X V I I V Í S I N D A R Á Ð S T E F N A H Í F Y L G I R I T 8 2 LÆKNAblaðið/Fylgirit 82 2015/101 67 proliferation of plasma cells in the bone marrow and overproduction of monoclonal immunoglobulins in serum or urine. Familial aggregation of MM has been reported by several authors but the underlying genetic cause of the disease is uncertain and the impact of family history on survival is unknown. The aim of our study was to compare survival in MM patients with family history of lymphoproliferative disorders (LPD) to MM patients without family history of LPD. Methods and data: MM patients and their first-degree relatives were identified using the nationwide Swedish Registries. Information on mal- ignancies in relatives of MM patients was obtained by record-linkages to the Swedish Cancer Registry. In statistical analysis all data were adjusted for age, sex and year at diagnosis. Results: A total of 13,926 MM patients diagnosed in 1957-2005 were included of whom 630 had a linkable first-degree relative, a total of 876 relatives. Compared to MM patients without family history, MM patients with family history had a significantly lower risk (HR 0.85; 95% CI 0.77-0.92, p<0.001) of death. The difference was greatest in the youngest age group (0.79; 0.65-0.96, p<0.05) and was more prominent in males than in females (1.20; 1.01-1.43, p<0.05). Conclusions: This large population-based study showed for the first time that survival in MM patients with family history of LPD was superior to MM patients without family history. The underlying expl- anations for our findings need to be established by further studies. V 31 The role of microRNA in gene regulation Linda Hrönn Sighvatsdóttir, Sigrún Guðjónsdóttir, Stefán Sigurðsson Biomedical Center, Faculty of Medicine, University of Iceland lhs4@hi.is Introduction: Gene expression by RNA polymerase II (RNAPII) is not exclusively regulated at the initiation step but also during the elongation phase of transcription. Specific transcription factors such as TCEA1 enhance transcription elongation by reactivating paused or stalled RNAPII, allowing transcription to proceed. Gene expression can also be regulated by microRNAs by their binding to the 3‘ untranslated (3´UTR) region of target mRNA. This binding of the microRNA to the 3´UTR of the mRNA results either in downregulation of protein translation or cleavage of the mRNA target. Our studies are aimed at studying the transcription elongation factor TCEA1, in particular its role in reactivating paused RNAPII and the role of microRNA in regulating TCEA1 expression. Methods and data: The 3´ UTR region of TCEA1 was cloned down- stream of a luciferase reporter. This reporter plasmid was co-transfected with different miRNA all found to have conserved binding sites in the 3´ UTR of TCEA1 based on microRNA and microRNA target databases. Endogeneous TCEA1 expression levels where also measured by using highly specific TCEA1 antibody. Results: We will present data that shows that TCEA1 expression is regulated by microRNA. This regulation is seen both when using the luciferase expression system as well as downregulation of endogenous TCEA1 measured by Western blotting. Conclusions: The microRNA family affecting TCEA1 expression is frequently found to be downregulated in various types of cancer. This raises a question regarding the role of TCEA1 in cancerous tissue, specifically the importance of efficient transcription elongation and gene expression. V 32 Algengi erfðabreytileika sem valda skorti í lektínferli komplímentkerfisins í íslenskum blóðgjöfum Margrét Arnardóttir1,2, Helga Bjarnadóttir1, Björn Rúnar Lúðvíksson1,2 1Ónæmisfræðideild Landspítala, 2læknadeild Háskóla Íslands margret84@gmail.com Inngangur: Lektínferill komplímentkerfisins (LP) er ræstur af mynstur- þekkjandi prótínum (PRPs). Þetta geta ýmist verið mannan-bindi lektín (MBL), fíkólín (1-3) eða kollektín-11 (CL-11). Í flóka með PRPs eru serín próteasar (MASPs (1-3)) og prótín án ensímvirkni (MAp1 og sMAP). Þekktar stökkbreytingar valda skorti í prótínum lektínferilsins. Einstaklingar með MBL2 arfgerðirnar O/O eða XA/O eru með MBL skort. Áhrif D120G samsætunnar í MASP2 geninu og 1637delC samsæt- unnar í FCN3 geninu á magn prótína í sermi er genaskammtaháð þannig að arfhreinir einstaklingar hafa ómælanlegt MASP-2 eða fíkólín-3 í sermi. Markmið þessarar rannsóknar var að meta algengi samsæta sem valda skorti í LP. Efniviður og aðferðir: Safnað var 500 blóðsýnum frá Blóðbankanum og DNA einangrað með hásaltsaðferð. Til að greina þekktar stökk- breytingar í MBL2 geninu (X/A/B/C/D) var