Valorisation of Agri-Food Waste for Bioactive Compounds: Recent Trends and Future Sustainable Challenges.

Worldwide, a massive amount of agriculture and food waste is a major threat to the environment, the economy and public health. However, these wastes are important sources of phytochemicals (bioactive), such as polyphenols, carotenoids, carnitine, coenzymes, essential oils and tocopherols, which have antioxidant, antimicrobial and anticarcinogenic properties. Hence, it represents a promising opportunity for the food, agriculture, cosmetics, textiles, energy and pharmaceutical industries to develop cost effective strategies. The value of agri-food wastes has been extracted from various valuable bioactive compounds such as polyphenols, dietary fibre, proteins, lipids, vitamins, carotenoids, organic acids, essential oils and minerals, some of which are found in greater quantities in the discarded parts than in the parts accepted by the market used for different industrial sectors. The value of agri-food wastes and by-products could assure food security, maintain sustainability, efficiently reduce environmental pollution and provide an opportunity to earn additional income for industries. Furthermore, sustainable extraction methodologies like ultrasound-assisted extraction, pressurized liquid extraction, supercritical fluid extraction, microwave-assisted extraction, pulse electric field-assisted extraction, ultrasound microwave-assisted extraction and high hydrostatic pressure extraction are extensively used for the isolation, purification and recovery of various bioactive compounds from agri-food waste, according to a circular economy and sustainable approach. This review also includes some of the critical and sustainable challenges in the valorisation of agri-food wastes and explores innovative eco-friendly methods for extracting bioactive compounds from agri-food wastes, particularly for food applications. The highlights of this review are providing information on the valorisation techniques used for the extraction and recovery of different bioactive compounds from agricultural food wastes, innovative and promising approaches. Additionally, the potential use of these products presents an affordable alternative towards a circular economy and, consequently, sustainability. In this context, the encapsulation process considers the integral and sustainable use of agricultural food waste for bioactive compounds that enhance the properties and quality of functional food.

Stem Rot of Pearl Millet Prevalence, Symptomatology, Disease Cycle, Disease Rating Scale and Pathogen Characterization in Pearl Millet-Klebsiella Pathosystem.

The oldest and most extensively cultivated form of millet, known as pearl millet (Pennisetum glaucum (L.) R. Br. Syn. Pennisetum americanum (L.) Leeke), is raised over 312.00 lakh hectares in Asian and African countries. India is regarded as the significant hotspot for pearl millet diversity. In the Indian state of Haryana, where pearl millet is grown, a new and catastrophic bacterial disease known as stem rot of pearl millet spurred by the bacterium Klebsiella aerogenes (formerly Enterobacter) was first observed during fall 2018. The disease appears in form of small to long streaks on leaves, lesions on stem, and slimy rot appearance of stem. The associated bacterium showed close resemblance to Klebsiella aerogenes that was confirmed by a molecular evaluation based on 16S rDNA and gyrA gene nucleotide sequences. The isolates were also identified to be Klebsiella aerogenes based on biochemical assays, where Klebsiella isolates differed in D-trehalose and succinate alkalisation tests. During fall 2021-2023, the disease has spread all the pearl millet-growing districts of the state, extending up to 70% disease incidence in the affected fields. The disease is causing considering grain as well as fodder losses. The proposed scale, consisting of six levels (0-5), is developed where scores 0, 1, 2, 3, 4, and 5 have been categorized as highly resistant, resistant, moderately resistant, moderately susceptible, susceptible, and highly susceptible disease reaction, respectively. The disease cycle, survival of pathogen, and possible losses have also been studied to understand other features of the disease.

First report of Klebsiella Leaf Streak on Sorghum Caused by Klebsiella variicola in Haryana, India.

