The Extracellular Matrix, Growth Factors and Morphogens in Biomaterial Design and Tissue Engineering

Cells, morphogens, growth factors, and custom scaffolds are the critical ingredients for successful tissue regeneration in which morphogens and growth factors function sequentially. Extensive studies, in vitro and in vivo, have been made to explore the mechanisms and the roles played by these molecules. As a consequence, precise, localized control over the signaling of these factors and appropriate strategy selection, depending on the tissue or organ to be repaired or regenerated, is known to permit specific management of regenerative processes. The first part of the chapter examines natural ECMs which are a set of molecules secreted by cells that provide structural and biochemical support to the surrounding cells. ECMs also perform many other functions, such as actively regulating cell function through the control of biochemical gradients, cell density, spatial organization, and ligand attachment, thus influencing various types of cell processes. Subsequently, growth factors and morphogens are examined in greater depth to clarify to what degree progress has been made into improving methodologies and functionality and, perhaps, to hint at what remains to be done for the future of tissue engineering

Insights into Insect Resistance in Pulse Crops: Problems and Preventions

Globally, insect pests cause considerable damage to pulse crops. Hence developing broad-spectrum resistance against insect pests has been a major challenge to pulse growers and scientists. Traditionally, cultural practices and synthetic insecticides are being utilized for effective control of insect pests since ages. Apart from these, other strategies such as host plant resistance, insect-resistant transgenic crops, and IPM are also being used to manage the infestation in pulse crops. Though screening of genetic resources for insect resistance has been promising in some pulse crops, fertility barriers and linkage drag minimize the effective utilization of identified resistance in commercially viable crop breeding programs. In parallel, insect-resistant transgenic plants have been developed using various insecticidal proteins from various sources including Bacillus thuringiensis endotoxin, plant protease inhibitors, chitinases, alpha-amylase inhibitors, secondary metabolites, and vegetative insecticidal proteins (VIPs). Deploying transgenic plants with high levels of toxin expression by gene pyramiding is another practical option to delay the resistance development in insects. Nevertheless, the success achieved so far in managing insect pests is limited mainly due to the complex mechanisms underlying the defense strategies together with the lack of precision in screening techniques. Here, we discuss the recent progress and current status of studies toward developing resistance to the most common insect pests of pulses. This chapter points the lack of detailed molecular studies exploring the insect resistance that can advance our knowledge on plant resistance mechanisms and the genes involved. Therefore, a step forward now will be on exploiting natural variations with novel technologies in combination of eco-safe management practices to develop durable insect-resistant pulse crops. Despite technical and regulatory difficulties, developing insect resistance should be the major priority area for future breeding and genetic engineering studies aiming at pulse crop improvement