leaf blight of onion.

Successful control of plant diseases is directly linked to the contact time of phages on plant surfaces. Gašić [82] successfully controlled bacterial pepper spot caused by Xanthomonas euvesicatoria by allowing a long contact time of phage Kφ1 (Myoviridae) on plant leaves. The longest time of phage contact was 2 h before and 15 min after pathogen inoculation. This resulted in an average lesion number of 157, 213, and 189 compared to 332, 422, and 567 of the untreated control in three greenhouse experiments. The contact time experiments were further tested on copper hydroxide mixed with Kφ1. At a contact time of 26 h before pathogen inoculation, a significant reduction in average lesion number was observed with scores of 63, 41, and 66 compared to 332, 422, and 567 of the untreated control. Thus longer contact time of phage Kφ1 on plant surfaces allows effective control of pepper bacterial spot. There is a direct relationship between the timing of phage application and the efficacy of disease control. Evening applications of phage on foliage achieve better disease control since this period minimizes phage exposure to UV irradiation and extends phage longevity [88] . Phage Kφ1 had the broadest host range where it lysed 59 out of 59 Xanthomonas euvesicatoria strains [50] and had a latent period and burst size of 20 min and 75 phage particles per infected cell respectively. Its multiplication and broad lytic abilities may contribute to its success at managing pepper bacterial spot.

The study of phage lysins as alternative biocontrol for Xanthomonas phytopathogens is rarely reported. One study has shown that phage lysozyme, Lys411, encoded by the genome of Xanthomonas oryzae phage, φXo411, can lyse Xanthomonas strains, making the protein a candidate with potential to control plant diseases caused by Xanthomonas [118] .

One of the limitations faced by plant-based phage application is the hostile environment of the phyllosphere, where phages degrade rapidly due to desiccation or UV light. Phage formulations demonstrate protective benefits that enhance phage longevity and antibacterial activity [19, 88] ; however, not all phages are effective in UV protectants [19] . Although, leaf surfaces of some plants do support phage multiplications, others do not; and this could potentially have adverse effects on the efficacy of a biocontrol product. Balogh [119] found that two Xanthomonas perforans phages (ɸXv3-21 and ɸXp06-02) multiplied and maintained populations on tomato leaf surface but did not achieve the same level of multiplication on grapefruit leaves. More research is needed to understand plant compounds involved and the mechanisms involved in this plant-phage interaction.

Several Xanthomonas phages are evaluated for their potential as biocontrol agents against Xanthomonas species. So far, most of these belong to order Caudovirales and are lytic to a broad range of host strains. They are isolated from diverse ecosystems and distributed across the globe depending on the presence of the pathogen they infect. Their structural integrity and functionality in in vitro conditions is maintained under optimal growth and storage conditions. Pathogenesis of Xanthomonas phages in bacteria induce molecular alterations that may have regulatory functions important during their life cycle. Although few studies have focused on this aspect of biology, more research is needed to understand their life cycle.

From their first discovery in filtrates to applications as phage/pathogen suspensions, or in combination with other antimicrobials or with UV-protectants or as cocktail/monophage treatments, phages have proved to be promising alternatives to agrochemicals and antibiotics. They can reduce disease severity or inhibit bacteria growth in diverse field settings. So far, two Xanthomonas phage-based biocontrol products are commercially available for plant disease control. As the transition into commercial products continues, more studies are needed to tap into the many unexploited potentials of Xanthomonas phages for a range of Xanthomonas related plant diseases.

Whole-proteome phylogeny of prokaryotes by feature frequency profiles: an alignment-free method with optimal feature resolution

Pathogenomics of Xanthomonas: understanding bacterium-plant interactions

Mechanistic insights into host adaptation, virulence and epidemiology of the phytopathogen Xanthomonas

Modifications of Xanthomonas axonopodis pv. citri lipopolysaccharide affect the basal response and the virulence process during citrus canker

XadM, a novel adhesin of Xanthomonas oryzae pv. Oryzae, exhibits similarity to Rhs family proteins and is required for optimum attachment, biofilm formation, and virulence

Xanthomonas citri subsp. citri type IV pilus is required for twitching motility, biofilm development, and adherence

Biofilm formation and dispersal in Xanthomonas campestris

Banana Xanthomonas wilt: a review of the disease, management strategies and future research directions

Antibiotic resistance in plant-pathogenic bacteria

Copper in plant protection: current situation and prospects

Phage therapy in the postantibiotic era

A review of phage therapy against bacterial pathogens of aquatic and terrestrial organisms