Sorghum (Sorghum bicolor [L.] Moench) is one of the top ten cereal crops in the world and is grown for fodder and seed purposes. During the fall of 2019 to 2022, a disease causing small to long streaks on leaves was observed in sorghum fields of Hisar (29° 9' 6.6996'' N, 75° 43' 16.0428'' E), Rohtak (28° 53' 43.8540'' N, 76° 36' 23.8068'' E) and Mohindergarh (28° 16' 6.0492'' N, 76° 9' 3.3552'' E) regions of Haryana between July and October. The reddish brown streaks were observed in the interveinal spaces of upper and lower leaves. The disease incidence reached 20-30% of plants in affected fields. The diseased leaf tissues were disinfected with 70% alcohol and placed in a tube with sterile water. After 30 minutes, 100 µl of the suspension was inoculated onto nutrient agar medium, incubated at 28 ± 2°C for three days, and a pure culture was obtained by restreaking on nutrient agar (Janse, 2005). The rod-shaped gram-negative bacterium with round, cream to white colonies was positive for methyl red, citrate utilization, urease activity, and glucose, lactose, sorbitol, rhamnose and sucrose fermentation tests. The genomic DNA of the bacterial suspension was extracted and 16S rDNA was amplified using universal 27F/1492R primers (Marchesi et al. 1998), resulting in tentative identification as Klebsiella sp. It was further confirmed with PCR amplification of Klebsiella specific primers (F:5'-CGCGTACTATACGCCATGAACGTA-3'; R:5'-ACCGTTGATCACTTCGGTCAGG-3') for gyrA gene (Brisse and Verhoef 2001). Discrete PCR amplicons of 1,500 (16S rDNA) and 300 bp (gyrA) were observed in a 1% (w/v) agarose gel. Forward and reverse DNA sequencing of both amplicons of the Hisar isolate (VMKV101) was carried out using a BDT v3.1 Cycle sequencing kit and consensus sequences were generated by using the program SeqMan Ultra (DNASTAR Lasergene). Sequences of the PCR products were deposited in GenBank with accession numbers MZ569433 (16S rDNA) and OP390080 (gyrA). The 16S rDNA sequence was 97.32% similar to K. variicola strain 13450 (CP026013; 1,450/1,490 bp) and the gyrA sequence had 99.66% similarity to K. variicola strain FH-1 (CP054254; 297/298 bp). A 16S RNA-based phylogenetic tree done by MEGA11 (Tamura et al. 2021) using the Maximum Likelihood method showed that strain VMKV101 clustered with K. variicola type strain F2R9. The complete bacterial genome (GCA025629215), sequenced by the Ion GeneStudio S5 system using Ion 530 chips (Thermo Fisher Scientific), was 99.03% identical by average nucleotide identity (ANI) to the type genome (CP045783) of Klebsiella variicola, with 87.8% genome coverage. For pathogenicity testing, a bacterial suspension (10 ml, 1×107 colony forming units/ml) was injected into the whole whorl after mechanical injury on 15-20 days old seedlings of the susceptible genotype HC-171, then plants were incubated at 35 ± 2°C, >80% relative humidity. Control plants were injected with sterile distilled water. Initial symptoms were observed on leaves of inoculated plants after 5 to 7 days as narrow, small longitudinal reddish brown streaks. As the disease progressed, the streaks on the leaf blade increased in number and size maintaining the reddish brown color. These streaks had slightly wavy margins and were surrounded by bright yellow halos. After 15 to 20 days, the streaks were 0.5 to 2.0 mm wide and 1.0 to 5.0 cm long, occasionally up to 10.0 cm long on both side of the leaves. Over time, neighboring streaks coalesced to form large necrotic areas. All inoculated plants exhibited identical symptoms. No symptoms were observed on control leaves. The reisolated bacterium from diseased sorghum leaves showed exactly the same morphological, biochemical and 16S RNA and gyrA molecular characteristics. To our knowledge, this is the first report of K. variicola causing a leaf streak disease on sorghum. Klebsiella species primarily cause diseases in humans and animals, but K. variicola has been found to incite banana soft rot (Fan et al. 2015) and K. aerogenes to cause stem rot in pearl millet (Malik et al. 2022). Differences of prevalence, spread and control between K. variicola and two other bacteria (Xanthomonas vasicola pv. holcicola causing Bacterial leaf streak; Paraburkholderia andropogonis causing Bacterial leaf stripe) causing leaf streak diseases on sorghum need to be determined. The identification of Klebsiella leaf streak disease lays the groundwork for future investigations into epidemiology and management of K. variicola on sorghum.

First report of Klebsiella aerogenes Inciting Stem Rot of Pearl Millet in Haryana, India.

