A*STAR Scientists Identify Mutation That Causes Skin Hyperproliferation
News Oct 19, 2012
Scientists have identified a mutation in a gene that causes patches of very thick skin to appear on the palms and soles of affected people.
This skin disorder is related, albeit in a much milder form, to that of the Indonesian 'Tree Man', Dede Koswara. These thick rough skin patches on hands and feet steadily increase in number as a person ages and often coalesce to form larger lesions. In severe cases, these lesions can be painful and debilitating.
The team of scientists from A*STAR's Institute of Medical Biology (IMB), in collaboration with hospitals and research centres from the UK, Japan and Tunisia, found that this skin disorder, called punctate palmoplantar keratoderma (punctate PPK), is caused by mutations in the AAGAB gene.
Punctate PPK is a rare subtype of palmoplantar keratoderma (PPK), which appears in subtly different forms and seems to have several possible causes.
Several families in Singapore are afflicted by different types of PPKs and scientists at A*STAR have also been working with doctors at the National Skin Centre to understand the different forms of this skin disorder.
The identification of the gene mutation will help scientists to better understand the molecular basis of this disease and potentially lead to a suitable treatment.
This discovery will improve the classification and diagnosis of PPKs as well as open the door to novel approaches to treatment of skin disorders. These findings were published in the recent advanced online issue of Nature Genetics on 14th October.
The scientists analyzed DNA samples collected from 18 families from Scotland, Ireland, Japan and Tunisia who had punctate PPK. They showed that the AAGAB gene, which encodes the protein p34, was expressed in skin and had a role in the control of cell division.
The depletion in AAGAB led to a deficiency in p34, which resulted in increased cell proliferation in the outer layers of skin, the epidermis, because of an increased growth signal coming through the epidermal growth factor receptor (EGFR).
The disruption of EGFR signalling is a feature of abnormal cell proliferation and the discovery suggests that PPK may be a benign form of hyperproliferation.
Dr Bruno Reversade, Senior Principal Investigator at IMB, who is a member of the team said, "The study of rare genetic disorders can often provide unexpected links; the phenotype seen in punctate PPK patients bears striking resemblance to common warts, and it is tempting to speculate that HPV could also hijack the same pathways to induce skin hyperproliferation. This discovery also demonstrates that EGFR, a hallmark of skin cancer, is part of the molecular explanation of the over proliferation of lesions in PKK patients."
"Every time we find a new genetic mutation that causes a skin disorder, it helps patients and their families to demystify their condition," said Prof Birgitte Lane, Executive Director of IMB.
Prof Lane continued, "With scientists and doctors working towards common goals like this, we find better treatments for more and more of these rare conditions."
Mechanism Controlling Multiple Sclerosis Risk IdentifiedNews
Researchers at Karolinska Institutet have now discovered a new mechanism of a major risk gene for multiple sclerosis (MS) that triggers disease through so-called epigenetic regulation. They also found a protective genetic variant that reduces the risk for MS through the same mechanism.
Synthetic DNA Shuffling Enzyme Outpaces Natural CounterpartNews
A new synthetic enzyme, crafted from DNA rather than protein, flips lipid molecules within the cell membrane, triggering a signal pathway that could be harnessed to induce cell death in cancer cells. Researchers say their lipid-scrambling DNA enzyme is the first in its class to outperform naturally occurring enzymes – and does so by three orders of magnitudeREAD MORE
Antarctic Worm and Machine Learning Help Identify Cerebral Palsy EarlierNews
A research team has released a study in the peer-reviewed journal BMC Bioinformatics showing that DNA methylation patterns in circulating blood cells can be used to help identify spastic cerebral palsy (CP) patients. The technique which makes use of machine learning, data science and even analysis of Antarctic worms, raises hopes for earlier targeted CP therapies.