Isolation of an inhibitory substance from plants

Inhibition of bacterial spot of peach foliage by Xanthomonas pruni bacteriophage

Comparative relationships between two Xanthomonas pruni bacteriophages and their bacterial host

Control of bacterial spot on tomato in the greenhouse and field with H-mutant bacteriophages

H-mutant bacteriophages as a potential biocontrol of bacterial blight of geranium

Management of Xanthomonas leaf blight of onion with bacteriophages and a plant activator

Control of citrus canker and citrus bacterial spot with bacteriophages

The filamentous phage XacF1 causes loss of virulence in Xanthomonas axonopodis pv. citri, the causative agent of citrus canker disease

Management of asiatic citrus canker under field conditions in Saudi Arabia using bacteriophages and acibenzolar-S-methyl

Diversity of bacteriophages infecting Xanthomonas oryzae pv. Oryzae in paddy fields and its potential to control bacterial leaf blight of rice

Bacteriophages: a new weapon for the control of bacterial blight disease in rice caused by Xanthomonas oryzae

Phage biocontrol of bacterial leaf blight disease on welsh onion caused by Xanthomonas axonopodis pv allii

Changes to virus taxonomy and the statutes ratified by the international committee on taxonomy of viruses

Tailed bacteriophages: the order Caudovirales

Virus taxonomy. Ninth report of the international committee on taxonomy of viruses

Comparison of genomes of three Xanthomonas oryzae bacteriophages

Isolation and characterization of a novel phage Xoo-sp2 that infects Xanthomonas oryzae pv

Identification and characterization of five new OP2-related Myoviridae bacteriophages infecting different strains of Xanthomonas oryzae pv

Characterization of three bacteriophages of Xanthomonas oryzae (Uyeda et Ishiyama) Dowson

Xanthomonas citri jumbo phage XacN1 exhibits a wide host range and high complement of tRNA genes

Complete Ggenome Ssequences of 10 Xanthomonas oryzae pv

Characterization of lytic bacteriophage XCC9SH3 infecting Xanthomonas campestris pv

Characterization of Xanthomonas axonopodis pv. punicae (Hingorani and Singh) Vauterin et al. and isolation of Xap specific bacteriophage

Complete genome sequence of Xanthomonas phage pagan

Complete genome sequence of Xanthomonas phage river rider, a novel N4-like bacteriophage that infects the strawberry pathogen Xanthomonas fragariae

Complete genome sequence of XaF13 a novel bacteriophage of Xanthomonas vesicatoria from Mexico

Biological and molecular characterization of a bacteriophage infecting Xanthomonas campestris pv. Campestris, isolated from brassica fields

Complete genome sequences of lytic bacteriophages of Xanthomonas arboricola pv

Improved efficacy of formulated bacteriophage in control of black rot caused by Xanthomonas campestris pv. Campestris on cabbage seedlings

Isolation and characterization of Xanthomonas euvesicatoria bacteriophages

Bacteriophages as a potential biocontrol agent against walnut blight (Xanthomonas campestris pv. Juglandis)

Isolation and characterization of bacteriophages infecting Xanthomonas arboricola pv. Juglandis, the causal agent of walnut blight disease

National Center for Biotechnology Information. Bethesda Maryland. 2021

Biocontrol of Xanthomonas axonopodis causing bacterial spot by application of formulated phage

Phage Xp12 of Xanthomonas oryzae (Uyeda et Ishiyama) Dowson

A filamentous bacteriophage from Xanthomonas oryzae

A bacteriophage that attacks numerous phytopathogenic Xanthomonas species

Bacteriophages promote metabolic changes in bacteria biofilm. Microorganisms

Isolation and characterization of a generalized transducing phage for Xanthomonas campestris pv

Host range and particle morphology of some bacteriophages affecting pathovars of Xanthomonas campestris

Specificity of bacterial virus for Xanthomonas trifolii

Characterization of Xanthomonas phaseoli bacteriophages

Phage types of Xanthomonas phaseoli isolated from beans

Complete genome sequence of Xanthomonas siphophage Samson

Phage multiplication

Ecology of prokaryotic viruses

Host specific bacteriophages of Xanthomonas vesicatoria

Classification of strains of Xanthomonas oryzae on the basis of their susceptibility against bacteriophages

5-Methylcytosine replacing cytosine in the deoxyribonucleic acid of a bacteriophage for Xanthomonas oryzae

Complete genome of the Xanthomonas euvesicatoria specific bacteriophage KΦ1, its survival and potential in control of pepper bacterial spot

