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         Mitochondrial Genetics:     more books (100)
  1. Mitochondrial Function and Biogenesis (Topics in Current Genetics)
  2. Genetics of Mitochondrial Diseases (Oxford Monographs on Medical Genetics)
  3. Human Mitochondrial DNA and the Evolution of Homo sapiens (Nucleic Acids and Molecular Biology)
  4. Mitochondrial Genetics and Cancer by Gabriel D. Dakubo, 2010-04-14
  5. The genetic function of mitochondrial DNA: Proceedings of the International Bari Conference on the Genetic Function of Mitochondrial DNA, Riva dei Tessali, Italy, 25-29 May, 1976 by C., and Kroon, A. M. Saccone, 1976
  6. Mitochondrial Biogenesis and Genetics, Part A (Methods in Enzymology, Vol. 260)
  7. Mitochondrial Biogenesis and Genetics, Part B, Volume 264 (Methods in Enzymology)
  8. Mitochondrial DNA: Methods and Protocols (Methods in Molecular Biology)
  9. Mitochondrial DNA Mutations in Aging, Disease & Cancer
  10. Mitochondrial Function and Biogenesis (Topics in Current Genetics)
  11. Genetic History of Europe: Genetic diversity, Mitochondrial DNA, Y chromosome, Autosome, Ancient DNA, Demography, Genetics, Paleolithic Europe, Last Glacial Maximum
  12. Human mitochondrial DNA haplogroup: Genetics, DNA, Mitochondrion, Nuclear DNA, Mitochondrial DNA, Ovum, Non-Mendelian inheritance, Mendelian inheritance, Paternal mtDNA transmission
  13. Genetic studies in Cameroon: mitochondrial DNA polymorphisms in Bamileke.: An article from: Human Biology by Rosaria Scozzari, Antonio Torroni, et all 1994-02-01
  14. Human mitochondrial genetics: Genetics, DNA, Mitochondrion, Nuclear DNA, Mitochondrial DNA, Ovum, Non-Mendelian inheritance, Mendelian inheritance, Paternal mtDNA transmission

1. ERIC A. SCHON
ERIC A. SCHON, Ph.D. mitochondrial genetics AND THE MOLECULAR BASIS OF HUMAN MITOCHONDRIAL DISEASE
http://cpmcnet.columbia.edu/dept/genetics/faculties/Schon.html
ERIC A. SCHON, Ph.D. Professor MITOCHONDRIAL GENETICS AND THE MOLECULAR BASIS OF HUMAN MITOCHONDRIAL DISEASE:
Mitochondria are unique among the constituents of the eukaryotic cell in that they are semi-autonomous organelles that contain their own genetic machinery. As such, they operate under the dual genetic controls of nuclear DNA (nDNA) and mitochondrial DNA (mtDNA). Mitochondrial genetics differs markedly from mendelian genetics, because first, mitochondria are inherited exclusively from the mother, and second, there are hundreds or thousands of mitochondria (and mtDNAs) per cell. In addition, organellar division and mtDNA replication are stochastic processes unrelated to the cell cycle, and mtDNA gene organization, DNA replication, RNA transcription, and protein translation all have a prokaryotic "look" about them. This latter feature is no surprise, given that mitochondria were once bacteria that were taken up by the proto-eukaryotic cell early in evolution. Biochemically, the most relevant aspect of mitochondrial function is the production of oxidative energy via the respiratory chain and oxidative phosphorylation. Mitochondrial diseases have turned out to be equally unusual. There are maternally-inherited, mendelian-inherited, sporadic, and even environmentally induced mitochondrial disorders, most of which are either severely debilitating or fatal. We are studying the molecular basis of a number of these diseases, most of which are heteroplasmic (i.e. both mutant and wild-type mtDNAs coexist in varying proportions in the same patient), using a novel tissue culture system called "r

