Enhanced unscheduled DNA synthesis in the cotyledons of Gossypium,barbadense L. by ethyl methanesulfonate (EMS)

When cotyledonary tissue of $\text{G.}\text{,}\text{barbadense}$ cotton are treated with the mutagen ethyl methanesulfonate and then germinated, an enhanced, unscheduled DNA synthesis response is observed, along with a concomitant increase in the thymidine triphosphate precursor pool size. The implications of these results are discussed in this paper.     

Chlamydia isopodii sp. n., an obligate intracellular parasite of Porcellio scaber

In an ultrastructural study of the hepatopancreas of Porcellio scaber, an obligate intracellular parasite, Chlamydia, was noted in the epithelial cells. Although the infection was found to extend the entire length of the hepatopancreas, it was most extensive in the glandular region. Indirect immunofluorescence testing revealed no cross-reactivity with either lymphogranuloma venereum or psittacosis antisera.     

On the non-existence of a tryptic peptide with biological activity derived from mouse nerve growth factor

Reverse-phase high-performance liquid chromatography was used to analyse the products of treatment of mouse nerve growth factor with cyanogen bromide followed by trypsin as described by Mercanti et al. All the biological activity was found to be due to incompletely cleaved starting material. Total digestion with trypsin led to complete loss of activity.     

Host plant resistance for insect control in some important crop plants

Insect pests of cereal crop plants are among the most destructive and devastating factors limiting world food production. Insects often inflict losses of 15 to 50% of the yield of some crops in various parts of the world. Insects also provide infection courts for various pathogens that inflict even greater damage. The nature of these losses is especially tragic for poor farmers in the tropics since the insects consume dry matter already produced using limited resources. Reduction of these losses would enhance the world food supply available to man, even if actual production remains the same, by allotting to man and animals that proportion of production now consumed by insects. Control of insect‐inflicted damage on a world‐wide basis is a very difficult task. Chemical control is effective and readily available in some, but not all, countries. However, chemical control is often unavailable, ineffective, too expensive, and likely to create environmental and safety hazards that make it unsuitable for many parts of the world. Several excellent examples of biological control of insects also attest to the potential usefulness of this method of reducing insect‐inflicted losses, but this method also has been ineffective for certain major insect pests due to lack of effective identification, distribution, and maintenance of biological control agents. On the whole, host plant resistance (HPR) to insects has been the most successful and widely used method of control. HPR has been used successfully in a number of major crop species to help control damage inflicted by major insect pests. However, problems with identifying sources of resistance and transferring it to usable varieties have often been difficult to overcome. Also, once resistance is deployed, changes in insect populations which allow them to overcome the resistance sometimes eliminate the potential advantages of resistant varieties. However, methods to quantify host‐insect interactions have improved significantly over the past few years, and the prospects for developing and maintaining usable levels of resistance to several major insect pests of most major crops are good. Studies of the biochemical and biophysical mechanisms of insect resistance have added a new dimension to HPR work. Knowledge of specific factors that contribute to insect resistance can be extremely useful to plant breeders and entomologists. The ability to identify and select for one specific plant component or group of components can speed the development of resistant varieties. Studies of the effect of such resistance components on insect development and behavior can help determine the likelihood of insects being able to overcome the resistance factors. Studies of the effect of the resistance factors on host plant yield, performance, or quality may help plant breeders overcome the problems often associated with the development of high yielding and high quality resistant varieties. Identification of several different mechanisms of resistance could provide breeders the opportunity to adjust levels of several resistance components in order to arrive at a proper blend of resistance, quality, and yield. Furthermore, development of varieties with multiple mechanisms of resistance should slow the development of new biotypes of insects that could overcome the HPR since the insects would have to simultaneously or sequentially develop the ability to overcome several resistance factors. Therefore, knowledge of mechanisms of insect resistance could facilitate the development of more stable and long‐lasting types of resistance.     

Genetic characterization of mouse immunoglobulin allotypic determinants (allotopes) defined by monoclonal antibodies

We have generated a new series of monoclonal antibodies recognizing allotypic determinants on mouse IgG₁, IgG_2a, and IgG_2b. In this communication we describe their reactivities with immunoglobulins of the inbred mouse strains. Comparison with serology charts indicates that many of these monoclonal antibodies detect allotypic specificities previously defined by conventional antisera; others define previously undescribed specificities. Strain and isotype distribution allows us to assign five new allotypic specificities to Igh-1 and three new specificities to Igh-3. In addition, on the basis of reactivity with the monoclonal antibodies, we have defined a new Igh haplotype in SWR/J mice, Igh ^p.Abbreviations used in this paper Igh immunoglobulin heavy chain - SDS sodium dodecyl sulfate     

Transmission of Salmonella montevideo in Wheat by Stored-Product Insects

Sitophilus oryzae (L.), S. granarius (L.), Tribolium castaneum (Hbst.), Oryzaephilus surinamensis (L.), Rhyzopertha dominica (F.), Tenebroides mauritanicus (L.), and Cryptolestes pusillus (Schon.) transmitted Salmonella montevideo from wheat contaminated with 10(6) organisms/g to clean wheat. The insects were fed on the contaminated grain for 21 days and were then transferred to clean grain and allowed to feed for 21 days. They were subsequently transferred to two more samples of clean wheat. All species carried S. montevideo into the initial sample of clean wheat but not into a second or third sample. Progeny of the original insects that developed in the contaminated wheat exhibited less ability than the original adults to contaminate clean wheat. Data indicated that few S. montevideo could be carried by the stored-product insects in large masses of grain.     

Cultivation and Survival Studies of Neisseria gonorrhoeae in a Human Diploid Cell Strain

Neisseria gonorrhoeae was cultivated in a human diploid cell strain (WI-38). Eighty percent of the cultures contained viable gonococci for at least 4 m at 36°C, as evidenced by subculture to brain heart infusion broth. Monthly subcultures of bacteria could be made to fresh WI-38 cultures for at least 11 monthly passages with a 69% survival rate. The identity of gonococci was confirmed by morphology, gram staining, oxidase testing and fermentation reactions. Viability in brain heart infusion broth, minimum essential medium (Eagle), and WI-38 spent fluid was of much shorter duration. The organisms grown in WI-38 cultures appeared to orient largely in the vicinity of the WI-38 cells as well as within the cytoplasm of the cells.