A study of New Testament teaching concerning the Christian's involvement in lawsuits

Mellick, Roger Wilbur.

January 1973

Thesis (M. Th.)--Capital Bible Seminary, 1973. / Includes bibliographical references (leaves 68-72).

Arabidopsis miR163 and its target are involved in defense against Pseudomonas syringae

Chow, Hiu Tung

02 September 2016

Small RNAs are important regulators for a variety of biological processes, including leaf development, flowering-time, embryogenesis and defense responses. Most ancient miRNAs are conserved among different plant species and well characterized, while young MIRNA genes are considered to be non-conserved, highly species-specific and less well-studied. miR163 is a non-conserved miRNA and its locus has evolved recently by inverted duplication events of its target gene. Previously, we have shown that miR163 acts as a negative regulator of defense response. However, it remains unclear how miR163 and its targets are being regulated in response to pathogen attacks. Here, we further elucidated the molecular controls and the involvement of miR163 and its targets in plant defense response. Elevated level of miR163 was observed by Pst treatment in Arabidopsis thaliana, and this upregulation was found to be important in controlling the accumulation of its targets (PXMT1 and FAMT), to which they were also inducible by Pst treatment. Transcript and protein level analyses in transgenic plants overexpressing miR163-resistant form of PXMT1 or FAMT provided evidence for miR163 in fine-tuning its targets, suggesting that the stress-inducible miR163 and its targets act in concert in affecting defense genes expression. Epigenetically, histone deacetylation was found to involve in the repression of miR163 targets before and after Pst infection. Our findings revealed additional mechanistic insights to the controls and the evolutionary significance of young miRNA in mediating plant defense pathways against biotic stresses.

How integrating a shipboard radar system to a[n] electronic warfare system can help defeat anti-ship missile attacks

Hogue, David W.

30 March 2010

The goal of this work to quantify the benefits integrating a shipboard radar system with the ship's electronic warfare (EW) system terms of increased effectiveness of chaff decoys against sea skimmimg missiles. Present shipboard EW and radar systems have been developed independently because of the functions or tasks they serve. By interfacing the two systems, chaff could now be launched based on radar data as well as based on Electronic Support Measures (ESM) data, resulting in increased ship survivability. <p>This project and report first addresses a need (section II) for a more adequate defense system against sea skimming missiles. Interfacing the EW and radar systems is suggested as a way to increase ship survivability. A dynamic, closed loop software model which includes the ship, missile, chaff, radar, and ESM sensors was developed to test this hypothesis. A description of this model is presented in section III. Results of the analysis is presented in section IV and concluding remarks are in section V. / Master of Science

Antiship missile defenses

LD5655.V851 1993.H638

Ontogenic Development of Heat Defenses in the Young Rat

Everett, James C.

05 1900

<p> Neonatal rats exposed to heat stress were studied to determine the age at which the saliva-spreading response appears, and to elucidate any other heat defenses that might exist before the response develops.</p> <p> Saliva-spreading appeared on the 17th day of age, the age at which hypothalamic maturity is attained. This finding thus agrees with previous hypotheses that the hypothalamus is involved in the regulation of body temperature.</p> <p> The tolerance of rats to an ambient temperature of 40 C dropped from 16 - 26 hours to 2 - 4 hours in the first 10 days of life. Three factors accounted for this change: decreased body water, increased rates of water loss, and increased metabolic rate.</p> / Thesis / Master of Arts (MA)

Identification, Characterization, and Functional Analysis of Terpenoid Specialized Metabolism in Switchgrass (Panicum virgatum) and Carrot (Daucus carota)

