Professor Robert J Beynon BSc PhD FLSW

Biochemist, protein chemist (retired), solar powered bird photography

Alphabetical Site Map: Use this for a forensic look at what we do. The closest thing we have to an index! Links now work as they should. Thanks LogHound


- A -
A degrading synthesis of proteome turnover research!
A new lipocalin, fully sequenced, from bank voles
A proteomics workbench?
A-Z |
About me -
Absolute quantification by QconCAT
Acetone modifies peptides! Be careful if you're using acetone precipitation.
Amino acid playing cards
An unusual marsupial urinary lipocalin - vulpeculin
Asymetric equalisation with combinatorial beads
Avian Proteomics
- B -
Biomarkers of ragwort poisoning in horses
- C -
Canine MMP identification
Caught in a trap - proteomics of NETS
Cauxin in big cat urine
Challenging the 'MHC' hypothesis
Characterising proteins in scent marks
Chromatographic separation at the protein level
Cochrane review of McArdle disease
Complete de novo sequencing of a mouse lemur protein
Connective tissue proteomics
Contact with urinary proteins stimulates countermarking in male mice
Copper toxicity in sheep
Cross-species proteomics
CSF proteomics in bacterial meningitis
- D -
Darcin and the neural circuits it activates
Darcin in the news
Darcin NMR structure lodged
Darcin stimulates neurogenesis
Darcin three dimensional structure solved!
Derivatization for proteomics
Designer genes for mass spectrometry
Designing QconCATs for a mammalian pathway
Detailed protein analysis of the rat MUP complex
Double standards in proteomics
Dynamic SILAC for global assessment of proteome turnover
Dynamic sperm labelling
- E -
Enzyme turnover and metabolic regulation
Even the smallest of hamsters have lipocalins in their urine.
Extending Progenesis to embrace SILAC and Hi3
- F -
Familiarity breeds...?
First 'zap the crap', now 'Fry the fly': REIMS for insect identification
First paper describing QconCAT
First paper on a systematic analysis of MUP expression
First paper on dynamic SILAC in intact animals
First paper on proteome turnover
FPGA acceleration of proteomics data processing
FTICR based quantification
FTICR resolution of similar mass proteins
- G -
Genetics of individual MUP variation
Global cooling
Global proteome quantification: dreams or reality?
Global proteomics of carbon source metabolism in Saccharomyces
- H -
Hardware accelerated proteomics
Heparin binding proteome
- I -
Identification of an atypical male-specific MUP in mouse urine
Improving the quality of turnover measurement
Inbreeding and individual recognition
Inbreeding compromises competitor recognition
Individual recognition through MUPs
Influence of viruses on MUP production
Intact mass proteomics
Involatile ownership signals in mouse scent marks
Isoformer
Isolation of N-terminal peptides
It is a truth, universally acknowledged, that a mouse in possession of darcin must be in want of a mate.
- J -
- K -
- L -
Limited proteolysis
Limited proteolysis of MUPs
Limited proteolysis of native proteins
- M -
Many MUPs expressed by wild mice
March of the acronyms.. ALACATs (a la carte proteomics)
Mass spectrometry identification of proteins
McArdle disease
McArdle disease
McArdle disease Cochrane systematic review
McArdle disease treatments
Mechanisms of kin recognition
Metabolic labelling in proteomics
Metabolomics in canine hepatology
MHC in scent communication
MHC is not involved in individual recognition
MMP Zymography
MMP zymography
MS from gels, top down or bottom up
MUP complexity and analytical challenges
MUP heterogeneity
MUP ligand binding
MUP molecular heterogeneity
MUP polymorphic variants
MUP polymorphism & ligand binding
MUP polymorphism in an island population of mice
MUP variation in lab mouse strains
MUP variation in mouse subspecies
MUPs advertise heterozyygosity and fitness
MUPs and competitive scent marking
MUPs and MHC in mate choice
MUPs bind volatiles and extend the duration of odour signals
MUPs can take up ligands from the environment
MUPs in an aboriginal mouse
MUPs in individual recognition
MUPs play multiple roles in mouse communication
MUPs shape the volatile odours of mice
