Application of nanoparticles for management of plant viral pathogen: Current status and future prospects.

Plant viruses are responsible for nearly 47 % of all crop losses brought by plant diseases, which have a considerable negative impact on agricultural output. Nanoparticles have the potential to greatly raise agricultural output due to their wonderful applications in the fields of highly sensitive biomolecular detection, disease diagnostics, antimicrobials, and therapeutic compounds. The application of nanotechnology in plant virology is known as nanophytovirology, and it involves biostimulation, drug transport, genetic manipulation, therapeutic agents, and induction of plant defenses. The inactivation and denaturation of capsid protein, nucleic acids (RNA or DNA), and other protein constituents are involved in the underlying mechanism. To determine the precise mechanism by which nanoparticles affect viral mobility, reproduction, encapsidation, and transmission, more research is however required. Nanoparticles can be used to precisely detect plant viruses using nanobiosensors or as biostimulants. The varieties of nanoparticles employed in plant virus control and their methods of virus suppression are highlighted in this review.

Emerging Nanotechnological Applications in Preserving and Improving the Shelf Life of Food.

The ever-growing demand for safe and nutritious food has activated the scrutinization of innovative approaches to enhance food preservation and extended shelf life. Nanotechnology has progressed by making a significant contribution to the food industry at the nanoscale level and appeared as a promising avenue for these challenges. Various nanomaterials have been employed to preserve and extend the shelf life of a variety of food products. Since most harvested fruits and vegetables have a perishable nature, they cannot be preserved in natural circumstances for a long period. Due to a range of unique qualities, nanotechnology-related shelf life extension technologies can compensate for the limitations of normal preservation procedures. The encapsulation of nutraceuticals increases their stability and bioavailability, resulting in beneficial effects on humans. Nanoparticles are used as carriers of health-promoting and/or functional substances in product formulations. They have shown excellent effectiveness in encapsulating bioactive substances and retaining their qualities to ensure their functioning (antioxidant and antibacterial) in food products. This review focuses on the current developments in nanotechnology and their application for improving shelf life and food preservation techniques. Here we excavated the implementation of different types and forms of nanostructured materials (NSMs), from inorganic metals, metal oxides, and their nanocomposites to nano-organic materials incorporating bioactive chemicals in the food system. This review also focuses on exploring the slow and sustainable release of the bioactive compounds, and nutrients enriching the taste and sensory characteristics of the food. Throughout the paper, we dug deep into the regulatory, food safety, and assessment concerns about nanotechnology. The review provides a deep understanding of the developing landscape of nanotechnological applications, challenges, and future opportunities revolutionizing the preservation and extended shelf life of food products.

Integration of phenotypic, qPCR and genome sequencing methodologies for the detection of antimicrobial resistance and virulence in clinical isolates of a tertiary hospital, India.

The emergence of antimicrobial resistance (AMR) and virulence in clinical isolates is a significant public health concern. The rapid and accurate detection of these traits in clinical isolates is essential for effective infection control and treatment. We demonstrated the integration of multiple detection methodologies, including phenotypic testing, quantitative polymerase chain reaction (qPCR), and genome sequencing, to detect AMR and virulence in clinical isolates. One hundred sixty-two gram-negative bacterial clinical isolates were selected for this study from the Shri Vinoba Bhave Civil Hospital, Silvassa, a tertiary government hospital. Antimicrobial susceptibility was detected by determining the Minimum Inhibitory Concentration (MIC) using Vitek-2, whereas the combined disk (CD) method was used for phenotypic detection of carbapenemase activity. The highest sensitivity rates were obtained for antibiotics colistin 87.93%, amikacin 67.52%, tigecycline 63.39%, nitrofurantoin 60.87%, and gentamycin 56.08%. The most resistant antibiotics were ceftazidime (71.93%), ciprofloxacin (67.95%) and trimethoprim/sulfamethoxazole (65.56%). Approximately 46.91% (76) of all the isolates were MBL isolates. The qPCR results confirmed the presence of blaNDM-1 in 29.01% of the isolates. The blaNDM-1 harbouring isolates in descending order, were Acinetobacter, Enterobacter cloacae, and Klebsiella pneumoniae. Klebsiella and Acinetobacter isolates were extensively drug-resistant. Whole genome sequencing performed on one of the Klebsiella pneumoniae isolates revealed the presence of many virulence factors, which increased the pathogenicity of the clinical isolates. The results showed that antimicrobial resistance, including carbapenem resistance, blaNDM-1, and virulence factors, was highly prevalent among isolates from tertiary clinical hospitals. The integration of multiple detection methodologies can potentially improve the detection of AMR and virulence in clinical isolates, leading to better patient outcomes and a reduced spread of these essential traits.

