Screening pearl millet cultivars by ELISA for resistance to downy mildew disease

In an earlier study, we described identification of a protein from a virulent pathotype of Sclerospora graminicola , the binding reaction of which differentiated susceptible and resistant cultivars of pearl millet to downy mildew disease. This protein and corresponding antibody were used in an enzyme-linked immunosorbent assay (ELISA) to screen suspension cells of pearl millet cultivars for their resistance to the downy mildew pathogen. Screening results for 31 pearl millet cultivars correlated positively with the established field screening method.     

ALMANAC 模型对黄土高原玉米、谷子和糜子产量的模拟

用ALMANAC作物模型对黄土高原安塞县大南沟小流域2000～2004年玉米、谷子和糜子的产量进行模拟.结果显示,ALMANAC模型能够很好地模拟该地区的粮食产量,模拟值与实测值回归方程的决定系数大于0.72,回归方程接近1∶1线.玉米、谷子和糜子模拟产量与实测产量之间的平均相对误差分别为-2.29%、-2.32%和8.34%,模拟产量与实测产量之间的标准化均方根差分别为15.7%、11.5%和15.8%.梯田、阴坡和阳坡之间的模拟误差有所差异,玉米梯田产量的模拟值比实测值偏高,阴坡和阳坡产量的模拟值偏低;谷子梯田和阴坡产量的模拟值偏低,阳坡产量的模拟值偏高;糜子梯田和阳坡产量的模拟值偏高.梯田模拟值与实测值之间的一致性较好,其次为阴坡,再次为阳坡.     

Insect pests of pearl millet in West Africa: A review

Abstract

Pearl millet (Pennisetum americanum (L.) K. Schum), a major food crop in the sahelian and savanna regions of West Africa, is attacked by about 100 species of insects. Of these, the only regular pests are stem borers (Acigona ignefusalis Hmps. and Sesamia spp.) and earhead caterpillars (Masalia spp., Raghuva spp.). Sporadic pests such as hairy caterpillars (Amsacta moloneyi Druce), armyworms (Spodoptera spp. and Mythimna spp.) and grasshoppers (Acrididae) may cause severe losses to crops during prolonged droughts early in the season. A grain midge (Geromyia penniseti (Felt)) attacks late millets and causes a considerable loss in yield. Information is presented on the biology, distribution, hosts and natural enemies of these pests, and some methods of control are discussed.     

Increasing complexity of resistance in host populations through intermating to manage rust of pearl millet

ABSTRACT Pearl millet inbreds Tift 23DB, Tift 85DB, PS748BC, and Tift 89D(2) were used to develop three categories of host mixtures (physical mixtures, random-mated populations, and mixtures of two-way and three-way crosses) representing different levels of complexity of resistance through increased heterogeneity within populations and through stacking of resistance genes within the heterogeneous populations. The potential of these mixtures to reduce rust epidemics was evaluated in the field. Area under the disease progress curves (AUDPCs) of all physical mixtures were less than the mean of the components in 1995 and were less than the mean of the components for five of the six mixtures in 1997. In 1996, AUDPCs of the physical mixtures were consistently greater than the mean of their components. AUDPCs of the random-mated mixtures and the mixtures of crosses were consistently less than the mean of the components in 1996 and 1997, with reductions ranging from 12 to 71%. Dry matter yield (DMY) of physical mixtures relative to the mean DMY of the components was inconsistent, ranging from 18% less to 50% more than the mean of the components. The random-mated populations and the mixtures of crosses yielded 18 to 40% more DMY than the mean yield of the pure stands of their components.     

Purification of an infection-related acidic peroxidase from pearl millet seedlings

Higher basal level of peroxidase activity was observed in highly resistant pearl millet cultivar IP 18292. Upon inoculation with downy mildew pathogen, Sclerospora graminicola, up to 60% increase in peroxidase activity was observed in highly resistant seedlings over the period of time. Iso-electric focusing analysis revealed that, two acidic isozymes of peroxidase with the pI of 5.9 and 5.1 present only in IP 18292 pearl millet seedlings. Upon inoculation with downy mildew pathogen, accumulation of these to isozymes was increased. These results indicated the possible involvement of acidic peroxidase in pearl millet defense. To study the nature of the acidic peroxidase which increases upon inoculation was purified from seedlings of highly resistant pearl millet cultivar using DEAE–Sepharose and Sephadex G-100 columns. The purified enzyme has a molecular weight of 21.8 kDa on SDS–PAGE and has a pI of 5.1. The optimum pH for maximum peroxidase activity was found to be at pH 7.0 and was resistant to high temperature (27–60 °C). The K_m for H₂O₂ and V_max of the enzyme reaction were 5.26 mM and 322.58 units, respectively. Purified peroxidase enzyme was found to be CaCl₂ dependent and both MgCl₂ and ZnCl₂ showed inhibitory effect on enzyme activity. Sodium azide and EDTA inhibited the enzyme and EGTA found to be specific inhibitor of peroxidase.     