Pearl millet [Pennisetum glaucum (L.) R. Br. Syn. Pennisetum americanum (L.) Leeke] is the oldest and widely cultivated millet in Asian and African countries, mostly grown over low fertile soils in more than 40 countries covering an area of 312.00 lakh hectares (FAOSTAT 2017). In Haryana, crop was grown over an area of 4.30 lakh hectares during Kharif 2019. Pearl millet is prone to many fungal and bacterial diseases. During 2018 to 2020, a new devastating diseas exhibiting stem rot like symptoms was observed in pearl millet growing regions in Indian state of Haryana. The isolated disease causing agent was a bacterium, where 16S rDNA-based nucleotide sequence deposited in NCBI GenBank (Accession nos. MZ433194.1) conferred its nearness to Klebsiella aerogenes (Hormaeche and Edwards 1960) Tindall et al. 2017. Further, DNA gyrase genomic sequence (NCBI Accession nos. MZ707528.1) also stayed its high homology to K. aerogenes. Klebsiella usually known to cause diseases in humans and animals, and also has been found inciting different kind of rots in different plantations viz. top rot in maize (Huang Min et al. 2016). Pearl millet is susceptible to minor bacterial diseases viz. bacterial leaf streak (Xanthomonas campestris), bacterial leaf spot (Pseudomonas syringae) and leaf stripe (P. avenae). Earlier, among the plant pathogenic bacterial entirety, only Erwinia chrysanthemi is known to cause stem rot diseases in sorghum (Saxena et al. 1991) amongst different types of millet. Extensive disease survey of pearl millet growing regions (Hisar, Bhiwani, Rewari, Mohindergarh and Bawal districts of Haryana having an altitude of 215, 225, 245, 262 and 266 m, respectively) in rainy seasons of 2019 and 2020 revealed the prevalence of typical stem rot disease, representing up to 70% disease incidence in the infected fields. The pieces of symptomatic stem of different plants were collected from two locations (Hisar and Bhiwani) and associated organism was isolated following the techniques of Janse (2005). The resulting growth of bacterial cultures were further purified on nutrient agar (NA) media using streak plate technique where colony growth of both the isolates were observed as morphotypes. The resulting bacteria were gram-negative and rod-shaped. Colonies were round and creamish white on NA. Isolated morphotypes were positive for indole production, methyl red, Voges Proskauer's test, citrate utilization, arabinose, mannitol, rhamnose and sucrose, whereas negative for glucose, adonitol, lactose and sorbitol tests. Biochemical tests were performed following standard methods (Holt et al. 1994). Molecular analysis of both isolates was performed using two sets of primers (universal 16S rRNA gene and genus-specific gyrA gene). The gyrA fragment (F: 5'-CGCGTACTATACGCCATGAACGTA-3'; R: 5'-ACCGTTGATCACTTCGGTCAGG-3') has been adopted as Klebsiella genus-specific gene (Brisse and Verhoef 2001). The quality and quantity of the isolated genomic DNA were analyzed using NanoDrop-2000 (Thermo Fisher Scientific, USA) and resolved in 1% (w/v) agarose gel. Thereafter, visualized in gel documentation to confirm a single band of high-molecular-weight DNA. The fragment 16S rDNA was amplified using 27F and 1492R primers, where a single discrete PCR amplicon of 1500 bp was observed in 1% (w/v) agarose gel. Similarly, the gyrA gene was amplified using 09510F and 09510R primers that conferred a single discrete band of 400 bp. The forward and reverse DNA sequencing reaction of purified PCR amplicons (16S rDNA and gyrA) was carried out using BDT v3.1 Cycle sequencing kit on a genetic analyzer to generate gene sequences. The consensus sequences of both gene were generated from forward and reverse sequences data using aligner software. The obtained sequences of both genes were compared with the available nucleotide sequences in the NCBI using the blast 2.2.9 system (https://blast.ncbi.nlm.nih.gov/Blast.cgi?PAGE_TYPE=BlastSearch). The sequenced PCR amplicons showed up to 100% similarity with Klebsiella aerogenes 16s RNA nucleotide sequences (Accession nos. NR102493.2, MT373521.1; MF682950.1; MF462979.1 etc.). The bacterium also showed high nucleotide homology to K. aerogenes gyrA gene sequences (Accession nos. LR607333.1; CP035466.1; CP049600.1 etc.). The molecular phylogenetic analysis was done by the maximum likelihood method based on the Tamura-Nei model, and 1000 replicates for bootstrap testing in MEGA 7.0 software. The analysis involved 16 nucleotide sequences and evolutionary distances were computed. The 16s RNA based phylogenetic tree raised using MEGA7 (Kumar et al. 2016) elucidates that Klebsiella aerogenes Hisar formed a cluster with three K. aerogenes strains (Accession nos. MZ577128.1, MT373521.1 and MT 373520.1), whereas K. aerogenes Bhiwani displayed higher homology to NCBI sequences viz. MF682950.1, MT355368.1, MW331687.1and LC515412.1. Bacterial suspension was prepared by suspending bacterial cells into sterile water and cell density was adjusted to 1×107 colony forming unit/ml. For pathogenicity, leaf whorl inoculation (10 ml suspension/ whorl) was done on 15 days old seedlings of pearl millet genotype 7042S raised under controlled conditions (Temperature 35±2°C and more than 80% Relative Humidity). The pathogenicity was proved under field conditions as well. Initial symptoms were observed 4-5 days after inoculation as long streaks on leaves. Soon a spike in number of these leaf streaks was observed. Thereafter, water-soaked lesions appeared on the stem at 20-25 days after inoculation which later on turned brown to black. Severely diseased plants were dead, exhibiting hollowing of the stem and drying of leaves. The infected stem pith disintegrated and showed slimy rot symptoms and the pearl millet clumps toppled down. The rotten stems of both inoculations were again cut in to small pieces and the reisolated bacterium showed exactly the same morphological, biochemical and molecular characteristics. To our knowledge, this is the first report of stem rot of pearl millet incited by K. aerogenes in south-western regions of Haryana, India. Because the stem rot caused by K. aerogenes poses a significant threat to pearl millet cultivation, further research on biology, epidemiology and management choices is needed.

