The cardio-renal effect of pea protein hydrolysate in a chronic kidney disease rat model

Prairie, Natalie Paula

03 January 2012

Pea protein hydrolysate (PPH) has antihypertensive effects and prostanoids have been implicated in renal diseases. To investigate the role of PPH and prostanoids on renal and cardiovascular effects in cardio-renal disease, normal and diseased Han:SPRD-cy rats were given diets containing either 0, 0.5% or 1% PPH for 8 weeks. At termination, diseased rat kidneys displayed increased renal cyst growth, fibrosis, plasma creatinine and lower monocyte chemoattractant protein-1. Diseased rats also exhibited left ventricular (LV) hypertrophy, elevated systolic and diastolic blood pressures and LV end diastolic and systolic pressures. Four of five prostanoids were elevated in diseased rat kidneys. PPH attenuated systolic blood pressure, but not other components of the cardio-renal syndrome. PPH also increased select prostanoids in normal and diseased rats. Thus, dietary PPH attenuates hypertension in the Han:SPRD-cy rat, but does not ameliorate other components of disease, possibly due to increased prostanoid effects or an insufficient treatment length.

pea protein hydrolysate

Han:SPRD-cy rat

chronic kidney disease

angiotensin converting enzyme

renin

Gelation properties of protein mixtures catalyzed by transglutaminase crosslinking

Sun, Xiangdong

07 April 2011

Gelation properties of a salt extracted pea (Pisum sativum) protein isolate (PPIs) were evaluated with a goal of using this isolate as a meat extender. Microbial transglutaminase (MTG) was used to improve gelation of PPIs, muscle protein isolate (MPI) from chicken breast and the two combined. Gelation properties were evaluated using small amplitude oscillatory rheology and texture analysis. SDS-PAGE and differential scanning calorimetry were used to examine protein structure. Minimum gelation concentration for PPIs was 5%, lower than the 14% obtained for a commercial pea protein isolate (PPIc), possibly because the PPIc undergone denaturation whereas PPIs had not. Storage modulus (G') and loss modulus (G") increased with protein concentration and maximum gel strength for PPIs occurred at pH 4.0 in 0.3M NaCl. Higher or lower pH values affected protein charge and the potential for network formation. Higher salt concentrations resulted in increased denaturation temperatures, to a point where the proteins did not denature at the 95ºC temperature used for gel formation. When both heating and cooling rate were increased, gel strength decreased, though the cooling rate had a greater impact. Chaotropic salts enhanced gel strength, whereas non-chaotropic salts stabilized protein structure and decreased gel formation. Based on effects of guanidine hydrochloride, urea, propylene glycol, β-mercaptoethanol, dithiothreitol and N-ethylmaleimide, hydrophobic and electrostatic interaction and hydrogen bonds were involved in pea protein gel formation but disulfide bond contribution was minimal. Gels formed with MPI at concentrations as low as 0.5% and were strongest at 95ºC, higher than the ~ 65ºC normally used in meat processing. Good gels were formed at pH 6 with 0.6 to 1.2 M NaCl. Addition of MTG increased gel strength for PPIs, MPI, and a combination of the two. SDS-PAGE showed that bands in the 35~100kDa range became fainter with higher MTG levels but no new bands were found to provide direct evidence of interaction between muscle and pea proteins. Improved gel strength for the MPI/PPI mixture (3:1) containing MTG suggested that some crosslinking occurred. Higher heating temperatures and MTG addition led to the formation of MPI/PPI gel and demonstrated the potential for utilization of pea protein in muscle foods.

Pea protein isolate

Myofibrillar protein isolate

Gelation

Microbial transglutaminase

Protein mixture

The cardio-renal effect of pea protein hydrolysate in a chronic kidney disease rat model

Prairie, Natalie Paula

03 January 2012

Pea protein hydrolysate (PPH) has antihypertensive effects and prostanoids have been implicated in renal diseases. To investigate the role of PPH and prostanoids on renal and cardiovascular effects in cardio-renal disease, normal and diseased Han:SPRD-cy rats were given diets containing either 0, 0.5% or 1% PPH for 8 weeks. At termination, diseased rat kidneys displayed increased renal cyst growth, fibrosis, plasma creatinine and lower monocyte chemoattractant protein-1. Diseased rats also exhibited left ventricular (LV) hypertrophy, elevated systolic and diastolic blood pressures and LV end diastolic and systolic pressures. Four of five prostanoids were elevated in diseased rat kidneys. PPH attenuated systolic blood pressure, but not other components of the cardio-renal syndrome. PPH also increased select prostanoids in normal and diseased rats. Thus, dietary PPH attenuates hypertension in the Han:SPRD-cy rat, but does not ameliorate other components of disease, possibly due to increased prostanoid effects or an insufficient treatment length.

pea protein hydrolysate

Han:SPRD-cy rat

chronic kidney disease

angiotensin converting enzyme

renin

Rectangular silos; Interaction of structure and stored bulk solid

Goodey, Richard J.