A streak disease of pearl millet caused by a leafhopper-transmitted geminivirus

The cause of a streak disease of pearl millet (Pennisetum glaucum), originating from Nigeria, has been attributed to a geminivirus belonging to the African streak virus cluster. A full-length, infectious clone of the virus was obtained which was transmissible by the vectorCicadulina mbila (Naudé). Analysis of the complete nucleotide sequence of the coat protein gene of this virus shows it to be most closely related to sugarcane streak virus. The possible evolutionary implications of this finding are discussed.     

Cellulysin induces downy mildew disease resistance in pearl millet driven through defense response

The responses to cellulysin as an immune inducer in pearl millet that confers downy mildew resistance mediated through lipoxygenase (LOX), a jasmonate-dependent enzyme involved in defence signalling, are discussed in this paper. The susceptible pearl millet cultivar 7042S was treated with cellulysin at 10, 15, 20, 30 and 50 μg/ml concentrations. All tested concentrations showed enhanced seed germination and seedling vigour when compared with the untreated control. Maximum seed germination of 92 % and seedling vigour was obtained following 20 μg/ml cellulysin treatment. Significant (P?<?0.05) downy mildew disease protection of 67 % and 71 % was observed when cellulysin was used at 20 μg/ml under greenhouse and field conditions, respectively. Further studies showed that the resistance induced by cellulysin treatment in pearl millet plant was systemic, required a minimum of 4 days to achieve maximum resistance development after pathogen inoculation seedling inoculation (five-day-old), and was sustained throughout the plant’s life. Plants raised from cellulysin-treated seeds and challenge inoculated at tillering (25-day-old) and inflorescence (45-day-old) showed persistence in resistance till the end of the crop period. A notable increase in LOX activity was observed in all the tested concentrations of cellulysin in plants inoculated with the pathogen at 24 h, compared to the control. However, a maximum 6-fold increase in LOX activity was noticed using a cellulysin concentration of 20 μg/ml 48 hours post inoculation. In contrast, glucanase (GLU) activity was high in control inoculated seedlings, but was low in cellulysin treated samples at all time intervals. The optimal cellulysin treatment (20 μg/ml) provided enhanced vegetative and reproductive parameters that resulted in higher yield compared to the untreated control.     

Comparative efficacy of strobilurin fungicides against downy mildew disease of pearl millet

Three commercial formulations of strobilurins, viz., azoxystrobin, kresoxim-methyl, and trifloxystrobin were evaluated for their efficacy against pearl millet downy mildew disease caused by Sclerospora graminicola. In vitro studies revealed inhibition of S. graminicola sporulation, zoospore release, and zoospore motility at 0.1-2 μg ml⁻¹ of all the three fungicides. The fungicides were evaluated for phytotoxic effects on seed quality parameters and for their effectiveness against downy mildew disease by treating pearl millet by: (1) seed dressing, (2) seed dressing followed by foliar spray, and (3) also by foliar spray alone. The highest non-phytotoxic concentrations of 5, 10, and 10 μg ml⁻¹ for azoxystrobin, trifloxystrobin, and kresoxim-methyl, respectively, were selected for further studies. Under greenhouse conditions, these fungicides showed varying degrees of protection against downy mildew disease. Among the three fungicides, azoxystrobin proved to be the best by offering disease protection of 66%. Further, seed treatment along with foliar application of these fungicides to diseased plants showed enhanced protection against the disease to 93, 82, and 62% in treatments of azoxystrobin, kresoxim-methyl and trifloxystrobin respectively. Foliar spray alone provided significant increase in disease protection levels of 91, 79, and 59% in treatments of azoxystrobin, kresoxim-methyl, and trifloxystrobin, respectively. Disease curative activity of azoxystrobin was higher compared to trifloxystrobin and kresoxim-methyl. Tested fungicides showed weaker translaminar activity, as the disease inhibition was marginal when applied on adaxial leaf surface. Partial systemic activity of azoxystrobin was evident by root uptake, while trifloxystrobin and kresoxim-methyl showed lack of systemic action in pearl millet. A trend in protection against downy mildew disease similar to greenhouse results was evident in the field trials. Grain yield was significantly increased in all strobilurin fungicide treatments over control and maximum increase in yield of 1673 kg ha⁻¹ was observed in combination treatments of seed treatment and foliar spray with azoxystrobin.     