The role of nanocomposites against biofilm infections in humans.

The use of nanomaterials in several fields of science has undergone a revolution in the last few decades. It has been reported by the National Institutes of Health (NIH) that 65% and 80% of infections are accountable for at least 65% of human bacterial infections. One of their important applications in healthcare is the use of nanoparticles (NPs) to eradicate free-floating bacteria and those that form biofilms. A nanocomposite (NC) is a multiphase stable fabric with one or three dimensions that are much smaller than 100 nm, or systems with nanoscale repeat distances between the unique phases that make up the material. Using NC materials to get rid of germs is a more sophisticated and effective technique to destroy bacterial biofilms. These biofilms are refractory to standard antibiotics, mainly to chronic infections and non-healing wounds. Materials like graphene and chitosan can be utilized to make several forms of NCs, in addition to different metal oxides. The ability of NCs to address the issue of bacterial resistance is its main advantage over antibiotics. This review highlights the synthesis, characterization, and mechanism through which NCs disrupt Gram-positive and Gram-negative bacterial biofilms, and their relative benefits and drawbacks. There is an urgent need to develop materials like NCs with a larger spectrum of action due to the rising prevalence of human bacterial diseases that are multidrug-resistant and form biofilms.

Development of a real-time RT-PCR method for the detection of Citrus tristeza virus (CTV) and its implication in studying virus distribution in planta.

Tristeza is an economically important disease of the citrus caused by Citrus tristeza virus (CTV) of genus Closterovirus and family Closteroviridae. The disease has caused tremendous losses to citrus industry worldwide by killing millions of trees, reducing the productivity and total production. Enormous efforts have been made in many countries to prevent the viral spread and the losses caused by the disease. To understand the reason behind this scenario, studies on virus distribution and tropism in the citrus plants are needed. Different diagnostic methods are available for early CTV detection but none of them is employed for in planta virus distribution study. In this study, a TaqMan RT-PCR-based method to detect and quantify CTV in different tissues of infected Mosambi plants (Citrus sinensis) has been standardized. The assay was very sensitive with the pathogen detection limit of > 0.0595 fg of in vitro-transcribed CTV-RNA. The assay was implemented for virus distribution study and absolute CTV titer quantification in samples taken from Tristeza-infected trees. The highest virus load was observed in the midribs of the symptomatic leaf (4.1 × 107-1.4 × 108/100 mg) and the lowest in partial dead twigs (1 × 103-1.7 × 104/100 mg), and shoot tip (2.3 × 103-4.5 × 103/100 mg). Interestingly, during the peak summer months, the highest CTV load was observed in the feeder roots (3 × 107-1.1 × 108/100 mg) than in the midribs of symptomatic leaf. The viral titer was highest in symptomatic leaf midrib followed by asymptomatic leaf midrib, feeder roots, twig bark, symptomatic leaf lamella, and asymptomatic leaf lamella. Overall, high CTV titer was primarily observed in the phloem containing tissues and low CTV titer in the other tissues. The information would help in selecting tissues with higher virus titer in disease surveillance that have implication in Tristeza management in citrus.

A Rapid and Sensitive Reverse Transcription-Loop-Mediated Isothermal Amplification (RT-LAMP) Assay for the Detection of Indian Citrus Ringspot Virus.