Phage choice, isolation, and preparation for phage therapy

Characterization of a new filamentous phage Cf from Xanthomonas citri

Cultural characteristics of Xanthomonas axonopodis pv. Citri bacteriophages CP1 from Korea

Factors affecting survival of bacteriophage on tomato leaf surfaces

Effects of sunlight on bacteriophage viability and structure

Improved efficacy of newly formulated bacteriophages for management of bacterial spot on tomato

Microbial selection strategies that enhance the likelihood of developing commercial biological control products

Nucleotide sequences involved in the neolysogenic insertion of filamentous phage Cf16-v1 into the Xanthomonas campestris pv.Citri chromosome

Isolation, characterization, and interactions. 1 st

Characterization of bacteriophages cp1 and cp2, the strain-typing agents for Xanthomonas axonopodis pv

Neolysogenization of Xanthomonas campestris pv. citri infected with filamentous phage Cf16

The lysogenic cycle of the filamentous phage Cflt from Xanthomonas campestris pv

Genomic characterization of the intron-containing T7-like phage phiL7 of Xanthomonas campestris

Complete nucleotide sequence of filamentous phage Cf1c from Xanthomonas campestris pv. citri

Complete nucleotide sequence of a new filamentous phage, Xf109, which integrates its genome into the chromosomal DNA of Xanthomonas oryzae

Characterization of an open reading frame involved in site-specific integration of filamentous phage Cflt from Xanthomonas campestris pv

Bacteriophage ecology. Encycl Microbiol

PilR enhances the sensitivity of Xanthomonas axonopodis pv. Citri to the infection of filamentous bacteriophage Cf

Mutation in the Xanthomonas campestris xanA gene required for synthesis of xanthan and lipopolysaccharide drastically reduces the efficiency of bacteriophage ΦL7 adsorption

Involvement of tonB-exbBD1D2 operon in infection of Xanthomonas campestris phage φL7

Identification of a broad-spectrum peptidoglycan hydrolase associated with the particle of Xanthomonas oryzae

The use of bacteriophage of Xanthomonas phaseoli in detecting infection in beans, with observation on its growth and morphology

Bacteriophages of plant pathogens

Unusual properties of the DNA from Xanthomonas phage XP-12 in which 5-methylcytosine completely replaces cytosine

Enzymatic synthesis of deoxy-5-methyl-cytidylic acid replacing deoxycytidylic acid in Xanthomonas oryzae phage Xp12 DNA

A new thymidylate biosynthesis in Xanthomonas oryzae infected by phage Xp12

Specific protein phosphorylation induced in Xanthomonas campestris pv. Oryzae by bacteriophage Xp12

Disassociation of sigma subunit from RNA polymerase of Xanthomonas oryzae pv. Oryzae by phage Xp10 infection

Bacteriophage Xp10 anti-termination factor p7 induces forward translocation by host RNA polymerase

Improved control of black rot of broccoli caused by Xanthomonas campestris pv. Campestris using a bacteriophage and a nonpathogenic Xanthomonas sp

Management of tomato bacterial spot in the field by foliar applications of bacteriophages and SAR inducers

Relationship of Xanthomonas pruni bacteriophages to bacterial spot disease in Prunus

Guidelines to compose an ideal bacteriophage cocktail

Phage cocktails and the future of phage therapy

Integrated management of bacterial leaf spot of mungbean with bacteriophages of Xanthomonas axonopodis pv. Vignaeradiatae and chemicals

A novel lysozyme from Xanthomonas oryzae phage ɸXo411 active against Xanthomonas and Stenotrophomonas

Relative level of bacteriophage multiplication in vitro or in phyllosphere may not predict in planta efficacy for controlling bacterial leaf spot on tomato caused by Xanthomonas perforans

Comparative analysis of two bacteriophages of Xanthomonas arboricola pv

Bacteriophage OP1, lytic for Xanthomonas oryzae pv. Oryzae, changes its host range by duplication and deletion of the small domain the deduced tail fiber gene

Genome of Xanthomonas oryzae bacteriophage Xp10: an odd T-odd phage

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Structure and composition of Xanthomonas pruni bacteriophage

Center for Biotechnology Information. Bethesda Maryland. 2021

Characterization of two novel filamentous phages of Xanthomonas

Characterization of filamentous bacteriophage ΦLf from Xanthomonas campestris pv

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The online version contains supplementary material available at https:// doi. org/ 10. 1186/ s12866-021-02351-7.Additional file 1 : Table S1 Taxonomic classification, genomic properties and host bacteria of Xanthomonas phages. Description of data: Xanthomonas phages of order Caudovirales and Tubulavirales, their morphological and genomic properties and host bacteria.