2. LTU: Microbiology: Dictyostelium Mitochondrial Genetics Laboratory
Dr. Christian Barth Welcome to the Dictyostelium mitochondrial geneticsPage. Location mitochondrial genetics Laboratory Department
http://www.latrobe.edu.au/microbiology/barth.html
About LTU Faculties Campuses Research ... Our Research Mitochondrial Genetics Our Staff Seminars Site Map Web Links
Dr. Christian Barth
Welcome to the Dictyostelium Mitochondrial Genetics Page
Location:
Mitochondrial Genetics Laboratory
Department of Microbiology
La Trobe University, Victoria, 3086
AUSTRALIA
Contact Information:
Office Phone:
Lab Phone:
Fax:
E-mail:
C.Barth@latrobe.edu.au Click here to see Dr Christian Barth's CV Research Interests: Mitochondria are found in almost all eukaryotic cells. They are the powerhouse of the cell, generating energy in form of ATP, and have other important functions in haem and lipid biosynthesis, intracellular signal transduction and programmed cell death. According to the endosymbiotic hypothesis Although the number of proteins still encoded in the mitochondrial genome is relatively small, the organellar genome has to be maintained, replicated and transcribed, and the encoded gene products have to be synthesised on ribosomes in the mitochondrial matrix. The genetic processes involved are quite different from those in the nucleus and in the cytoplasm of the eukaryotic host - in fact they are strikingly similar to the genetic processes found in bacteria. However, the proteins that mediate mitochondrial replication, transcription and protein synthesis are now all nuclear-encoded.

3. Basic Genetics
The following article from the MDA has a great explanation of mitochondrial geneticsand can be found at http//www.mdausa.org/publications/Quest/q64mito.html.
http://www.umdf.org/mitodisease/genetics.html
The Genetics of Mitochondrial Disease
Autosomal Recessive Inheritance

Maternal Inheritance

X-linked Recessive Inheritance

Autosomal Dominant Inheritance
...
Sporadic
Introduction and Definition Unfortunately, the multiple diseases classified as mitochondrial disorders are inherited in different manners. In fact, nearly every inheritance "model" known has been demonstrated to occur in mitochondrial disease. However, most mitochondrial disorders known to date are inherited in either an autosomal recessive or maternal manner. The model of inheritance is important in that it can be helpful in answering the following questions:
  • Are other family members, either existing or not yet born, at risk for developing mitochondrial disease? What is the risk (percentage)? When will other affected relatives become ill? Will other affected relatives be as sick as my child/myself? Possibly even sicker? What kinds of problems/diseases might other affected relatives suffer from?
  • 4. NeuroCAST - Genetics And Diagnosis Of Mitochondrial Disorders
    This article is a brief review of mitochondrial genetics, disorders, and theirdiagnosis for neurologists, geneticists, genetic counselors, and other
    http://www.neurocast.com/site/content/sessions_02_2002.asp
    Mitochondria are the intracellular organelles that supply most of a cell's energy needs by producing adenosine triphosphate (ATP) through oxidative phosphorylation. More recently, mitochondria have also been found to play a central role in programmed cell death, or apoptosis. In addition to these well-known tasks, mitochondria are also responsible for a variety of other metabolic functions specific to the almost 250 different cell types in the human body. Mitochondria are unique organelles in that they contain their own DNA (mtDNA), which is distinct from the DNA in the cell nucleus (nDNA). Thus, proper mitochondrial function depends on the coordinated expression of both the nuclear and mitochondrial genomes and therefore, mitochondrial dysfunction can arise from mutations in either genome (Figure 1). This article is a brief review of mitochondrial genetics, disorders, and their diagnosis for neurologists, geneticists, genetic counselors, and other healthcare professionals involved in the care of people with complex neurological diseases that may be due to mitochondrial dysfunction. Figure 1.

    5. Mitochondrial Genetics
    English title mitochondrial genetics Swedish title Mitokondriell genetik Projectleader NilsGöran Larsson All projects by this author Institution Department
    http://research.kib.ki.se/e-uven/show_project.cfm?projects_no=K1974

    6. Mitochondrial Genetics
    How does a murine cell cope with loss of mitochondrial DNA? The Howis the mitochondrial transcription machinery regulated? How
    http://www.mednut.ki.se/research/ngl/mito.html
    How does a murine cell cope with loss of mitochondrial DNA? The answer is different depending on cell type, but the end is always the same; cell death. The group is situated at the Department of Medical Nutrition at Karolinska Institutet in Stockholm, the beautiful capital of Sweden. From being rather small, the team has expanded significantly during the last couple of years and now consists of five postdoctoral fellows, eight graduate students, one undergraduate student and one technical assistant. The research carried out in the laboratory is very diverse, but the main focus is on mitochondrial transcription and what happens when it is impaired. We have to date primarily worked with the nuclear encoded mitochondrial transcription factor A, Tfam, and what happens when this protein is lacking. Tfam is essential for mtDNA maintenance and loss of the Tfam protein leads to a complete loss of mtDNA. Oxidative phosphorylation, OXPHOS; is depending on mitochondrial encoded subunits to function, so the mitochondria are not able to produce ATP if mtDNA is gone. We have knocked out the Tfam gene from the entire mouse as well as in individual tissues such as skeletal muscle, heart, pancreas and brain. In all instances the affected cells cannot survive without the Tfam protein. For how long depends on the affected tissue and how early the knockout occurs.

