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The Biomedical Relevance of Microbial Catabolic Diversity

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Title: The Biomedical Relevance of Microbial Catabolic Diversity


1
The Biomedical Relevance of Microbial Catabolic
Diversity
  • John Archer
  • Department of Genetics
  • University of Cambridge
  • j.archer_at_gen.cam.ac.uk

2
Free Radical Theory of Aging
  • Harman, 1956
  • Auto-oxidative damage ultimately impairs
    metabolic efficiency
  • Prediction promotion of oxidative reactions will
    correlate with reduced longevity
  • Genetic factors may promote oxidative stress

3
Metabolism
  • CellsnutrientO2-gt more cellsCO2H2O
  • Energy metabolism derive high energy compounds
    from carbon-energy source
  • Anabolism complexity of carbon-containing
    compounds increases
  • Catabolism complexity of carbon-containing
    compounds decreases
  • Enzyme-catalysed catabolism is highly sensitive
    to oxidative modification of substrate because
    modified substrates may not bind their cognate
    enzyme

4
Degenerative Molecular Markers Characteristics
  • Marker often formed by reactive oxygen species
  • Marker concentration should increase with age
  • Rate of accumulation of the marker should be
    inversely related to longevity of the organism
  • Genetic factors influence rate of accumulation
  • Aberrant accumulation of marker associated with
    pathology

5
Degenerative Molecular Markers Candidates
  • Lipofuscin
  • Ceroid-lipofuscin
  • Modified lipids (especially cholesterol) in foam
    cells leading to atherosclerosis
  • N-retinyl-N-retinylidene ethanolamine (A2E) in
    retinal pigment epithelial cells

6
Degenerative Markers or Causative Agent?
  • Lipofuscin may not be direct cause of aging. At
    moderate levels it has no effect on RER in
    neurons, but in high levels (75 of pericarion)
    is deleterious to neuronal adaptability. LSD are
    strongly linked to ceroid lipofuscin
    accumulation.
  • Atheroma is correlated with coronary disease and
    is a clear causative agent.
  • N-retinyl-N-retinylidene ethanolamine (A2E) in
    retinal pigment epithelial cells may have a role
    age-related macular degeneration

7
Enzyme Addition Therapy
  • Degenerative marker compounds accumulate because
    they are not substrates for normal lysosomal
    enzymes
  • Degenerative markers do not accumulate in the
    environment there must be enzymes which can
    process these molecules
  • Can one identify enzymes from other living
    systems that can recognise degenerative marker
    compounds?
  • Brady et al., mannose-terminal glucocerebrosidase
    treatment for Gaucher's Disease

8
The Substrate Lipofuscin
  • 30-70 protein (standard amino acids)
  • 20-50 lipid (triglycerides, fatty acids,
    cholesterol, phospholipids, dolichol,
    phosphorylated dolichol)
  • Fe, and other heavy metals
  • Autofluorescent compounds 1,4-dihydropyridines,
    2-hydroxy-1,2-dihydropyrrol-3-ones?
  • Resistant to lysosomal enzymes

9
Rhodococcus Metabolic Diversity
  • Rhodococcus harmless, Gram-positive Actinomycete
    mycolic acid bacterium
  • Genome is sequenced gt7 Mb
  • Thousands of catabolic genes, specific for a vast
    range of carbon-energy sources
  • Aliphatic, halogenated hydrocarbons, halogenated
    aromatics (pentachlorophenol), BTEX, PAH,
    Nitroaromatics, Lignin-related, alkoxy aromatics,
    terephthalates, heteroaromatics, steroids,
    dioxane, tetrahydrofuran etc. etc..

10
Isolation Protocol
  • Rhodococcus is an oligotrophic bacterium, highly
    adapted to catabolise complex, recalcitrant
    mixtures of substrates simultaneously (no
    catabolic repression)
  • Provide 80-100 microMolar lipofuscin as sole
    carbon-energy source to Rhodococcus strains.
    Incubate and score.

11
Rhodococcus Catabolism of Lipofuscin
  • Demonstrated Rhodococcus could utilise
    lipofuscin, or components of lipofuscin, as a
    carbon-energy source
  • Rhodococcus is a fungal-like bacterium, possesses
    membrane bound vesicles in which substrates are
    degraded by membrane associated enzyme complexes
  • It is very probable that the entire spectrum of
    lipofuscin can be metabolised by Rhodococcus
  • We propose that Rhodococcus can act as a source
    of xeno-enzymes to augment human metabolism

12
Atheroma
  • Macrophages enter artery wall to recycle modified
    lipoproteins entrapped
  • Recalcitrant modified lipoprotein products
    accumulate in foam cell lysosome
  • Lysosomal function impaired
  • Additional macrophage are recruited
  • Aberrant proliferative response by vascular
    smooth muscle cells
  • Formation of atherosclerotic plaque

13
Rhodococcus and Atherosclerosis
  • Rhodococcus can utilise cholesterol as a sole
    carbon-energy source
  • Both extracellular and intracellular membrane
    bound cholesterol oxidases are characterised
  • Reaction catalysed by cholesterol oxidase-
  • Cholesterol ---gt 4-cholesten-3-one
  • We propose that Rhodococcus can act as a source
    of xeno-enzymes to augment catabolism of
    atherosclerotic plaque

14
Supporting Indications
  • Cross-talk Problems
  • Substrate specificity of the bacterial
    xeno-enzyme will restrict the level of cross-talk
    between the bacterial enzyme and the human
    metabolism
  • Delivery to lysosomal compartment
  • Mannose-terminal glucocerebrosidase treatment of
    Gaucher's Disease
  • Lysosomal targeting by glycosylation
  • Acid pH of lysosomal compartment
  • Enzyme properties can be engineered in vitro
  • Immune response
  • Small sample data, but promising so far

15
Steps to Biomedical Application of Xenohydrolases
  • Isolate competent enzymes using a genomics
    approach
  • Engineer the recombinant protein for lysosomal
    targeting
  • Partner
  • Competence assay in cell system
  • Murine tests
  • Assay competence in disease models

16
Conclusions
  • Lipofuscin, a degenerative molecular marker and
    component of several lysosomal storage diseases
    can be catabolised completely or partially by
    enzyme(s) encoded by the bacterium Rhodococcus
  • Rhodococcus can catabolise several components of
    atheroma
  • It is highly likely that recalcitrant lysosomal
    components can be removed by xeno-enzyme treatment
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