January 2002

The main aim of this research is directed towards the study of thin-walled rectangular planform silos with a view to maximising their structural efficiency. In thin plates of the type making up the wall, membrane action may increase the load carrying capability and current design guides make no account of this. Designing rectangular silos with this in mind can lead to significant structural savings. The core of the research involves using the finite element method to study the patterns of pressure exerted by the weight of a granular bulk solid on the walls of the silo structure. The stored granular solid must use an elastic-plastic material law in order to account for large deformations that can occur in a thin-walled structure. The need for this type of constitutive law led to the investigation of bulk solid properties and shows that parameters that have previously been used to categorise bulk solids may not be sufficient to describe all aspects of their behaviour. The finite element model created uses material constitutive laws that can be found in a number of packages. The required granular material parameters can be determined from a number of simple tests. This approach aims to enable engineers to routinely use similar models when designing silos. The results obtained from the finite element model exhibited some anomalies that had been observed in previous work. These were mainly apparent in the form of localised pressure peaks near the base of the model. These effects were investigated and possible mechanisms that lead to them were proposed. The results from the finite element model were compared to previous experimental work and existing theories. The model was then used to conduct parametric surveys on square and rectangular planform silos and the distribution of pressure across the wall compared to previous predictive models. Finally, a scale thin-walled metal silo was constructed and pressure measurements on filling with pea gravel made. These are compared to predictions made by the finite element model.

624

Development and evaluation of procedures and reagents for extraction of proteins from dried blood spots for analysis using Proseek

Björkesten, Johan

January 2014

A method for extraction of proteins from dried blood spots (DBS) for analysis using Proseek is developed and evaluated. DBS, as sample format, possesses a number of desirable advantages over for example plasma samples. These advantages include for example minimal patient invasiveness, sampling simplicity and non regulated sample transportation. Highly reproducible quantitative detection of 92 proteins is demonstrated from a 1.2 mm in diameter DBS disk. The DBS inter spot analysis precision (7% coefficient of variance) is comparable to plasma inter assay precision (6% coefficient of variance). Coefficient of variance is the ratio between standard deviation to mean value for the analysed replicates. Proseek analysis of DBS could possibly reveal a unique opportunity to examine health related issues in extremely premature infants hopefully resulting in increased survival rates in the future.

DBS

dried blood spots

PEA

Proseek

Proseek Multiplex

qPCR

Protein detection

Olink

Integrated pest management of Sitona lineatus L. (Coleoptera: Curculionidae) in crops of Pisum sativum L. (Fabales: Fabaceae) in Western Canada

Vankosky, Meghan Ann

11 1900

Sitona lineatus L. (Coleoptera: Curculionidae) is a pest of Pisum sativum L. (Fabales: Fabaceae) and managing it is a challenge because of its fecundity, migratory behavior and concealed larval habitat. Potential components of an integrated pest management program for S. lineatus were investigated near Lethbridge and Vauxhall, Alberta over three years. Cage studies indicated that larval feeding is more damaging than adult feeding but that larval populations are not dependent on adult weevil density. In open plot experiments, thiamethoxam-treated plants experienced significantly less foliar feeding damage than plants receiving no insecticide treatment but no consistent effects on yield were observed for any plot treatment over six site-years. Rhizobium inoculation had a synergistic interaction with thiamethoxam. Laboratory trials showed that Bembidion quadrimaculatum L. (Coleoptera: Carabidae) consumed S. lineatus eggs. Seed treatment with thiamethoxam and Rhizobium inoculant, and egg predation should be included in an integrated pest management program for S. lineatus. / Plant Science