framkvæmd rauntíma kjarnsýrumögnun (real-time PCR) með þekktri bræðslumarksgreiningu. Til að greina 1637delC var notast við skerðibútagreiningu. Til að greina D120G var notast við PCR-SSP (sequence specific primer PCR). Niðurstöður: Alls voru 498 blóðgjafar 1637delC og D120G arfgerða- greindir. Fimmtán (3%) greindust 1637delC arfblendnir (C/-) og 39 (7,8%) mældust D120G arfblendnir (D/G). Alls voru 494 einstaklingar arfgerðagreindir fyrir fimm stökkbreytingum í MBL2 geninu. Algengi arfgerða sem valda háum MBL styrk (YA/YA, XA/XA og YA/O) og arfgerða sem valda MBL skorti (XA/O og O/O) var 92,1% og 7,9%. Ályktanir: Áætlað algengi 1637delC og D120G samsætanna er því 0,015 og 0,041. Við getum reiknað með að um 1:4500 Íslendinga eru með fíkólín-3 skort (~70 einstaklingar) og 1:640 (~500) með MASP-2 skort. Niðurstöður okkar eru sambærilegar við genatíðni í sams konar þýðum. Hins vegar er algengi MBL skorts (7,9%) í okkar rannsóknum nokkuð lægri en í sambærilegum þýðum af hvítum evrópskum uppruna (16%). V 33 Lichen derived metabolites show synergistic effects with known cancer drugs against cancer cells Margrét Bessadóttir1,2, Edda A. Skúladóttir1, Sindri Baldursson1, Sesselja Ómarsdóttir2, Helga M. Ögmundsdóttir1 1Faculty of Medicine, University of Iceland, 2Faculty of Pharmaceutical Science, University of Iceland mab24@hi.is Introduction: Protolichesterinic acid (PA) is the major biologically active secondary metabolite of the lichen Cetraria islandica. PA has anti- proliferative effects on several types of cancer cells, but no effect on normal skin fibroblasts and is an inhibitor of 5- and 12-lipoxygenase (LOX). Usnic acid (UA) (from Cladonia arbuscula) has a wide range of biological activities, e.g. anti-inflammatory, anti-viral and anti-bacterial activity. UA affects pH gradients and inhibits growth and proliferation of several cancer cells. Fatty acid synthase (FASN) is up-regulated in a variety of cancers. Overexpression of human epidermal growth factor receptor 2 (HER2) has been linked to increased translation of FASN. The chemical structure of PA is very similar to a known FASN inhibitor, C75. FASN inhibition interacts synergistically with HER2 targeted drug (e.g. lapatinib) in breast cancer cells and can overcome resistance.

Qupperneq 1
Qupperneq 2
Qupperneq 3
Qupperneq 4
Qupperneq 5
Qupperneq 6
Qupperneq 7
Qupperneq 8
Qupperneq 9
Qupperneq 10
Qupperneq 11
Qupperneq 12
Qupperneq 13
Qupperneq 14
Qupperneq 15
Qupperneq 16
Qupperneq 17
Qupperneq 18
Qupperneq 19
Qupperneq 20
Qupperneq 21
Qupperneq 22
Qupperneq 23
Qupperneq 24
Qupperneq 25
Qupperneq 26
Qupperneq 27
Qupperneq 28
Qupperneq 29
Qupperneq 30
Qupperneq 31
Qupperneq 32
Qupperneq 33
Qupperneq 34
Qupperneq 35
Qupperneq 36
Qupperneq 37
Qupperneq 38
Qupperneq 39
Qupperneq 40
Qupperneq 41
Qupperneq 42
Qupperneq 43
Qupperneq 44
Qupperneq 45
Qupperneq 46
Qupperneq 47
Qupperneq 48
Qupperneq 49
Qupperneq 50
Qupperneq 51
Qupperneq 52
Qupperneq 53
Qupperneq 54
Qupperneq 55
Qupperneq 56
Qupperneq 57
Qupperneq 58
Qupperneq 59
Qupperneq 60
Qupperneq 61
Qupperneq 62
Qupperneq 63
Qupperneq 64
Qupperneq 65
Qupperneq 66
Qupperneq 67
Qupperneq 68
Qupperneq 69
Qupperneq 70
Qupperneq 71
Qupperneq 72
Qupperneq 73
Qupperneq 74
Qupperneq 75
Qupperneq 76
Qupperneq 77
Qupperneq 78
Qupperneq 79
Qupperneq 80
Qupperneq 81
Qupperneq 82
Qupperneq 83
Qupperneq 84
Qupperneq 85
Qupperneq 86
Qupperneq 87
Qupperneq 88
Qupperneq 89
Qupperneq 90
Qupperneq 91
Qupperneq 92
Qupperneq 93
Qupperneq 94
Qupperneq 95
Qupperneq 96
Qupperneq 97
Qupperneq 98
Qupperneq 99
Qupperneq 100
Qupperneq 101
Qupperneq 102
Qupperneq 103
Qupperneq 104
Qupperneq 105
Qupperneq 106
Qupperneq 107
Qupperneq 108
Qupperneq 109
Qupperneq 110
Qupperneq 111
Qupperneq 112
Qupperneq 113
Qupperneq 114
Qupperneq 115
Qupperneq 116
Qupperneq 117
Qupperneq 118
Qupperneq 119
Qupperneq 120
Qupperneq 121
Qupperneq 122
Qupperneq 123
Qupperneq 124
Qupperneq 125
Qupperneq 126
Qupperneq 127
Qupperneq 128
Qupperneq 129
Qupperneq 130
Qupperneq 131
Qupperneq 132
Qupperneq 133
Qupperneq 134
Qupperneq 135
Qupperneq 136
Qupperneq 137
Qupperneq 138
Qupperneq 139
Qupperneq 140
Qupperneq 141
Qupperneq 142
Qupperneq 143
Qupperneq 144
Qupperneq 145
Qupperneq 146
Qupperneq 147
Qupperneq 148
Qupperneq 149
Qupperneq 150
Qupperneq 151
Qupperneq 152
Qupperneq 153
Qupperneq 154
Qupperneq 155
Qupperneq 156
Qupperneq 157
Qupperneq 158
Qupperneq 159
Qupperneq 160
Qupperneq 161
Qupperneq 162
Qupperneq 163
Qupperneq 164
Qupperneq 165
Qupperneq 166
Qupperneq 167
Qupperneq 168
Qupperneq 169
Qupperneq 170
Qupperneq 171
Qupperneq 172
Qupperneq 173