Indian citrus ringspot virus (ICRSV) is a devastating pathogen that has a particularly deleterious effect on the 'Kinnow mandarin', a commercial citrus crop cultivated in the northwest of India. ICRSV belongs to the Mandarivirus genus within the family of Alphaflexiviridae and has a positive sense single-stranded RNA (ssRNA) genome consisting of six open reading frames (ORFs). Severe cases of ICRSV result in a significant reduction in both the yield and quality of crops. Consequently, there is an urgent need to develop methods to detect ICRSV in an accurate and timely manner. Current methods involve a two-step reverse transcription polymerase chain reaction (RT-PCR) that is time consuming. Here, we describe a novel, one-step reverse transcription loop-mediated isothermal amplification (RT-LAMP) method for the sensitive and rapid detection of ICRSV. To standardize the RT-LAMP assay, four different primers were designed and tested to target the coat protein gene of ICRSV. Amplification results were visualized by a color change after addition of SYBR Green I. The standardized RT-LAMP assay was highly specific and successfully detected all 35 ICRSV isolates tested from the Punjab and Haryana states of India. Furthermore, there was no cross-reaction with 17 isolates of five other citrus pathogens that are common in India. The ICRSV RT-LAMP assay developed in the present study is a simple, rapid, sensitive, specific technique. Moreover, the assay consists of only a single step and is more cost effective than existing methods. This is the first application of RT-LAMP for the detection of ICRSV. Our RT-LAMP assay is a powerful tool for the detection of ICRSV and will be particularly useful for large-scale indexing of field samples in diagnostic laboratories, in nurseries, and for quarantine applications.

In-silico characterization and RNA-binding protein based polyclonal antibodies production for detection of citrus tristeza virus.

Citrus tristeza virus (CTV) is the etiologic agent of the destructive Tristeza disease, a massive impediment for the healthy citrus industry worldwide. Routine indexing of CTV is an essential component for disease surveys and citrus budwood certification for production of disease-free planting material. Therefore, the present study was carried out to develop an efficient serological assay for CTV detection based on the RNA binding protein (CTV-p23), which is translated from a subgenomic RNA (sgRNA) that accumulates at higher levels in CTV-infected plants. CTV-p23 gene was amplified, cloned and polyclonal antibodies were raised against recombinant CTV-p23 protein. The efficacy of the produced polyclonal antibodies was tested by Western blots and ELISA to develop a quick, sensitive and economically affordable CTV detection tool and was used for indexing of large number of plant samples. The evaluation results indicated that the developed CTV-p23 antibodies had an excellent diagnostic agreement with RT-PCR and would be effective for the detection of CTV in field samples. Furthermore, CTV-p23 gene specific primers designed in the present study were found 1000 times more sensitive than the reported coat protein (CTV-p25) gene specific primers for routine CTV diagnosis. In silico characterizations of CTV-p23 protein revealed the presence of key conserved amino acid residues that involved in the regulation of protein stability, suppressor activity and protein expression levels. This would provide precious ground information towards understanding the viral pathogenecity and protein level accumulation for early diagnosis of virus.

Rapid and Sensitive Detection of Citrus tristeza virus Using Reverse Transcription Loop-Mediated Isothermal Amplification (RT-LAMP) Assay.

Loop-mediated isothermal amplification (LAMP) is one recently developed gene amplification technique that emerges as a simple and quick diagnostic tool for early detection of nucleic acid targets. The LAMP technique works on the principle of strand displacement activity of Bst polymerase. It contains a set of four specially designed primers, which recognizes six different regions on the target nucleotide sequence. In the LAMP reaction, amplification is carried out in an isothermal conditions (60-65°C) using simple and inexpensive device like water bath or dry bath. Additional benefits of LAMP technique are that final results can be seen directly with naked eyes by adding intercalating dye SYBR Green I in the reaction tube. Reverse transcription loop-mediated isothermal amplification (RT-LAMP) is one of the novel techniques used for detection of RNA targets. The technology has been successfully applied for rapid and sensitive detection of Citrus tristeza virus (CTV) by using four oligo-primers, targeting a conserved coat protein gene (CPG) of an Indian CTV isolate. The result of assay is visible in naked eyes easily in the presence of SYBR Green I (100×) or on 1.5% agarose gel electrophoresis. CTV-RT-LAMP could be used away from plant pathology laboratories even in remote location.

Development of a recombinase polymerase based isothermal amplification combined with lateral flow assay (HLB-RPA-LFA) for rapid detection of "Candidatus Liberibacter asiaticus".