Sitona lineatus

Field pea

Integrated pest management

Biological control

Thiamethoxam

Rhizobium leguminosarum

Ground beetles

INTERACTIONS BETWEEN AUXIN AND STRIGOLACTONE IN THE CONTROL OF ARABIDOPSIS SHOOT BRANCHING

Alice Hayward

Unknown Date

Diversity in plant architecture is largely generated by the post-embryonic regulation of meristem initiation and activity. In a phenomenon known as apical dominance, the active growth of the shoot apical meristem (SAM) exerts significant inhibitory force on the outgrowth of axillary meristems (AMs) into shoot branches. The degree of branching in plants is a determinant of yield in many crop species and is carefully regulated to ensure that plants only branch at specific stages of development or in response to their environment. Apical dominance has been attributed to the action of the hormone auxin, produced in SAM tissues and transported downwards. A second hormone, cytokinin, acts antagonistically to auxin to promote branching. Nonetheless, the exact mechanism by which these hormones operate is still being elucidated and continued research suggested that novel signals are involved. The recent discovery that strigolactones, previously implicated in parasitic weed germination and mycorrhizal associations, are branching inhibitors supports the existence of additional signals controlling branching in plants. In garden pea (Pisum sativum) strigolactones are synthesised by the coordinated action of the carotenoid cleavage dioxygenase (CCD) family enzymes, RMS1 (RAMOSUS1) and RMS5. These are encoded by MAX4 (MORE AXILLARY GROWTH4) and MAX3 in Arabidopsis thaliana respectively. Mutants for MAX genes have increased amounts of auxin travelling in the polar auxin transport stream (PATS) of inflorescence stems but exhibit increased branching that is insensitive to inhibition by this auxin. Two hypotheses for the action of strigolactones have been presented. The first is that strigolactones modulate the levels of auxin transport proteins, preventing axillary buds from establishing an active auxin transport flow into the primary stem, which inhibits growth. The second is that strigolactones act downstream of auxin signalling to inhibit the action of outgrowth-promoters. Consistent with this latter hypothesis, in pea, rice (Oryza sativa) and petunia (Petunia hybrida), the expression of RMS1/MAX4 orthologues is auxin regulated. These genes are also regulated by feedback signalling in strigolactone pathway mutants and this is proposed to involve an additional novel signal. In Arabidopsis, however, research showed that MAX4 is not regulated by feedback or auxin in the shoot and placed doubt on the importance of this regulation for branching control. The strigolactone biosynthetic pathway offers a novel target for the manipulation of plant architecture and yield while controlling the germination of parasitic weed species that are detrimental to agriculture. Therefore, a greater understanding of the pathway and its regulators is beneficial. The majority of the research in this thesis pre-dates the discovery of strigolactones as the RMS/MAX-derived branching inhibitor, yet aimed to clarify the evolutionary conservation and functional importance of the regulation of strigolactone biosynthetic genes by auxin and feedback signalling in Arabidopsis. Quantitative real-time PCR analysis demonstrated that MAX3 and MAX4 are co-ordinately and systemically regulated by auxin and by feedback throughout development. Both auxin and feedback regulation required the AXR1/TIR1 auxin response pathway, which targets Aux/IAA transcriptional repressors for proteasomal degradation. In particular, correct degradation of the Aux/IAA protein IAA12 appears to be necessary for optimal MAX3 and MAX4 expression. Moreover this regulation affects strigolactone-dependent branching inhibition. Therefore it is proposed that auxin inhibits branching, in part, by positively regulating strigolactone synthesis. As feedback requires AXR1, this also suggests that increased auxin level and/or signalling in the PATS in conditions of reduced strigolactone signalling mediates feedback regulation of the strigolactone pathway. Consistent with this, microarray analysis revealed that in addition to the inflorescence, max mutants have increased global auxin-responsive gene expression associated with the PATS in the vegetative stage. The pea RMS1 gene was the first strigolactone pathway gene demonstrated to be auxin-regulated. Sequencing of the RMS1 promoter and comparative bioinformatic analysis with promoters of other strigolactone synthesis genes revealed a number of conserved, putative regulatory cis-elements that could mediate this regulation and cross-talk with additional branching cues. However a 2.5 kb fragment of the RMS1 promoter was not sufficient to drive transcriptional and translational fusions with GFP and the RMS1 coding region in Arabidopsis. The RMS1 coding region driven by the CAMV 35S promoter complemented the max4 mutant but did not affect branching induced by auxin-depleting treatments. Grafting studies with axr1 and iaa12 mutants, and decapitation and auxin-transport inhibition in max4 mutants, demonstrated that auxin signalling has a function in branching control independent from the regulation of strigolactone synthesis genes. Overall, data obtained herein was incorporated into current models for the interaction of the strigolactone pathway with auxin and cytokinin in the control of shoot branching. It is suggested that both strigolactone and auxin have the capacity to regulate the levels or distribution of each other in interlocking feedback loop that intersects with additional developmental, physiological and environmental cues for the precise control of axillary branching in plants.