    7. Mitochondrial Genetics Publications
    Increased mitochondrial mass in mitochondrial myopathy mice. Larsson NG. Leber hereditaryoptic neuropathy A nuclear solution of a mitochondrial problem.
    http://www.mednut.ki.se/research/ngl/pub.html
    List of publications Wredenberg A, Wibom R, Wilhelmsson H, Graff C, Wiener HH, Burden SJ, Oldfors A, Westerblad H, Larsson NG. Increased mitochondrial mass in mitochondrial myopathy mice. PNAS 2002 Nov 12; 99 (23):15066-15071 Larsson NG. Leber hereditary optic neuropathy: A nuclear solution of a mitochondrial problem. Ann Neurol 2002 Nov; 52(5):529-530 ... A single mouse gene encodes the mitochondrial transcription factor A and a testis-specific nuclear HMG-box protein. Nat Genet. 1996 Jul;13(3):296-302.

    8. Unique Challenges Mitochondrial Genetics Biology Of The
    Advanced Human Genetics. mitochondrial genetics (D. P. Nierlich)
    http://www.genetics.ucla.edu/home/class/1-18-01.pdf

    9. Genetics Department
    14. Hisheh,S., Schmitt,L and Westerman, M. (1998). Indonesian biogeographymitochondrial genetics of the fruit bat, Eonycteris spelaea. Biol.
    http://www.latrobe.edu.au/genetics/staff/westerman/homepage/
    About La Trobe Faculties Campuses Research ... International HomePage A.Prof. Michael Westerman BSc(Hons), PhD, DSc. (Birmingham). Reader in Marsupial Molecular Evolution My research interests centre primarily on the reconstruction and understanding of the phylogenetic relationships of marsupials using nuclear and mitochondrial DNA sequence data as well as chromosome banding and painting techniques.
    Molecular Phylogenetics of Dasyurids. The family dasyuridae includes over 65 species of carnivorous/insectivorous marsupials from Australia and New Guinea. They occupy almost all Australasian habitats from rainforests to the arid interior. Ongoing collaboration with Dr C.Krajewski (SIU, Carbondale,Illinois) is aimed at reconstructing phylogenetic relationships of all species using DNA sequences to help clarify palaeobiological questions as well as the evolution of reproductive strategies in the group. Currently we are utilising a series of nuclear genes to complement our extensive mitochondrial database for dasyurid species
    Detailed analysis (both of DNA sequences and allozymes) of the subfamily sminthopsinae has led to a reassessment of species relationships in this group and has revealed a great deal of previously unrecognised genetic diversity, including new species complexes.

    10. Mayo Clinic - Isaya Lab - Mitochondrial Genetics
    Isaya Lab mitochondrial genetics.
    http://www.mayo.edu/research/isayalab/
    Isaya Lab - Mitochondrial Genetics Research Isaya Lab
    Lab Directory

    Research Highlights
    ...
    Contact Information

    The Isaya Lab is located on the seventh floor of the Stabile Building.
    A look inside the lab
    The Lab Members
    Research
    Mitochondrial oxidative phosphorylation (OXPHOS) is the main source of ATP for the eukaryotic cell. OXPHOS, however, is also the main source of reactive oxygen species (ROS). As it turns out, OXPHOS is the most immediate target of ROS attack because biomolecules essential for OXPHOS activity such as mitochondrial DNA and iron-sulfur proteins are exquisitely susceptible to oxidative damage . This situation is exacerbated by the fact that OXPHOS biogenesis requires a continuous supply of iron-sulfur clusters and heme , which in turn depends on the availability of Fe , and redox-active iron can catalyze production of hydroxyl radical , OH , the most reactive oxygen species known. Our lab is interested in the mechanisms that enable the cell to exploit the energy efficiency of OXPHOS in spite of the risks inherent in ROS production. In particular, we are interested in the role played by components of the mitochondrial protein import machinery in OXPHOS maintenance. Another area of great interest to our lab are mitochondrial proteins involved in