Huanglongbing (HLB) or citrus greening is highly destructive disease that is affecting the citrus industry worldwide and it has killed millions of citrus plants globally. HLB is caused by the phloem limited, Gram negative, non-culturable, alpha-proteobacterium, 'Candidatus Liberibacter asiaticus'. Currently, polymerase chain reaction (PCR) and real time PCR have been the gold standard techniques used for detection of 'Ca. L. asiaticus'. These diagnostic methods are expensive, require well equipped laboratories, not user-friendly and not suitable for on-site detection of the pathogen. In this study, a sensitive, reliable, quick and low cost recombinase polymerase based isothermal amplification combined with lateral flow assay (HLB-RPA-LFA) technique has been developed as a diagnostic tool for detection of 'Ca. L. asiaticus'. The assay was standardized by designing the specific primer pair and probe based on the conserved 16S rRNA gene of 'Ca. L. asiaticus'. The assay was optimized for temperature and reaction time by using purified DNA and crude plant extracts and the best HLB-RPA-LFA was achieved at the isothermal temperature of 38°C for 20 to 30 min. The efficacy and sensitivity of the assay was carried out by using field grown, HLB-infected, HLB-doubtful and healthy citrus cultivars including mandarin, sweet orange cv. mosambi, and acid lime. The HLB-RPA-LFA did not show cross-reactivity with other citrus pathogens and is simple, cost-effective, rapid, user-friendly and sensitive. Thus, the HLB-RPA-LFA method has great potential to provide an improved diagnostic tool for detection of 'Ca. L. asiaticus' for the farmers, nurserymen, disease surveyors, mobile plant pathology laboratories, bud-wood certification and quarantine programs.

Antimicrobial nano-zinc oxide-2S albumin protein formulation significantly inhibits growth of "Candidatus Liberibacter asiaticus" in planta.

Huanglongbing (HLB, also known as citrus greening) is considered to be the most devastating disease that has significantly damaged the citrus industry globally. HLB is caused by the Candidatus Liberibacter asiaticus (CLas), the fastidious phloem-restricted gram-negative bacterium, vectored by the asian citrus psyllid. To date, there is no effective control available against CLas. To alleviate the effects of HLB on the industry and protect citrus farmers, there is an urgent need to identify or develop inhibitor molecules to suppress or eradicate CLas from infected citrus plant. In this paper, we demonstrate for the first time an in planta efficacy of two antimicrobial compounds against CLas viz. 2S albumin (a plant based protein; ~12.5 kDa), Nano-Zinc Oxide (Nano-ZnO; ~ 4.0 nm diameter) and their combinations. Aqueous formulations of these compounds were trunk-injected to HLB affected Mosambi plants (Citrus sinensis) grafted on 3-year old rough lemon (C. jambhiri) rootstock with known CLas titer maintained inside an insect-free screen house. The effective concentration of 2S albumin (330 ppm) coupled with the Nano-ZnO (330 ppm) at 1:1 ratio was used. The dynamics of CLas pathogen load of treated Mosambi plants was assessed using TaqMan-qPCR assay every 30 days after treatment (DAT) and monitored till 120 days. We observed that 2S albumin-Nano-ZnO formulation performed the best among all the treatments decreasing CLas population by 96.2%, 97.6%, 95.6%, and 97% of the initial bacterial load (per 12.5 ng of genomic DNA) at 30, 60, 90, and 120 DAT, respectively. Our studies demonstrated the potency of 2S albumin-Nano-ZnO formulation as an antimicrobial treatment for suppressing CLas in planta and could potentially be developed as a novel anti CLas therapeutics to mitigate the HLB severity affecting the citrus industry worldwide.

The analysis of subtle internal communications through mutation studies in periplasmic metal uptake protein CLas-ZnuA2.