Differential induction of superoxide dismutase in downy mildew-resistant and -susceptible genotypes of pearl millet

Differential induction of superoxide dismutase (SOD) in downy mildew-resistant and -susceptible genotypes of pearl millet ( Pennisetum glaucum ) was observed on inoculation with Sclerospora graminicola . SOD activity was studied in resistant (IP18292) and susceptible (23B) pearl millet seedlings inoculated with S. graminicola . SOD activity increased by 2·3-fold in resistant seedlings upon inoculation. SOD activity was greatest in roots, with a specific activity of 3182 U per mg protein, after inoculation. SOD activity increased in all the resistant genotypes upon inoculation with S. graminicola . Native PAGE analysis showed four isozymes of SOD, three of which (SOD-1, -2 and -4) were Cu/Zn-SOD, whereas isozyme SOD-3 was Mn-SOD. This study also revealed increased intensity of all four isozymes of SOD in the resistant genotype upon inoculation. The involvement of SOD in pearl millet (host)–downy mildew pathogen interaction is discussed.     

Spore cell wall components ofAspergillus niger elicit downy mildew disease resistance in pearl millet

Elicitors derived from the cell wall of fungi are shown to be active in eliciting resistance in plants against a wide range of pathogens. In the present study carbohydrate components from the autoclaved spore cell wall ofAspergillus niger were prepared as aqueous suspensions and tested for defense response in pearl millet (Pennisetum glaucum (L.) R.Br.) against the oomycetous downy mildew pathogenSclerospora graminicola (Sacc.) Schroet. The aqueous suspension derived from the spore cell wall ofA. niger was used as a seed soak treatment at concentrations of 0.25, 0.5, 1.0, 1.5 and 2.0 mg ml⁻¹ for time intervals of 3, 6, 9 and 12 h. The concentration of 0.5 mg ml⁻¹ for a 6 h soaking period offered 94% seed germination and seedling vigor index increased to 1526. The seed germination and the seedling vigor were significantly higher than the untreated check. Spore cell wall suspension as seed treatment at a concentration of 0.5 mg ml⁻¹ required a 3-day time interval to provide 67% protection against downy mildew. Histological and biochemical studies were conducted to elucidate the mechanism of defense response in treated seedlings uponS. graminicola infection. Resistance host response was detected in the form of lignin and callose deposition in the epidermal cell wall of pearl millet seedlings, which is the site ofS. graminicola infection. A time course study showed rapid and localized deposition of lignin and callose in epidermal cell wall of carbohydrate components-treated pearl millet seedling coleoptiles. Increased levels of the defense-related enzyme peroxidase were detected in the treated seedlings. Peroxidase activity in elicitor-treated samples reached a peak at 8 h post-infection, which was 45% more than in their respective uninoculated control. Characterization of peroxidase isoforms by isoelectric focusing revealed 16 different isoforms, of which pI 6.8, 7.2 and 8.7 increased in elicitor-treated samples uponS. graminicola infection. http://www.phytoparasitica.org posting Nov. 14, 2005.     

Mapping of easy to screen SSR markers for selection of RFLP markers-bracketed downy mildew resistance QTLs in pearl millet