    11. Mitochondrial Genetics
    RFLP analysis show that the phenotypic modifications and male sterility are associatedwith a pure Arabidopsis or a recombined mitochondrial genome containing
    http://www.vbiol.slu.se/tema/growth/CMS/21.html
    Principal Investigator s
    Kristina Glimelius

    Maria Landgren

    Postdoc
    Isabelle Farbos

    PhD students
    Matti Leino

    Rita Teixeira

    Technical assistant s
    Ingrid Eriksson
      Regulation of floral organogenesis and CMS in Brassica
      Brassica napus Arabidopsis thaliana somatic cybrids as a tool for investigating floral development and cytoplasmic male sterility (CMS)
      From protoplast fusions between Arabidopsis thaliana and Brassica napus (oil seed rape) alloplasmic lines have been produced. Several lines display modified and aberrant flower phenotypes with distorted petals and anthers. Most of these lines are also male sterile.
      Genetic characterizations of mitochondria using RFLP analysis show that the phenotypic modifications and male sterility are associated with a pure Arabidopsis or a recombined mitochondrial genome containing mtDNA from both species. Recurrent backcrosses are performed to obtain a stable nuclear Brassica napus genome. The aim is to find mitochondrial genes involved in the CMS trait and flower development. The availability of the complete Arabidopsis thaliana mitochondrial DNA sequence facilitates studies of mitochondrial gene expression by run-on and Northern experiments.

    12. Mitochondrial Genetics
    English title. mitochondrial genetics. Swedish title
    http://research.kib.ki.se/e-uven/public/K1974.html
    Research project #K1974
    English title Mitochondrial genetics Swedish title Mitokondriell genetik Project leader Nils-Göran Larsson All projects by this author Institution Department of Molecular Medicine All projects at this institution Description Safari Main
    Financing
    Pharmacia-Upjohn, MFR References
    Larsson NG, Wang J, Wilhelmsson H, Oldfors A, Rustin P, Lewandoski M, Barsh GS, Clayton DA. Mitochondrial transcription factor A is necessary for mtDNA maintenance and embryogenesis in mice.Nature Genetics 1998:18:231-236. Larsson NG, Garman JD, Oldfors A, Barsh GS, Clayton DA. A single mouse gene encodes the mitochondrial transcription factor A and a testis-specific nuclear HMG-box protein.Nature Genetics 1996:13:296-302. Project staff Caroline Graff Postdoc Jose Silva Postdoc Jianming Wang PhD student Anja Rantanen PhD studen Hong Li PhD studen Mats Ekstrand PhD studen Carita Holm Technichian Entered Updated
    news
    education research library ... about Karolinska Institutet Karolinska Institutet, SE-171 77 Stockholm, Sweden.
    Tel: +46-8-728 64 00, Fax: +46-8-31 11 01

    13. Flower Development & Mitochondrial Genetics
    Lines displaying modified and aberrant flower. phenotypes with distortedpetals and anthers. Normal Brassica napus. CMSline with shrunken anthers.
    http://www.vbiol.slu.se/tema/growth/CMS/lines
      Lines displaying modified and aberrant flower
      phenotypes with distorted petals and anthers
      Normal Brassica napus CMS-line with shrunken anthers CMS-line with anthers deformed to carpels Uppdaterad 000928 av Per.Bergman@vbiol.slu.se

    14. Mitochondrial Genetics
    mitochondrial genetics Mitochondria (mitochondrion, singular) are littleorganelles found in the cytoplasm of most cells. They are
    http://schools.sd68.bc.ca/ed611/phyllida/Mitochon_gen.htm
    Mitochondrial Genetics Mitochondria (mitochondrion, singular) are little organelles found in the cytoplasm of most cells. They are often referred to as the "power houses" of the cell because they are the sites of ATP (chemical energy) formation. Structually, mitochondria are bean shaped and are bounded by two membranes. The inner membrane is folded into cristae which is the site of ATP formation. Mitochondria possess their own circular (usually) DNA molecule in multiple copies. Mitochondrial DNA can be differentiated from nuclear DNA because it has a different base (examples of nitrogenous bases are adenine, thymine, cytosine and guanine) composition. Experiments have shown that the genes on mitochondrial DNA govern the normal structure and function of these organelles.