The subtle internal communications through an intricate network of interactions play a key role in metal-binding and release in periplasmic metal uptake proteins of cluster A-I family, a component of ABC transport system. These proteins have evolved different mechanisms of metal-binding and release through sequence and thereby structure-function divergence. The CLas-ZnuA2 from Candidatus Liberibacter asiaticus (CLA), in previous studies, showed a lower metal-binding affinity. The subtle communications within and between domains from crystal structure analysis revealed that protein seems to prefer a metal-free state. The unique features of CLas-ZnuA2 included a highly restrained loop L3 and presence of a proline in linker helix. In present work, S38A and Y68F mutants were studied as they play an important role during metal-binding in CLas-ZnuA2. The mutations in linker helix could not be studied as the expressed protein was not soluble and in most cases degraded with time. The crystal structure analysis of (S38A and Y68F) mutants in metal-free and metal-bound forms showed variations in interactions, an increase in number of alternate conformations and distortions in secondary structure elements, despite a similar overall structure, suggesting alterations in internal communications. The results suggested that any change in critical residues could alter the subtle internal communications and result in disturbing the fine-tuned structure required for optimal functioning.

Quantitative distribution of Citrus yellow mosaic badnavirus in sweet orange (Citrus sinensis) and its implication in developing disease diagnostics.

Citrus yellow mosaic badnavirus (CMBV) is the etiologic agent of citrus yellow mosaic disease, which has caused serious economic losses to Indian citrus industry. CMBV is a quarantined pathogen that is geographically restricted to India. To prevent unintentional movement of the virus to other major citrus-growing countries in fruits, root stocks or grafted citrus plants and facilitate trade, a sensitive, validated diagnostic tool is needed. In the present study, we developed a SYBR Green real-time PCR-based method to detect and quantify CMBV in different tissues of infected Mosambi sweet orange (Citrus sinensis) and compared its sensitivity to conventional PCR protocols. Primers were designed to recognize a portion of the CMBV capsid protein gene. Conventional and real-time PCR were performed on several different tissues: shoot tips, leaves displaying typical CMBV symptoms, asymptomatic leaves, senescent leaves, thorns, green stems and feeder roots. The detection limit of CMBV by conventional PCR was 2.5 × 104 copies per 5 ng of total genomic DNA, while the detection limit of real-time PCR was found to be 4.6 × 102 virus copies per 5 ng of viral DNA. The viral load varied between different tissues. The highest concentration occurred in feeder roots (3.5 × 108 copies per 5 ng of total genomic DNA) and the lowest in thorns (1 × 106 copies per 5 ng of total genomic DNA). The variation in viral load within different tissues suggests movement of the virus within an infected plant that follows the path of photo-assimilates via the phloem. In symptomatic leaves, the CMBV concentration was highest in the lamella followed by midrib and petiole, suggesting that virus resides inside these sections of a leaf and side by side symptoms develop. On the other hand, in asymptomatic leaves, the petiole contained higher virus load than the lamella and midrib suggesting that the pathogen gets established from the stem through the phloem into petiole then infects the lamella and midrib. In addition to information on virus movement, the distribution of CMBV in different tissues helps with the selection of tissues with relatively higher viral load to sample for early and sensitive diagnosis of the disease, which will be useful for better management of the disease in endemic areas.

Development of a simple and rapid reverse transcription-loop mediated isothermal amplification (RT-LAMP) assay for sensitive detection of Citrus tristeza virus.

Tristeza is a devastating disease of citrus and reported to be present in almost all countries where it is cultivated as a commercial crop. The etiological agent of this disease is Citrus tristeza virus (CTV), a member of the genus Closterovirus with in the family Closteroviridae. The pathogen is restricted to the phloem tissue of the infected citrus plant and has a monopartite ss (+) RNA genome of ∼20kb size. Till date, there is no effective control measure available for this virus. Management of tristeza depends on destruction of CTV infected field plants, production of virus-free planting material for new orchard establishment and controlling viruliferous aphid vectors responsible for field spread of the pathogen. Availability of rapid diagnostic assay is essential for rapid and efficient detection of the pathogen. In the present investigation, RT-LAMP (reverse transcription-loop mediated isothermal amplification), a highly sensitive, robust and low cost assay has been developed for rapid detection of CTV in infected citrus plant samples. Based on conserved nucleotide sequences available in GenBank and specific to p25 gene (major coat protein gene) of predominant CTV isolates of India, four primer sets (CTV-F3, CTV-B3, CTV-FIP and CTV-BIP) ware designed and custom synthesized. The amplified LAMP products obtained after maintaining isothermal condition of 65°C for 60min duration could be visible easily with necked eyes in presence of SYBR Green I (100X). Subsequently, LAMP products were verified by electrophoresis run in 1.5% agarose gel. The RT-LAMP results obtained with known CTV isolates maintained in screen house of CCRI, Nagpur were validated using field samples and thereafter it was further confirmed by conventional RT-PCR (reveres transcription-polymerase chain reaction) assay. The sensitivity of CTV-RT-LAMP protocol standardized in the present study was 100 times more than conventional one step RT-PCR assay. It also has maximum detection limit up to 0.0001ng RNA in individual reaction mixture. CTV-RT-LAMP assay is a simple, sensitive, rapid and less costly detection technique. This assay could be used for CTV diagnosis in pathology laboratories having limited facility and resources and even by citrus nurseries situated in remote locations. As per our knowledge and available literature, the present study reports first time about the usefulness of RT-LAMP assay for detection of CTV from India.

