From disease marker identification to accelerated drug development, Protein Arrays, Biochips, and Proteomics offers a detailed overview of current and emerging trends in the field of array-based proteomics. This reference focuses on innovations in protein microarrays and biochips, mass spectrometry, high-throughput protein expression, protein-protein interactions, structural proteomics, and the proteomic marketplace for comprehensive understanding of past, present, and future proteomic research. Offering an abundance of figures and charts, the book compiles a wide variety of technologies and applications ranging from functionalized chip surfaces to strategies for protein expression.

From disease marker identification to accelerated drug development, Protein Arrays, Biochips, and Proteomics offers a detailed overview of current and emerging trends in the field of array-based proteomics. This reference focuses on innovations in protein microarrays and biochips, mass spectrometry, high-throughput protein expression, protein-protein interactions, structural proteomics, and the proteomic marketplace for comprehensive understanding of past, present, and future proteomic research. Offering an abundance of figures and charts, the book compiles a wide variety of technologies and applications ranging from functionalized chip surfaces to strategies for protein expression.

We open Volume 7 with a series of four chapters on plant virus transmission by insects. In Chapter 1, Karen Gibb and John Randles present preliminary information about an association between the plant bug Cyrtopeitis nicotianae (Heteroptera: Miridae) and velvet tobacco mottle virus (VTMo V): the only reported instance of mirid transmission of a known virus. Mirids could be considered as likely vectors of plant viruses because they are phytophagous, possess a piercing-sucking-feeding apparatus, have winged adults, and are cosmopolitan pests of a wide range of crops. Surprisingly, however, there are only three plant viruses purportedly transmitted by heteropterous vectors, compared with the nearly 250 by homopterous ones. To what extent these figures reflect actual differences in the abilities of members of the two suborders to transmit plant pathogens remains to be determined. Compared with the Homop tera, the Heteroptera have been ignored by researchers as potential vectors of plant viruses. The authors are quick to point out that additional studies are needed before generalizations can be made about virus-mirid-plant interactions and that virus transmission by mirids is not easily characterized using the conventional transmission criteria and terminology established for such homopterous vectors as aphids and leafhoppers. Transmission of VTMoV by C. nicotianae appears to have characteristics in common with both nonpersistent noncirculative and circulative (persistent) transmission."