Mechanism of Arthropod-mediated Transmission of Plant Viruses - A Review

In the intricate world of botanical life, an often-overlooked menace lurks – plant viruses. Viruses invade their target and hijack the plant cell's mechanisms to multiply and reproduce. The impact of these microscopic assailants is profound, affecting food security, food safety, national economies, biodiversity, and the rural environment. Plant viruses, although small in stature, wield immense influence in the plant kingdom. They are sub-microscopic entities comprised of genetic material, either DNA or RNA, encased within a protective protein coat. They need a medium of transmission for survival and spread, which can be air, water, contaminated tools, or certain other organisms known as vectors. These vectors, often insects, fungi, or nematodes, serve as intermediaries between the virus and its plant host, facilitating transmission and infection. Understanding the intricate interactions between plant viruses and their vectors is vital for developing effective control strategies that can mitigate the devastating impact of these diseases on crops. This relationship between a plant virus and a vector is a testament to the complexity of the natural world, where microscopic organisms wield enormous influence over the health and fate of plants, impacting ecosystems and even human agriculture. This review delves into the world of plant virus vectors, un-ravelling their roles in disease transmission, their biological mechanisms, and the pivotal role they play in shaping agricultural landscapes worldwide. It also explores the types of virus transmission and their effects on vector behaviour. This knowledge is essential for developing strategies to mitigate the impact of plant viruses and protect global food security

ROLE OF DRIP IRRIGATION IN PLANT HEALTH MANAGEMENT, ITS IMPORTANCE AND MAINTENANCE

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Anthracnose of Capsicum annuum L. (Chilli)

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Correlation between mite population (Aceria cajani) and environmental factors causing sterility mosaic disease of Pigeon pea

ABSTRACT KEYWORDS Pigeon pea Cajanus cajan (L.) Millspaugh, is one of the major pulse crops of the tropics and subtropics also popularly known as red gram, tuar or arhar is a primary source of protein for millions in India. Sterility mosaic disease (SMD) caused by mite (Aceria cajani) is a major disease limiting the pigeon pea production in the Indian subcontinent. Effect of abiotic factors like temperature, relative humidity and rainfall on mite population was observed during the experiment. Out of theses abiotic factors strong significant correlation was observed with relative humidity. Average temperature of about 20-30°C was found to be congenial for the multiplication of mite. But very high temperature is not suitable for the growth of mite. Heavy rainfall is also not suitable for the growth of mite. Wind velocity is also a very important factor responsible for spreading of disease. The effect of SMD on plant height along with their branches was also observed and can be concluded that severe mosaic affect the plant height, and branches of the pigeon pea plants. The disease severity was high in the early stage of infection causing severe mosaic disease where flower and pod formation was ceased resulting in complete crop failure

Microsatellite markers for crop improvement: A review: Role of microsatellite markers

Microsatellites or simple sequence repeats (SSRs) markers are a helpful strategy among the various molecular marker techniques for strengthening molecular breeding programs. These are useful markers for genotyping plant populations with tandem repeats of 2-6 base pair length DNA patterns. The expansion of various molecular markers and advances in sequencing technologies has aided crop improvement. Several articles for research scholars with progressive knowledge of molecular genetics have been published in the last three decades to probe the information regarding molecular markers. This article reviews novel advances regarding molecular markers and their implementations in plant breeding for researchers with no expertise in using molecular markers in plant breeding. A superior comprehension of molecular markers, and a better consciousness of the spectrum of crops that can be grown, has resulted from progress in molecular plant breeding, genetics, genomic selection, and genome rectification. Further-generation sequence technology must enable the production of novel genetic markers for multifaceted and amorphous groups through genotyping-by-sequencing and union mapping. The review also discusses almost all the microsatellite markers and their advantages and disadvantages.