There is a growing necessity to replace chemical agents with ecofriendly materials, arising from the impact on the environment and/or human health, which calls for the design of new broad-spectrum fungicides. In this work, chitosan oligomers (COs), propolis (Ps) and silver nanoparticles (AgNPs) mixtures in solution were assessed to control the growth of different phytopathogenic fungi and oomycetes in vitro. Binary solutions of COs-Ps and COs-AgNPs evinced the highest antifungal effect against Fusarium circinatum and Diplodia pinea fungi, respectively, with a ca. 80% reduction in their mycelial growth. The COs solution by itself also proved to be greatly effective against Gremmeniella abietina, Cryphonectria parasitica and Heterobasidion annosum fungi, causing a reduction of 78%, 86% and 93% in their growth rate, respectively. Likewise, COs also attained a 100% growth inhibition on the oomycete Phytophthora cambivora. On the other hand, Ps inhibited totally the growth of Phytophthora ×alni and Phytophthora plurivora. The application of AgNPs reduced the mycelial growth of F. circinatum and D. pinea. However, the AgNPs in some binary and ternary mixtures had a counter-productive effect on the anti-fungal/oomycete activity. In spite of the fact that the anti-fungal/oomycete activity of the different treatments showed a dependence on the particular type of microorganism, these solutions based on natural compounds can be deemed as a promising tool for control of tree diseases.     

Induction of resistance against downy mildew pathogen in pearl millet by a synthetic jasmonate analogon

The synthetic 1-oxo-indanoyl-l-isoleucine methyl ester (Ind-Ile-Me) represents a highly active mimic of octadecanoic phytohormones, which are involved in plant defenses against pathogens and pests. Seed treatments and foliar spray with Ind-Ile-Me were tested for induced resistance against downy mildew disease caused by the phytopathogenic oomycete Sclerospora graminicola in pearl millet (Pennisetum glaucum) under greenhouse and field conditions. Under greenhouse conditions, a 50% protection level was achieved after seed treatment. Seed treatment in combination with foliar spray resulted in 60% protection. The induction of resistance was correlated with the enhanced activities of defense-related proteins such as phenylalanine-ammonia-lyase, peroxidase, and enhanced level of hydroxyproline-rich glycoproteins. Under field conditions, a maximum protection of 62% was recorded upon seed treatment along with foliar spray. Hence, it infers that Ind-Ile-Me can be used as a valuable protection compound at least in downy mildew disease management.     

Activity of cyazofamid against Sclerospora graminicola, a downy mildew disease of pearl millet

The efficacy of cyazofamid was tested against pearl millet downy mildew disease caused by Sclerospora graminicola Schroet. Significant inhibition of sporangial sporulation, zoospore release and motility was observed at 0.3 mg mL(-1), and this concentration also provided good fungicidal activity under in vitro conditions. Under glasshouse conditions, none of the concentrations tested, either 0.01-2 mg mL(-1) as seed treatment or 1-10 mg mL(-1) by foliar application, was found to be phytotoxic. The effect of cyazofamid was tested by seed treatment alone, seed treatment followed by foliar application and foliar application alone. Seed treatment with cyazofamid offered only 19.7% disease control, but seed treatment followed by a single foliar application to diseased plants provided good control over disease, seed treatment with two foliar applications was significantly superior and foliar application alone showed a high level of activity, with 10 mg mL(-1) giving 97.9% disease control. Lack of systemic activity of cyazofamid was evident, root treatment giving disease levels on a par with the untreated control. The fungicide exhibited strong curative activity, but only moderate translaminar activity, with only marginal (34.8%) disease control after treatment of the adaxial leaf surface at 10 mg mL(-1). Loss of cyazofamid activity over time was very low, indicating stable residual and rainfastness activity. These results indicate that cyazofamid has a high potential to be an effective fungicide for the control of downy mildew disease of pearl millet.     

糜子细菌性条斑病病原菌鉴定及其对13种杀菌剂的敏感性

为有效防治糜子细菌性条斑病,采用平板划线分离法对2016年自黑龙江省齐齐哈尔市采集的罹细菌性条斑病的糜子植株进行病原菌分离与纯化,依据柯赫氏法则对其致病性进行测定;采用Biolog自动微生物鉴定系统、16S rDNA和16S-23S rDNA间隔区序列分析及病原菌的生理生化反应对病原菌进行鉴定;并测定该病原菌对13种常用杀菌剂的敏感性。结果显示,从糜子叶片和叶鞘病斑中共分离纯化获得10株培养性状一致的菌株,经柯赫氏法则验证均为细菌性条斑病病原菌。经Biolog鉴定,3株代表菌株与标准菌株燕麦噬酸菌Acidovorax avenae的相似值分别为0.716、0.705、0.723,序列分析显示,这3株代表菌株与燕麦噬酸菌燕麦亚种A. avenae subsp. avenae的一致性为99%以上;该病原菌的革兰氏染色反应及碳源利用等生理生化反应与对照菌株燕麦噬酸菌ICMP3183表现一致。因此,确定糜子细菌性条斑病病原菌为燕麦噬酸菌。糜子细菌性条斑病病原菌代表菌株MZ121101对80%乙蒜素乳油、30%乙蒜素乳油及0.3%四霉素水剂的敏感性较高,抑制中浓度EC50介于389.31～939.94μg/mL之间,这2种药剂可作为防治糜子细菌性条斑病的首选药剂。     