Muscle proteomics
Muscle proteomics: anabolic agent effects
Myths about MUPs
- N -
New paper on CSF proteomics in paediatric meningitis
News |
Nextgen QconCATs - MEERCAT!
- O -
Of mice, mups and mass spectrometry
On catnip and mosquitoes - solving an evolutionary puzzle
Overview of McArdle disease
Oxidative stress and MUPs
- P -
Parasite proteomics
Peptide map drawing tool
Peptide mapping tool
PFG Lab Opening
pH Buffers |
Pheromones and contextual information.
Photography |
Plasticity of the mouse seminal vesical fluid proteome
Positional proteomics and MetAP-2 substrates
Pre-eclampsia biomarkers
Prevention of proteolysis
PRIDE Datasets
Professor Rob Beynon, FLSW!
Protease inhibitors
Proteasome proteolysis
Protein binding in chemical communication
Protein turnover in a vertebrate
Proteome dynamics
Proteome dynamics in a non-model species - the challenges!
Proteome dynamics review
Proteome plasticity in sperm competition
Proteome turnover: why is it not being studied?
Proteomics and animal disease
Proteomics and animal disease
Proteomics and genome annotation
Proteomics and protein moonlighting
Proteomics in craniopharyngioma
Proteomics of a marine organism
Proteomics of copper effects in Ronaldsay sheep
Proteomics of copper toxicity
Proteomics of dystrophic muscle
Proteomics of epileptogenesis
Proteomics of growing muscle
Proteomics of HGF/EGF signalling
Proteomics of hippocampus in elipepsy
Proteomics of myofibroblasts
Proteomics of ocular cancer secretomes reveal malignancy potential
Proteomics of oxidative stress in mice
Proteomics of tissue samples
Proteomics suppporting supramolecular studies
Proteomics to identify galectin binding partners
Publications |
- Q -
QconCAT compared to label-free for plasma proteins
QconCAT for equine acute phase proteins
QconCAT protocols defined
QconCATs for mastitis research
QconCATs in equine wound healing
Quantification of a metabolic pathway
Quantification of proteins in the human osteoarthritic secretome
Quantitative analysis of the yeast 'chaperome'
Quantitative proteomics in systems biology
- R -
Rats have MUPs too - but different!
REIMS for the analysis of bacterial protein production
Removal of journal titles
Review of M4 proteases
Review of rodent urinary lipocalins
Review of thermolysins
Role of RNA polymerase III through proteomics
Romeo, Romeo, 'whiff'-fore art thou, Romeo?
- S -
Scent exposure influences competitive behaviour in lab mice
Scent marks signal competitive ability
Scent of sensecence
Scent signals of status
Scent wars
Schistosome parasite QconCAT
Secretome analysis of cancer cells
Seminal vesicle protein evolution
Sequential exoproteolysis is not valid as a structural probe
Sex pheromones are not aways attractive
Shall we rethink posters?
SIDLS: stable isotope labelling for secretome dynamics
Significance of animal scents in behaviour
Social status and mate choice
Soluble meprin alpha
Soluble urinary meprin
Speeding up proteomics with hardware computing solutions
Sperm proteomes, gone large
SRM data standards
Stable isotope labelling for identification
Strategies for dynamic SILAC
Structural comparison of central and peripheral mouse MUPs
Structure and asparagine deamidation
Synovial fluid proteomes
- T -
Tarui disease review
The avoidance of inbreeding
The biggest absolute quantification study ever! A tale of 100 QconCATs for nearly 2,000 proteins
The end of proteomics
The joys of running a training course!
Tools |
Treatment for McArdle disease
- U -
Unkind cuts - proteolysis and proteomics
Urinary lipocalins
Using protemics to define MMP7 processing
Using proteomics to explore 'pseudogene' expression
Using proteomics to identify targets for schistosomiasis
Using QconCATs to establish protein complex stoichiometry
Using stable isotopes to track sperm competition
- V -
Vitamin B6 and McArdle disease
- W -
Who's got the biggest workload? Analysis of chaperone abundance and workload
Whole animal protein turnover studies
Wild mice show much more MUP polymorphism than inbred lab mice
- X -
- Y -
Yeast complex proteomics
- Z -
Zap the crap! Using REIMS to obtain valuable information from animal faeces