    15. Mitochondrial Genetics Innovations And Patents
    mitochondrial genetics Innovations and Patents More information on MitochondrialGenetics and mitochondrial genetics Research References.
    http://www.air.xq23.com/energy_science_resources/Mitochondrial_Genetics.html
    Mitochondrial Genetics Innovations and Patents © 2002, XQ23.COM Research (air.xq23.com)
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    kurt vonnegut arthur c clarke david brin ... Dialysis More information on: Mitochondrial Genetics and Mitochondrial Genetics Research References. Recent U.S. patents related to Mitochondrial Genetics: 5,989,557: Process for extracting polyphenol fractions of tea and compositions produced therewith : scattered data using color to represent values of a categorical variable 6,373,131: TBGA semiconductor package 6,372,842: Methods of using an aqueous composition containing a water-soluble or water-dispersible synthetic polymer and resultant compositions formed thereof 6,372,838: Fine latex and seed method of making 6,372,833: Fluorocarbon thermoplastic random copolymer composition curable at low temperatures 6,372,822: Methods and apparatus for producing and treating novel elastomer composites 6,372,700: Fluorinated solvent compositions containing ozone

    16. Genomic Disorders: Mutation Research, Genetic Disease
    Genomic Disorders Research Centre. mitochondrial genetics.
    http://www.genomic.unimelb.edu.au/pmito.html
    Genomic Disorders
    Research Centre
    Mitochondrial Genetics About Us Contact Us Support Us Research News Education Resource Centre Seminars Personnel Conferences
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    Dr. Ian Trounce joined the Centre in 1997 from the world's leading laboratory in this area. Numerous adult and children's disorders are caused by faults in the mitochondria and this work involves important collaborators across Melbourne. Using cell biology, genetic and biochemical approaches, we aim to improve our understanding of the variable clinical features of mitochondrial diseases to investigate mitochondrial function in neurodegenerative diseases, and create robust mtDNA mutation detection methods to define levels of somatic mtDNA mutations.
    Mechanisms of pathogenesis in mtDNA diseases
    Background: A major ongoing interest of the group has been to help define the cellular mechanisms underlying the extremely variable phenotypes seen in the mtDNA diseases. In particular we are interested in understanding the contributions of decreased ATP supply and increased oxidative stress, to pathology. We use cell culture methods including the transmission of mtDNAs of interest between cell lines (cybrid transfer), together with biochemical definition of key mitochondrial functions, especially oxidative phosphorylation and apoptosis. A major current project is to produce unique mouse models of mtDNA disease by introducing mtDNAs from different muridae species into mouse embryonic stem cells. In January 2001 we succeeded in producing chimeric animals from our transmitochondrial stem cells.

    17. J. Piskur - Mitochondrial Genetics Of The Genus Saccharomyces .
    93 28 09 mitochondrial genetics of the genus Saccharomyces. J. Piskur,C. Groth, M. Manuel and RF Petersen . Department of Genetics
    http://genome-www.stanford.edu/Saccharomyces/yeast96/f3028.html
    Yeast Genetics and Molecular Biology 1996
    Madison, Wisconsin
    August 1996
    Name: j. piskur .
    Mailing Address: Microbiology, DTU, Bldg. 301, 2800 Lyngby , Denmark
    Email Address: jurecph@biobase.dk
    Phone and Fax numbers:
    Mitochondrial genetics of the genus Saccharomyces
    J. Piskur, C. Groth, M. Manuel and R.F. Petersen . Department of Genetics, University of Copenhagen, Oester Farimagsgade 2A, 1353 Copenhagen K, Denmark The Saccharomyces cerevisiae mitochondrial genome (mtDNA) consists of coding regions, introns and intergenic regions. The intergenic sequences represent two-thirds of the genome and are made up of adenine-thymine streches and numerous guanosine-cytosine (G-C) clusters. These clusters are involved in the spontaneous breakdown of mtDNA leading to petite mutants and in the transmission of mtDNA to the progeny. In the present study we examined other yeast species in the genus Saccharomyces for the organization and transmission capacities of their mtDNAs. One group of yeasts, Saccharomyces sensu stricto, have mtDNAs that are larger than 60 kilo bases (kb) and contain many G-C clusters. The other group, Saccharomyces senso lato, contains smaller mtDNAs, ranging in size from 23 to 48 kb, and has almost no G-C clusters. The lower inducibility of petites arising in the