MAX

RMS

BODENLOS/IAA12

Branching

Auxin

Strigolactone

Cytokinin

Pea

Arabidopsis

Transcription

INTERACTIONS BETWEEN AUXIN AND STRIGOLACTONE IN THE CONTROL OF ARABIDOPSIS SHOOT BRANCHING

Alice Hayward

Unknown Date

Diversity in plant architecture is largely generated by the post-embryonic regulation of meristem initiation and activity. In a phenomenon known as apical dominance, the active growth of the shoot apical meristem (SAM) exerts significant inhibitory force on the outgrowth of axillary meristems (AMs) into shoot branches. The degree of branching in plants is a determinant of yield in many crop species and is carefully regulated to ensure that plants only branch at specific stages of development or in response to their environment. Apical dominance has been attributed to the action of the hormone auxin, produced in SAM tissues and transported downwards. A second hormone, cytokinin, acts antagonistically to auxin to promote branching. Nonetheless, the exact mechanism by which these hormones operate is still being elucidated and continued research suggested that novel signals are involved. The recent discovery that strigolactones, previously implicated in parasitic weed germination and mycorrhizal associations, are branching inhibitors supports the existence of additional signals controlling branching in plants. In garden pea (Pisum sativum) strigolactones are synthesised by the coordinated action of the carotenoid cleavage dioxygenase (CCD) family enzymes, RMS1 (RAMOSUS1) and RMS5. These are encoded by MAX4 (MORE AXILLARY GROWTH4) and MAX3 in Arabidopsis thaliana respectively. Mutants for MAX genes have increased amounts of auxin travelling in the polar auxin transport stream (PATS) of inflorescence stems but exhibit increased branching that is insensitive to inhibition by this auxin. Two hypotheses for the action of strigolactones have been presented. The first is that strigolactones modulate the levels of auxin transport proteins, preventing axillary buds from establishing an active auxin transport flow into the primary stem, which inhibits growth. The second is that strigolactones act downstream of auxin signalling to inhibit the action of outgrowth-promoters. Consistent with this latter hypothesis, in pea, rice (Oryza sativa) and petunia (Petunia hybrida), the expression of RMS1/MAX4 orthologues is auxin regulated. These genes are also regulated by feedback signalling in strigolactone pathway mutants and this is proposed to involve an additional novel signal. In Arabidopsis, however, research showed that MAX4 is not regulated by feedback or auxin in the shoot and placed doubt on the importance of this regulation for branching control. The strigolactone biosynthetic pathway offers a novel target for the manipulation of plant architecture and yield while controlling the germination of parasitic weed species that are detrimental to agriculture. Therefore, a greater understanding of the pathway and its regulators is beneficial. The majority of the research in this thesis pre-dates the discovery of strigolactones as the RMS/MAX-derived branching inhibitor, yet aimed to clarify the evolutionary conservation and functional importance of the regulation of strigolactone biosynthetic genes by auxin and feedback signalling in Arabidopsis. Quantitative real-time PCR analysis demonstrated that MAX3 and MAX4 are co-ordinately and systemically regulated by auxin and by feedback throughout development. Both auxin and feedback regulation required the AXR1/TIR1 auxin response pathway, which targets Aux/IAA transcriptional repressors for proteasomal degradation. In particular, correct degradation of the Aux/IAA protein IAA12 appears to be necessary for optimal MAX3 and MAX4 expression. Moreover this regulation affects strigolactone-dependent branching inhibition. Therefore it is proposed that auxin inhibits branching, in part, by positively regulating strigolactone synthesis. As feedback requires AXR1, this also suggests that increased auxin level and/or signalling in the PATS in conditions of reduced strigolactone signalling mediates feedback regulation of the strigolactone pathway. Consistent with this, microarray analysis revealed that in addition to the inflorescence, max mutants have increased global auxin-responsive gene expression associated with the PATS in the vegetative stage. The pea RMS1 gene was the first strigolactone pathway gene demonstrated to be auxin-regulated. Sequencing of the RMS1 promoter and comparative bioinformatic analysis with promoters of other strigolactone synthesis genes revealed a number of conserved, putative regulatory cis-elements that could mediate this regulation and cross-talk with additional branching cues. However a 2.5 kb fragment of the RMS1 promoter was not sufficient to drive transcriptional and translational fusions with GFP and the RMS1 coding region in Arabidopsis. The RMS1 coding region driven by the CAMV 35S promoter complemented the max4 mutant but did not affect branching induced by auxin-depleting treatments. Grafting studies with axr1 and iaa12 mutants, and decapitation and auxin-transport inhibition in max4 mutants, demonstrated that auxin signalling has a function in branching control independent from the regulation of strigolactone synthesis genes. Overall, data obtained herein was incorporated into current models for the interaction of the strigolactone pathway with auxin and cytokinin in the control of shoot branching. It is suggested that both strigolactone and auxin have the capacity to regulate the levels or distribution of each other in interlocking feedback loop that intersects with additional developmental, physiological and environmental cues for the precise control of axillary branching in plants.