Nitric oxide is involved in chitosan‐induced systemic resistance in pearl millet against downy mildew disease

BACKGROUND: The nature and durability of resistance offered by chitosan and the involvement of nitric oxide (NO) in chitosan‐induced defence reactions in pearl millet against downy mildew disease were investigated. RESULTS: It had previously been reported that chitosan seed priming protected pearl millet plants against downy mildew disease. Further elucidation of the mechanism of resistance showed that chitosan seed priming protects the plants systemically. A minimum 4 day time gap is required between the chitosan treatment and pathogen inoculation for maximum resistance development, and it was found to be durable. Chitosan seed priming elevated NO accumulation in pearl millet seedlings, beginning from 2 h post‐inoculation, and it was found to be involved in the activation of early defence reactions such as hypersensitive reaction, callose deposition and PR‐1 protein expression. Pretreatment with NO scavenger C‐PTIO and nitric oxide synthase (NOS) inhibitor L‐NAME before pathogen inoculation reduced the disease‐protecting ability of chitosan, and defence reactions were also downregulated, which indicated a possible role for NO in chitosan‐induced resistance. CONCLUSION: Protection offered by chitosan against pearl millet downy mildew disease is systemic in nature and durable. Chitosan‐induced resistance is activated via NO signalling, as defence reactions induced by chitosan were downregulated under NO deficient conditions. Copyright © 2009 Society of Chemical Industry     

The epidemiology, variability and control of the downy mildews of pearl millet and sorghum, with particular reference to Africa

Sorghum downy mildew ( Peronosclerospora sorghi ) infecting sorghum and maize, and pearl millet downy mildew ( Sclerospora graminicola ) infecting pearl millet can cause considerable yield loss in Africa. The last 15 years have witnessed an increase in knowledge of the biology, epidemiology and control of these two pathogens. Much information has been obtained on the effect of environmental factors on disease epidemiology, spore production and dispersal. Molecular techniques applied to study pathogenic variability have aided in defining relationships among these pathogens, although scope of the work is limited. Knowledge of the genetics and inheritance of resistance, and of resistance mechanisms, has also increased. This review presents the current state of knowledge of both downy mildew pathogens, with focus on their status on sorghum and pearl millet in Africa. Despite the advances in knowledge over the last 15 years, these downy mildews remain important constraints to sustainable crop production in the semi-arid regions of Africa. In some cases information obtained in Asia and the Americas can be extrapolated to Africa but care must be taken in ensuring its applicability. Priorities for future research relevant for Africa are proposed and discussed.     

Serodiagnosis of pearl millet resistance to downy mildew by quantitating cell wall P/HRGP using polyclonal antiserum Pab-P/HRGP

Proline/hydroxyproline-rich glycoprotein (P/HRGP) level in pearl millet genotypes resistant to downy mildew increase after inoculation with the oomycete pathogen Sclerospora graminicola. Using purified P/HRGPs from pearl millet cell walls, polyclonal antibodies (Pab-P/HRGP) were raised in rabbit. Based on this antiserum, an enzyme immunoassay was developed that displays a linearity detection range from 0.01 to 10 μg P/HRGP. Western blot analysis, confirming the induction of three marker P/HRGPs in the infected resistant genotype, and immunocytochemical studies on P/HRGP localization either in epidermal peelings or in suspension-cultured cells demonstrated the specificity of the antiserum. Besides its characterization, Pab-P/HRGP was employed to screen various genotypes of pearl millet for fast, sensitive and specific detection of induced P/HRGPs upon infections. The results presented are discussed with presumed importance to downy mildew disease and the use of this new antiserum in pearl millet screening for disease resistance.     