    18. Mitochondrial Genetics For Dummies
    Yo Mama mitochondrial genetics for Dummies. Another anthropologicalmystery solved with mitochondrial genetics is that of Polynesia.
    http://www.geocities.com/coligulosis/mtDNA.htm
    Yo Mama: Mitochondrial Genetics for Dummies Though I know that not everyone is as interested in stuff like this as I am, I want to provide a basic understanding of the topic for those who would like it. Plus I'm bored and a loser. That said, here is a slightly amended version of my I-Search paper (which, for those of you who don't know...was part of a semester long project all the 9th grade GATE people have to do) I know it's boring, but I think it's interesting...and you don't have to read it if you don't like. Also, take note that the paper was informal, and we had to talk about our search as well as our findings, but I ommited most of that cuz it's hella boring. And don't worry...the title of the page will be explained. What I Knew, Assumed, and Imagined What do mitochondria look like? Well...more less like this. This is a colorized electron micrograph found on the cover of the 5 March 1999 issue of Science. What I Learned My findings are varied and, I think, interesting. I discovered a lot about evolutionary studies in particular, but I also learned a lot about mitochondrial inheritance, diseases, and other aspects of mitochondrial genetics. Firstly, both chloroplasts, which serve much the same purpose in plants as mitochondria do in animals, and mitochondria were once, probably millions of years ago prokaryotic cells. These cells had an endosymbiotic relationship, a relationship in which both parties benefit, which allowed the eukaryotic cells to use sugars to create energy. Because of this, mitochondria, like bacteria, have their own set of DNA, but instead of the "x" shaped chromosomes of the nucleus, mitochondrial DNA is in the shape of a circle. The mitochondrial genome is 16,568 base pairs (bp) in length. As mitochondria produce ATP, their DNA, referred to as mtDNA, codes for the production of 13 different proteins involved in the process of producing ATP, called oxidative phosphorylation. The rest of the proteins involved in ATP production are coded for in the nucleus.

    19. C.elegans Mitochondrial Genetics
    ADP/ATP carrier protein. EC ADP/ATP transporter is the most abundant mitochondrialprotein, and is a member of the Mitochondrial transporter superfamily.
    http://www.sanger.ac.uk/Users/dl1/MTDNA_2.0/TEXT/ADP_ATP_translocase.html
    This user page is hosted by the Sanger Institute
    ADP/ATP carrier protein
    EC ADP/ATP transporter is the most abundant mitochondrial protein, and is a member of the Mitochondrial transporter super-family . The protein exchanges ATP in the matrix with ADP from the exterior of the mitochondrion. The functional protein consists of a dimer embedded asymmetrically in the inner mitochondrial membrane forming a gated pore through which ADP and ATP are exchanged. In metazoan systems it has been shown that a number of isoforms of the ADT are present, (2/3 in bovine and human respectiverly). These isoforms have distinct sequences and are expressed in a tissue-specific manner, thought to be linked to the energy requirement of the tissue type. Organism Gene C.elegans [temp-#01] H.sapiens B.taurus M.musculus R.norvegicus D.melanogaster S.cerevisiae S.pombe A.thaliana Alignments : Transporters Complexes ...
    dl1@sanger.ac.uk

    20. Main
    mitochondrial genetics (Wing 3.2). Head of Laboratory, Dr. BrigitteMeunier, PhD. Group Dr. Brigitte Meunier Group Leader, Research
    http://www.ucl.ac.uk/wibr/2/research/mito.htm
    Mitochondrial Genetics (Wing 3.2)
    Head of Laboratory, Dr. Brigitte Meunier, PhD Group: Dr. Brigitte Meunier Group Leader, Research Information and publications
    Group title:
    Mitochondrial Genetics,
    Member of the MRC Cooperative Group ' Mitochondria in Health and Disease'
    Brigitte Meunier, PhD - MRC Fellowship
    Amanda Brown, PhD - Syngenta
    Kate Castleden, PhD MRC grant
    Nick Fisher, PhD - BBSRC Research Project Philip Hill - BBSRC Studentship
    Susannah Horan - BBSRC CASE Studentship

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