MAX

RMS

BODENLOS/IAA12

Branching

Auxin

Strigolactone

Cytokinin

Pea

Arabidopsis

Transcription

Incorporation of pea weevil resistance from wild pea (Pisum fulvum) into cultivated field pea (Pisum sativum)

Byrne, Oonagh Marie Therese

January 2005

The pea weevil (Bruchus pisorum L.) is the most significant pest of field pea (Pisum sativum L.) in Australia. The only available means for controlling pea weevil at the present time is with chemical pesticides. The aim of this study was to introgress natural pea weevil resistance, derived from the wild pea species, Pisum fulvum Sibth. & Sm. into cultivated field pea and devise strategies for screening for the resistance with breeding applications. Traditional breeding methods were used to transfer pea weevil resistance from P. fulvum accession ‘ATC113’ to cultivated field pea, cv. ‘Pennant’. Progeny derived from this population were examined for inheritance of pod and seed resistance. Seed resistance in F2 plants segregated in a ratio of 1:37:26 (resistant: mixed response: susceptible), indicating a trigenic mode of inheritance (1:63), with at least three major recessive genes controlling pea weevil resistance. Seed resistance was conserved over consecutive generations (F2 to F5) and was successfully transferred to populations crossed with a second adapted field pea variety‘Helena’. Pod resistance presented as a quantitative trait in the F2 population, but this resistance was not retained in subsequent generations. Amplified fragment length polymorphisms (AFLPs) were sought in the parents and in resistant and susceptible F3 plants. Restricted maximum likelihood (REML) analysis was used to identify 13 AFLP markers with a statistically significant association with pea weevil resistance and 23 with pea weevil susceptibility. Principal coordinate analysis (PCO) showed that the AFLP marker loci formed clusters in the PCO space, which could indicate the three proposed gene locations. Eight AFLP markers were cloned, sequenced and converted to sequence characterised amplified regions (SCAR). Two SCAR markers, SC47359 and SC47435 were polymorphic between the resistant and susceptible parents. Both markers co-segregated with the resistant lines and with 30-36% of susceptible lines. Plants which did not possess either band were highly susceptible. The other PCR products were either monomorphic between the resistant and susceptible parents or produced more than one band product. A range of phenotypic traits was measured in the F2 population derived from the hybridisation between P. fulvum and P. sativum and associations with pea weevil resistance were made. In the F2 population, pea weevil resistance was not correlated with any of the negative traits originating from the wild parent, such as increased basal branching, dark seed coat or small seed size, neither was resistance correlated with flower colour, flowering time or seeds per pod. Pea weevil resistance should therefore be transferable with minimal linkage drag. A convenient morphological marker, such as flower or seed colour was not identified in this study based on these results. Using principal component analysis (PCA) as a visual tool, resistant and semi-resistant plants in the F3 and ‘backcross’ introgression populations were identified with improved trait performance compared with the wild parent

Pisum sativum

Pisum fulvum

Pea Weevil

Interspecific

Hybridisation

Breeding

Resistance

Inheritance

Relocating segregation : the Pea Island Life-Saving Station /

Caldwell, Jessica.

January 2006

Theses (M.A.)--Marshall University, 2006. / Includes abstract. Originally issued in electronic format. UMI number: 1434476. Includes bibliographical references (p. 100-108). Also available via the World Wide Web.