Crystal structure analysis in Zn2+-bound state and biophysical characterization of CLas-ZnuA2.

A periplasmic solute binding protein from second of the two gene clusters of Znu system in CLA (CLas-ZnuA2) belong to Cluster A1 family of solute binding proteins (SBPs). The crystal structures in metal-free, intermediate and metal-bound states, in the previous study, revealed the unusual mechanism of metal binding and release for CLas-ZnuA2. Although CLas-ZnuA2 showed maximum sequence identity to the Mn/Fe-specific SBPs, the mechanistic resemblance seems to be closer to Zn-specific SBPs of Cluster A-I family. The present study reports the binding affinity studies using SPR and CD and crystal structure of CLas-ZnuA2 in Zn2+-bound state. Despite a similar overall structure, there are noticeable differences at the metal binding site. The SPR and CD analysis confirmed our previous observation that CLas-ZnuA2 exhibits a low metal-binding affinity. The low metal-binding affinity of CLas-ZnuA2 could be attributed to the presence of a proline in linker helix resulting in relatively higher bending and rigidity of the same. This structural feature fixes the C-domain similar to metal-bound states of related SBPs. Further, the binding of both Mn2+ and Zn2+ occurs pentavalently with square pyramidal geometry not preferred by either. The site-specific positive Darwinian selection analysis showed that the proline in linker helix is under purifying selection and might have diverged long ago. Our structural and evolutionary analyses suggest that CLasZnua2 might have evolved, particularly for plant pathogens, to facilitate transport of both Mn2+ and Zn2+, with reversible binding to Zn2+, unlike other Mn-binding SBPs (PsaA).

Genetic Diversity of the Indian Populations of 'Candidatus Liberibacter asiaticus' Based on the Tandem Repeat Variability in a Genomic Locus.

Citrus huanglongbing (HLB, citrus greening disease) is an extremely destructive disease affecting citrus and causes severe economic loss to the crop yield worldwide. The disease is caused by a phloem-limited, noncultured, gram-negative bacteria Candidatus Liberibacter spp., the widely present and most destructive species being 'Candidatus Liberibacter asiaticus'. Although the disease has been reported from almost all citrus growing regions of India, knowledge on the molecular variability of the pathogen 'Ca. L. asiaticus' populations from different geographical regions and cultivars is limited. In the present study, variability of the Indian 'Ca. L. asiaticus' based on the tandem repeats at the genomic locus CLIBASIA_01645 was characterized and categorized into four classes based on the tandem repeat number (TRN); Class I (TRN≤5), Class II (TRN>5≤10), Class III (TRN>10≤15), and Class IV (TRN>15). The study revealed that the Indian population of 'Ca. L. asiaticus' is more diverse than reported for Florida and Guangdong populations, which showed less diversity. While Florida and Guangdong populations were dominated by a TRN5 and TRN7 genotype, respectively, the Indian 'Ca. L. asiaticus' populations with TRN copy numbers 9, 10, 11, 12, and 13 were widely distributed throughout the country. Additionally, TRN2 and TRN17 genotypes were also observed among the Indian 'Ca. L. asiaticus' populations. The predominant 'Ca. L. asiaticus' genotypes from the northeastern region of India were TRN6 and TRN7 (53.12%) and surprisingly similar to neighboring South China populations. Preliminary results showed absence of preference of citrus cultivars to any specific 'Ca. L. asiaticus' genotype.