Muchlinski, Andrew Joseph

01 October 2019

Plants produce a large number of specialized or secondary compounds that aid in their reproduction and protection against biotic and abiotic stress. In this work I investigated the metabolism and function of terpenes, the largest class of specialized metabolites, in switchgrass and carrot. Switchgrass (Panicum virgatum L.), a perennial C4 grass of the Tallgrass Prairie, represents an important species in natural and anthropogenic grasslands of North America. Its natural resilience to abiotic and biotic stress has made switchgrass a preferred bioenergy crop. I have investigated the metabolism of terpenes in switchgrass leaves and roots in response to herbivory or defense hormone treatments and the application of drought. With a focus on volatile terpene metabolites, I functionally characterized over thirty genes (terpene synthases, TPSs), of which one third could be correlated with the production and release of volatile monoterpenes and sesquiterpenes that likely function in direct chemical defense or in the attraction of insect predators or parasitoids. Drought stress application caused switchgrass roots to accumulate a larger amount of oxygenated terpenes and presumably non-volatile terpenes, the function of which in direct or indirect drought stress protection requires further investigation. I also examined the metabolic dynamics and role of the monoterpene borneol, which accumulates at high concentrations in the roots of switchgrass and to a lower extent in the roots of the close relative Setaria viridis, in root microbe interactions. Although we demonstrated a successful RNAi based knock down of the borneol terpene synthase TPS04, we found no immediate evidence that borneol significantly modifies bacterial communities in the root. Further studies on Setaria and equivalent RNAi lines in switchgrass will provide more detailed and needed insight to decipher the role of monoterpene accumulation in grasses interactions with mutualists, pathogens, and pests. In an applied project, I investigated terpene specialized metabolism in carrot (Daucus carota L.) to identify genetic determinants of carrot aroma and flavor. To determine central enzymes which contribute to the terpene component of carrot volatile blends, we first analyzed tissue specific expression patterns of carrot terpene synthase genes (TPS) in the genomic model carrot (cv. DH1) and in roots of four aromatically unique colored carrot genotypes (orange-4943B, red-R6637, yellow-Y9244A and purple-P7262). We selected nineteen key biosynthetic enzymes involved in terpene formation and compared in vitro products from recombinant proteins with native volatile profiles obtained from DH1 and colored carrot genotypes. We biochemically characterized several highly expressed TPSs with direct correlations to major compounds of carrot flavor and aroma including germacrene-D (DcTPS11), (DcTPS30) and -terpinolene (DcTPS03). Random forest analysis of colored carrot volatiles revealed that nine terpene compounds are sufficient for distinguishing the flavor and aroma of raw colored carrots. Interestingly, accumulation of specific terpene compounds rather than chemical diversity is responsible for differences in sensory quality traits in colored genotypes. As accumulations of specific terpene compounds can contribute to the undesired flavor in carrot, our report provides a detailed roadmap for future breeding efforts to enhance carrot flavor and aroma. / Doctor of Philosophy / Plants produce a large number of chemicals that are important for growth, defense, flavor, and aroma. While chemical production has been studied in some major food crops (corn, tomato, rice), knowledge of the formation and function of chemicals in switchgrass and carrot is still limited. Switchgrass (Panicum virgatum L.), a grass of the Tallgrass Prairie, represents an important species grasslands of North America. Its natural resilience to stress has made switchgrass a preferred bioenergy crop. I found that switchgrass produces many compounds in the chemical class of terpenoids in roots and leaves that likely serve as a defense against damage from pests. In addition, I found that drought stress leads to the production of terpenoid compounds that may have roles in protection when water is limited. My research also demonstrates that roots of switchgrass and the related grass Setaria maintain substantial levels of the essential oil compound borneol. This terpenoid compound can act as a nutrient source for specific bacteria and/or an antimicrobial agent. Therefore, I proposed that switchgrass and Setaria roots produce borneol to establish a distinct root microbiome by recruitment of beneficial bacteria and deterrence of harmful microorganisms. To test this hypothesis, we genetically engineered plants to reduce borneol formation and accumulation in roots. Using these plants, we evaluated changes in the root microbiome in response to altered borneol levels. We found that interfering with borneol production in Setaria roots has limited influence on the microbiome inside roots. Although a similar approach was used for switchgrass, we were unable to significantly reduce borneol V formation in roots. Results from this study provide a better understanding of belowground plant-microbe interactions, and potential for enhancing resistance traits into other crop species. I also investigated the flavor and aroma compounds produced in carrots, which are considered a key supplemental vegetable due to high nutritional value and pleasant taste. Surprisingly, little has been known about the genetic factors that control flavor and aroma traits in colored carrot varieties. Therefore, I performed a robust characterization of the biosynthesis of terpenoids, which are the predominant aroma and flavor compounds in carrot. I identified several enzymes in carrot that can produce a diverse blend of terpenoids which are associated with sweet, spicy and bitter tastes. In addition, I discovered that carrot stems and leaves also maintain a rich chemistry of terpenoids similar to that in roots. Results from this work provide a baseline for engineering enhanced flavor in carrot and provide a deeper insight into essential oil formation in root crops.

terpene

chemical defenses

roots

plant-microbe interactions

A test of optimal defense theory vs. the growth-differentiation balance hypothesis as predictors of seaweed palatability and defenses

Heckman, Melanie L.

31 August 2011

Because organisms have limited resources to allocate to multiple life history traits, the Optimal Defense Theory (ODT) and the Growth-Differentiation Balance Hypothesis (GDBH) were developed by terrestrial plant ecologists to predict intraindividual defense allocation based on the cost of defense and these life history trade-offs. However, these theories have garnered equivocal experimental support over the years and are rarely experimentally extended from predictions of plant physiology to the palatability of the tissues an herbivore experiences. We therefore examined tissue palatability, nutritional value, and defense mechanisms in multiple Dictyotalean seaweeds in two Caribbean locations, using two herbivores. Relative palatability of tissues varied greatly with algal species, grazer species, and location. Because older bases were not consistently defended, GDBH did not predict relative palatability. We could not reject ODT without intensive measures of tissue fitness value and herbivore risk, and this theory was therefore not useful in making broad predictions of tissue palatability. In testing the physiological predictions of these theories, we found the young, growing apices of these seaweeds to be generally more nutritionally valuable than the old, anchoring bases and found organic-rich apices to be more chemically deterrent, thus supporting ODT. However, the combined chemical, nutritional, and structural traits of these algae all influenced herbivore choice. As a result, these patterns of apical value and chemical defense reflected palatability of live tissues for only one of five algal species, which rendered ODT and GDBH poor predictors of relative palatability for most algae.

Defense theory

Seaweeds

Herbivory

Chemical defense

Defense allocation

Macroalgae

Marine algae

Plant defenses

Plant chemical defenses

World systems theory and military expenditures : a comparison of Sweden and Canada

Shewchuk, David

January 1987

No description available.

Canada -- Defenses

Sweden -- Defenses

Mitigating the MANPADS threat : International Agency, U.S., and Russian efforts /

Bartak, John R.

January 2005

Thesis (M.A. in National Security Affairs)--Naval Postgraduate School, March 2005. / Thesis Advisor(s): Mikhail Tsypkin, Edward J. Laurance. Includes bibliographical references (p. 73-79). Also available online.

World systems theory and military expenditures : a comparison of Sweden and Canada

Shewchuk, David

January 1987

No description available.

Canada -- Defenses

Sweden -- Defenses

Studies of Trogoderma species development and starvation, and effects of their hastisetae on selected stored-product insects

Kokubu, Hirotaka.

January 1979

Call number: LD2668 .T4 1979 K63 / Master of Science

Trogoderma.

Grain--Storage--Diseases and injuries.

Animal defenses.

Masters theses