Efficacy of Newer Molecules, Bioagents and Botanicals against Maydis Leaf Blight and Banded Leaf and Sheath Blight of Maize.

Maize (Zea mays L.; 2N=20) is major staple food crop grown worldwide adapted to several biotic and abiotic stresses. Maydis leaf blight (MLB) and banded leaf and sheath blight (BLSB) are serious foliar fungal diseases may cause up to 40% and 100% grain yield loss, respectively. The present studies were undertaken to work out the efficacy of chemicals, botanicals and bioagents for the management of MLB and BLSB under field condition for two seasons Kharif 2014 and 2015. Five molecules (propiconazole 25 EC, hexaconazole 25 EC, carbendazim 50 WP, mancozeb 75 WP and carbedazim 12 WP + mancozeb 63 WP), two bioagents i.e. Trichoderma harzianum and T. viridae and three botanicals namely azadirachtin, sarpagandha and bel pathar were tested for their efficacy against MLB. Eight newer fungicides viz., difenconazole 250 SC, hexaconazole 5 EC, carbendazim 50WP, validamycin 3 L, tebuconazole 250 EC, trifloxystrobin 50 WG + tebuconazole 50 WG, azoxystrobin 250 EC and pencycuron 250 SC were evaluated against BLSB. Analysis revealed significant effects of propiconazole at 0.1%, carbendazim 12 WP + mancozeb 63 WP at 0.125% and sarpagandha leaves at 10% against MLB pathogen, whereas validamycin at 0.1% and trifloxystrobin 25 WG + tebuconazole 50 WG at 0.05% were found effective against BLSB. The slow rate of disease control virtually by the bioagents might have not shown instant effect on plant response to the yield enhancing components. The identified sources of management can be used further in strengthening the plant protection in maize against MLB and BLSB.

The role of laparoscopy in the localization and management of adult impalpable testes.

BACKGROUND: Very few studies are available that describe the role of laparoscopy in adults with impalpable testes. This study compares laparoscopy with ultrasonography in this subset of patients. METHODS: Fourteen adults, having a mean age of 21 years, with 19 undescended testes were evaluated. None of the testes was palpable, preoperative ultrasound localized 7 testes (36.8%), but a change in findings was observed in 3 of these cases (42.8%) on subsequent laparoscopy. On laparoscopy, 18 (94.7%) of the testes were localized as intraabdominal. The remaining patient had a case of true anorchia. Seven patients with unilateral undescended testes underwent laparoscopic orchiectomy, and 2 patients with unilateral undescended testes and all the patients with bilateral undescended testes underwent laparoscopic-assisted orchiopexy. No complication was noted in any of the cases. Hernia, present in 4 patients, was simultaneously repaired laparoscopically. CONCLUSION: Laparoscopy is a safe and effective modality in the localization and management of adult undescended testes. In adults, orchiectomy with the subsequent reduction in the risk of malignancy is the major issue of concern. Also, the repair of concomitant hernias is desirable. Both of these procedures can be done laparoscopically in the same sitting without the need for inguinal exploration.

A difficult laparoscopic cholecystectomy that requires conversion to open procedure can be predicted by preoperative ultrasonography.

A prospective study was conducted from March 1999 to April 2000 that included 73 patients who underwent elective laparoscopic cholecystectomy for uncomplicated gallstone disease. The study was conducted at one surgical unit in the Department of Surgery and Department of Radio-diagnosis and one surgical unit in the Department of Surgery, Maulana Azad Medical College and the associated Lok Nayak Hospital, which is the largest referral hospital in northern India and is located in the capital of India. A preoperative ultrasound was performed just prior to surgery, and 4 ultrasonographic parameters were analyzed. namely gallbladder wall thickness, contracted gallbladder, impaction of gallstones at the neck of the gallbladder, and common bile duct stones. The surgical findings were objectively graded as difficult or easy laparoscopic cholecystectomy according to 5 operative parameters, namely total time taken for the surgery, time taken to dissect gallbladder bed, spillage of stones, tear of gallbladder during dissection, and conversion to the open procedure. Of the 73 cases, 17 (23.3%) were conversions to the open procedure. Of the 21 (28.76%) cases predicted to be difficult, 17 (23.3%) were technically difficult, of which 13 (17.8%) were converted to the open procedure. Of the 52 (71.23%) cases predicted to be easy on ultrasonography, only 7 (9.38%) were found to be difficult on surgery, of which only 4 (5.48%) had to be converted to the open procedure. Based on our results, we conclude that preoperative ultrasonography is of great value in selecting patients preoperatively for laparoscopic cholecystectomy and minimizing complications and conversion to the open procedure.