Chitosan enhances disease resistance in pearl millet against downy mildew caused by Sclerospora graminicola and defence-related enzyme activation

BACKGROUND: The present study investigated the effect of chitosan seed priming on the induction of disease resistance in pearl millet against downy mildew disease caused by Sclerospora graminicola (Sacc.) Schroet. RESULTS: Pearl millet seeds were primed with chitosan at different concentrations: 0.5, 1.5, 2.5 and 3 g kg^?1 seed. Of the different concentrations, 2.5 g kg^?1 was found to be optimum, with enhanced seed germination of 99% and seedling vigour of 1782, whereas the untreated control recorded values of 87% and 1465 respectively. At optimum concentration, chitosan did not inhibit sporulation and release of zoospores from sporangia. Furthermore, pearl millet seedlings raised after seed treatment with chitosan showed an increased level of the defence‐related enzymes chitosanase and peroxidase as compared with the untreated pearl millet seedlings on downy mildew pathogen inoculation. The effect of chitosan in reducing downy mildew incidence was evaluated in both greenhouse and field conditions, in which respectively 79.08 and 75.8% disease protection was obtained. CONCLUSION: Chitosan was effective in protecting pearl millet plants against downy mildew under both greenhouse and field conditions by inducing resistance against the pathogen. Thus, chitosan formulation can be recommended for seed treatment in the management of downy mildew disease. Copyright © 2008 Society of Chemical Industry     

Seed priming with plant gum biopolymers enhances efficacy of metalaxyl 35 SD against pearl millet downy mildew

‘Priming’ the plant and seed induces a physiological state in which plants are able to activate defense responses. Plant-based exudates are excellent gum biopolymers which contain plant growth-regulating hormones with priming potential without any side effects. In this study, gum exudates of Acacia arabica, Moringa oleifera, Carica papaya and Azadirachta indica were evaluated for synergistic effects of seed priming with exuded gum biopolymer combined with metalaxyl (Apron 35 SD) on pearl millet seed quality, growth parameters, and resistance to Sclerospora graminicola. Seeds of 7042S were primed with gum biopolymers and metalaxyl 35 SD and evaluated under laboratory and greenhouse conditions. Seed germination and vigor were synergistically enhanced using gum biopolymers solution (1:2 w/v) with 3 g kg⁻¹ metalaxyl 35 SD. A. arabica and A. indica gum biopolymers alone or with 3 g kg⁻¹ of metalaxyl 35 SD resulted in seed germination of >91%. Seed priming with 6 g kg⁻¹ of metalaxyl 35 SD gave 89% seed germination and was not significantly different from control. A similar trend in vigor was observed among treatments. Seed priming with gum biopolymers alone provided varied disease protection levels when compared with the control. A. arabica or A. indica gum with 3 g kg⁻¹ of metalaxyl 35 SD was the superior treatment, offering significant 86% disease reduction while exhibiting a growth-promoting effect. Synergistic use of gum biopolymers and metalaxyl 35 SD by seed priming is highly effective in growth promotion and management of pearl millet downy mildew disease.     

Nitric oxide donor seed priming enhances defense responses and induces resistance against pearl millet downy mildew disease

Nitric oxide (NO) donors Nitroso-R-Salt, 2-Nitroso-1-Naphthol and Sodium Nitro Prusside (SNP) were evaluated for their effectiveness in protecting pearl millet [(Pennisetum glaucum L.) R. Br.] plants against downy mildew disease caused by Sclerospora graminicola [(Sacc). Schroet]. Optimization experiments with NO donors showed no adverse effect either on the host or pathogen. Aqueous SNP seed treatment with or without polyethylene glycol (PEG) priming was the most effective in inducing the host resistance against downy mildew both under greenhouse and field conditions. Potassium Ferrocyanide, a structural analog of NO donor lacking NO moiety failed to protect the pearl millet plants from downy mildew indicating a role for NO in induced host resistance. Spatio-temporal studies corroborated that the protection offered by NO donor treatment was systemic in nature and a minimum of 3-day time gap between the inducer treatment and subsequent pathogen inoculation was necessary for maximum resistance development. Disease protection ability of NO donors was also validated as durable in nature. Conversely, prior-treatment with NO scavenger 2-4-carboxyphenyl-4,4,5,5 tetrazoline-1-oxyl-3-oxide potassium salt (C-PTIO) rendered the pearl millet plants relatively susceptible for pathogen infection. Expression of primary defense responses like hypersensitive response, lignin deposition and defense related enzyme phenylalanine ammonialyase −EC 4.3.1.5 (PAL) were enhanced by NO donor treatments.